[go: up one dir, main page]
More Web Proxy on the site http://driver.im/

EP1455816A2 - Hla class i and ii binding peptides and their uses - Google Patents

Hla class i and ii binding peptides and their uses

Info

Publication number
EP1455816A2
EP1455816A2 EP01274676A EP01274676A EP1455816A2 EP 1455816 A2 EP1455816 A2 EP 1455816A2 EP 01274676 A EP01274676 A EP 01274676A EP 01274676 A EP01274676 A EP 01274676A EP 1455816 A2 EP1455816 A2 EP 1455816A2
Authority
EP
European Patent Office
Prior art keywords
nef
hiv
peptide
hγv
psm
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Withdrawn
Application number
EP01274676A
Other languages
German (de)
French (fr)
Other versions
EP1455816A4 (en
Inventor
Alessandro Sette
John Sidney
Scott Southwood
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Pharmexa Inc
Original Assignee
Epimmune Inc
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Epimmune Inc filed Critical Epimmune Inc
Priority to EP07023116A priority Critical patent/EP1911461B1/en
Publication of EP1455816A2 publication Critical patent/EP1455816A2/en
Publication of EP1455816A4 publication Critical patent/EP1455816A4/en
Withdrawn legal-status Critical Current

Links

Classifications

    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61KPREPARATIONS FOR MEDICAL, DENTAL OR TOILETRY PURPOSES
    • A61K39/00Medicinal preparations containing antigens or antibodies
    • A61K39/385Haptens or antigens, bound to carriers
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61PSPECIFIC THERAPEUTIC ACTIVITY OF CHEMICAL COMPOUNDS OR MEDICINAL PREPARATIONS
    • A61P35/00Antineoplastic agents
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61KPREPARATIONS FOR MEDICAL, DENTAL OR TOILETRY PURPOSES
    • A61K39/00Medicinal preparations containing antigens or antibodies
    • A61K2039/51Medicinal preparations containing antigens or antibodies comprising whole cells, viruses or DNA/RNA
    • A61K2039/515Animal cells
    • A61K2039/5154Antigen presenting cells [APCs], e.g. dendritic cells or macrophages
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61KPREPARATIONS FOR MEDICAL, DENTAL OR TOILETRY PURPOSES
    • A61K39/00Medicinal preparations containing antigens or antibodies
    • A61K2039/51Medicinal preparations containing antigens or antibodies comprising whole cells, viruses or DNA/RNA
    • A61K2039/515Animal cells
    • A61K2039/5158Antigen-pulsed cells, e.g. T-cells
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61KPREPARATIONS FOR MEDICAL, DENTAL OR TOILETRY PURPOSES
    • A61K39/00Medicinal preparations containing antigens or antibodies
    • A61K2039/60Medicinal preparations containing antigens or antibodies characteristics by the carrier linked to the antigen
    • A61K2039/6031Proteins
    • A61K2039/605MHC molecules or ligands thereof

Definitions

  • the present invention relates to compositions and methods for preventing, treating or diagnosing a number of pathological states such as viral diseases and cancers.
  • MHC major histocompatibility complex
  • MHC molecules are classified as either class I or class II molecules.
  • Class II MHC molecules are expressed primarily on cells involved in initiating and sustaining immune responses, such as T lymphocytes, B lymphocytes, macrophages, etc.
  • Class II MHC molecules are recognized by helper T lymphocytes and induce proliferation of helper T lymphocytes and amplification of the immune response to the particular immunogenic peptide that is displayed.
  • Class I MHC molecules are expressed on almost all nucleated cells and are recognized by cytotoxic T lymphocytes (CTLs), which then destroy the antigen-bearing cells. CTLs are particularly important in tumor rejection and in fighting viral infections.
  • CTLs cytotoxic T lymphocytes
  • the CTL recognizes the antigen in the form of a peptide fragment bound to the MHC class I molecules rather than the intact foreign antigen itself.
  • the antigen must normally be endogenously synthesized by the cell, and a portion of the protein antigen is degraded into small peptide fragments in the cytoplasm. Some of these small peptides translocate into a pre-Golgi compartment and interact with class I heavy chains to facilitate proper folding and association with the subunit ⁇ microglobulin.
  • the peptide-MHC class I complex is then routed to the cell surface for expression and potential recognition by specific CTLs.
  • a complex of an HLA molecule and a peptidic antigen acts as the ligand recognized by HLA-restricted T cells (Buus, S.
  • Peptides of the present invention may also comprise epitopes that bind to HLA class II DR molecules.
  • This increased heterogeneity of HLA class II peptide ligands is due to the structure of the binding groove of the HLA class II molecule which, unlike its class I counterpart, is open at both ends. Crystallographic analysis of HLA class II DRB*0101- peptide complexes showed that the major energy of binding is contributed by peptide residues complexed with complementary pockets on the DRB*0101 molecules.
  • PI position 1
  • PI may represent the N-terminal residue of a class II binding peptide epitope, but more typically is flanked towards the N-terminus by one or more residues.
  • Other studies have also pointed to an important role for the peptide residue in the 6 th position towards the C- terminus, relative to P 1 , for binding to various DR molecules.
  • HLA class I and class II molecules can be classified into a relatively few supertypes, each characterized by largely overlapping peptide binding repertoires, and consensus structures of the main peptide binding pockets.
  • peptides of the present invention are identified by any one of several HLA-specific amino acid motifs, or if the presence of the motif corresponds to the ability to bind several allele-specific HLA molecules, a supermotif.
  • the HLA molecules that bind to peptides that possess a particular amino acid supermotif are collectively referred to as an HLA "supertype.”
  • class I and class II allele-specific HLA binding motifs allows identification of regions within a protein that have the potential of binding particular HLA molecules.
  • compositions comprising immunogenic peptides having allele-specific binding motifs, such as binding motifs for HLA-A2.1 molecules.
  • immunogenic peptides having allele-specific binding motifs, such as binding motifs for HLA-A2.1 molecules.
  • the peptides typically comprise epitopes from 8-11 amino acids in length, often 9 to 10 residues in length, that comprise conserved residues at certain positions such as positions
  • the peptides preferably do not comprise negative binding residues as defined herein at other positions such as, in an HLA-A2.1 motif-bearing epitope, positions 1, 3, 6 and/or 7 in the case of peptides 9 amino acids in length and positions 1, 3, 4, 5, 7, 8 and or 9 in the case of peptides 10 amino acids in length.
  • the peptides typically comprise a motif of 6 to about 25 amino acids for a class II HLA motif, typically, 9 to 13 amino acids in length, which is recognized by a particular HLA molecule.
  • TRP1 and TRP tumor-associated antigens
  • suitable antigens include tumor-associated antigens such as tyrosinase related proteins 1 and 2 (TRP1 and TRP), which are frequently associated with melanoma; MARTI, p53, carcinoembryonic antigen (CEA), Her2/neu, and MAGE, including MAGE1, MAGE2, and MAGE3, which are expressed on abroad range of tumors; prostate cancer-associated antigens such as prostate specific antigen (PSA), human kallikrein (huK2), prostate specific membrane antigen (PSM), and prostatic acid phosphatase (PAP); antigens from viruses such as hepatitis B (e.g., HBV core and surface antigens (HBVc, HBVs)) hepatitis C (HCV), Epstein-Barr virus, human immunodeficiency type-1 virus (HIV1), Kaposi's sarcoma herpe
  • viruses such as hepatitis B (e.g.
  • peptide is used interchangeably with “oligopeptide” in the present specification to designate a series of residues, typically L-amino acids, connected one to the other, typically by peptide bonds between the ⁇ -amino and carboxyl groups of adjacent amino acids.
  • the preferred CTL-inducing peptides of the invention are 13 residues or less in length and usually consist of between about 8 and about 11 residues, preferably 9 or 10 residues.
  • an epitope is a set of amino acid residues which is involved in recognition by a particular immunoglobulin, or in the context of T cells, those residues necessary for recognition by T cell receptor proteins and/or Major Histocompatibility Complex (MHC) receptors, h an immune system setting, in vivo or in vitro, an epitope is the collective features of a molecule, such as primary, secondary and tertiary peptide structure, and charge, that together form a site recognized by an immunoglobulin, T cell receptor or HLA molecule. Throughout this disclosure epitope and peptide are often used interchangeably.
  • protein or peptide molecules that comprise an epitope of the invention as well as additional amino acid(s) are still within the bounds of the invention.
  • there is a limitation on the length of a peptide of the invention. The embodiment that is length-limited occurs when the protein peptide comprising an epitope of the invention comprises a region (i.e., a contiguous series of amino acids) having 100% identity with a native sequence.
  • a region i.e., a contiguous series of amino acids
  • an "epitope" of the invention is comprised by a peptide having a region with less than 51 amino. acids that has 100% identity to a native peptide sequence, in any increment down to 5 amino acids.
  • peptide or protein sequences longer than 600 amino acids are within the scope of the invention, so long as they do not comprise any contiguous sequence of more than 600 amino acids that have 100% identity with a native peptide sequence.
  • a CTL epitope be less than 600 residues long in any increment down to eight amino acid residues.
  • immunogenic peptide or “peptide epitope” is a peptide that comprises an allele-specific motif or supermotif such that the peptide will bind an HLA molecule and induce a CTL.
  • immunogenic peptides of the invention are capable of binding to an appropriate HLA molecule and thereafter inducing a cytotoxic T cell response to the antigen from which the immunogenic peptide is derived.
  • a derived epitope when used to discuss an epitope is a synonym for "prepared."
  • a derived epitope can be isolated from a natural source, or it can be synthesized in accordance with standard protocols in the art.
  • Synthetic epitopes can comprise artificial amino acids "amino acid mimetics,” such as D isomers of natural occurring L amino acids or non-natural amino acids such as cyclohexylalanine.
  • a derived/prepared epitope can be an analog of a native epitope.
  • Immunogenic peptides are conveniently identified using the algorithms of the invention.
  • the algorithms are mathematical procedures that produce a score which enables the selection of immunogenic peptides.
  • the algorithm is based upon either the effects on MHC binding of a particular amino acid at a particular position of a peptide or the effects on binding of a particular substitution in a motif containing peptide.
  • a binding affinity threshold associated with immunogenicity has been determined for HLA Class I.
  • a threshold binding affinity of about 500 nM or less typically determines the capacity of a peptide epitope to elicit a CTL response.
  • "high affinity” with respect to HLA class I molecules is defined as binding with an IC 50 , or K D value, of 50 nM or less; “intermediate affinity” is binding with an IC 50 or K D value of between about 50 and about 500 nM.
  • "High affinity” with respect to binding to HLA class II molecules is defined as binding with an IC 50 or K D value of 100 nM or less; “intermediate affinity” is binding with an IC 50 or K D value of between about 100 and about 1000 nM.
  • IC 50 is the concentration of peptide in a binding assay at which 50% inhibition of binding of a reference peptide is observed. Given the conditions in which the assays are run (i.e., limiting HLA proteins and labeled peptide concentrations), these values approximate K D values. Assays for determining binding are described in detail, e.g., in PCT publications WO 94/20127 and WO 94/03205. It should be noted that IC 50 values can change, often dramatically, if the assay conditions are varied, and depending on the particular reagents used (e.g., HLA preparation, etc.). For example, excessive concentrations of HLA molecules will increase the apparent measured IC 50 of a given ligand. Alternatively, binding is expressed relative to a reference peptide.
  • the ICso's of the peptides tested may change somewhat, the binding relative to the reference peptide will not significantly change.
  • the assessment of whether a peptide is a good, intermediate, weak, or negative binder is generally based on its IC 50 , relative to the IC 50 of a standard peptide.
  • Binding may also be determined using other assay systems including those using: live cells (e.g., Ceppellini et al, Nature 339:392 (1989); Christnick et al, Nature 352:67 (1991); Busch et al, Int. Immunol. 2:443 (1990); Hill et al, J. Immunol. 147:189 (1991); del Guercio et al, J. Immunol. 154:685 (1995)), cell free systems using detergent lysates (e.g., Cerundolo et al, J. Immunol 21:2069 (1991)), immobilized purified MHC (e.g., Hill et al, J. Immunol.
  • live cells e.g., Ceppellini et al, Nature 339:392 (1989); Christnick et al, Nature 352:67 (1991); Busch et al, Int. Immunol. 2:443 (1990); Hill e
  • a "conserved residue” is an amino acid which occurs in a significantly higher frequency than would be expected by random distribution at a particular position in a peptide. Typically a conserved residue is one where the MHC structure may provide a contact point with the immunogenic peptide.
  • At least one to three or more, preferably two, conserved residues within a peptide of defined length defines a motif for an immunogenic peptide. These residues are typically in close contact with the peptide binding groove, with their side chains buried in specific pockets of the groove itself. Typically, an immunogenic peptide will comprise up to three conserved residues, more usually two conserved residues.
  • negative binding residues are amino acids which if present at certain positions (for example, positions 1, 3 and/or 7 of a 9-mer) will result in a peptide being a nonbinder or poor binder and in turn fail to be immunogenic i.e. induce a CTL response.
  • motif refers to the pattern of residues in a peptide of defined length, usually a peptide of from about 8 to about 13 amino acids, often 8 to 11 amino acids, for a class I HLA motif and from about 6 to about 25 amino acids for a class II HLA motif, which is recognized by a particular HLA molecule.
  • Peptide motifs are typically different for each protein encoded by each human HLA allele and differ in the pattern of the primary and secondary anchor residues.
  • the binding motif for an allele can be defined with increasing degrees of precision, hi one case, all of the conserved residues are present in the correct positions in a peptide and there are no negative residues in positions 1 ,3 and/or 7.
  • a "supermotif is a peptide binding specificity shared by HLA molecules encoded by two or more HLA alleles.
  • a supermotif-bearing peptide is recognized with high or intermediate affinity (as defined herein) by two or more HLA molecules.
  • An "HLA supertype or family”, as used herein, describes sets of HLA molecules grouped on the basis of shared peptide-binding specificities. HLA class I molecules that share somewhat similar binding affinity for peptides bearing certain amino acid motifs are grouped into HLA supertypes.
  • the terms HLA superfamily, HLA supertype family, HLA family, and HLA xx-like molecules are synonyms.
  • Heteroclitic analogs are defined herein as a peptide with increased potency for a specific T cell, as measured by increased responses to a given dose, or by a requirement of lesser amounts to achieve the same response as a homologous native class I peptide. Advantages of heteroclitic analogs include that the antigens can be more potent, or more economical (since a lower amount is required to achieve the same effect as a homologous class I peptide). In addition, heteroclitic analogs are also useful to overcome antigen-specific T cell unresponsiveness (T cell tolerance).
  • isolated or “biologically pure” refer to material which is substantially or essentially free from components which normally accompany it as found in its native state.
  • the peptides of this invention do not contain materials normally associated with their in situ environment, e.g., MHC I molecules on antigen presenting cells. Even where a protein has been isolated to a homogenous or dominant band, there are trace contaminants in the range of 5-10% of native protein which co-purify with the desired protein. Isolated peptides of this invention do not contain such endogenous co- purified protein.
  • residue refers to an amino acid or amino acid mimetic incorporated in an oligopeptide by an amide bond or amide bond mimetic.
  • Link refers to any method known in the art for functionally connecting peptides, including, without limitation, recombinant fusion, covalent bonding, disulfide bonding, ionic bonding, hydrogen bonding, and electrostatic bonding.
  • “Pharmaceutically acceptable” refers to a generally non-toxic, inert, and/or physiologically compatible composition.
  • a “pharmaceutical excipient” comprises a material such as an adjuvant, a carrier, pH-adjusting and buffering agents, tonicity adjusting agents, wetting agents, preservatives, and the like.
  • Synthetic peptide refers to a peptide that is not naturally occurring, but is man-made using such methods as chemical synthesis or recombinant DNA technology.
  • a "non-native” sequence or “construct” refers to a sequence that is not found in nature, i.e., is “non-naturally occurring”. Such sequences include, e.g., peptides that are lipidated or otherwise modified, and polyepitopic compositions that contain epitopes that are not contiguous in a native protein sequence.
  • a "vaccine” is a composition that contains one or more peptides of the invention.
  • vaccines in accordance with the invention, such as by a cocktail of one or more peptides; one or more epitopes of the invention comprised by a polyepitopic peptide; or nucleic acids that encode such peptides or polypeptides, e.g., a minigene that encodes a polyepitopic peptide.
  • the "one or more peptides” can include any whole unit integer from 1-150, e.g., at least 2, 3, 4, 5, 6, 1, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40 , 45, 50, 55, 60, 65, 70, 75, 80, 85, 90, 95, 100, 105, 110, 115, 120, 125, 130, 135, 140, 145, or 150 or more peptides of the invention.
  • the peptides or polypeptides can optionally be modified, such as by lipidation, addition of targeting or other sequences.
  • HLA class I-binding peptides of the invention can be admixed with, or linked to, HLA class II-binding peptides, to facilitate activation of both cytotoxic T lymphocytes and helper T lymphocytes.
  • Vaccines can also comprise peptide- pulsed antigen presenting cells, e.g., dendritic cells.
  • each residue is generally represented by standard three letter or single letter designations.
  • the L-form of an amino acid residue is represented by a capital single letter or a capital first letter of a three-letter symbol, and the D-form for those amino acids having D-forms is represented by a lower case single letter or a lower case three letter symbol.
  • Glycine has no asymmetric carbon atom and is simply referred to as "Gly" or G.
  • the present invention relates to the determination of allele-specific peptide motifs for human class I and class II allele subtypes. These motifs are then used to define T cell epitopes from any desired antigen, particularly those associated with human viral diseases, cancers or autoiummune diseases, for which the amino acid sequence of the potential antigen or autoantigen targets is known.
  • the application of supermotifs and motifs and binding analysis to the identification of epitopes is described in WOOl/21189 and co-pending U.S.
  • antigens include tumor- associated antigens such as TRP1, p53, CEA, Her2/neu, and MAGE, including MAGE1, MAGE2, and MAGE3; prostate cancer-associated antigens such as prostate specific antigen (PSA), human kallikrein (huK2), prostate specific membrane antigen (PSM), and prostatic acid phosphatase (PAP); antigens from viruses such as hepatitis B (e.g., HBV core and surface antigens (HBVc, HBVs)) hepatitis C, Epstein-Barr virus, human immunodeficiency type-1 virus (HIV1), Kaposi's sarcoma herpes (KSHV), human papilloma virus (HPV), influenza virus, and Lassa virus antigens, Mycobacterium tuberculosis (MT) antigens, trypanosome, e.g., Ti ⁇ pansoma cruzi (T. cruzi), antigens such as surface antigen (TSA), tumor-
  • Peptides comprising the epitopes from these antigens are synthesized and then tested for their ability to bind to the appropriate MHC molecules in assays using, for example, purified class I molecules and radioiodonated peptides and/or cells expressing empty class I molecules by, for instance, immunofluorescent staining and flow microfluorometry, peptide-dependent class I assembly assays, and inhibition of CTL recognition by peptide competition.
  • Those peptides that bind to the class I molecule are further evaluated for their ability to serve as targets for CTLs derived from infected or immunized individuals, as well as for their capacity to induce primary in vitro or in vivo CTL responses that can give rise to CTL populations capable of reacting with virally infected target cells or tumor cells as potential therapeutic agents.
  • HLA class I antigens are encoded by the HLA- A, B, and C loci.
  • HLA-A and B antigens are expressed at the cell surface at approximately equal densities, whereas the expression of HLA-C is significantly lower (perhaps as much as 10-fold lower).
  • Each of these loci have a number of alleles.
  • the peptide binding motifs of the invention are relatively specific for each allelic subtype.
  • the peptides of the present invention preferably comprise a supermotif and/or motif recognized by an HLA I or HLA II molecule having a wide distribution in the human population.
  • Immunogenic peptides of interest for vaccine compositions preferably include those that have an IC 50 or binding affinity value for a class I HLA molecule(s) of 500 nM or better (i.e., the value is ⁇ 500 nM) or, for class II HLA molecules, 1000 nM or better (i.e., the value is ⁇ 1000 nM).
  • peptide binding is assessed by testing the capacity of a candidate peptide to bind to a purified HLA molecule in vitro. Peptides exhibiting high or intermediate affinity are then considered for further analysis. Selected peptides are generally tested on other members of the supertype family, h preferred embodiments, peptides that exhibit cross-reactive binding are then used in cellular screening analyses or vaccines.
  • Immunogenicity corresponds to whether an immune response is elicited at all, and to the vigor of any particular response, as well as to the extent of a population in which a response is elicited.
  • a peptide might elicit an immune response in a diverse array of the population, yet in no instance produce a vigorous response, h accordance with these principles, close to 90% of high binding peptides have been found to elicit a response and thus be "immunogenic," as contrasted with about 50% of the peptides that bind with intermediate affinity.
  • binding affinity and immunogenicity was analyzed by the present inventors by two different experimental approaches (see, e.g., Sette, et al, J. Immunol. 153:5586-5592 (1994)).
  • first approach the immunogenicity of potential epitopes ranging in HLA binding affinity over a 10,000-fold range was analyzed in HLA-A*0201 transgenic mice.
  • second approach the antigenicity of approximately 100 different hepatitis B virus (HBV)-derived potential epitopes, all carrying A*0201 binding motifs, was assessed by using PBL from acute hepatitis patients.
  • HBV hepatitis B virus
  • an affinity threshold value of approximately 500 nM determines the capacity of a peptide epitope to elicit a CTL response.
  • DR restriction was associated with high binding affinities, i.e. binding affinity values of 100 nM or less. In the other half of the cases (16 of 32), DR restriction was associated with intermediate affinity (binding affinity values in the 100-1000 nM range), h only one of 32 cases was DR restriction associated with an IC 50 of 1000 nM or greater.
  • 1000 11M can be defined as an affinity threshold associated with immunogenicity in the context of DR molecules.
  • motifs that are predictive of binding to specific class I and class II alleles allows the identification of potential peptide epitopes from an antigenic protein whose amino acid sequence is known. Typically, identification of potential peptide epitopes is initially carried out using a computer to scan the amino acid sequence of a desired antigen for the presence of motifs and/or supermotifs.
  • HLA Class I Motifs indicative of CTL Inducing Peptide Epitopes The primary anchor residues of the HLA class I peptide epitope supermotifs and motifs are delineated below. In some cases, peptide epitopes may be listed in both a motif and a supermotif Table. The relationship of a articular motif and respective supermotif is indicated in the description of the individual motifs.
  • the HLA-A1 supermotif is characterized by the presence in peptide ligands of a small (T or S) or hydrophobic (L, I, V, or M) primary anchor residue in position 2, and an aromatic (Y, F, or W) primary anchor residue at the C-terminal position of the epitope.
  • the corresponding family of HLA molecules that bind to the Al supermotif i.e., the HLA-A1 supertype
  • is comprised of at least A*0101, A*2601, A*2602, A*2501, and A*3201 see, e.g., DiBrino, M. et al, J. Immunol. 151:5930, 1993; DiBrino, M. et al, J.
  • HLA-A2 supermotif which presence in peptide ligands corresponds to the ability to bind several different HLA-A2 and -A28 molecules.
  • the HLA-A2 supermotif comprises peptide ligands with L, I, V, M, A, T, or Q as a primary anchor residue at position 2 and L, I, V, M, A, or T as a primary anchor residue at the C- terminal position of the epitope.
  • the corresponding family of HLA molecules i. e.
  • the HLA- A2 supertype that binds these peptides is comprised of at least: A*0201, A*0202, A*0203, A*0204, A*0205, A*0206, A*0207, A*0209, A*0214, A*6802, and A*6901.
  • Other allele-specific HLA molecules predicted to be members of the A2 superfamily are shown in Table 1.
  • binding to each of the individual allele-specific HLA molecules can be modulated by substitutions at the primary anchor and/or secondary anchor positions, preferably choosing respective residues specified for the supermotif.
  • the HLA- A3 supermotif is characterized by the presence in peptide ligands of A, L, I, V, M, S, or, T as a primary anchor at position 2, and a positively charged residue, R or K, at the C-terminal position of the epitope, e.g., in position 9 of 9- mers (see, e.g., Sidney et al, Hum. Immunol. 45:79, 1996).
  • Exemplary members of the corresponding family of HLA molecules (the HLA- A3 supertype) that bind the A3 supermotif include at least A*0301, A*1101, A*3101, A*3301, and A*6801.
  • the HLA-A24 supermotif is characterized by the presence in peptide ligands of an aromatic (F, W, or Y) or hydrophobic aliphatic (L, I, V, M, or T) residue as a primary anchor in position 2, and Y, F, W, L, I, or M as primary anchor at the C- terminal position of the epitope (see, e.g., Sette and Sidney, Immunogenetics, in press, 1999).
  • the corresponding family of HLA molecules that bind to the A24 supermotif i.e., the A24 supertype
  • Other allele-specific HLA molecules predicted to be members of the A24 supertype are shown in Table 1. Peptide binding to each of the allele-specific HLA molecules can be modulated by substitutions at primary and/or secondary anchor positions, preferably choosing respective residues specified for the supermotif.
  • the HLA-B7 supermotif is characterized by peptides bearing proline in position 2 as a primary anchor, and a hydrophobic or aliphatic amino acid (L, I, V, M, A, F, W, or Y) as the primary anchor at the C-terminal position of the epitope.
  • the corresponding family of HLA molecules that bind the B7 supermotif is comprised of at least twenty six HLA-B proteins including: B*0702, B*0703, B*0704, B*0705, B*1508, B*3501, B*3502, B*3503, B*3504, B*3505, B*3506, B*3507, B*3508, B*5101, B*5102, B*5103, B*5104, B*5105, B*5301, B*5401, B*5501, B*5502, B*5601, B*5602, B*6701, and B*7801 (see, e.g., Sidney, et al, J. Immunol.
  • the HLA-B27 supermotif is characterized by the presence in peptide ligands of a positively charged (R, H, or K) residue as a primary anchor at position 2, and a hydrophobic (F, Y, L, W, M, I, A, or V) residue as a primary anchor at the C-terminal position of the epitope (see, e.g., Sidney and Sette, Immunogenetics, in press, 1999).
  • Exemplary members of the corresponding family of HLA molecules that bind to the B27 supermotif include at least B*1401, B*1402, B*1509, B*2702, B*2703, B*2704, B*2705, B*2706, B*3801, B*3901, B*3902, and B*7301.
  • Other allele-specific HLA molecules predicted to be members of the B27 supertype are shown in Table 1. Peptide binding to each of the allele-specific HLA molecules can be modulated by substitutions at primary and/or secondary anchor positions, preferably choosing respective residues specified for the supermotif.
  • the HLA-B44 supermotif is characterized by the presence in peptide ligands of negatively charged (D or E) residues as a primary anchor in position 2, and hydrophobic residues (F, W, Y, L, I, M, V, or A) as a primary anchor at the C-terminal position of the epitope (.see, e.g., Sidney et al., Immunol. Today 17:261, 1996).
  • Exemplary members of the corresponding family of HLA molecules that bind to the B44 supermotif include at least: B*1801, B*1802, B*3701, B*4001, B*4002, B*4006, B*4402, B*4403, and B*4006.
  • Peptide binding to each of the allele- specific HLA molecules can be modulated by substitutions at primary and/or secondary anchor positions; preferably choosing respective residues specified for the supermotif.
  • the HLA-B58 supermotif is characterized by the presence in peptide ligands of a small aliphatic residue (A, S, or T) as a primary anchor residue at position 2, and an aromatic or hydrophobic residue (F, W, Y, L, I, V, M, or A) as a primary anchor residue at the C-terminal position of the epitope (see, e.g., Sidney and Sette, Immunogenetics, in press, 1999 for reviews of relevant data).
  • Exemplary members of the corresponding family of HLA molecules that bind to the B58 supermotif include at least: B*1516, B*1517, B*5701, B*5702, and B*5801.
  • Allele-specific HLA molecules predicted to be members of the B58 supertype are shown in Table 1. Peptide binding to each of the allele-specific HLA molecules can be modulated by substitutions at primary and/or secondary anchor positions, preferably choosing respective residues specified for the supermotif.
  • the HLA-B62 supermotif is characterized by the presence in peptide ligands of the polar aliphatic residue Q or a hydrophobic aliphatic residue (L, V, M, I, or P) as a primary anchor in position 2, and a hydrophobic residue (F, W, Y, M, I, V, L, or A) as a primary anchor at the C-terminal position of the epitope (see, e.g., Sidney and
  • Exemplary members of the corresponding family of HLA molecules that bind to the B62 supermotif include at least: B*1501, B*1502, B*1513, and B5201.
  • Other allele-specific HLA molecules predicted to be members of the B62 supertype are shown in Table 1. Peptide binding to each of the allele-specific HLA molecules can be modulated by substitutions at primary and/or secondary anchor positions, preferably choosing respective residues specified for the supermotif.
  • A2 A*0201, A*0202, A*0203, A*0204, A*0208, A*0210, A*0211, A*0212, A*0205, A*0206, A*0207, A*0209, A*0213 A*0214, A*6802, A*6901
  • A3 A*0301, A*1101, A*3101, A*3301, A*0302, A*1102, A*2603, A*3302, A*6801 A*3303, A*3401, A*3402, A*6601, A*6602, A*7401
  • Verified alleles include alleles whose specificity has been determined by pool sequencing analysis, peptide binding assays, or by analysis of the sequences of CTL epitopes.
  • Predicted alleles are alleles whose specificity is predicted on the basis of B and F pocket structure to overlap with the supertype specificity.
  • the HLA-A1 motif is characterized by the presence in peptide ligands of T, S, or M as a primary anchor residue at position 2 and the presence of Y as a primary anchor residue at the C-terminal position of the epitope.
  • An alternative allele-specific Al motif is characterized by a primary anchor residue at position 3 rather than position 2. This motif is characterized by the presence of D, E, A, or S as a primary anchor residue in position 3, and a Y as a primary anchor residue at the C-terminal position of the epitope (see, e.g., DiBrino et al, J.
  • An HLA-A1 extended motif includes a D residue in position 3 and A, I, L, or F at the C- terminus.
  • Peptide binding to HLA Al can be modulated by substitutions at primary and/or secondary anchor positions, preferably choosing respective residues specified for the motif. Residues T, S, or M at position 2 and Y at the C-terminal position are a subset of the Al supermotif primary anchors.
  • HLA-A2*0201 motif was characterized by the presence in peptide ligands of L or M as a primary anchor residue in position 2, and L or V as a primary anchor residue at the C-terminal position of a 9-residue peptide (see, e.g., Falk et al, Nature 351 :290-296, 1991) and was further found to comprise an I at position 2 and I or A at the C-terminal position of a nine amino acid peptide (see, e.g., Hunt et al, Science 255:1261-1263, March 6, 1992; Parker et al, J. Immunol. 149:3580-3587, 1992).
  • the A*0201 allele-specific motif has also been defined to additionally comprise V, A, T, or Q as a primary anchor residue at position 2, and M or T as a primary anchor residue at the C-terminal position of the epitope (see, e.g., Kast et al, J. Immunol 152:3904-3912, 1994).
  • the HLA-A*0201 motif comprises peptide ligands with L, I, V, M, A, T, or Q as primary anchor residues at position 2 and L, I, V, M, A, or T as a primary anchor residue at the C-terminal position of the epitope.
  • the preferred and tolerated residues that characterize the primary anchor positions of the HLA-A*0201 motif are identical to the residues describing the A2 supermotif. (For reviews of relevant data, .see, e.g., Del Guercio et al, J. Immunol. 154:685-693, 1995; Ruppert et al, Cell 74:929-937, 1993; Sidney et al, Immunol. Today 11:261-266, 1996; Sette and Sidney, Curr. Opin. in Immunol. 10:478-482, 1998).
  • HLA-A*0201 motif Secondary anchor residues that characterize the A*0201 motif have additionally been defined (see, e.g., Ruppert et al, Cell 74:929-937, 1993). Peptide binding to HLA-A*0201 molecules can be modulated by substitutions at primary and/or secondary anchor positions, preferably choosing respective residues specified for the motif.
  • the HLA- A3 motif is characterized by the presence in peptide ligands of
  • HLA-A11 motif is characterized by the presence in peptide ligands of
  • Peptide binding to HLA-A11 can be modulated by substitutions at primary and/or secondary anchor positions, preferably choosing respective residues specified for the motif.
  • the HLA-A24 motif is characterized by the presence in peptide ligands of Y, F, W, or M as a primary anchor residue in position 2, and F, L, I, or W as a primary anchor residue at the C-terminal position of the epitope (see, e.g., Kondo et al, J. Immunol 155:4307-4312, 1995; and Kubo et al, J. Immunol. 152:3913-3924, 1994).
  • Peptide binding to HLA-A24 molecules can be modulated by substitutions at primary and/or secondary anchor positions; preferably choosing respective residues specified for the motif.
  • HLA DR- 1-4-7 supermotif
  • Peptides that bind to these DR molecules carry a supermotif characterized by a large aromatic or hydrophobic residue (Y, F, W, L, I, V, or M) as a primary anchor residue in position 1, and a small, non-charged residue (S, T, C, A, P, V, I, L, or M) as a primary anchor residue in position 6 of a 9-mer core region. Allele- specific secondary effects and secondary anchors for each of these HLA types have also been identified (Southwood et al, supra). These are set forth in Table III.
  • Peptide binding to HLA- DRB1*0401, DRB1*0101, and/or DRB1*0701 can be modulated by substitutions at primary and/or secondary anchor positions, preferably choosing respective residues specified for the supemiotif.
  • Two alternative motifs i.e., submotifs characterize peptide epitopes that bind to HLA-DR3 molecules (see, e.g., Geluk et al, J. Immunol 152:5742, 1994).
  • the first motif (submotif DR3 A) a large, hydrophobic residue (L, I, V, M, F, or Y) is present in anchor position 1 of a 9-mer core, and D is present as an anchor at position 4, towards the carboxyl terminus of the epitope.
  • core position 1 may or may not occupy the peptide N-terminal position.
  • the alternative DR3 submotif provides for lack of the large, hydrophobic residue at anchor position 1, and/or lack of the negatively charged or amide-like anchor residue at position 4, by the presence of a positive charge at position 6 towards the carboxyl terminus of the epitope.
  • L, I, V, M, F, Y, A, or Y is present at anchor position 1; D, N, Q, E, S, or T is present at anchor position 4; and K, R, or H is present at anchor position 6.
  • Peptide binding to HLA-DR3 can be modulated by substitutions at primary and/or secondary anchor positions, preferably choosing respective residues specified for the motif.
  • peptides corresponding to the sequences are then synthesized and, typically, evaluated for binding to the corresponding HLA allele.
  • the capacity to bind MHC Class molecules is measured in a variety of different ways.
  • One means is a Class I molecule binding assay as described in the related applications, noted above.
  • Other alternatives described in the literature include inhibition of antigen presentation (Sette, et al, J. Immunol. 141:3893 (1991), in vitro assembly assays (Townsend, et al, Cell 62:285 (1990), and FACS based assays using mutated ells, such as RMA-S (Melief, et al, Eur. J. Immunol.
  • Peptides that test positive in the binding assay are assayed for the ability of the peptides to induce specific CTL (or HTL, for class II motif-bearing peptides) responses in vitro.
  • CTL or HTL, for class II motif-bearing peptides
  • antigen-presenting cells that have been incubated with a peptide can be assayed for the ability to induce CTL responses in responder cell populations.
  • Antigen-presenting cells can be normal cells such as peripheral blood mononuclear cells or dendritic cells (Inaba, et al, J. Exp. Med. 166:182 (1987); Boog, Eur. J. Immunol 18:219 (1988)).
  • mutant mammalian cell lines that are deficient in their ability to load class I molecules with internally processed peptides, such as the mouse cell lines RMA-S (Karre, et al. Nature, 319:675 (1986); Ljunggren, et al, Eur. J. Immunol. 21:2963-2970 (1991)), and the human somatic T cell hybrid, T-2 (Cerundolo, et al, Nature 345:449-452 (1990)) and which have been transfected with the appropriate human class I genes are conveniently used, when peptide is added to them, to test for the capacity of the peptide to induce in vitro primary CTL responses.
  • RMA-S mouse cell lines
  • T-2 human somatic T cell hybrid
  • eukaryotic cell lines which could be used include various insect cell lines such as mosquito larvae (ATCC cell lines CCL 125, 126, 1660, 1591, 6585, 6586), silkworm (ATTC CRL 8851), armyworm (ATCC CRL 1711), moth (ATCC CCL 80) and Drosophila cell lines such as a Schneider cell line (see Schneider, J. Embryol Exp. Morphol. 27:353-365 (1927)).
  • Peripheral blood lymphocytes are conveniently isolated following simple venipuncture or leukapheresis of normal donors or patients and used as the responder cell sources of CTL precursors.
  • the appropriate antigen-presenting cells are incubated with 10-100 ⁇ M of peptide in serum- free media for 4 hours under appropriate culture conditions.
  • the peptide-loaded antigen-presenting cells are then incubated with the responder cell populations in vitro for 7 to 10 days under optimized culture conditions.
  • Positive CTL activation can be determined by assaying the cultures for the presence of CTLs that kill radiolabeled target cells, both specific peptide-pulsed targets as well as target cells expressing endogenously processed form of the relevant virus or tumor antigen from which the peptide sequence was derived.
  • immunogenicity Specificity and HLA restriction of the CTL is determined by testing against different peptide target cells expressing appropriate or inappropriate human HLA class I.
  • the peptides that test positive in the HLA binding assays and give rise to specific CTL responses are referred to herein as immunogenic peptides.
  • additional confirmatory work can be performed to select, amongst these vaccine candidates, epitopes with preferred characteristics in terms of population coverage, antigenicity, and immunogenicity.
  • various strategies can be utilized to evaluate immunogenicity, including:
  • HLA transgenic mice see, e.g., Wentworth, P. A. et al, J. Immunol. 26:97, 1996; Wentworth, P. A. et al, Int. Immunol. 8:651, 1996; Alexander, J. et al, J. Immunol. 159:4753, 1997); hi this method, peptides in incomplete Freund's adjuvant are administered subcutaneously to HLA transgenic mice. Several weeks following immunization, splenocytes are removed and cultured in vitro in the presence of test peptide for approximately one week. Peptide-specific T cells are detected using, e.g., a ⁇ lCr-release assay involving peptide sensitized target cells and target cells expressing endogenously generated antigen.
  • a ⁇ lCr-release assay involving peptide sensitized target cells and target cells expressing endogenously generated antigen.
  • recall responses are detected by culturing PBL from patients with cancer who have generated an immune response "naturally", or from patients who were vaccinated with tumor antigen vaccines.
  • PBL from subjects are cultured in vitro for 1-2 weeks in the presence of test peptide plus antigen presenting cells (APC) to allow activation of "memory" T cells, as compared to "naive” T cells.
  • APC antigen presenting cells
  • T cell activity is detected using assays for T cell activity including 5 I - release involving peptide-sensitized targets, T cell proliferation, or lymphokine release.
  • Peptides that comprise epitopes of the invention can be prepared synthetically, or by recombinant DNA technology or from natural sources such as whole viruses or tumors. Although the peptide will preferably be substantially free of other naturally occurring host cell proteins and fragments thereof, in some embodiments the peptides can be synthetically conjugated to native fragments or particles
  • polypeptides or peptides can be a variety of lengths, either in their neutral (uncharged) forms or in forms which are salts, and either free of modifications such as glycosylation, side chain oxidation, or phosphorylation or containing these modifications, subject to the condition that the modification not destroy the biological activity of the polypeptides as herein described.
  • the peptide will be as small as possible while still maintaining substantially all of the biological activity of the large peptide.
  • coding sequence for peptides of the length contemplated herein can be synthesized by chemical techniques, for example, the phosphotriester method of Matteucci et al, J. Am. Chem. Soc. 103:3185 (1981), Alternatively, recombinant DNA technology may be employed wherein a nucleotide sequence which encodes an immunogenic peptide of interest is inserted into an expression vector, transformed or transfected into an appropriate host cell and cultivated under conditions suitable for expression. These procedures are generally known in the art, as described generally in Sambrook et al, Molecular Cloning, A Laboratory Manual, Cold Spring Harbor Press, Cold Spring Harbor, New York (1982), which is incorporated herein by reference.
  • a coding sequence encoding a peptide of the invention can be provided with appropriate linkers and ligated into expression vectors commonly available in the art, and the vectors used to transform suitable hosts to produce the desired fusion protein.
  • suitable host systems are now available.
  • Expression constructs, i.e., minigenes are described in greater detail in the sections below.
  • Peptides having the desired activity maybe modified as necessary to provide certain desired attributes, e.g., improved pharmacological characteristics, while increasing or at least retaining substantially all of the biological activity of the unmodified peptide to bind the desired MHC molecule and activate the appropriate T cell.
  • the peptides may be subject to various changes, such as substitutions, either conservative or non-conservative, where such changes might provide for certain advantages in their use, such as improved MHC binding.
  • conservative substitutions is meant replacing an amino acid residue with another which is biologically and/or chemically similar, e.g., one hydrophobic residue for another, or one polar residue for another.
  • the substitutions include combinations such as Gly, Ala; Nal, lie, Leu, Met; Asp, Glu; Asn, Gin; Ser, Thr; Lys, Arg; and Phe, Tyr.
  • the effect of single amino acid substitutions may also be probed using D-amino acids.
  • peptide synthesis procedures may be made using well known peptide synthesis procedures, as described in e.g., Merrifield, Science 232:341-347 (1986), Barany & Merrifield, The Peptides, Gross & Meienhofer, eds. ( ⁇ .Y., Academic Press), pp. 1-284 (1979); and Stewart & Young, Solid Phase Peptide Synthesis, (Rockford, 111., Pierce), 2d Ed. (1984), incorporated by reference herein.
  • the peptides can also be modified by extending or decreasing the compound's amino acid sequence, e.g., by the addition or deletion of amino acids.
  • the peptides or analogs of the invention can also be modified by altering the order or composition of certain residues, it being readily appreciated that certain amino acid residues essential for biological activity, e.g., those at critical contact sites or conserved residues, may generally not be altered without an adverse effect on biological activity.
  • the non-critical amino acids need not be limited to those naturally occurring in proteins, such as L- ⁇ -amino acids, or their D-isomers, but may include non-natural amino acids as well as many derivatives of L- ⁇ -amino acids.
  • a series of peptides with single amino acid substitutions are employed to determine the effect of electrostatic charge, hydrophobicity, etc. on binding. For instance, a series of positively charged (e.g., Lys or Arg) or negatively charged (e.g., Glu) amino acid substitutions are made along the length of the peptide revealing different patterns of sensitivity towards various MHC molecules and T cell receptors.
  • a series of positively charged (e.g., Lys or Arg) or negatively charged (e.g., Glu) amino acid substitutions are made along the length of the peptide revealing different patterns of sensitivity towards various MHC molecules and T cell receptors.
  • multiple substitutions using small, relatively neutral moieties such as Ala, Gly, Pro, or similar residues may be employed.
  • the substitutions may be homo-oligomers or hetero- oligomers.
  • substitutions The number and types of residues which are substituted or added depend on the spacing necessary between essential contact points and certain functional attributes which are sought (e.g., hydrophobicity versus hydrophilicity). Increased binding affinity for an MHC molecule or T cell receptor may also be achieved by such substitutions, compared to the affinity of the parent peptide. h any event, such substitutions should employ amino acid residues or other molecular fragments chosen to avoid, for example, steric and charge interference which might disrupt binding.
  • substitutions are typically of single residues. Substitutions, deletions, insertions or any combination thereof may be combined to arrive at a final peptide. Substitutional variants are those in which at least one residue of a peptide has been removed and a different residue inserted in its place. Substantial changes in function (e.g., affinity for MHC molecules or T cell receptors) are made by selecting substitutions that are less conservative than those in Table 3, i.e., selecting residues that differ more significantly in their effect on maintaining (a) the structure of the peptide backbone in the area of the substitution, for example as a sheet or helical conformation, (b) the charge or hydrophobicity of the molecule at the target site or (c) the bulk of the side chain.
  • substitutions e.g., affinity for MHC molecules or T cell receptors
  • substitutions wlich in general are expected to produce the greatest changes in peptide properties will be those in which (a) hydrophilic residue, e.g. seryl, is substituted for (or by) a hydrophobic residue, e.g. leucyl, isoleucyl, phenylalanyl, valyl or alanyl; (b) a residue having an electropositive side chain, e.g., lysl, arginyl, orhistidyl, is substituted for (or by) an electronegative residue, e.g. glutamyl or aspartyl; or (c) a residue having a bulky side chain, e.g. phenylalanine, is substituted for (or by) one not having a side chain, e.g., glycine.
  • hydrophilic residue e.g. seryl
  • a hydrophobic residue e.g. leucyl, isoleucyl, phenylal
  • the peptides may also comprise isosteres of two or more residues in the immunogenic peptide.
  • An isostere as defined here is a sequence of two or more residues that can be substituted for a second sequence because the steric conformation of the first sequence fits a binding site specific for the second sequence.
  • the term specifically includes peptide backbone modifications well known to those skilled in the art. Such modifications include modifications of the amide nitrogen, the ⁇ -carbon, amide carbonyl, complete replacement of the amide bond, extensions, deletions or backbone crosslinks. See, generally, Spatola, Chemistry and Biochemistry of Amino Acids, Peptides and Proteins, Vol. Nil (Weinstein ed., 1983).
  • Modifications of peptides with various amino acid mimetics or unnatural amino acids are particularly useful in increasing the stability of the peptide in vivo. Stability can be assayed in a number of ways. For instance, peptidases and various biological media, such as human plasma and serum, have been used to test stability. See, e.g., Verhoef et al, Eur. J. DrugMetab Pharmacokin. 11:291-302 (1986). Half life of the peptides of the present invention is conveniently determined using a 25%) human serum (v/v) assay. The protocol is generally as follows. Pooled human serum (Type AB, non-heat inactivated) is delipidated by centrifugation before use.
  • Type AB non-heat inactivated
  • the serum is then diluted to 25% with RPMI tissue culture media and used to test peptide stability. At predetermined time intervals a small amount of reaction solution is removed and added to either 6% aqueous trichloracetic acid or ethanol. The cloudy reaction sample is cooled (4°C) for 15 minutes and then spun to pellet the precipitated serum proteins. The presence of the peptides is then determined by reversed-phase HPLC using stability- specific chromatography conditions.
  • Another embodiment for generating effective peptide analogs involves the substitution of residues that have an adverse impact on peptide stability or solubility in, e.g., a liquid environment. This substitution may occur at any position of the peptide epitope.
  • a cysteine (C) can be substituted out in favor of ⁇ -amino butyric acid. Due to its chemical nature, cysteine has the propensity to form disulfide bridges and sufficiently alter the peptide structurally so as to reduce binding capacity.
  • the binding activity, particularly modification of binding affinity or cross- reactivity among HLA supertype family members, of peptides of the invention can also be altered using analoging, which is described in co-pending U.S. application number 09/226,775 filed 1/6/99.
  • the analoging strategy utilizes the motifs or supermotifs that correlate with binding to certain HLA molecules.
  • Analog peptides can be created by substituting amino acid residues at primary anchor, secondary anchor, or at primary and secondary anchor positions. Generally, analogs are made for peptides that aheady bear a motif or supermotif.
  • residues are defined which are deleterious to binding to allele-specific HLA molecules or members of HLA supertypes that bind the respective motif or supermotif (see, e.g., Rupert et al Cell 74:929, 1993; Sidney, J. et al, Hu. Immunol. 45:79, 1996; and Sidney et al; Sidney, et al, J. Immunol. 154:247, 1995). Accordingly, removal of such residues that are detrimental to binding can be performed in accordance with the present invention.
  • one strategy to improve the cross-reactivity of peptides within a given supennotif is simply to delete one or more of the deleterious residues present within a peptide and substitute a small "neutral" residue such as Ala (that may not influence T cell recognition of the peptide).
  • An enhanced likelihood of cross-reactivity is expected if, together with elimination of detrimental residues within a peptide, "preferred" residues associated with high affinity binding to an allele-specific HLA molecule or to multiple HLA molecules within a superfamily are inserted.
  • the analog peptide when used as a vaccine, actually elicits a CTL response to the native epitope in vivo, the analog peptide may be used to induce T cells in vitro from individuals of the appropriate HLA allele. Thereafter, the immunized cells' capacity to lyse wild type peptide sensitized target cells is evaluated. Alternatively, evaluation of the cells' activity can be evaluated by monitoring IFN release. Each of these cell monitoring strategies evaluate the recognition of the APC by the CTL. It will be desirable to use as antigen presenting cells, typically cells that have been either infected, or transfected with the appropriate genes to establish whether endogenously produced antigen is also recognized by the T cells induced by the analog peptide. It is to be noted that peptide/protein-pulsed dendritic cells can be used to present whole protein antigens for both HLA class I and class II.
  • Another embodiment of the invention is to create analogs of weak binding peptides, to thereby ensure adequate numbers of cellular binders.
  • Class I binding peptides exhibiting binding affinities of 500-5000 nM, and carrying an acceptable but suboptimal primary anchor residue at one or both positions can be "fixed” by substituting preferred anchor residues in accordance with the respective supertype. The analog peptides can then be tested for binding and/or cross-binding capacity.
  • Another embodiment of the invention is to create analogs of peptides that are already cross-reactive binders and are vaccine candidates, but which bind weakly to one or more alleles of a supertype. If the cross-reactive binder carries a suboptimal residue (less preferred or deleterious) at a primary or secondary anchor position, the peptide can be analoged by substituting out a deleterious residue and replacing it with a preferred or less preferred one, or by substituting out a less preferred reside and replacing it with a preferred one. The analog peptide can then be tested for cross-binding capacity.
  • Heteroclitic analog peptides of the invention are particularly useful to induce an immune response against antigens to which a patient's immune system has become tolerant.
  • Tolerance refers to a specific immunologic nonresponsiveness induced by prior exposure to an antigen.
  • tolerance can be overcome in the patient by identifying a particular class I peptide epitope to which a patient is tolerant, modifying the peptide epitope sequence according to the methods of the invention, and inducing an immune response that cross-reacts against the tolerized epitope (antigen).
  • Overcoming tolerance is particularly desirable, for example, when a patient's immune system is tolerant of a viral or tumor-associated antigen, the latter antigens being often over- expressed self-proteins as a consequence of cell transfonnation.
  • Heteroclitic analoging is described in co-pending US provisional application number 60/166,529 filed 11/18/99 and US provisional application for "Heteroclitic Analogs And Related Methods", Tangri et al, inventors, Attorney Docket number 018623-015810US, filed 10/6/00.
  • the peptides of the present invention or analogs thereof which have CTL stimulating activity may be modified to provide desired attributes other than improved serum half life.
  • the ability of the peptides to induce CTL activity can be enhanced by linkage to a sequence which contains at least one epitope that is capable of inducing a T helper cell response.
  • Particularly preferred immunogenic peptides/T helper conjugates are linked by a spacer molecule.
  • the spacer is typically comprised of relatively small, neutral molecules, such as amino acids or amino acid mimetics, which are substantially uncharged under physiological conditions.
  • the spacers are typically selected from, e.g., Ala, Gly, or other neutral spacers of nonpolar amino acids or neutral polar amino acids.
  • the optionally present spacer need not be comprised of the same residues and thus may be a hetero- or homo-oligomer.
  • the spacer will usually be at least one or two residues, more usually three to six residues.
  • the CTL peptide may be linked to the T helper peptide without a spacer.
  • the immunogenic peptide may be linked to the T helper peptide either directly or via a spacer either at the amino or carboxy terminus of the CTL peptide.
  • the amino terminus of either the immunogenic peptide or the T helper peptide may be acylated.
  • Exemplary T helper peptides include tetanus toxoid 830-843, influenza 307- 319, malaria circumsporozoite 382-398 and 378-389.
  • compositions of the invention may be desirable to include in the pharmaceutical compositions of the invention at least one component which assists in priming CTL.
  • Lipids have been identified as agents capable of assisting the priming CTL in vivo against viral antigens.
  • palmitic acid residues can be attached to the alpha and epsilon amino groups of a Lys residue and then linked, e.g., via one or more linking residues such as Gly, Gly-Gly-, Ser, Ser-Ser, or the like, to an immunogenic peptide.
  • lipidated peptide can then be injected directly in a micellar form, incorporated into a liposome or emulsified in an adjuvant, e.g., incomplete Freund's adjuvant.
  • an adjuvant e.g., incomplete Freund's adjuvant.
  • a particularly effective immunogen comprises palmitic acid attached to alpha and epsilon amino groups of Lys, which is attached via linkage, e.g., Ser-Ser, to the amino terminus of the immunogenic peptide.
  • E. coli lipoproteins such as tripalmitoyl-S-glycerylcysteinlyseryl-serine (P 3 CSS) can be used to prime virus specific CTL when covalently attached to an appropriate peptide.
  • P 3 CSS tripalmitoyl-S-glycerylcysteinlyseryl-serine
  • P 3 CSS tripalmitoyl-S-glycerylcysteinlyseryl-serine
  • amino acids can be added to the termini of a peptide to provide for ease of linking peptides one to another, for coupling to a carrier support, or larger peptide, for modifying the physical or chemical properties of the peptide or oligopeptide, or the like.
  • Amino acids such as tyrosine, cysteine, lysine, glutamic or aspartic acid, or the like, can be introduced at the C- or N-terminus of the peptide or oligopeptide. Modification at the C terminus in some cases may alter binding characteristics of the peptide.
  • the peptide or oligopeptide sequences can differ from the natural sequence by being modified by terminal-NH2 acylation, e.g., by alkanoyl (C1-C20) or thioglycolyl acetylation, terminal-carboxyl amidation, e.g., ammonia, methylamine, etc. In some instances these modifications may provide sites for linking to a support or other molecule.
  • the peptides of the present invention and pharmaceutical and vaccine compositions thereof are useful for administration to mammals, particularly humans, to treat and/or prevent viral infection and cancer.
  • diseases which can be treated or prevented using the immunogenic peptides of the invention include prostate cancer, hepatitis B, hepatitis C, HPV infection, AIDS, renal carcinoma, cervical carcinoma, lymphoma, CMV, malaria, and condlyloma acuminatum.
  • Vaccines that contain an immunogenically effective amount of one or more peptides as described herein are a further embodiment of the invention.
  • vaccine compositions.
  • Such vaccine compositions can include, for example, lipopeptides (e.g-.,Vitiello, A. et al, J. Clin. Invest. 95:341, 1995), peptide compositions encapsulated in poly(DL-lactide-co-glycolide) ("PLG”) microspheres (see, e.g., Eldridge, et al, Molec. Immunol.
  • Toxin-targeted delivery technologies also known as receptor mediated targeting, such as those of Avant hnmunotherapeutics, h e. (Needham, Massachusetts) may also be used.
  • Vaccine compositions of the invention include nucleic acid-mediated modalities. DNA or RNA encoding one or more of the peptides of the invention can also be administered to a patient. This approach is described, for instance, in Wolff et. al, Science 247:1465 (1990) as well as U.S. Patent Nos. 5,580,859; 5,589,466; 5,804,566; 5,739,118; 5,736,524; 5,679,647; WO 98/04720; and in more detail below.
  • DNA-based delivery technologies include "naked DNA”, facilitated (bupivicaine, polymers, peptide-mediated) delivery, cationic lipid complexes, and particle-mediated (“gene gun”) or pressure-mediated delivery (see, e.g., U.S. Patent No. 5,922,687).
  • the peptides of the invention can be expressed by viral or bacterial vectors.
  • expression vectors include attenuated viral hosts, such as vaccinia or fowlpox. This approach involves the use of vaccinia virus, for example, as a vector to express nucleotide sequences that encode the peptides of the invention.
  • the recombinant vaccinia virus Upon introduction into an acutely or chronically infected host or into a non-infected host, the recombinant vaccinia virus expresses the immunogenic peptide, and thereby elicits a host CTL and/or HTL response.
  • Vaccinia vectors and methods useful in immunization protocols are described in, e.g., U.S.
  • Patent No. 4,722,848 Another vector is BCG (Bacille Calmette Guerin).
  • BCG vectors are described in Stover et al, Nature 351:456-460 (1991).
  • a wide variety of other vectors useful for therapeutic administration or immunization of the peptides of the invention e.g. adeno and adeno-associated virus vectors, retroviral vectors, Salmonella typhi vectors, detoxified anthrax toxin vectors, and the like, will be apparent to those skilled in the art from the description herein.
  • vaccines in accordance with the invention can encompass one or more of the peptides of the invention.
  • a peptide can be present in a vaccine individually.
  • the peptide can be individually linked to its own carrier; alternatively, the peptide can exist as a homopolymer comprising multiple copies of the same peptide, or as a heteropolymer of various peptides.
  • Polymers have the advantage of increased immunological reaction and, where different peptide epitopes are used to make up the polymer, the additional ability to induce antibodies and/or CTLs that react with different antigenic determinants of the pathogenic organism or tumor-related peptide targeted for an immune response.
  • the composition may be a naturally occurring region of an antigen or may be prepared, e.g., recombinantly or by chemical synthesis.
  • Carriers that can be used with vaccines of the invention are well known in the art, and include, e.g., thyroglobulin, albumins such as hmnan serum albumin, tetanus toxoid, polyamino acids such as poly L-lysine, poly L-glutamic acid, influenza, hepatitis B virus core protein, and the like.
  • the vaccines can contain a physiologically tolerable (i.e., acceptable) diluent such as water, or saline, preferably phosphate buffered saline.
  • the vaccines also typically include an adjuvant.
  • Adjuvants such as incomplete Freund's adjuvant, aluminum phosphate, aluminum hydroxide, or alum are examples of materials well known in the art. Additionally, CTL responses can be primed by conjugating peptides of the invention to lipids, such as tripalmitoyl-S-glycerylcysteinlyseryl- serine (P 3 CSS).
  • the immune system of the host Upon immunization with a peptide composition in accordance with the invention, via injection, aerosol, oral, transdermal, transmucosal, intrapleural, intrathecal, or other suitable routes, the immune system of the host responds to the vaccine by producing large amounts of CTLs specific for the desired antigen. Consequently, the host becomes at least partially immune to later infection, or at least partially resistant to developing an ongoing chronic infection, or derives at least some therapeutic benefit when the antigen was tumor-associated.
  • components that induce T cell responses are combined with component that induce antibody responses to the target antigen of interest, combine class I peptide vaccines of the invention with vaccines which induce or facilitate neutralizing antibody responses to the target antigen of interest, particularly to viral envelope antigens.
  • a preferred embodiment of such a composition comprises class I and class II epitopes in accordance with the invention.
  • An alternative embodiment of such a composition comprises a class I epitope in accordance with the invention, along with a pan DR binding molecule, e.g., PADRETM (Epimmune, San Diego, CA) (described, for example, in U.S. Patent Number 5,736,142).
  • Minigenes A preferred means of administering nucleic acids encoding the peptides of the invention uses minigene constructs encoding multiple epitopes of the invention. To create a DNA sequence encoding the selected CTL epitopes (minigene) for expression in human cells, the amino acid sequences of the epitopes are reverse translated. A human codon usage table is used to guide the codon choice for each amino acid. These epitope- encoding DNA sequences are directly adjoined, creating a continuous polypeptide sequence. To optimize expression and/or immunogenicity, additional elements can be incorporated into the minigene design.
  • MHC presentation of CTL epitopes may be improved by including synthetic (e.g. poly-alanine) or naturally-occurring flanking sequences adjacent to the CTL epitopes.
  • the minigene sequence is converted to DNA by assembling oligonucleotides that encode the plus and minus strands of the minigene. Overlapping oligonucleotides (30-100 bases long) are synthesized, phosphorylated, purified and annealed under appropriate conditions using well known techniques, he ends of the oligonucleotides are joined using T4 DNA ligase. This synthetic minigene, encoding the CTL epitope polypeptide, can then cloned into a desired expression vector.
  • Standard regulatory sequences well known to those of skill in the art are included in the vector to ensure expression in the target cells.
  • Several vector elements are required: a promoter with a down-stream cloning site for minigene insertion; a polyadenylation signal for efficient transcription termination; an E. coli origin of replication; and an E. coli selectable marker (e.g. ampicillin or kanamycin resistance).
  • E. coli origin of replication e.g. ampicillin or kanamycin resistance
  • Numerous promoters can be used for this purpose, e.g., the human cytomegalovirus (hCMV) promoter. See, U.S. Patent Nos. 5,580,859 and 5,589,466 for other suitable promoter sequences.
  • introns are required for efficient gene expression, and one or more synthetic or naturally-occurring introns could be incorporated into the transcribed region of the minigene.
  • mRNA stabilization sequences can also be considered for increasing minigene expression.
  • immunostimulatory sequences ISSs or CpGs
  • a bicistronic expression vector to allow production of the minigene-encoded epitopes and a second protein included to enhance or decrease immunogenicity
  • proteins or polypeptides that could beneficially enhance the immune response if co-expressed include cytokines (e.g., ⁇ L2, IL12, GM-CSF), cytokine-inducing molecules (e.g. LelF) or costimulatory molecules.
  • Helper (HTL) epitopes could be joined to intracellular targeting signals and expressed separately from the CTL epitopes. This would allow direction of the HTL epitopes to a cell compartment different than the CTL epitopes.
  • immunosuppressive molecules e.g. TGF- ⁇
  • the minigene is cloned into the polylinker region downstream of the promoter.
  • This plasmid is transformed into an appropriate E. coli strain, and DNA is prepared using standard techniques. The orientation and DNA sequence of the minigene, as well as all other elements included in the vector, are confirmed using restriction mapping and DNA sequence analysis. Bacterial cells harboring the correct plasmid can be stored as a master cell bank and a working cell bank.
  • Therapeutic quantities of plasmid DNA are produced by fermentation in E. coli, followed by purification. Aliquots from the working cell bank are used to inoculate fermentation medium (such as Terrific Broth), and grown to saturation in shaker flasks or a bioreactor according to well known techniques. Plasmid DNA can be purified using standard bioseparation technologies such as solid phase anion-exchange resins supplied by Quiagen. If required, supercoiled DNA can be isolated from the open circular and linear forms using gel electrophoresis or other methods.
  • Purified plasmid DNA can be prepared for injection using a variety of formulations. The simplest of these is reconstitution of lyophilized DNA in sterile phosphate-buffer saline (PBS). A variety of methods have been described, and new techniques may become available. As noted above, nucleic acids are conveniently formulated with cationic lipids. In addition, glycolipids, fusogenic liposomes, peptides and compounds referred to collectively as protective, interactive, non-condensing (PINC) could also be complexed to purified plasmid DNA to influence variables such as stability, intramuscular dispersion, or trafficking to specific organs or cell types.
  • PINC protective, interactive, non-condensing
  • Target cell sensitization can be used as a functional assay for expression and MHC class I presentation of minigene-encoded CTL epitopes.
  • the plasmid DNA is introduced into a mammalian cell line that is suitable as a target for standard CTL chromium release assays. The transfection method used will be dependent on the final formulation. Electroporation can be used for "naked" DNA, whereas cationic lipids allow direct in vitro transfection.
  • a plasmid expressing green fluorescent protein (GFP) can be co-transfected to allow enrichment of transfected cells using fluorescence activated cell sorting (FACS). These cells are then chromium-51 labeled and used as target cells for epitope-specific CTL lines. Cytolysis, detected by 51 Cr release, indicates production of MHC presentation of minigene-encoded CTL epitopes.
  • GFP green fluorescent protein
  • In vivo immunogenicity is a second approach for functional testing of minigene DNA formulations.
  • Transgenic mice expressing appropriate human MHC molecules are immunized with the DNA product.
  • the dose and route of administration are formulation dependent (e.g. EVI for DNA in PBS, IP for lipid-complexed DNA).
  • Twenty-one days after immunization splenocytes are harvested and restimulated for 1 week in the presence of peptides encoding each epitope being tested.
  • These effector cells (CTLs) are assayed for cytolysis of peptide-loaded, chromium-51 labeled target cells using standard techniques. Lysis of target cells sensitized by MHC loading of peptides corresponding to minigene-encoded epitopes demonstrates DNA vaccine function for in vivo induction of CTLs.
  • An embodiment of a vaccine composition in accordance with the invention comprises ex vivo administration of a cocktail of epitope-bearing peptides to PBMC, or isolated DC therefrom, from the patient's blood. After pulsing the DC with peptides and prior to reinfusion into patients, the DC are washed to remove unbound peptides.
  • a vaccine comprises peptide-pulsed DCs which present the pulsed peptide epitopes in HLA molecules on their surfaces.
  • Dendritic cells can also be transfected, e.g., with a minigene comprising nucleic acid sequences encoding the epitopes in accordance with the invention, in order to elicit immune responses.
  • Vaccine compositions can be created in vitro, following dendritic cell mobilization and harvesting, whereby loading of dendritic cells occurs in vitro.
  • Antigenic peptides are used to elicit a CTL response ex vivo, as well.
  • the resulting CTL cells can be used to treat chronic infections, or tumors in patients that do not respond to other conventional fonns of therapy, or will not respond to a therapeutic vaccine peptide or nucleic acid in accordance with the invention.
  • Ex vivo CTL or HTL responses to a particular antigen are induced by incubating in tissue culture the patient's, or genetically compatible, CTL or HTL precursor cells together with a source of antigen-presenting cells (APC), such as dendritic cells, and the appropriate immunogenic peptide.
  • APC antigen-presenting cells
  • the cells After an appropriate incubation time (typically about 7-28 days), in which the precursor cells are activated and expanded into effector cells, the cells are infused back into the patient, where they will destroy their specific target cell (an infected cell or a tumor cell).
  • Transfected dendritic cells may also be used as antigen presenting cells.
  • compositions are administered to an individual already suffering from cancer or infected with the virus of interest. Those in the incubation phase or the acute phase of infection can be treated with the immunogenic peptides separately or in conjunction with other treatments, as appropriate.
  • compositions are administered to a patient in an amount sufficient to elicit an effective CTL response to the virus or tumor antigen and to cure or at least partially arrest symptoms and/or complications.
  • Amounts effective for this use will depend on, e.g., the peptide composition, the manner of administration, the stage and severity of the di jease being treated, the weight and general state of health of the patient, and the judgment of the prescribing physician, but generally range for the initial immunization (that is for therapeutic or prophylactic administration) from about 1.0 ⁇ g to about 50,000 ⁇ g of peptide for a 70 kg patient, followed by boosting dosages of from about 1.0 ⁇ g to about 10,000 ⁇ g of peptide pursuant to a boosting regimen over weeks to months depending upon the patient's response and condition by measuring specific CTL activity in the patient's blood.
  • peptides and compositions of the present invention may generally be employed in serious disease states, that is, life- threatening or potentially life threatening situations, hi such cases, in view of the minimization of extraneous substances and the relative nontoxic nature of the peptides, it is possible and may be felt desirable by the treating physician to administer substantial excesses of these peptide compositions.
  • administration should begin at the first sign of viral infection or the detection or surgical removal of tumors or shortly after diagnosis in the case of acute infection. This is followed by boosting doses until at least symptoms are substantially abated and for a period thereafter. In chronic infection, loading doses followed by boosting doses may be required.
  • Treatment of an infected individual with the compositions of the invention may hasten resolution of the infection in acutely infected individuals.
  • the compositions are particularly useful in methods for preventing the evolution from acute to chronic infection.
  • the susceptible individuals are identified prior to or during infection, for instance, as described herein, the composition can be targeted to them, minimizing need for administration to a larger population.
  • the peptide compositions can also be used for the treatment of chronic infection and to stimulate the immune system to eliminate virus-infected cells in carriers. It is important to provide an amount of iinmuno-potentiating peptide in a formulation and mode of administration sufficient to effectively stimulate a cytotoxic T cell response.
  • a representative dose is in the range of about 1.0 ⁇ g to about 50,000 ⁇ g, preferably about 5 ⁇ g to 10,000 ⁇ g for a 70 kg patient per dose.
  • compositions for therapeutic treatment are intended for parenteral, topical, oral or local administration.
  • the pharmaceutical compositions are administered parenterally, e.g., intravenously, subcutaneously, intradermally, or intramuscularly.
  • the invention provides compositions for parenteral administration which comprise a solution of the immunogenic peptides dissolved or suspended in an acceptable carrier, preferably an aqueous carrier.
  • an acceptable carrier preferably an aqueous carrier.
  • aqueous carriers maybe used, e.g., water, buffered water, 0.9% saline, 0.3% glycine, hyaluronic acid and the like.
  • These compositions may be sterilized by conventional, well known sterilization techniques, or may be sterile filtered.
  • compositions may be packaged for use as is, or lyophilized, the lyophilized preparation being combined with a sterile solution prior to administration.
  • the compositions may contain pharmaceutically acceptable auxiliary substances as required to approximate physiological conditions, such as pH adjusting and buffering agents, tonicity adjusting agents, wetting agents and the like, for example, sodium acetate, sodium lactate, sodium chloride, potassium chloride, calcium chloride, sorbitan monolaurate, triethanolamine oleate, etc.
  • concentration of CTL stimulatory peptides of the invention in the pharmaceutical formulations can vary widely, i.e., from less than about 0.1%, usually at or at least about 2% to as much as 20% to 50%> or more by weight, and will be selected primarily by fluid volumes, viscosities, etc., in accordance with the particular mode of administration selected.
  • the peptides of the invention may also be administered via liposomes, which target the peptides to a particular cells tissue, such as lymphoid tissue.
  • Liposomes are also useful in increasing the half-life of the peptides. Liposomes include emulsions, foams, micelles, insoluble monolayers, liquid crystals, phospholipid dispersions, lamellar layers and the like. In these preparations the peptide to be delivered is incorporated as part of a liposome, alone or in conjunction with a molecule which binds to, e.g., a receptor prevalent among lymphoid cells, such as monoclonal antibodies which bind to the CD45 antigen, or with other therapeutic or immunogenic compositions.
  • liposomes filled with a desired peptide of the invention can be directed to the site of lymphoid cells, where the liposomes then deliver the selected therapeutic/immunogenic peptide compositions.
  • Liposomes for use in the invention are formed from standard vesicle-forming lipids, which generally include neutral and negatively charged phospholipids and a sterol, such as cholesterol. The selection of lipids is generally guided by consideration of, e.g., liposome size, acid lability and stability of the liposomes in the blood stream. A variety of methods are available for preparing liposomes, as described in, e.g., Szoka et al, Ann. Rev. Biophys. Bioeng. 9:467 (1980), U.S. Patent Nos. 4,235,871, 4,501,728, 4,837,028, and 5,019,369, incorporated herein by reference.
  • a ligand to be incorporated into the liposome can include, e.g., antibodies or fragments thereof specific for cell surface determinants of the desired immune system cells.
  • a liposome suspension containing a peptide may be administered intravenously, locally, topically, etc. in a dose which varies according to, inter alia, the manner of administration, the peptide being delivered, and the stage of the disease being treated.
  • nontoxic solid carriers may be used which include, for example, pharmaceutical grades of mannitol, lactose, starch, magnesium stearate, sodium saccharin, talcum, cellulose, glucose, sucrose, magnesium carbonate, and the like.
  • a pharmaceutically acceptable nontoxic composition is formed by incorporating any of the normally employed excipients, such as those carriers previously listed, and generally 10-95%) of active ingredient, that is, one or more peptides of the invention, and more preferably at a concentration of 25%-75%.
  • the immunogenic peptides are preferably supplied in finely divided form along with a surfactant and propellant.
  • Typical percentages of peptides are 0.01%-20% by weight, preferably 1%-10%.
  • the surfactant must, of course, be nontoxic, and preferably soluble in the propellant.
  • Representative of such agents are the esters or partial esters of fatty acids containing from 6 to 22 carbon atoms, such as caproic, octanoic, lauric, palmitic, stearic, linoleic, linolenic, olesteric and oleic acids with an aliphatic polyhydric alcohol or its cyclic anhydride.
  • Mixed esters, such as mixed or natural glycerides may be employed.
  • the surfactant may constitute 0.1%-20% by weight of the composition, preferably 0.25-5%>.
  • the balance of the composition is ordinarily propellant.
  • a carrier can also be included, as desired, as with, e.g., lecithin for intranasal delivery.
  • Antigenic peptides may be used to elicit CTL ex vivo, as well.
  • the resulting CTL can be used to treat chronic infections (viral or bacterial) or tumors in patients that do not respond to other conventional forms of therapy, or will not respond to a peptide vaccine approach of therapy.
  • Ex vivo CTL responses to a particular pathogen are induced by incubating in tissue culture the patient's CTL precursor cells (CTLp) together with a source of antigen-presenting cells (APC) and the appropriate immunogenic peptide.
  • CTLp CTL precursor cells
  • APC antigen-presenting cells
  • the cells After an appropriate incubation time (typically 1-4 weeks), in which the CTLp are activated and mature and expand into effector CTL, the cells are infused back into the patient, where they will destroy their specific target cell (an infected cell or a tumor cell).
  • the culture of stimulator cells is maintained in an appropriate serum-free medium.
  • an amount of antigenic peptide is added to the stimulator cell culture, of sufficient quantity to become loaded onto the human Class I molecules to be expressed on the surface of the stimulator cells.
  • a sufficient amount of peptide is an amount that will allow about 200, and preferably 200 or more, human Class I MHC molecules loaded with peptide to be expressed on the surface of each stimulator cell.
  • the stimulator cells are incubated with >20 ⁇ g/ml peptide. Resting or precursor CD 8+ cells are then incubated in culture with the appropriate stimulator cells for a time period sufficient to activate the CD8+ cells.
  • the CD8+ cells are activated in an antigen-specific manner.
  • the ratio of resting or precursor CD8+ (effector) cells to stimulator cells may vary from individual to individual and may further depend upon variables such as the amenability of an individual's lymphocytes to culturing conditions and the nature and severity of the disease condition or other condition for which the within-described treatment modality is used.
  • the lymphocyte: stimulator cell ratio is in the range of about 30: 1 to 300: 1.
  • the effector/stimulator culture may be maintained for as long a time as is necessary to stimulate a therapeutically useable or effective number of CD8+ cells.
  • CTL CTL precursor
  • Peptide loading of empty major histocompatability complex molecules on cells allows the induction of primary cytotoxic T lymphocyte responses.
  • Peptide loading of empty major histocompatability complex molecules on cells enables the induction of primary cytotoxic T lymphocyte responses.
  • mutant cell lines do not exist for every human MHC allele, it is advantageous to use a technique to remove endogenous MHC-associated peptides from the surface of APC, followed by loading the resulting empty MHC molecules with the immunogenic peptides of interest.
  • the use of non-transformed (non-tumorigenic), non- infected cells, and preferably, autologous cells of patients as APC is desirable for the design of CTL induction protocols directed towards development of ex vivo CTL therapies.
  • This application discloses methods for stripping the endogenous MHC- associated peptides from the surface of APC followed by the loading of desired peptides.
  • a stable MHC class I molecule is a trimeric complex formed of the following elements: 1) a peptide usually of 8 - 10 residues, 2) a transmembrane heavy polymorphic protein chain which bears the peptide-binding site, and 3) a non-covalently associated non-polymorphic light chain, ⁇ 2 microglobulin. Removing the bound peptides and/or dissociating the ⁇ 2 microglobulin from the complex renders the MHC class I molecules nonfunctional and unstable, resulting in rapid degradation. All MHC class I molecules isolated from peripheral blood monocytic cells (PBMC) have endogenous peptides bound to them. Therefore, the first step is to remove all endogenous peptides bound to MHC class I molecules on the APC without causing their degradation before exogenous peptides can be added to them.
  • PBMC peripheral blood monocytic cells
  • Two possible ways to free up MHC class I molecules of bound peptides include lowering the culture temperature from 37°C to 26°C overnight to destablize ⁇ 2microglobulin and stripping the endogenous peptides from the cell using a mild acid treatment.
  • the methods release previously bound peptides into the extracellular environment allowing new exogenous peptides to bind to the empty class I molecules.
  • the cold-temperature incubation method enables exogenous peptides to bind efficiently to the MHC complex, but requires an overnight incubation at 26°C which may slow the cell's metabolic rate. It is also likely that cells not actively synthesizing MHC molecules (e.g. , resting PBMC) would not produce high amounts of empty surface MHC molecules by the cold temperature procedure.
  • Harsh acid stripping involves extraction of the peptides with trifluoroacetic acid, pH 2, or acid denaturation of the immunoaffinity purified class I-peptide complexes. These methods are not feasible for CTL induction, since it is important to remove the endogenous peptides while preserving APC viability and an optimal metabolic state which is critical for antigen presentation.
  • Mild acid solutions of pH 3 such as glycine or citrate-phosphate buffers have been used to identify endogenous peptides and to identify tumor associated T cell epitopes. The treatment is especially effective, in that only the MHC class I molecules are destabilized (and associated peptides released), while other surface antigens remain intact, including MHC class II molecules.
  • monoclonal antibodies specific for the stimulator cells, for the peptides loaded onto the stimulator cells, or for the CD8+ cells (or a segment thereof) may be utilized to bind their appropriate complementary ligand.
  • Antibody-tagged molecules may then be extracted from the stimulator-effector cell admixture via appropriate means, e.g., via well-known immunoprecipitation or immunoassay methods.
  • Effective, cytotoxic amounts of the activated CD8+ cells can vary between in vitro and in vivo uses, as well as with the amount and type of cells that are the ultimate target of these killer cells. The amount will also vary depending on the condition of the patient and should be determined via consideration of all appropriate factors by the practitioner. Preferably, however, about 1 X 10 to about 1 X 10 , more preferably about 1 X 10 8 to about 1 X 10 11 , and even more preferably, about 1 X 10 9 to about 1 X 10 10 activated CD8+ cells are utilized for adult humans, compared to about 5 X 10 6 - 5 X 10 7 cells used in mice.
  • the activated CD8+ cells are harvested from the cell culture prior to administration of the CD8+ cells to the individual being treated. It is important to note, however, that unlike other present and proposed treatment modalities, the present method uses a cell culture system that is not tumorigenic. Therefore, if complete separation of stimulator cells and activated CD8+ cells is not achieved, there is no inherent danger known to be associated with the administration of a small number of stimulator cells, whereas administration of mammalian tumor-promoting cells may be extremely hazardous.
  • Methods of re-introducing cellular components are known in the art and include procedures such as those exemplified in U.S. Patent No. 4,844,893 to Honsik, et al and U.S. Patent No. 4,690,915 to Rosenberg. For example, administration of activated CD8+ cells via intravenous infusion is appropriate.
  • HLA class I and class II binding peptides can be used as reagents to evaluate an immune response.
  • the evaluated immune response can be induced by any immunogen.
  • the immunogen may result in the production of antigen-specific CTLs or HTLs that recognize the peptide epitope(s) employed as the reagent.
  • a peptide of the invention may or may not be used as the immunogen.
  • Assay systems that can be used for such analyses include tetramer-based protocols, staining for intracellular lymphokines, interferon release assays, or ELISPOT assays.
  • a peptide of the invention can be used in a tetramer staining assay to assess peripheral blood mononuclear cells for the presence of any antigen-specific CTLs.
  • the HLA-tetrameric complex is used to directly visualize antigen-specific CTLs and thereby determine the frequency of such antigen-specific CTLs in a sample of peripheral blood mononuclear cells (see, e.g., Ogg et al, Science 279:2103-2106, 1998; and Altinan et al, Science 174:94-96, 1996).
  • a tetramer reagent comprising a peptide of the invention is generated as follows: A peptide that binds to an HLA molecule is refolded in the presence of the corresponding HLA heavy chain and ⁇ 2 -microglobulin to generate a trimolecular complex. The complex is biotinylated at the carboxyl terminal end of the HLA heavy chain, at a site that was previously engineered into the protein. Tetramer formation is then induced by adding streptavidin. When fluorescently labeled streptavidin is used, the tetrameric complex is used to stain antigen-specific cells. The labeled cells are then readily identified, e.g., by flow cytometry.
  • PBMC sample from an individual expressing a disease-associated antigen (e.g.
  • a tumor-associated antigen such as CEA, p53, MAGE2/3,HER2neu, or an organism associated with neoplasia such as HPV or HS V
  • a tumor-associated antigen such as CEA, p53, MAGE2/3,HER2neu, or an organism associated with neoplasia such as HPV or HS V
  • a blood sample containing mononuclear cells may be evaluated by cultivating the PBMCs and stimulating the cells with a peptide of the invention. After an appropriate cultivation period, the expanded cell population may be analyzed, for example, for CTL or for HTL activity.
  • the peptides can be used to evaluate the efficacy of a vaccine.
  • PBMCs obtained from a patient vaccinated with an immunogen may be analyzed by methods such as those described herein.
  • the patient is HLA typed, and peptide epitopes that are bound by the HLA molecule(s) present in that patient are selected for analysis.
  • the immunogenicity of the vaccine is indicated by the presence of CTLs and/or HTLs directed to epitopes present in the vaccine, o
  • the peptides of the invention may also be used to make antibodies, using techniques well known in the art (see, e.g. CURRENT PROTOCOLS IN IMMUNOLOGY, Wiley/Greene, NY; and Antibodies A Laboratory Manual Harlow, Harlow and Lane, Cold Spring Harbor Laboratory Press, 1989). Such antibodies are useful as reagents to determine the presence of disease-associated antigens or may be used therapetucially. Antibodies in this category include those that recognize a peptide when bound by an HLA molecule, i.e., antibodies that bind to a peptide-MHC complex.
  • Epitopes in accordance with the present invention were successfully used to induce an immune response. Immune responses with these epitopes have been induced by administering the epitopes in various forms.
  • the epitopes have been administered as peptides, as nucleic acids, and as viral vectors comprising nucleic acids that encode the epitope(s) of the invention.
  • immune responses Upon administration of peptide-based epitope forms, immune responses have been induced by direct loading of an epitope onto an empty HLA molecule that is expressed on a cell, and via intemalization of the epitope and processing via the HLA class I pathway; in either event, the HLA molecule expressing the epitope was then able to interact with and induce a CTL response.
  • Peptides can be delivered directly or using such agents as liposomes. They can additionally be delivered using ballistic delivery, in which the peptides are typically in a crystalline form.
  • DNA When DNA is used to induce an irnmuiie response, it is administered either as naked DNA, generally in a dose range of approximately 1-5 mg, or via the ballistic "gene gun" delivery, typically in a dose range of approximately 10-100 ⁇ g.
  • the DNA can be delivered in a variety of conformations, e.g., linear, circular etc.
  • Various viral vectors have also successfully been used that comprise nucleic acids which encode epitopes in accordance with the invention. Accordingly compositions in accordance with the invention exist in several forms. Embodiments of each of these composition forms in accordance with the invention have been successfully used to induce an immune response.
  • composition in accordance with the invention comprises a plurality of peptides.
  • This plurality or cocktail of peptides is generally admixed with one or more pharmaceutically acceptable excipients.
  • the peptide cocktail can comprise multiple copies of the same peptide or can comprise a mixture of peptides.
  • the peptides can be analogs of naturally occurring epitopes.
  • the peptides can comprise artificial amino acids and/or chemical modifications such as addition of a surface active molecule, e.g., lipidation; acetylation, glycosylation, biotinylation, phosphorylation etc.
  • the peptides can be CTL or HTL epitopes.
  • the peptide cocktail comprises a plurality of different CTL epitopes and at least one HTL epitope.
  • the HTL epitope can be naturally or non-naturally (e.g., PADRE®, Epimmune Inc., San Diego, CA).
  • the number of distinct epitopes in an embodiment of the invention is generally a whole unit integer from one through one hundred fifty (e.g., 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64, 65, 66, 67, 68, 69, 70, 71, 72, 73, 74, 75, 76, 77, 78, 79, 80, 81, 82, 83, 84, 85, 86, 87, 88, 89, 90, 91, 92, 93, 94, 95, 96, 97, 98, 99, or, 100).
  • composition in accordance with the invention comprises a polypeptide multi-epitope construct, i.e., a polyepitopic peptide.
  • Polyepitopic peptides in accordance with the invention are prepared by use of technologies well-known in the art. By use of these known technologies, epitopes in accordance with the invention are connected one to another.
  • the polyepitopic peptides can be linear or non-linear, e.g., multivalent.
  • These polyepitopic constructs can comprise artificial amino acids, spacing or spacer amino acids, flanking amino acids, or chemical modifications between adjacent epitope units.
  • the polyepitopic construct can be a heteropolymer or a homopolymer.
  • the polyepitopic constructs generally comprise epitopes in a quantity of any whole unit integer between 2-150 (e.g., 2, 3, , 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64, 65, 66, 67, 68, 69, 70, 71, 72, 73, 74, 75, 76, 77, 78, 79, 80, 81, 82, 83, 84, 85, 86, 87, 88, 89, 90, 91, 92, 93, 94, 95, 96, 97, 98, 99, or, 100).
  • 2-150 e.g., 2, 3, , 5, 6, 7, 8, 9,
  • the polyepitopic construct can comprise CTL and/or HTL epitopes.
  • One or more of the epitopes in the construct can be modified, e.g., by addition of a surface active material, e.g. a lipid, or chemically modified, e.g., acetylation, etc.
  • bonds in the multiepitopic construct can be other than peptide bonds, e.g., covalent bonds, ester or ether bonds, disulfide bonds, hydrogen bonds, ionic bonds etc.
  • composition in accordance with the invention comprises construct which comprises a series, sequence, stretch, etc. , of amino acids that have homology to ( i.e., corresponds to or is contiguous with) to a native sequence.
  • This stretch of amino acids comprises at least one subsequence of amino acids that, if cleaved or isolated from the longer series of amino acids, functions as an HLA class I or HLA class II epitope in accordance with the invention.
  • the peptide sequence is modified, so as to become a construct as defined herein, by use of any number of techniques known or to be provided in the art.
  • the polyepitopic constructs can contain homology to a native sequence in any whole unit integer increment from 70-100%, e.g., 70, 71, 72, 73, 74, 75, 76, 77, 78, 79, 80, 81, 82, 83, 84, 85, 86, 87, 88, 89, 90, 91, 92, 93, 94, 95, 96, 97, 98, 99, or, 100 percent.
  • a further embodiment of a composition in accordance with the invention is an antigen presenting cell that comprises one or more epitopes in accordance with the invention.
  • the antigen presenting cell can be a "professional" antigen presenting cell, such as a dendritic cell.
  • the antigen presenting cell can comprise the epitope of the invention by any means known or to be determined in the art. Such means include pulsing of dendritic cells with one or more individual epitopes or with one or more peptides that comprise multiple epitopes, by nucleic acid administration such as ballistic nucleic acid delivery or by other techniques in the art for administration of nucleic acids, including vector-based, e.g. viral vector, delivery of nucleic acids.
  • compositions in accordance with the invention comprise nucleic acids that encode one or more peptides of the invention, or nucleic acids which encode a polyepitopic peptide in accordance with the invention.
  • nucleic acids compositions will encode the same peptide due to the redundancy of the genetic code.
  • Each of these nucleic acid compositions falls within the scope of the present invention.
  • This embodiment of the invention comprises DNA or RNA, and in certain embodiments a combination of DNA and RNA. It is to be appreciated that any composition comprising nucleic acids that will encode a peptide in accordance with the invention or any other peptide based composition in accordance with the invention, falls within the scope of this invention.
  • peptide-based forms of the invention can comprise analogs of epitopes of the invention generated using priniciples aheady known, or to be known, in the art.
  • Principles related to analoging are now known in the art, and are disclosed herein; moreover, analoging principles are disclosed in co-pending application serial number U.S.S.N. 09/226,775 filed 6 January 1999.
  • compositions of the invention are isolated or purified.
  • Example 1 HLA class I supermotif and motif analysis of antigens of interest was performed as described herein and in the related applications, noted above. Peptides comprising the appropriate HLA I motif or supermotif were then synthesized and assayed for binding activity.
  • a detailed description of the protocol utilized to measure the binding of peptides to Class I and Class II MHC has been published (Sette et al, Mol. Immunol. 31:813, 1994; Sidney et al., in Current Protocols in Immunology, Margulies, Ed., John Wiley & Sons, New York, Section 18.3, 1998).
  • HLA class I supermotif and motif-bearing peptides from HIV regulatory proteins e.g., nef, rev, vif, tat, and vpr
  • Tables 2-11 HLA class I supermotif and motif-bearing peptides from HIV regulatory proteins, e.g., nef, rev, vif, tat, and vpr
  • % conserv refers to percent conservance, which is the degree to which the sequences are conserved in the strains evaluated to identify the sequences.
  • the "A” designation indicates that the peptide is an analog of the native sequence, hi the motif column, the designation "i” refers to individual motif and "s" refers to supermotif.
  • HLA class I supermotif and motif-bearing peptides from other antigens e.g., cancer antigens such as CEA, p53, Her2/neu, MARTI, MAGE2, MAGE3, tyrosinase, flu, gp 100, HB V, HCV, HIV, HPV (including the strain designation), Epstein Barr Virus (EBV), prostate cancer-associated antigens, gliadin, Mycobacterium leprae, Mycobacterium tuberculosis, T. cruzi, Candida antigens, and malaria (Plasmodium falciparum) antigens are shown in Tables 12-24.
  • cancer antigens such as CEA, p53, Her2/neu, MARTI, MAGE2, MAGE3, tyrosinase, flu, gp 100, HB V, HCV, HIV, HPV (including the strain designation), Epstein Barr Virus (EBV), prostate cancer-associated antigens, gliadin, Mycobacterium leprae
  • Tables 12 and 13 show peptides bearing an HLA-Al supermotif and/or motif.
  • Tables 14-17 shows peptides bearing an HLA-A2 supennotif.
  • Tables 18 and 19 show peptides bearing an HLA- A3 supermotif and/or motif.
  • Tables 20 and 21 show peptides bearing an HLA-A24 supermotif and/or motif.
  • Tables 22 and 23 show peptides bearing an HLA-B7 supermotiff.
  • Table 24 shows peptides bearing an HLA-B44 supermotif.
  • Peptide binding data for the designated HLA molecules are provided as IC 50 values unless otherwise indicated.
  • the "A" designation indicates that the peptide is an analog of the native sequence.
  • Example 2 Using the HLA class II supermotif and motifs identified in related applications and as described above, sequences from various pathogens and tumor-related proteins were analyzed for the presence of these motifs. Screening and binding assays was carried out as described in the related applications designated herein.
  • HLA class II DR supermotif and DR3 motif-bearing peptides from HIV regulatory proteins e.g. , nef, rev, vif, tat, and vpr
  • % conserv refers to percent conservance, which is the degree to which the sequences are conserved in the strains evaluated to identify the sequences.
  • the core sequence of the motif-bearing peptide is in lower case.
  • Tables 26-31 shows HLA class II DR supermotif and DR 3 motif bearing peptides and the antigens from which they are derived.
  • Table 27a shows binding data for DRB1*0101, *0301, *0401, *0404, and *0405.
  • Table 27b shows binding data for DRB1*0701, *0802, *0901, *1101, ⁇ 1201, *1302, *1501, DRB3*0101, DRB4*0101, DRB5*0101, and DQBl*0301.
  • Table 28a and 29a provide the peptide reference number sequence and protein antigen/position of sequence in antigen for the peptides. Binding data are provided in Tables 28b and 29B.
  • Peptide binding data for the designated HLA molecules are provided as IC 50 values unless otherwise indicated.
  • the "A” designation indicates that the peptide is an analog of the native sequence.

Landscapes

  • Health & Medical Sciences (AREA)
  • Life Sciences & Earth Sciences (AREA)
  • Medicinal Chemistry (AREA)
  • Public Health (AREA)
  • Veterinary Medicine (AREA)
  • General Health & Medical Sciences (AREA)
  • Animal Behavior & Ethology (AREA)
  • Pharmacology & Pharmacy (AREA)
  • Chemical & Material Sciences (AREA)
  • Organic Chemistry (AREA)
  • Nuclear Medicine, Radiotherapy & Molecular Imaging (AREA)
  • General Chemical & Material Sciences (AREA)
  • Chemical Kinetics & Catalysis (AREA)
  • Immunology (AREA)
  • Microbiology (AREA)
  • Mycology (AREA)
  • Epidemiology (AREA)
  • Peptides Or Proteins (AREA)
  • Medicines Containing Antibodies Or Antigens For Use As Internal Diagnostic Agents (AREA)

Abstract

The present invention provides the means and methods for selecting immunogenic peptides and the immunogenic peptide compositions capable of specifically binding glycoproteins encoded by HLA alleles and inducing T cell activation in T cells restricted by the allele. The peptides are useful to elicit an immune response against a desired antigen.

Description

HLA CLASS I AND II BINDING PEPTIDES AND THEIR USES
CROSS REFERENCE TO RELATED APPLICATIONS
This application claims the benefit of priority of U.S.S.N. 60/242,350, filed October 19, 2000 and U.S.S.N. 60/285,624, filed April 20, 2001, each of which applications is herein incorporated by reference. BACKGROUND OF THE INVENTION
The present invention relates to compositions and methods for preventing, treating or diagnosing a number of pathological states such as viral diseases and cancers. In particular, it provides novel peptides capable of binding selected major histocompatibility complex (MHC) molecules and inducing an immune response. MHC molecules are classified as either class I or class II molecules. Class
II MHC molecules are expressed primarily on cells involved in initiating and sustaining immune responses, such as T lymphocytes, B lymphocytes, macrophages, etc. Class II MHC molecules are recognized by helper T lymphocytes and induce proliferation of helper T lymphocytes and amplification of the immune response to the particular immunogenic peptide that is displayed. Class I MHC molecules are expressed on almost all nucleated cells and are recognized by cytotoxic T lymphocytes (CTLs), which then destroy the antigen-bearing cells. CTLs are particularly important in tumor rejection and in fighting viral infections.
The CTL recognizes the antigen in the form of a peptide fragment bound to the MHC class I molecules rather than the intact foreign antigen itself. The antigen must normally be endogenously synthesized by the cell, and a portion of the protein antigen is degraded into small peptide fragments in the cytoplasm. Some of these small peptides translocate into a pre-Golgi compartment and interact with class I heavy chains to facilitate proper folding and association with the subunit β microglobulin. The peptide-MHC class I complex is then routed to the cell surface for expression and potential recognition by specific CTLs. A complex of an HLA molecule and a peptidic antigen acts as the ligand recognized by HLA-restricted T cells (Buus, S. et al, Cell 47:1071, 1986; Babbitt, B. P. et al, Nature 317:359, 1985; Townsend, A. and Bodmer, H., Annu. Rev. Immunol. 7:601, 1989; Germain, R. N., Annu. Rev. Immunol. 11:403, 1993). Through the study of single amino acid substituted antigen analogs and the sequencing of endogenously bound, naturally processed peptides, critical residues that correspond to motifs required for specific binding to HLA antigen molecules have been identified (see also, e.g., Southwood, et al, J. Immunol. 160:3363, 1998; Rammensee, et al, Immunogenetics 41 : 178, 1995; Rammensee et al, SYFPEITHI, access via web at : http://134.2.96.221/scripts.hlaserver.dll/home.htm; Sette, A. and Sidney, J. Curr. Opin. Immunol. 10:478, 1998; Engelhard, N. H., Curr. Opin. Immunol. 6:13, 1994; Sette, A. and Grey, H. M., Curr. Opin. Immunol. 4:79, 1992; Sinigaglia, F. and Hammer, J. Curr. Biol. 6:52, 1994; Ruppert et al, Cell 74:929-937, 1993; Kondo et al, J. Immunol. 155:4307-4312, 1995; Sidney et al, J. Immunol. 157:3480-3490, 1996; Sidney et al, Human Immunol. 45:79-93, 1996; Sette, A. and Sidney, J. Immunogenetics 50:201-212, 1999).
Furthermore, x-ray crystallographic analysis of HLA-peptide complexes has revealed pockets within the peptide binding cleft of HLA molecules which accommodate, in an allele-specific mode, specific residues of peptide ligands; these residues in turn determine the HLA binding capacity of the peptides in which they are present. (See, e.g., Madden, D.R. Annu. Rev. Immunol. 13:587, 1995; Smith, et al, Immunity 4:203, 1996; Fremont et al, Immunity 8:305, 1998; Stem et al, Structure 2:245, 1994; Jones, E.Y. Curr. Opin. Immunol 9:75, 1997; Brown, J. H. et al, Nature 364:33, 1993; Guo, H. C. et al, Proc. Natl Acad. Sci. USA 90:8053, 1993; Guo, H. C. et al, Nature 360:364, 1992; Silver, M. L. et al, Nature 360:367, 1992; Matsumura, M. et al, Science 257:927, 1992; Madden et al, Cell 70:1035, 1992; Fremont, D. H. et al, Science 257:919, 1992; Saper, M. A. , Bjorkman, P. J. and Wiley, D. C, J. Mol. Biol. 219:277, 1991.).
Peptides of the present invention may also comprise epitopes that bind to HLA class II DR molecules. A greater degree of heterogeneity in both size and binding frame position of the motif, relative to the Ν and C termini of the peptide, exists for class II peptide ligands. This increased heterogeneity of HLA class II peptide ligands is due to the structure of the binding groove of the HLA class II molecule which, unlike its class I counterpart, is open at both ends. Crystallographic analysis of HLA class II DRB*0101- peptide complexes showed that the major energy of binding is contributed by peptide residues complexed with complementary pockets on the DRB*0101 molecules. An important anchor residue engages the deepest hydrophobic pocket (see, e.g., Madden, D.R. Ann. Rev. Immunol 13:587, 1995) and is referred to as position 1 (PI). PI may represent the N-terminal residue of a class II binding peptide epitope, but more typically is flanked towards the N-terminus by one or more residues. Other studies have also pointed to an important role for the peptide residue in the 6th position towards the C- terminus, relative to P 1 , for binding to various DR molecules.
In the past few years evidence has accumulated to demonstrate that a large fraction of HLA class I and class II molecules can be classified into a relatively few supertypes, each characterized by largely overlapping peptide binding repertoires, and consensus structures of the main peptide binding pockets. Thus, peptides of the present invention are identified by any one of several HLA-specific amino acid motifs, or if the presence of the motif corresponds to the ability to bind several allele-specific HLA molecules, a supermotif. The HLA molecules that bind to peptides that possess a particular amino acid supermotif are collectively referred to as an HLA "supertype."
1 Accordingly, the definition of class I and class II allele-specific HLA binding motifs, or class I or class II supermotifs allows identification of regions within a protein that have the potential of binding particular HLA molecules.
Despite the developments in the art, the prior art has yet to provide a useful human epitope-based vaccine or therapeutic agent based on this work. The present invention provides these and other advantages.
SUMMARY OF THE INVENTION The present invention provides compositions comprising immunogenic peptides having allele-specific binding motifs, such as binding motifs for HLA-A2.1 molecules. For HLA class I epitopes, which bind to the appropriate HLA Class I allele, the peptides typically comprise epitopes from 8-11 amino acids in length, often 9 to 10 residues in length, that comprise conserved residues at certain positions such as positions
2 and the C-terminal position. Moreover, the peptides preferably do not comprise negative binding residues as defined herein at other positions such as, in an HLA-A2.1 motif-bearing epitope, positions 1, 3, 6 and/or 7 in the case of peptides 9 amino acids in length and positions 1, 3, 4, 5, 7, 8 and or 9 in the case of peptides 10 amino acids in length. For HLA class II epiotpes, the peptides typically comprise a motif of 6 to about 25 amino acids for a class II HLA motif, typically, 9 to 13 amino acids in length, which is recognized by a particular HLA molecule.
Epitopes on a number of immunogenic target proteins, i.e., target antigens, have been identified. Examples of suitable antigens include tumor-associated antigens such as tyrosinase related proteins 1 and 2 (TRP1 and TRP), which are frequently associated with melanoma; MARTI, p53, carcinoembryonic antigen (CEA), Her2/neu, and MAGE, including MAGE1, MAGE2, and MAGE3, which are expressed on abroad range of tumors; prostate cancer-associated antigens such as prostate specific antigen (PSA), human kallikrein (huK2), prostate specific membrane antigen (PSM), and prostatic acid phosphatase (PAP); antigens from viruses such as hepatitis B (e.g., HBV core and surface antigens (HBVc, HBVs)) hepatitis C (HCV), Epstein-Barr virus, human immunodeficiency type-1 virus (HIV1), Kaposi's sarcoma herpes virus (KSHV), human papilloma virus (HPV), influenza virus, and Lassa virus antigens, Mycobacterium tuberculosis (MT) antigens, trypanosome, e.g., Tiypansoma cruzi (T. cruzi), antigens such as surface antigen (TSA), and malaria antigens.
DEFINITIONS The term "peptide" is used interchangeably with "oligopeptide" in the present specification to designate a series of residues, typically L-amino acids, connected one to the other, typically by peptide bonds between the α-amino and carboxyl groups of adjacent amino acids. The preferred CTL-inducing peptides of the invention are 13 residues or less in length and usually consist of between about 8 and about 11 residues, preferably 9 or 10 residues.
With regard to a particular amino acid sequence, an "epitope" is a set of amino acid residues which is involved in recognition by a particular immunoglobulin, or in the context of T cells, those residues necessary for recognition by T cell receptor proteins and/or Major Histocompatibility Complex (MHC) receptors, h an immune system setting, in vivo or in vitro, an epitope is the collective features of a molecule, such as primary, secondary and tertiary peptide structure, and charge, that together form a site recognized by an immunoglobulin, T cell receptor or HLA molecule. Throughout this disclosure epitope and peptide are often used interchangeably.
It is to be appreciated that protein or peptide molecules that comprise an epitope of the invention as well as additional amino acid(s) are still within the bounds of the invention. In certain embodiments, there is a limitation on the length of a peptide of the invention. The embodiment that is length-limited occurs when the protein peptide comprising an epitope of the invention comprises a region (i.e., a contiguous series of amino acids) having 100% identity with a native sequence. In order to avoid the definition of epitope from reading, e.g. , on whole natural molecules, there is a limitation on the length of any region that has 100% identity with a native peptide sequence. Thus, for a peptide comprising an epitope of the invention and a region with 100% identity with a native peptide sequence, the region with 100% identity to a native sequence generally has a length of: less than or equal to 600 amino acids, often less than or equal to 500 amino acids, often less than or equal to 400 amino acids, often less than or equal to 250 amino acids, often less than or equal to 100 amino acids, , often less than or equal to 85 amino acids, often less than or equal to 75 amino acids, often less than or equal to 65 amino acids, and often less than or equal to 50 amino acids, h certain embodiments, an "epitope" of the invention is comprised by a peptide having a region with less than 51 amino. acids that has 100% identity to a native peptide sequence, in any increment down to 5 amino acids.
Accordingly, peptide or protein sequences longer than 600 amino acids are within the scope of the invention, so long as they do not comprise any contiguous sequence of more than 600 amino acids that have 100% identity with a native peptide sequence. For any peptide that has five contiguous residues or less that correspond to a native sequence, there is no limitation on the maximal length of that peptide in order to fall within the scope of the invention. It is presently preferred that a CTL epitope be less than 600 residues long in any increment down to eight amino acid residues.
An "immunogenic peptide" or "peptide epitope" is a peptide that comprises an allele-specific motif or supermotif such that the peptide will bind an HLA molecule and induce a CTL. Thus, immunogenic peptides of the invention are capable of binding to an appropriate HLA molecule and thereafter inducing a cytotoxic T cell response to the antigen from which the immunogenic peptide is derived.
The term "derived" when used to discuss an epitope is a synonym for "prepared." A derived epitope can be isolated from a natural source, or it can be synthesized in accordance with standard protocols in the art. Synthetic epitopes can comprise artificial amino acids "amino acid mimetics," such as D isomers of natural occurring L amino acids or non-natural amino acids such as cyclohexylalanine. A derived/prepared epitope can be an analog of a native epitope.
Immunogenic peptides are conveniently identified using the algorithms of the invention. The algorithms are mathematical procedures that produce a score which enables the selection of immunogenic peptides. Typically one uses the algorithmic score with a "binding threshold" to enable selection of peptides that have a high probability of binding at a certain affinity and will in turn be immunogemc. The algorithm is based upon either the effects on MHC binding of a particular amino acid at a particular position of a peptide or the effects on binding of a particular substitution in a motif containing peptide.
A binding affinity threshold associated with immunogenicity has been determined for HLA Class I. A threshold binding affinity of about 500 nM or less (preferably 50 nM or less) typically determines the capacity of a peptide epitope to elicit a CTL response. A binding affinity threshold of about 1000 nM of less, preferably 100 nM or less, typicallydetermines the capacity of a peptide epitope to elicit an HTL response. As used herein, "high affinity" with respect to HLA class I molecules is defined as binding with an IC50, or KD value, of 50 nM or less; "intermediate affinity" is binding with an IC50 or KD value of between about 50 and about 500 nM. "High affinity" with respect to binding to HLA class II molecules is defined as binding with an IC50 or KD value of 100 nM or less; "intermediate affinity" is binding with an IC50 or KD value of between about 100 and about 1000 nM.
"IC50" is the concentration of peptide in a binding assay at which 50% inhibition of binding of a reference peptide is observed. Given the conditions in which the assays are run (i.e., limiting HLA proteins and labeled peptide concentrations), these values approximate KD values. Assays for determining binding are described in detail, e.g., in PCT publications WO 94/20127 and WO 94/03205. It should be noted that IC50 values can change, often dramatically, if the assay conditions are varied, and depending on the particular reagents used (e.g., HLA preparation, etc.). For example, excessive concentrations of HLA molecules will increase the apparent measured IC50 of a given ligand. Alternatively, binding is expressed relative to a reference peptide.
Although as a particular assay becomes more, or less, sensitive, the ICso's of the peptides tested may change somewhat, the binding relative to the reference peptide will not significantly change. For example, in an assay run under conditions such that the IC50 of the reference peptide increases 10-fold, the IC50 values of the test peptides will also shift approximately 10-fold. Therefore, to avoid ambiguities, the assessment of whether a peptide is a good, intermediate, weak, or negative binder is generally based on its IC50, relative to the IC50 of a standard peptide.
Binding may also be determined using other assay systems including those using: live cells (e.g., Ceppellini et al, Nature 339:392 (1989); Christnick et al, Nature 352:67 (1991); Busch et al, Int. Immunol. 2:443 (1990); Hill et al, J. Immunol. 147:189 (1991); del Guercio et al, J. Immunol. 154:685 (1995)), cell free systems using detergent lysates (e.g., Cerundolo et al, J. Immunol 21:2069 (1991)), immobilized purified MHC (e.g., Hill et al, J. Immunol. 152, 2890 (1994); Marshall et al, J. Immunol 152:4946 (1994)), ELISA systems (e.g., Reay et al, EMBO J. 11:2829 (1992)), surface plasmon resonance (e.g., Khilko et al, J. Biol. Chem. 268:15425 (1993)); high flux soluble phase assays (Hammer et al, J. Exp. Med. 180:2353 (1994)), and measurement of class I MHC stabilization or assembly (e.g., Ljunggren et al, Nature 346:476 (1990); Schumacher et al, Cell 62:563 (1990); Townsend et al, Cell 62:285 (1990); Parker et al, J. Immunol 149:1896 (1992)). A "conserved residue" is an amino acid which occurs in a significantly higher frequency than would be expected by random distribution at a particular position in a peptide. Typically a conserved residue is one where the MHC structure may provide a contact point with the immunogenic peptide. At least one to three or more, preferably two, conserved residues within a peptide of defined length defines a motif for an immunogenic peptide. These residues are typically in close contact with the peptide binding groove, with their side chains buried in specific pockets of the groove itself. Typically, an immunogenic peptide will comprise up to three conserved residues, more usually two conserved residues.
As used herein, "negative binding residues" are amino acids which if present at certain positions (for example, positions 1, 3 and/or 7 of a 9-mer) will result in a peptide being a nonbinder or poor binder and in turn fail to be immunogenic i.e. induce a CTL response.
The term "motif refers to the pattern of residues in a peptide of defined length, usually a peptide of from about 8 to about 13 amino acids, often 8 to 11 amino acids, for a class I HLA motif and from about 6 to about 25 amino acids for a class II HLA motif, which is recognized by a particular HLA molecule. Peptide motifs are typically different for each protein encoded by each human HLA allele and differ in the pattern of the primary and secondary anchor residues.
The binding motif for an allele can be defined with increasing degrees of precision, hi one case, all of the conserved residues are present in the correct positions in a peptide and there are no negative residues in positions 1 ,3 and/or 7.
A "supermotif is a peptide binding specificity shared by HLA molecules encoded by two or more HLA alleles. Preferably, a supermotif-bearing peptide is recognized with high or intermediate affinity (as defined herein) by two or more HLA molecules. An "HLA supertype or family", as used herein, describes sets of HLA molecules grouped on the basis of shared peptide-binding specificities. HLA class I molecules that share somewhat similar binding affinity for peptides bearing certain amino acid motifs are grouped into HLA supertypes. The terms HLA superfamily, HLA supertype family, HLA family, and HLA xx-like molecules (where xx denotes a particular HLA type), are synonyms.
"Heteroclitic analogs" are defined herein as a peptide with increased potency for a specific T cell, as measured by increased responses to a given dose, or by a requirement of lesser amounts to achieve the same response as a homologous native class I peptide. Advantages of heteroclitic analogs include that the antigens can be more potent, or more economical (since a lower amount is required to achieve the same effect as a homologous class I peptide). In addition, heteroclitic analogs are also useful to overcome antigen-specific T cell unresponsiveness (T cell tolerance). The phrases "isolated" or "biologically pure" refer to material which is substantially or essentially free from components which normally accompany it as found in its native state. Thus, the peptides of this invention do not contain materials normally associated with their in situ environment, e.g., MHC I molecules on antigen presenting cells. Even where a protein has been isolated to a homogenous or dominant band, there are trace contaminants in the range of 5-10% of native protein which co-purify with the desired protein. Isolated peptides of this invention do not contain such endogenous co- purified protein.
The term "residue" refers to an amino acid or amino acid mimetic incorporated in an oligopeptide by an amide bond or amide bond mimetic.
"Link" or "join" refers to any method known in the art for functionally connecting peptides, including, without limitation, recombinant fusion, covalent bonding, disulfide bonding, ionic bonding, hydrogen bonding, and electrostatic bonding.
"Pharmaceutically acceptable" refers to a generally non-toxic, inert, and/or physiologically compatible composition.
A "pharmaceutical excipient" comprises a material such as an adjuvant, a carrier, pH-adjusting and buffering agents, tonicity adjusting agents, wetting agents, preservatives, and the like.
"Synthetic peptide" refers to a peptide that is not naturally occurring, but is man-made using such methods as chemical synthesis or recombinant DNA technology. A "non-native" sequence or "construct" refers to a sequence that is not found in nature, i.e., is "non-naturally occurring". Such sequences include, e.g., peptides that are lipidated or otherwise modified, and polyepitopic compositions that contain epitopes that are not contiguous in a native protein sequence. As used herein, a "vaccine" is a composition that contains one or more peptides of the invention. There are numerous embodiments of vaccines in accordance with the invention, such as by a cocktail of one or more peptides; one or more epitopes of the invention comprised by a polyepitopic peptide; or nucleic acids that encode such peptides or polypeptides, e.g., a minigene that encodes a polyepitopic peptide. The "one or more peptides" can include any whole unit integer from 1-150, e.g., at least 2, 3, 4, 5, 6, 1, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40 , 45, 50, 55, 60, 65, 70, 75, 80, 85, 90, 95, 100, 105, 110, 115, 120, 125, 130, 135, 140, 145, or 150 or more peptides of the invention. The peptides or polypeptides can optionally be modified, such as by lipidation, addition of targeting or other sequences. HLA class I-binding peptides of the invention can be admixed with, or linked to, HLA class II-binding peptides, to facilitate activation of both cytotoxic T lymphocytes and helper T lymphocytes. Vaccines can also comprise peptide- pulsed antigen presenting cells, e.g., dendritic cells.
The nomenclature used to describe peptide compounds follows the conventional practice wherein the amino group is presented to the left (the N-terminus) and the carboxyl group to the right (the C-terminus) of each amino acid residue. In the formulae representing selected specific embodiments of the present invention, the amino- and carboxyl-terminal groups, although not specifically shown, are in the form they would assume at physiologic pH values, unless otherwise specified. In the amino acid structure formulae, each residue is generally represented by standard three letter or single letter designations. The L-form of an amino acid residue is represented by a capital single letter or a capital first letter of a three-letter symbol, and the D-form for those amino acids having D-forms is represented by a lower case single letter or a lower case three letter symbol. Glycine has no asymmetric carbon atom and is simply referred to as "Gly" or G.
DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention relates to the determination of allele-specific peptide motifs for human class I and class II allele subtypes. These motifs are then used to define T cell epitopes from any desired antigen, particularly those associated with human viral diseases, cancers or autoiummune diseases, for which the amino acid sequence of the potential antigen or autoantigen targets is known. The application of supermotifs and motifs and binding analysis to the identification of epitopes is described in WOOl/21189 and co-pending U.S. applications numbers 09/239,043, filed 1/27/99; 09/350,401, filed 7/8/99; 09/412,863 filed 10/5/99; 09/390,061 filed 9/3/99; 09/458,302 filed 12 10/99; 09, 458,297 filed 12 10/99; 09/458,298 filed 12/10/99, 09/633,364 filed 8/7/00; 09/458,299 filed 12 10/99; and 09/641,528 filed 8/15/00. Epitopes on a number of immunogenic target proteins can be identified using the peptides of the invention. Examples of suitable antigens include tumor- associated antigens such as TRP1, p53, CEA, Her2/neu, and MAGE, including MAGE1, MAGE2, and MAGE3; prostate cancer-associated antigens such as prostate specific antigen (PSA), human kallikrein (huK2), prostate specific membrane antigen (PSM), and prostatic acid phosphatase (PAP); antigens from viruses such as hepatitis B (e.g., HBV core and surface antigens (HBVc, HBVs)) hepatitis C, Epstein-Barr virus, human immunodeficiency type-1 virus (HIV1), Kaposi's sarcoma herpes (KSHV), human papilloma virus (HPV), influenza virus, and Lassa virus antigens, Mycobacterium tuberculosis (MT) antigens, trypanosome, e.g., Tiγpansoma cruzi (T. cruzi), antigens such as surface antigen (TSA), and malaria antigens. The peptides are thus useful in pharmaceutical compositions for both in vivo and ex vivo therapeutic and diagnostic applications.
Peptides comprising the epitopes from these antigens are synthesized and then tested for their ability to bind to the appropriate MHC molecules in assays using, for example, purified class I molecules and radioiodonated peptides and/or cells expressing empty class I molecules by, for instance, immunofluorescent staining and flow microfluorometry, peptide-dependent class I assembly assays, and inhibition of CTL recognition by peptide competition. Those peptides that bind to the class I molecule are further evaluated for their ability to serve as targets for CTLs derived from infected or immunized individuals, as well as for their capacity to induce primary in vitro or in vivo CTL responses that can give rise to CTL populations capable of reacting with virally infected target cells or tumor cells as potential therapeutic agents.
The HLA class I antigens are encoded by the HLA- A, B, and C loci. HLA-A and B antigens are expressed at the cell surface at approximately equal densities, whereas the expression of HLA-C is significantly lower (perhaps as much as 10-fold lower). Each of these loci have a number of alleles. The peptide binding motifs of the invention are relatively specific for each allelic subtype.
For epitope-based vaccines, the peptides of the present invention preferably comprise a supermotif and/or motif recognized by an HLA I or HLA II molecule having a wide distribution in the human population.
Identification of Epitopes
The large degree of HLA polymorphism is an important factor to be taken into account with the epitope-based approach to vaccine development. To address this factor, epitope selection encompassing identification of peptides capable of binding at high or intermediate affinity to multiple HLA molecules is preferably utilized, most preferably these epitopes bind at high or intermediate affinity to two or more allele- specific HLA molecules. Immunogenic peptides of interest for vaccine compositions preferably include those that have an IC50 or binding affinity value for a class I HLA molecule(s) of 500 nM or better (i.e., the value is < 500 nM) or, for class II HLA molecules, 1000 nM or better (i.e., the value is < 1000 nM). For example, peptide binding is assessed by testing the capacity of a candidate peptide to bind to a purified HLA molecule in vitro. Peptides exhibiting high or intermediate affinity are then considered for further analysis. Selected peptides are generally tested on other members of the supertype family, h preferred embodiments, peptides that exhibit cross-reactive binding are then used in cellular screening analyses or vaccines.
Peptide Epitope Binding Motifs and Supermotifs
Through the study of single amino acid substituted antigen analogs and the sequencing of endogenously bound, naturally processed peptides, critical residues required for allele-specific binding to HLA molecules have been identified. The presence of these residues correlates with binding affinity for HLA molecules. The identification of motifs and/or supermotifs that correlate with high and intermediate affinity binding is an important issue with respect to the identification of immunogenic peptide epitopes for the inclusion in a vaccine. Kast et al. (J. Immunol. 152:3904-3912, 1994) have shown that motif-bearing peptides account for 90% of the epitopes that bind to allele-specific HLA class I molecules. In this study all possible peptides of 9 amino acids in length and overlapping by eight amino acids (240 peptides), which cover the entire sequence of the E6 and E7 proteins of human papillomavirus type 16, were evaluated for binding to five allele-specific HLA molecules that are expressed at high frequency among different ethnic groups. This unbiased set of peptides allowed an evaluation of the predictive value of HLA class I motifs. From the set of 240 peptides, 22 peptides were identified that bound to an allele-specific HLA molecule with high or intermediate affinity. Of these 22 peptides, 20 (i.e. 91%) were motif-bearing. Thus, this study demonstrates the value of motifs for the identification of peptide epitopes for inclusion in a vaccine: application of motif-based identification techniques will identify about 90% of the potential epitopes in a target antigen protein sequence.
A relationship between binding affinity for HLA class I molecules and immunogenicity of discrete peptide epitopes on bound antigens was determined by the present inventors. As disclosed in greater detail herein, higher HLA binding affinity is correlated with greater immunogenicity.
Greater immunogenicity can be manifested in several different ways. Immunogenicity corresponds to whether an immune response is elicited at all, and to the vigor of any particular response, as well as to the extent of a population in which a response is elicited. For example, a peptide might elicit an immune response in a diverse array of the population, yet in no instance produce a vigorous response, h accordance with these principles, close to 90% of high binding peptides have been found to elicit a response and thus be "immunogenic," as contrasted with about 50% of the peptides that bind with intermediate affinity. (See, e.g., Schaeffer et al. PNAS (1988)) Moreover, not only did peptides with higher binding affinity have an enhanced probability of generating an immune response, the generated response tended to be more vigorous than the response seen with weaker binding peptides. As a result, less peptide is required to elicit a similar biological effect if a high affinity binding peptide is used rather than a lower affinity one. Thus, in preferred embodiments of the invention, high affinity binding epitopes are used.
The correlation between binding affinity and immunogenicity was analyzed by the present inventors by two different experimental approaches (see, e.g., Sette, et al, J. Immunol. 153:5586-5592 (1994)). In the first approach, the immunogenicity of potential epitopes ranging in HLA binding affinity over a 10,000-fold range was analyzed in HLA-A*0201 transgenic mice. In the second approach, the antigenicity of approximately 100 different hepatitis B virus (HBV)-derived potential epitopes, all carrying A*0201 binding motifs, was assessed by using PBL from acute hepatitis patients. Pursuant to these approaches, it was determined that an affinity threshold value of approximately 500 nM (preferably 50 nM or less) determines the capacity of a peptide epitope to elicit a CTL response. These data are true for class I binding affinity measurements for naturally processed peptides and for synthesized T cell epitopes. An affinity threshold associated with immunogenicity in the context of HLA class II DR molecules has also been delineated (see, e.g., Southwood et al J. Immunology 160:3363-3373,1998, and WO99/61916). h order to define a biologically significant threshold of DR binding affinity, a database of the binding affinities of 32 DR- restricted epitopes for their restricting element (i.e., the HLA molecule that binds the motif) was compiled. In approximately half of the cases (15 of 32 epitopes), DR restriction was associated with high binding affinities, i.e. binding affinity values of 100 nM or less. In the other half of the cases (16 of 32), DR restriction was associated with intermediate affinity (binding affinity values in the 100-1000 nM range), h only one of 32 cases was DR restriction associated with an IC50 of 1000 nM or greater. Thus, 1000 11M can be defined as an affinity threshold associated with immunogenicity in the context of DR molecules.
Definition of motifs that are predictive of binding to specific class I and class II alleles allows the identification of potential peptide epitopes from an antigenic protein whose amino acid sequence is known. Typically, identification of potential peptide epitopes is initially carried out using a computer to scan the amino acid sequence of a desired antigen for the presence of motifs and/or supermotifs.
HLA Class I Motifs indicative of CTL Inducing Peptide Epitopes: The primary anchor residues of the HLA class I peptide epitope supermotifs and motifs are delineated below. In some cases, peptide epitopes may be listed in both a motif and a supermotif Table. The relationship of a articular motif and respective supermotif is indicated in the description of the individual motifs.
The HLA-A1 supermotif is characterized by the presence in peptide ligands of a small (T or S) or hydrophobic (L, I, V, or M) primary anchor residue in position 2, and an aromatic (Y, F, or W) primary anchor residue at the C-terminal position of the epitope. The corresponding family of HLA molecules that bind to the Al supermotif (i.e., the HLA-A1 supertype) is comprised of at least A*0101, A*2601, A*2602, A*2501, and A*3201 (see, e.g., DiBrino, M. et al, J. Immunol. 151:5930, 1993; DiBrino, M. et al, J. Immunol 152:620, 1994; Kondo, A. et al, Immunogenetics 45:249, 1997). Other allele-specific HLA molecules predicted to be members of the Al superfamily are shown in Table 1. Peptides binding to each of the individual HLA proteins can be modulated by substitutions at primary and/or secondary anchor positions, preferably choosing respective residues specified for the supermotif.
Primary anchor specificities for allele-specific HLA-A2.1 molecules (see, e.g., Falk et al, Nature 351:290-296, 1991; Hunt et al, Science 255:1261-1263, 1992; Parker et al, J. Immunol. 149:3580-3587, 1992; Ruppert et al, Cell 74:929-937, 1993) and cross-reactive binding among HLA-A2 and -A28 molecules have been described. (See, e.g., Fruci et al, Human Immunol. 38:187-192, 1993; Tanigaki et al, Human Immunol. 39:155-162, 1994; Del Guercio et al, J. Immunol. 154:685-693, 1995; Kast et al, J. Immunol. 152:3904-3912, 1994 for reviews of relevant data.) These primary anchor residues define the HLA-A2 supermotif; which presence in peptide ligands corresponds to the ability to bind several different HLA-A2 and -A28 molecules. The HLA-A2 supermotif comprises peptide ligands with L, I, V, M, A, T, or Q as a primary anchor residue at position 2 and L, I, V, M, A, or T as a primary anchor residue at the C- terminal position of the epitope. The corresponding family of HLA molecules (i. e. , the HLA- A2 supertype that binds these peptides) is comprised of at least: A*0201, A*0202, A*0203, A*0204, A*0205, A*0206, A*0207, A*0209, A*0214, A*6802, and A*6901. Other allele- specific HLA molecules predicted to be members of the A2 superfamily are shown in Table 1. As explained in detail below, binding to each of the individual allele-specific HLA molecules can be modulated by substitutions at the primary anchor and/or secondary anchor positions, preferably choosing respective residues specified for the supermotif.
The HLA- A3 supermotif is characterized by the presence in peptide ligands of A, L, I, V, M, S, or, T as a primary anchor at position 2, and a positively charged residue, R or K, at the C-terminal position of the epitope, e.g., in position 9 of 9- mers (see, e.g., Sidney et al, Hum. Immunol. 45:79, 1996). Exemplary members of the corresponding family of HLA molecules (the HLA- A3 supertype) that bind the A3 supermotif include at least A*0301, A*1101, A*3101, A*3301, and A*6801. Other allele-specific HLA molecules predicted to be members of the A3 supertype are shown in Table 1. As explained in detail below, peptide binding to each of the individual allele- specific HLA proteins can be modulated by substitutions of amino acids at the primary and/or secondary anchor positions of the peptide, preferably choosing respective residues specified for the supermotif.
The HLA-A24 supermotif is characterized by the presence in peptide ligands of an aromatic (F, W, or Y) or hydrophobic aliphatic (L, I, V, M, or T) residue as a primary anchor in position 2, and Y, F, W, L, I, or M as primary anchor at the C- terminal position of the epitope (see, e.g., Sette and Sidney, Immunogenetics, in press, 1999). The corresponding family of HLA molecules that bind to the A24 supermotif (i.e., the A24 supertype) includes at least A*2402, A*3001, and A*2301. Other allele-specific HLA molecules predicted to be members of the A24 supertype are shown in Table 1. Peptide binding to each of the allele-specific HLA molecules can be modulated by substitutions at primary and/or secondary anchor positions, preferably choosing respective residues specified for the supermotif.
The HLA-B7 supermotif is characterized by peptides bearing proline in position 2 as a primary anchor, and a hydrophobic or aliphatic amino acid (L, I, V, M, A, F, W, or Y) as the primary anchor at the C-terminal position of the epitope. The corresponding family of HLA molecules that bind the B7 supermotif (i.e., the HLA-B7 supertype) is comprised of at least twenty six HLA-B proteins including: B*0702, B*0703, B*0704, B*0705, B*1508, B*3501, B*3502, B*3503, B*3504, B*3505, B*3506, B*3507, B*3508, B*5101, B*5102, B*5103, B*5104, B*5105, B*5301, B*5401, B*5501, B*5502, B*5601, B*5602, B*6701, and B*7801 (see, e.g., Sidney, et al, J. Immunol. 154:247, 1995; Barber, et al., Curr. Biol. 5:179, 1995; Hill, et al, Nature 360:434, 1992; Rammensee, et al, Immunogenetics 41:178, 1995 for reviews of relevant data). Other allele-specific HLA molecules predicted to be members of the B7 supertype are shown in Table 1. As explained in detail below, peptide binding to each of the individual allele-specific HLA proteins can be modulated by substitutions at the primary and/or secondary anchor positions of the peptide, preferably choosing respective residues specified for the supermotif.
The HLA-B27 supermotif is characterized by the presence in peptide ligands of a positively charged (R, H, or K) residue as a primary anchor at position 2, and a hydrophobic (F, Y, L, W, M, I, A, or V) residue as a primary anchor at the C-terminal position of the epitope (see, e.g., Sidney and Sette, Immunogenetics, in press, 1999). Exemplary members of the corresponding family of HLA molecules that bind to the B27 supermotif (i.e., the B27 supertype) include at least B*1401, B*1402, B*1509, B*2702, B*2703, B*2704, B*2705, B*2706, B*3801, B*3901, B*3902, and B*7301. Other allele-specific HLA molecules predicted to be members of the B27 supertype are shown in Table 1. Peptide binding to each of the allele-specific HLA molecules can be modulated by substitutions at primary and/or secondary anchor positions, preferably choosing respective residues specified for the supermotif.
The HLA-B44 supermotif is characterized by the presence in peptide ligands of negatively charged (D or E) residues as a primary anchor in position 2, and hydrophobic residues (F, W, Y, L, I, M, V, or A) as a primary anchor at the C-terminal position of the epitope (.see, e.g., Sidney et al., Immunol. Today 17:261, 1996).
Exemplary members of the corresponding family of HLA molecules that bind to the B44 supermotif (i.e., the B44 supertype) include at least: B*1801, B*1802, B*3701, B*4001, B*4002, B*4006, B*4402, B*4403, and B*4006. Peptide binding to each of the allele- specific HLA molecules can be modulated by substitutions at primary and/or secondary anchor positions; preferably choosing respective residues specified for the supermotif. The HLA-B58 supermotif is characterized by the presence in peptide ligands of a small aliphatic residue (A, S, or T) as a primary anchor residue at position 2, and an aromatic or hydrophobic residue (F, W, Y, L, I, V, M, or A) as a primary anchor residue at the C-terminal position of the epitope (see, e.g., Sidney and Sette, Immunogenetics, in press, 1999 for reviews of relevant data). Exemplary members of the corresponding family of HLA molecules that bind to the B58 supermotif (i.e., the B58 supertype) include at least: B*1516, B*1517, B*5701, B*5702, and B*5801. Other allele-specific HLA molecules predicted to be members of the B58 supertype are shown in Table 1. Peptide binding to each of the allele-specific HLA molecules can be modulated by substitutions at primary and/or secondary anchor positions, preferably choosing respective residues specified for the supermotif.
The HLA-B62 supermotif is characterized by the presence in peptide ligands of the polar aliphatic residue Q or a hydrophobic aliphatic residue (L, V, M, I, or P) as a primary anchor in position 2, and a hydrophobic residue (F, W, Y, M, I, V, L, or A) as a primary anchor at the C-terminal position of the epitope (see, e.g., Sidney and
Sette, Immunogenetics, in press, 1999). Exemplary members of the corresponding family of HLA molecules that bind to the B62 supermotif (i.e., the B62 supertype) include at least: B*1501, B*1502, B*1513, and B5201. Other allele-specific HLA molecules predicted to be members of the B62 supertype are shown in Table 1. Peptide binding to each of the allele-specific HLA molecules can be modulated by substitutions at primary and/or secondary anchor positions, preferably choosing respective residues specified for the supermotif.
Table 1
Allelle- specific HLA-supertype members
HLA supermotif
Verified" Predicted"
Al A*0101, A*2501, A*2601, A*2602, A*0102, A*2604, A*3601, A*4301, A*3201 A*8001
A2 A*0201, A*0202, A*0203, A*0204, A*0208, A*0210, A*0211, A*0212, A*0205, A*0206, A*0207, A*0209, A*0213 A*0214, A*6802, A*6901
A3 A*0301, A*1101, A*3101, A*3301, A*0302, A*1102, A*2603, A*3302, A*6801 A*3303, A*3401, A*3402, A*6601, A*6602, A*7401
A24 A*2301, A*2402, A*3001 A*2403, A*2404, A*3002, A*3003
B7 B*0702, B*0703, B*0704, B*0705, B*1511, B*4201, B*5901 B*1508, B*3501, B*3502, B*3503, B*3503, B*3504, B*3505, B*3506, B*3507, B*3508, B*5101, B*5102, B*5103, B*5104, B*5105, B*5301, B*5401, B*5501, B*5502, B*5601, B*5602, B*6701, B*7801
B27 B*1401, B*1402, B*1509, B*2702, B*2701, B*2707, B*2708, B*3802,
B*2703, B*2704, B*2705, B*2706, B*3903, B*3904, B*3905, B*4801,
B*3801, B*3901, B*3902, B*7301 B*4802, B*1510, B*1518, B*1503
B44 B*1801, B*1802, B*3701, B*4402, B*4101, B*4501, B*4701, B*4901,
B*4403, B*4404, B*4001, B*4002, B*5001
B*4006
B58 B*5701, B*5702, B*5801, B*5802, B*1516, B*1517
B62 B*1501, B*1502, B*1513, B*5201 B*1301, B*1302, B*1504, B*1505, B*1506, B*1507, B*1515, B*1520, B*1521, B*1512, B*1514, B*1510 a. Verified alleles include alleles whose specificity has been determined by pool sequencing analysis, peptide binding assays, or by analysis of the sequences of CTL epitopes. b. Predicted alleles are alleles whose specificity is predicted on the basis of B and F pocket structure to overlap with the supertype specificity.
The HLA-A1 motif is characterized by the presence in peptide ligands of T, S, or M as a primary anchor residue at position 2 and the presence of Y as a primary anchor residue at the C-terminal position of the epitope. An alternative allele-specific Al motif is characterized by a primary anchor residue at position 3 rather than position 2. This motif is characterized by the presence of D, E, A, or S as a primary anchor residue in position 3, and a Y as a primary anchor residue at the C-terminal position of the epitope (see, e.g., DiBrino et al, J. hnmunol., 152:620, 1994; Kondo et al, Immunogenetics 45:249, 1997; and Kubo et al, J. Immunol. 152:3913, 1994 for reviews of relevant data). An HLA-A1 extended motif includes a D residue in position 3 and A, I, L, or F at the C- terminus. Peptide binding to HLA Al can be modulated by substitutions at primary and/or secondary anchor positions, preferably choosing respective residues specified for the motif. Residues T, S, or M at position 2 and Y at the C-terminal position are a subset of the Al supermotif primary anchors.
An HLA-A2*0201 motif was characterized by the presence in peptide ligands of L or M as a primary anchor residue in position 2, and L or V as a primary anchor residue at the C-terminal position of a 9-residue peptide (see, e.g., Falk et al, Nature 351 :290-296, 1991) and was further found to comprise an I at position 2 and I or A at the C-terminal position of a nine amino acid peptide (see, e.g., Hunt et al, Science 255:1261-1263, March 6, 1992; Parker et al, J. Immunol. 149:3580-3587, 1992). The A*0201 allele-specific motif has also been defined to additionally comprise V, A, T, or Q as a primary anchor residue at position 2, and M or T as a primary anchor residue at the C-terminal position of the epitope (see, e.g., Kast et al, J. Immunol 152:3904-3912, 1994). Thus, the HLA-A*0201 motif comprises peptide ligands with L, I, V, M, A, T, or Q as primary anchor residues at position 2 and L, I, V, M, A, or T as a primary anchor residue at the C-terminal position of the epitope. The preferred and tolerated residues that characterize the primary anchor positions of the HLA-A*0201 motif are identical to the residues describing the A2 supermotif. (For reviews of relevant data, .see, e.g., Del Guercio et al, J. Immunol. 154:685-693, 1995; Ruppert et al, Cell 74:929-937, 1993; Sidney et al, Immunol. Today 11:261-266, 1996; Sette and Sidney, Curr. Opin. in Immunol. 10:478-482, 1998). Secondary anchor residues that characterize the A*0201 motif have additionally been defined (see, e.g., Ruppert et al, Cell 74:929-937, 1993). Peptide binding to HLA-A*0201 molecules can be modulated by substitutions at primary and/or secondary anchor positions, preferably choosing respective residues specified for the motif. The HLA- A3 motif is characterized by the presence in peptide ligands of
L, M, V, I, S, A, T, F, C, G, or D as a primary anchor residue at position 2, and the presence of K, Y, R, H, F, or A as a primary anchor residue at the C-terminal position of the epitope (.see, e.g., DiBrino et al, Proc. Natl. Acad. Sci USA 90:1508, 1993; and Kubo et al, J. Immunol. 152:3913-3924, 1994). Peptide binding to HLA-A3 can be modulated by substitutions at primary and/or secondary anchor positions, preferably choosing respective residues specified for the motif. The HLA-A11 motif is characterized by the presence in peptide ligands of
V, T, M, L, I, S, A, G, N, C, D, or F as a primary anchor residue in position 2, and K, R, Y, or H as a primary anchor residue at the C-terminal position of the epitope (see, e.g., Zhang et al, Proc. Natl. Acad. Sci USA 90:2217-2221, 1993; and Kubo et al, J. Immunol. 152:3913-3924, 1994). Peptide binding to HLA-A11 can be modulated by substitutions at primary and/or secondary anchor positions, preferably choosing respective residues specified for the motif.
The HLA-A24 motif is characterized by the presence in peptide ligands of Y, F, W, or M as a primary anchor residue in position 2, and F, L, I, or W as a primary anchor residue at the C-terminal position of the epitope (see, e.g., Kondo et al, J. Immunol 155:4307-4312, 1995; and Kubo et al, J. Immunol. 152:3913-3924, 1994). Peptide binding to HLA-A24 molecules can be modulated by substitutions at primary and/or secondary anchor positions; preferably choosing respective residues specified for the motif.
Motifs Indicative of Class IIHTL Inducing Peptide Epitopes
The primary anchor residues of the HLA class II supermotifs and motifs are delineated below. HLA DR- 1-4-7 supermotif
Motifs have also been identified for peptides that bind to three common HLA class II allele-specific HLA molecules: HLA DRB1*0401, DRB1*0101, and DRB1*0701 (see, e.g., the review by Southwood et al. J. Immunology 160:3363- 3373,1998). Collectively, the common residues from these motifs delineate the HLA DR- 1-4-7 supermotif. Peptides that bind to these DR molecules carry a supermotif characterized by a large aromatic or hydrophobic residue (Y, F, W, L, I, V, or M) as a primary anchor residue in position 1, and a small, non-charged residue (S, T, C, A, P, V, I, L, or M) as a primary anchor residue in position 6 of a 9-mer core region. Allele- specific secondary effects and secondary anchors for each of these HLA types have also been identified (Southwood et al, supra). These are set forth in Table III. Peptide binding to HLA- DRB1*0401, DRB1*0101, and/or DRB1*0701 can be modulated by substitutions at primary and/or secondary anchor positions, preferably choosing respective residues specified for the supemiotif. Two alternative motifs (i.e., submotifs) characterize peptide epitopes that bind to HLA-DR3 molecules (see, e.g., Geluk et al, J. Immunol 152:5742, 1994). h the first motif (submotif DR3 A) a large, hydrophobic residue (L, I, V, M, F, or Y) is present in anchor position 1 of a 9-mer core, and D is present as an anchor at position 4, towards the carboxyl terminus of the epitope. As in other class II motifs, core position 1 may or may not occupy the peptide N-terminal position.
The alternative DR3 submotif provides for lack of the large, hydrophobic residue at anchor position 1, and/or lack of the negatively charged or amide-like anchor residue at position 4, by the presence of a positive charge at position 6 towards the carboxyl terminus of the epitope. Thus, for the alternative allele-specific DR3 motif (submotif DR3B): L, I, V, M, F, Y, A, or Y is present at anchor position 1; D, N, Q, E, S, or T is present at anchor position 4; and K, R, or H is present at anchor position 6. Peptide binding to HLA-DR3 can be modulated by substitutions at primary and/or secondary anchor positions, preferably choosing respective residues specified for the motif.
Evaluation of motif-bearing peptide epitopes
Upon identification of motif-bearing sequences, peptides corresponding to the sequences are then synthesized and, typically, evaluated for binding to the corresponding HLA allele. The capacity to bind MHC Class molecules is measured in a variety of different ways. One means is a Class I molecule binding assay as described in the related applications, noted above. Other alternatives described in the literature include inhibition of antigen presentation (Sette, et al, J. Immunol. 141:3893 (1991), in vitro assembly assays (Townsend, et al, Cell 62:285 (1990), and FACS based assays using mutated ells, such as RMA-S (Melief, et al, Eur. J. Immunol. 21:2963 (1991)). Peptides that test positive in the binding assay are assayed for the ability of the peptides to induce specific CTL (or HTL, for class II motif-bearing peptides) responses in vitro. For instance, antigen-presenting cells that have been incubated with a peptide can be assayed for the ability to induce CTL responses in responder cell populations. Antigen-presenting cells can be normal cells such as peripheral blood mononuclear cells or dendritic cells (Inaba, et al, J. Exp. Med. 166:182 (1987); Boog, Eur. J. Immunol 18:219 (1988)). Alternatively, mutant mammalian cell lines that are deficient in their ability to load class I molecules with internally processed peptides, such as the mouse cell lines RMA-S (Karre, et al. Nature, 319:675 (1986); Ljunggren, et al, Eur. J. Immunol. 21:2963-2970 (1991)), and the human somatic T cell hybrid, T-2 (Cerundolo, et al, Nature 345:449-452 (1990)) and which have been transfected with the appropriate human class I genes are conveniently used, when peptide is added to them, to test for the capacity of the peptide to induce in vitro primary CTL responses. Other eukaryotic cell lines which could be used include various insect cell lines such as mosquito larvae (ATCC cell lines CCL 125, 126, 1660, 1591, 6585, 6586), silkworm (ATTC CRL 8851), armyworm (ATCC CRL 1711), moth (ATCC CCL 80) and Drosophila cell lines such as a Schneider cell line (see Schneider, J. Embryol Exp. Morphol. 27:353-365 (1927)).
Peripheral blood lymphocytes are conveniently isolated following simple venipuncture or leukapheresis of normal donors or patients and used as the responder cell sources of CTL precursors. In one embodiment, the appropriate antigen-presenting cells are incubated with 10-100 μM of peptide in serum- free media for 4 hours under appropriate culture conditions. The peptide-loaded antigen-presenting cells are then incubated with the responder cell populations in vitro for 7 to 10 days under optimized culture conditions. Positive CTL activation can be determined by assaying the cultures for the presence of CTLs that kill radiolabeled target cells, both specific peptide-pulsed targets as well as target cells expressing endogenously processed form of the relevant virus or tumor antigen from which the peptide sequence was derived.
Specificity and HLA restriction of the CTL is determined by testing against different peptide target cells expressing appropriate or inappropriate human HLA class I. The peptides that test positive in the HLA binding assays and give rise to specific CTL responses are referred to herein as immunogenic peptides. After determining their binding affinity, additional confirmatory work can be performed to select, amongst these vaccine candidates, epitopes with preferred characteristics in terms of population coverage, antigenicity, and immunogenicity. Thus, various strategies can be utilized to evaluate immunogenicity, including:
1) Evaluation of primary T cell cultures from normal individuals (see, e.g., Wentworth, P. A. et al, Mol. Immunol 32:603, 1995; Celis, E. et al, Proc. Natl Acad. Sci. USA 91 :2105, 1994; Tsai, V. et al, J. Immunol 158:1796, 1997; Kawashima, I. et al, Human Immunol 59:1, 1998); This procedure involves the stimulation of peripheral blood lymphocytes (PBL) from normal subjects with a test peptide in the presence of antigen presenting cells in vitro over a period of several weeks. T cells specific for the peptide become activated during this time and are detected using, e.g., a lymphokine- release or a -> 1 Cr cytotoxicity assay involving peptide sensitized target cells.
2) Immunization of HLA transgenic mice (see, e.g., Wentworth, P. A. et al, J. Immunol. 26:97, 1996; Wentworth, P. A. et al, Int. Immunol. 8:651, 1996; Alexander, J. et al, J. Immunol. 159:4753, 1997); hi this method, peptides in incomplete Freund's adjuvant are administered subcutaneously to HLA transgenic mice. Several weeks following immunization, splenocytes are removed and cultured in vitro in the presence of test peptide for approximately one week. Peptide-specific T cells are detected using, e.g., a ^lCr-release assay involving peptide sensitized target cells and target cells expressing endogenously generated antigen.
3) Demonstration of recall T cell responses from patients who have been effectively vaccinated or who have a tumor; (see, e.g., Rehermann, B. et al, J. Exp. Med.
181:1047, 1995; Doolan, D. L. et al, Immunity 7:97, 1997; Bertoni, R. et al, J. Clin. Invest. 100:503, 1997; Threlkeld, S. C. et al, J. Immunol. 159:1648, 1997; Diepolder, H. M. et β/., J Virol 71:6011, 1997; Tsmg et al., J. Natl. Cancer Inst. 87:982-990, 1995; Disis et al, J. Immunol 156:3151-3158, 1996). In applying this strategy, recall responses are detected by culturing PBL from patients with cancer who have generated an immune response "naturally", or from patients who were vaccinated with tumor antigen vaccines. PBL from subjects are cultured in vitro for 1-2 weeks in the presence of test peptide plus antigen presenting cells (APC) to allow activation of "memory" T cells, as compared to "naive" T cells. At the end of the culture period, T cell activity is detected using assays for T cell activity including 5 I - release involving peptide-sensitized targets, T cell proliferation, or lymphokine release. Preparation of peptides
Peptides that comprise epitopes of the invention can be prepared synthetically, or by recombinant DNA technology or from natural sources such as whole viruses or tumors. Although the peptide will preferably be substantially free of other naturally occurring host cell proteins and fragments thereof, in some embodiments the peptides can be synthetically conjugated to native fragments or particles
The polypeptides or peptides can be a variety of lengths, either in their neutral (uncharged) forms or in forms which are salts, and either free of modifications such as glycosylation, side chain oxidation, or phosphorylation or containing these modifications, subject to the condition that the modification not destroy the biological activity of the polypeptides as herein described.
Often, the peptide will be as small as possible while still maintaining substantially all of the biological activity of the large peptide. In some embodiments, it may be desirable to optimize peptides of the invention to a length of 8, 9, 10, or 11 amino acid residues, commensurate in size with endogenously processed viral peptides or tumor cell peptides that are bound to MHC class I molecules on the cell surface.
As the coding sequence for peptides of the length contemplated herein can be synthesized by chemical techniques, for example, the phosphotriester method of Matteucci et al, J. Am. Chem. Soc. 103:3185 (1981), Alternatively, recombinant DNA technology may be employed wherein a nucleotide sequence which encodes an immunogenic peptide of interest is inserted into an expression vector, transformed or transfected into an appropriate host cell and cultivated under conditions suitable for expression. These procedures are generally known in the art, as described generally in Sambrook et al, Molecular Cloning, A Laboratory Manual, Cold Spring Harbor Press, Cold Spring Harbor, New York (1982), which is incorporated herein by reference. For example, a coding sequence encoding a peptide of the invention can be provided with appropriate linkers and ligated into expression vectors commonly available in the art, and the vectors used to transform suitable hosts to produce the desired fusion protein. A number of such vectors and suitable host systems are now available. Expression constructs, i.e., minigenes are described in greater detail in the sections below. Peptides having the desired activity maybe modified as necessary to provide certain desired attributes, e.g., improved pharmacological characteristics, while increasing or at least retaining substantially all of the biological activity of the unmodified peptide to bind the desired MHC molecule and activate the appropriate T cell. For instance, the peptides may be subject to various changes, such as substitutions, either conservative or non-conservative, where such changes might provide for certain advantages in their use, such as improved MHC binding. By conservative substitutions is meant replacing an amino acid residue with another which is biologically and/or chemically similar, e.g., one hydrophobic residue for another, or one polar residue for another. The substitutions include combinations such as Gly, Ala; Nal, lie, Leu, Met; Asp, Glu; Asn, Gin; Ser, Thr; Lys, Arg; and Phe, Tyr. The effect of single amino acid substitutions may also be probed using D-amino acids. Such modifications may be made using well known peptide synthesis procedures, as described in e.g., Merrifield, Science 232:341-347 (1986), Barany & Merrifield, The Peptides, Gross & Meienhofer, eds. (Ν.Y., Academic Press), pp. 1-284 (1979); and Stewart & Young, Solid Phase Peptide Synthesis, (Rockford, 111., Pierce), 2d Ed. (1984), incorporated by reference herein. The peptides can also be modified by extending or decreasing the compound's amino acid sequence, e.g., by the addition or deletion of amino acids. The peptides or analogs of the invention can also be modified by altering the order or composition of certain residues, it being readily appreciated that certain amino acid residues essential for biological activity, e.g., those at critical contact sites or conserved residues, may generally not be altered without an adverse effect on biological activity. The non-critical amino acids need not be limited to those naturally occurring in proteins, such as L-α-amino acids, or their D-isomers, but may include non-natural amino acids as well as many derivatives of L-α-amino acids.
Typically, a series of peptides with single amino acid substitutions are employed to determine the effect of electrostatic charge, hydrophobicity, etc. on binding. For instance, a series of positively charged (e.g., Lys or Arg) or negatively charged (e.g., Glu) amino acid substitutions are made along the length of the peptide revealing different patterns of sensitivity towards various MHC molecules and T cell receptors. In addition, multiple substitutions using small, relatively neutral moieties such as Ala, Gly, Pro, or similar residues may be employed. The substitutions may be homo-oligomers or hetero- oligomers. The number and types of residues which are substituted or added depend on the spacing necessary between essential contact points and certain functional attributes which are sought (e.g., hydrophobicity versus hydrophilicity). Increased binding affinity for an MHC molecule or T cell receptor may also be achieved by such substitutions, compared to the affinity of the parent peptide. h any event, such substitutions should employ amino acid residues or other molecular fragments chosen to avoid, for example, steric and charge interference which might disrupt binding.
Amino acid substitutions are typically of single residues. Substitutions, deletions, insertions or any combination thereof may be combined to arrive at a final peptide. Substitutional variants are those in which at least one residue of a peptide has been removed and a different residue inserted in its place. Substantial changes in function (e.g., affinity for MHC molecules or T cell receptors) are made by selecting substitutions that are less conservative than those in Table 3, i.e., selecting residues that differ more significantly in their effect on maintaining (a) the structure of the peptide backbone in the area of the substitution, for example as a sheet or helical conformation, (b) the charge or hydrophobicity of the molecule at the target site or (c) the bulk of the side chain. The substitutions wlich in general are expected to produce the greatest changes in peptide properties will be those in which (a) hydrophilic residue, e.g. seryl, is substituted for (or by) a hydrophobic residue, e.g. leucyl, isoleucyl, phenylalanyl, valyl or alanyl; (b) a residue having an electropositive side chain, e.g., lysl, arginyl, orhistidyl, is substituted for (or by) an electronegative residue, e.g. glutamyl or aspartyl; or (c) a residue having a bulky side chain, e.g. phenylalanine, is substituted for (or by) one not having a side chain, e.g., glycine.
The peptides may also comprise isosteres of two or more residues in the immunogenic peptide. An isostere as defined here is a sequence of two or more residues that can be substituted for a second sequence because the steric conformation of the first sequence fits a binding site specific for the second sequence. The term specifically includes peptide backbone modifications well known to those skilled in the art. Such modifications include modifications of the amide nitrogen, the α-carbon, amide carbonyl, complete replacement of the amide bond, extensions, deletions or backbone crosslinks. See, generally, Spatola, Chemistry and Biochemistry of Amino Acids, Peptides and Proteins, Vol. Nil (Weinstein ed., 1983).
Modifications of peptides with various amino acid mimetics or unnatural amino acids are particularly useful in increasing the stability of the peptide in vivo. Stability can be assayed in a number of ways. For instance, peptidases and various biological media, such as human plasma and serum, have been used to test stability. See, e.g., Verhoef et al, Eur. J. DrugMetab Pharmacokin. 11:291-302 (1986). Half life of the peptides of the present invention is conveniently determined using a 25%) human serum (v/v) assay. The protocol is generally as follows. Pooled human serum (Type AB, non-heat inactivated) is delipidated by centrifugation before use. The serum is then diluted to 25% with RPMI tissue culture media and used to test peptide stability. At predetermined time intervals a small amount of reaction solution is removed and added to either 6% aqueous trichloracetic acid or ethanol. The cloudy reaction sample is cooled (4°C) for 15 minutes and then spun to pellet the precipitated serum proteins. The presence of the peptides is then determined by reversed-phase HPLC using stability- specific chromatography conditions.
Another embodiment for generating effective peptide analogs involves the substitution of residues that have an adverse impact on peptide stability or solubility in, e.g., a liquid environment. This substitution may occur at any position of the peptide epitope. For example, a cysteine (C) can be substituted out in favor of α-amino butyric acid. Due to its chemical nature, cysteine has the propensity to form disulfide bridges and sufficiently alter the peptide structurally so as to reduce binding capacity. Substituting α- a ino butyric acid for C not only alleviates this problem, but actually improves binding and crossbinding capability in certain instances (see, e.g., the review by Sette et al, In: Persistent Viral Infections, Eds. R. Ahmed and I. Chen, John Wiley & Sons, England, 1999). Substitution of cysteine with α-amino butyric acid may occur at any residue of a peptide epitope, i.e. at either anchor or non-anchor positions.
Modification of binding activity
The binding activity, particularly modification of binding affinity or cross- reactivity among HLA supertype family members, of peptides of the invention can also be altered using analoging, which is described in co-pending U.S. application number 09/226,775 filed 1/6/99. In brief, the analoging strategy utilizes the motifs or supermotifs that correlate with binding to certain HLA molecules. Analog peptides can be created by substituting amino acid residues at primary anchor, secondary anchor, or at primary and secondary anchor positions. Generally, analogs are made for peptides that aheady bear a motif or supermotif. For a number of the motifs or supermotifs in accordance with the invention, residues are defined which are deleterious to binding to allele-specific HLA molecules or members of HLA supertypes that bind the respective motif or supermotif (see, e.g., Rupert et al Cell 74:929, 1993; Sidney, J. et al, Hu. Immunol. 45:79, 1996; and Sidney et al; Sidney, et al, J. Immunol. 154:247, 1995). Accordingly, removal of such residues that are detrimental to binding can be performed in accordance with the present invention. For example, in the case of the A3 supertype, when all peptides that have such deleterious residues are removed from the population of peptides used in the analysis, the incidence of cross-reactivity increased from 22% to 37% (see, e.g., Sidney, J. et al, Hu. Immunol 45:79, 1996).
Thus, one strategy to improve the cross-reactivity of peptides within a given supennotif is simply to delete one or more of the deleterious residues present within a peptide and substitute a small "neutral" residue such as Ala (that may not influence T cell recognition of the peptide). An enhanced likelihood of cross-reactivity is expected if, together with elimination of detrimental residues within a peptide, "preferred" residues associated with high affinity binding to an allele-specific HLA molecule or to multiple HLA molecules within a superfamily are inserted.
To ensure that an analog peptide, when used as a vaccine, actually elicits a CTL response to the native epitope in vivo, the analog peptide may be used to induce T cells in vitro from individuals of the appropriate HLA allele. Thereafter, the immunized cells' capacity to lyse wild type peptide sensitized target cells is evaluated. Alternatively, evaluation of the cells' activity can be evaluated by monitoring IFN release. Each of these cell monitoring strategies evaluate the recognition of the APC by the CTL. It will be desirable to use as antigen presenting cells, typically cells that have been either infected, or transfected with the appropriate genes to establish whether endogenously produced antigen is also recognized by the T cells induced by the analog peptide. It is to be noted that peptide/protein-pulsed dendritic cells can be used to present whole protein antigens for both HLA class I and class II.
Another embodiment of the invention is to create analogs of weak binding peptides, to thereby ensure adequate numbers of cellular binders. Class I binding peptides exhibiting binding affinities of 500-5000 nM, and carrying an acceptable but suboptimal primary anchor residue at one or both positions can be "fixed" by substituting preferred anchor residues in accordance with the respective supertype. The analog peptides can then be tested for binding and/or cross-binding capacity.
Another embodiment of the invention is to create analogs of peptides that are already cross-reactive binders and are vaccine candidates, but which bind weakly to one or more alleles of a supertype. If the cross-reactive binder carries a suboptimal residue (less preferred or deleterious) at a primary or secondary anchor position, the peptide can be analoged by substituting out a deleterious residue and replacing it with a preferred or less preferred one, or by substituting out a less preferred reside and replacing it with a preferred one. The analog peptide can then be tested for cross-binding capacity.
Heteroclitic analogs
Heteroclitic analog peptides of the invention are particularly useful to induce an immune response against antigens to which a patient's immune system has become tolerant. Tolerance refers to a specific immunologic nonresponsiveness induced by prior exposure to an antigen. Thus, tolerance can be overcome in the patient by identifying a particular class I peptide epitope to which a patient is tolerant, modifying the peptide epitope sequence according to the methods of the invention, and inducing an immune response that cross-reacts against the tolerized epitope (antigen). Overcoming tolerance is particularly desirable, for example, when a patient's immune system is tolerant of a viral or tumor-associated antigen, the latter antigens being often over- expressed self-proteins as a consequence of cell transfonnation. Heteroclitic analoging is described in co-pending US provisional application number 60/166,529 filed 11/18/99 and US provisional application for "Heteroclitic Analogs And Related Methods", Tangri et al, inventors, Attorney Docket number 018623-015810US, filed 10/6/00.
Combinations of CTL andHTL epitopes
The peptides of the present invention or analogs thereof which have CTL stimulating activity may be modified to provide desired attributes other than improved serum half life. For instance, the ability of the peptides to induce CTL activity can be enhanced by linkage to a sequence which contains at least one epitope that is capable of inducing a T helper cell response. Particularly preferred immunogenic peptides/T helper conjugates are linked by a spacer molecule. The spacer is typically comprised of relatively small, neutral molecules, such as amino acids or amino acid mimetics, which are substantially uncharged under physiological conditions. The spacers are typically selected from, e.g., Ala, Gly, or other neutral spacers of nonpolar amino acids or neutral polar amino acids. It will be understood that the optionally present spacer need not be comprised of the same residues and thus may be a hetero- or homo-oligomer. When present, the spacer will usually be at least one or two residues, more usually three to six residues. Alternatively, the CTL peptide may be linked to the T helper peptide without a spacer.
The immunogenic peptide may be linked to the T helper peptide either directly or via a spacer either at the amino or carboxy terminus of the CTL peptide. The amino terminus of either the immunogenic peptide or the T helper peptide may be acylated. Exemplary T helper peptides include tetanus toxoid 830-843, influenza 307- 319, malaria circumsporozoite 382-398 and 378-389.
Combination with agents to prime the immune response h some embodiments it may be desirable to include in the pharmaceutical compositions of the invention at least one component which assists in priming CTL. Lipids have been identified as agents capable of assisting the priming CTL in vivo against viral antigens. For example, palmitic acid residues can be attached to the alpha and epsilon amino groups of a Lys residue and then linked, e.g., via one or more linking residues such as Gly, Gly-Gly-, Ser, Ser-Ser, or the like, to an immunogenic peptide. The lipidated peptide can then be injected directly in a micellar form, incorporated into a liposome or emulsified in an adjuvant, e.g., incomplete Freund's adjuvant. In a preferred embodiment a particularly effective immunogen comprises palmitic acid attached to alpha and epsilon amino groups of Lys, which is attached via linkage, e.g., Ser-Ser, to the amino terminus of the immunogenic peptide.
As another example of lipid priming of CTL responses, E. coli lipoproteins, such as tripalmitoyl-S-glycerylcysteinlyseryl-serine (P3CSS) can be used to prime virus specific CTL when covalently attached to an appropriate peptide. See, Deres et al, Nature 342:561-564 (1989), incorporated herein by reference. Peptides of the invention can be coupled to P3CSS, for example, and the lipopeptide administered to an individual to specifically prime a CTL response to the target antigen. Further, as the induction of neutralizing antibodies can also be primed with P3CSS conjugated to a peptide which displays an appropriate epitope, the two compositions can be combined to more effectively elicit both humoral and cell-mediated responses to infection.
In addition, additional amino acids can be added to the termini of a peptide to provide for ease of linking peptides one to another, for coupling to a carrier support, or larger peptide, for modifying the physical or chemical properties of the peptide or oligopeptide, or the like. Amino acids such as tyrosine, cysteine, lysine, glutamic or aspartic acid, or the like, can be introduced at the C- or N-terminus of the peptide or oligopeptide. Modification at the C terminus in some cases may alter binding characteristics of the peptide. hi addition, the peptide or oligopeptide sequences can differ from the natural sequence by being modified by terminal-NH2 acylation, e.g., by alkanoyl (C1-C20) or thioglycolyl acetylation, terminal-carboxyl amidation, e.g., ammonia, methylamine, etc. In some instances these modifications may provide sites for linking to a support or other molecule.
Vaccine compositions
The peptides of the present invention and pharmaceutical and vaccine compositions thereof are useful for administration to mammals, particularly humans, to treat and/or prevent viral infection and cancer. Examples of diseases which can be treated or prevented using the immunogenic peptides of the invention include prostate cancer, hepatitis B, hepatitis C, HPV infection, AIDS, renal carcinoma, cervical carcinoma, lymphoma, CMV, malaria, and condlyloma acuminatum.
Vaccines that contain an immunogenically effective amount of one or more peptides as described herein are a further embodiment of the invention. Once appropriately immunogenic epitopes have been defined, they can be delivered by various means, herein referred to as "vaccine" compositions. Such vaccine compositions can include, for example, lipopeptides (e.g-.,Vitiello, A. et al, J. Clin. Invest. 95:341, 1995), peptide compositions encapsulated in poly(DL-lactide-co-glycolide) ("PLG") microspheres (see, e.g., Eldridge, et al, Molec. Immunol. 28:287-294, 1991: Alonso et al, Vaccine 12:299-306, 1994; Jones et al, Vaccine 13:675-681, 1995), peptide compositions contained in immune stimulating complexes (ISCOMS) (.see, e.g., Takahashi et al, Nature 344:873-875, 1990; Hu et al, Clin Exp Immunol 113:235-243, 1998), multiple antigen peptide systems (MAPs) (see e.g., Tarn, J. P., Proc. Natl. Acad. Sci. U A. 85:5409-5413, 1988; Tarn, J.P., J. Immunol. Methods 196:17-32, 1996), viral delivery vectors (Perkus, M. E. et al, In: Concepts in vaccine development, Kaufmann, S. H. E., ed., p. 379, 1996; Chakrabarti, S. et al, Nature 320:535, 1986; Hu, S. L. et al, Nature 320:537, 1986; Kieny, M.-P. et al, AIDS Bio/Technology 4:790, 1986; Top, F. H. et al, J. Infect. Dis. 124:148, 1971; Chanda, P. K. et al, Virology 175:535, 1990), particles of viral or synthetic origin (e.g., Kofler, N. et al, J. Immunol. Methods. 192:25, 1996; Eldridge, J. H. et al, Sem. Hematol 30:16, 1993; Falo, L. D., Jr. et al, Nature Med. 7:649, 1995), adjuvants (Warren, H. S., Vogel, F. R., and Chedid, L. A. Annu. Rev. Immunol 4:369, 1986; Gupta, R. K. et al, Vaccine 11:293, 1993), liposomes (Reddy, R. et al, J. Immunol. 148:1585, 1992; Rock, K. L., Immunol. Today 17:131, 1996), or, naked or particle absorbed cDNA (Ulmer, J. B. et al, Science 259:1745, 1993; Robinson, H. L, Hunt, L. A., and Webster, R. G., Vaccine 11:957, 1993; Shiver, J. W. et al, In: Concepts in vaccine development, Kaufmann, S. H. E., ed., p. 423, 1996; Cease, K. B., and Berzofsky, J. A., Annu. Rev. Immunol 12:923, 1994 and Eldridge, J. H. et al, Sem. Hematol. 30:16, 1993). Toxin-targeted delivery technologies, also known as receptor mediated targeting, such as those of Avant hnmunotherapeutics, h e. (Needham, Massachusetts) may also be used.
Vaccine compositions of the invention include nucleic acid-mediated modalities. DNA or RNA encoding one or more of the peptides of the invention can also be administered to a patient. This approach is described, for instance, in Wolff et. al, Science 247:1465 (1990) as well as U.S. Patent Nos. 5,580,859; 5,589,466; 5,804,566; 5,739,118; 5,736,524; 5,679,647; WO 98/04720; and in more detail below. Examples of DNA-based delivery technologies include "naked DNA", facilitated (bupivicaine, polymers, peptide-mediated) delivery, cationic lipid complexes, and particle-mediated ("gene gun") or pressure-mediated delivery (see, e.g., U.S. Patent No. 5,922,687).
For therapeutic or prophylactic immunization purposes, the peptides of the invention can be expressed by viral or bacterial vectors. Examples of expression vectors include attenuated viral hosts, such as vaccinia or fowlpox. This approach involves the use of vaccinia virus, for example, as a vector to express nucleotide sequences that encode the peptides of the invention. Upon introduction into an acutely or chronically infected host or into a non-infected host, the recombinant vaccinia virus expresses the immunogenic peptide, and thereby elicits a host CTL and/or HTL response. Vaccinia vectors and methods useful in immunization protocols are described in, e.g., U.S. Patent No. 4,722,848. Another vector is BCG (Bacille Calmette Guerin). BCG vectors are described in Stover et al, Nature 351:456-460 (1991). A wide variety of other vectors useful for therapeutic administration or immunization of the peptides of the invention, e.g. adeno and adeno-associated virus vectors, retroviral vectors, Salmonella typhi vectors, detoxified anthrax toxin vectors, and the like, will be apparent to those skilled in the art from the description herein.
Furthermore, vaccines in accordance with the invention can encompass one or more of the peptides of the invention. Accordingly, a peptide can be present in a vaccine individually. Alternatively, the peptide can be individually linked to its own carrier; alternatively, the peptide can exist as a homopolymer comprising multiple copies of the same peptide, or as a heteropolymer of various peptides. Polymers have the advantage of increased immunological reaction and, where different peptide epitopes are used to make up the polymer, the additional ability to induce antibodies and/or CTLs that react with different antigenic determinants of the pathogenic organism or tumor-related peptide targeted for an immune response. The composition may be a naturally occurring region of an antigen or may be prepared, e.g., recombinantly or by chemical synthesis.
Carriers that can be used with vaccines of the invention are well known in the art, and include, e.g., thyroglobulin, albumins such as hmnan serum albumin, tetanus toxoid, polyamino acids such as poly L-lysine, poly L-glutamic acid, influenza, hepatitis B virus core protein, and the like. The vaccines can contain a physiologically tolerable (i.e., acceptable) diluent such as water, or saline, preferably phosphate buffered saline. The vaccines also typically include an adjuvant. Adjuvants such as incomplete Freund's adjuvant, aluminum phosphate, aluminum hydroxide, or alum are examples of materials well known in the art. Additionally, CTL responses can be primed by conjugating peptides of the invention to lipids, such as tripalmitoyl-S-glycerylcysteinlyseryl- serine (P3CSS).
Upon immunization with a peptide composition in accordance with the invention, via injection, aerosol, oral, transdermal, transmucosal, intrapleural, intrathecal, or other suitable routes, the immune system of the host responds to the vaccine by producing large amounts of CTLs specific for the desired antigen. Consequently, the host becomes at least partially immune to later infection, or at least partially resistant to developing an ongoing chronic infection, or derives at least some therapeutic benefit when the antigen was tumor-associated.
In certain embodiments, components that induce T cell responses are combined with component that induce antibody responses to the target antigen of interest, combine class I peptide vaccines of the invention with vaccines which induce or facilitate neutralizing antibody responses to the target antigen of interest, particularly to viral envelope antigens. A preferred embodiment of such a composition comprises class I and class II epitopes in accordance with the invention. An alternative embodiment of such a composition comprises a class I epitope in accordance with the invention, along with a pan DR binding molecule, e.g., PADRE™ (Epimmune, San Diego, CA) (described, for example, in U.S. Patent Number 5,736,142).
Minigenes A preferred means of administering nucleic acids encoding the peptides of the invention uses minigene constructs encoding multiple epitopes of the invention. To create a DNA sequence encoding the selected CTL epitopes (minigene) for expression in human cells, the amino acid sequences of the epitopes are reverse translated. A human codon usage table is used to guide the codon choice for each amino acid. These epitope- encoding DNA sequences are directly adjoined, creating a continuous polypeptide sequence. To optimize expression and/or immunogenicity, additional elements can be incorporated into the minigene design. Examples of amino acid sequence that could be reverse translated and included in the minigene sequence include: helper T lymphocyte epitopes, a leader (signal) sequence, and an endoplasmic reticulum retention signal. In addition, MHC presentation of CTL epitopes may be improved by including synthetic (e.g. poly-alanine) or naturally-occurring flanking sequences adjacent to the CTL epitopes.
The minigene sequence is converted to DNA by assembling oligonucleotides that encode the plus and minus strands of the minigene. Overlapping oligonucleotides (30-100 bases long) are synthesized, phosphorylated, purified and annealed under appropriate conditions using well known techniques, he ends of the oligonucleotides are joined using T4 DNA ligase. This synthetic minigene, encoding the CTL epitope polypeptide, can then cloned into a desired expression vector.
Standard regulatory sequences well known to those of skill in the art are included in the vector to ensure expression in the target cells. Several vector elements are required: a promoter with a down-stream cloning site for minigene insertion; a polyadenylation signal for efficient transcription termination; an E. coli origin of replication; and an E. coli selectable marker (e.g. ampicillin or kanamycin resistance). Numerous promoters can be used for this purpose, e.g., the human cytomegalovirus (hCMV) promoter. See, U.S. Patent Nos. 5,580,859 and 5,589,466 for other suitable promoter sequences.
Additional vector modifications may be desired to optimize minigene expression and immunogenicity. In some cases, introns are required for efficient gene expression, and one or more synthetic or naturally-occurring introns could be incorporated into the transcribed region of the minigene. The inclusion of mRNA stabilization sequences can also be considered for increasing minigene expression. It has recently been proposed that immunostimulatory sequences (ISSs or CpGs) play a role in the immunogenicity of DNA vaccines. These sequences could be included in the vector, outside the minigene coding sequence, if found to enhance immunogenicity. h some embodiments, a bicistronic expression vector, to allow production of the minigene-encoded epitopes and a second protein included to enhance or decrease immunogenicity can be used. Examples of proteins or polypeptides that could beneficially enhance the immune response if co-expressed include cytokines (e.g., ΪL2, IL12, GM-CSF), cytokine-inducing molecules (e.g. LelF) or costimulatory molecules. Helper (HTL) epitopes could be joined to intracellular targeting signals and expressed separately from the CTL epitopes. This would allow direction of the HTL epitopes to a cell compartment different than the CTL epitopes. If required, this could facilitate more efficient entry of HTL epitopes into the MHC class II pathway, thereby improving CTL induction. In contrast to CTL induction, specifically decreasing the immune response by co-expression of immunosuppressive molecules (e.g. TGF-β) maybe beneficial in certain diseases.
Once an expression vector is selected, the minigene is cloned into the polylinker region downstream of the promoter. This plasmid is transformed into an appropriate E. coli strain, and DNA is prepared using standard techniques. The orientation and DNA sequence of the minigene, as well as all other elements included in the vector, are confirmed using restriction mapping and DNA sequence analysis. Bacterial cells harboring the correct plasmid can be stored as a master cell bank and a working cell bank.
Therapeutic quantities of plasmid DNA are produced by fermentation in E. coli, followed by purification. Aliquots from the working cell bank are used to inoculate fermentation medium (such as Terrific Broth), and grown to saturation in shaker flasks or a bioreactor according to well known techniques. Plasmid DNA can be purified using standard bioseparation technologies such as solid phase anion-exchange resins supplied by Quiagen. If required, supercoiled DNA can be isolated from the open circular and linear forms using gel electrophoresis or other methods.
Purified plasmid DNA can be prepared for injection using a variety of formulations. The simplest of these is reconstitution of lyophilized DNA in sterile phosphate-buffer saline (PBS). A variety of methods have been described, and new techniques may become available. As noted above, nucleic acids are conveniently formulated with cationic lipids. In addition, glycolipids, fusogenic liposomes, peptides and compounds referred to collectively as protective, interactive, non-condensing (PINC) could also be complexed to purified plasmid DNA to influence variables such as stability, intramuscular dispersion, or trafficking to specific organs or cell types.
Target cell sensitization can be used as a functional assay for expression and MHC class I presentation of minigene-encoded CTL epitopes. The plasmid DNA is introduced into a mammalian cell line that is suitable as a target for standard CTL chromium release assays. The transfection method used will be dependent on the final formulation. Electroporation can be used for "naked" DNA, whereas cationic lipids allow direct in vitro transfection. A plasmid expressing green fluorescent protein (GFP) can be co-transfected to allow enrichment of transfected cells using fluorescence activated cell sorting (FACS). These cells are then chromium-51 labeled and used as target cells for epitope-specific CTL lines. Cytolysis, detected by 51Cr release, indicates production of MHC presentation of minigene-encoded CTL epitopes.
In vivo immunogenicity is a second approach for functional testing of minigene DNA formulations. Transgenic mice expressing appropriate human MHC molecules are immunized with the DNA product. The dose and route of administration are formulation dependent (e.g. EVI for DNA in PBS, IP for lipid-complexed DNA). Twenty-one days after immunization, splenocytes are harvested and restimulated for 1 week in the presence of peptides encoding each epitope being tested. These effector cells (CTLs) are assayed for cytolysis of peptide-loaded, chromium-51 labeled target cells using standard techniques. Lysis of target cells sensitized by MHC loading of peptides corresponding to minigene-encoded epitopes demonstrates DNA vaccine function for in vivo induction of CTLs.
Ex vivo administration of epitopes
An embodiment of a vaccine composition in accordance with the invention comprises ex vivo administration of a cocktail of epitope-bearing peptides to PBMC, or isolated DC therefrom, from the patient's blood. After pulsing the DC with peptides and prior to reinfusion into patients, the DC are washed to remove unbound peptides. In this embodiment, a vaccine comprises peptide-pulsed DCs which present the pulsed peptide epitopes in HLA molecules on their surfaces.
Dendritic cells can also be transfected, e.g., with a minigene comprising nucleic acid sequences encoding the epitopes in accordance with the invention, in order to elicit immune responses. Vaccine compositions can be created in vitro, following dendritic cell mobilization and harvesting, whereby loading of dendritic cells occurs in vitro.
Antigenic peptides are used to elicit a CTL response ex vivo, as well. The resulting CTL cells, can be used to treat chronic infections, or tumors in patients that do not respond to other conventional fonns of therapy, or will not respond to a therapeutic vaccine peptide or nucleic acid in accordance with the invention. Ex vivo CTL or HTL responses to a particular antigen (infectious or tumor-associated antigen) are induced by incubating in tissue culture the patient's, or genetically compatible, CTL or HTL precursor cells together with a source of antigen-presenting cells (APC), such as dendritic cells, and the appropriate immunogenic peptide. After an appropriate incubation time (typically about 7-28 days), in which the precursor cells are activated and expanded into effector cells, the cells are infused back into the patient, where they will destroy their specific target cell (an infected cell or a tumor cell). Transfected dendritic cells may also be used as antigen presenting cells.
Administration of vaccine compositions For pharmaceutical compositions, the immunogenic peptides of the invention are administered to an individual already suffering from cancer or infected with the virus of interest. Those in the incubation phase or the acute phase of infection can be treated with the immunogenic peptides separately or in conjunction with other treatments, as appropriate. In therapeutic applications, compositions are administered to a patient in an amount sufficient to elicit an effective CTL response to the virus or tumor antigen and to cure or at least partially arrest symptoms and/or complications. An amount adequate to accomplish this'is defined as "therapeutically effective dose." Amounts effective for this use will depend on, e.g., the peptide composition, the manner of administration, the stage and severity of the di jease being treated, the weight and general state of health of the patient, and the judgment of the prescribing physician, but generally range for the initial immunization (that is for therapeutic or prophylactic administration) from about 1.0 μg to about 50,000 μg of peptide for a 70 kg patient, followed by boosting dosages of from about 1.0 μg to about 10,000 μg of peptide pursuant to a boosting regimen over weeks to months depending upon the patient's response and condition by measuring specific CTL activity in the patient's blood. It must be kept in mind that the peptides and compositions of the present invention may generally be employed in serious disease states, that is, life- threatening or potentially life threatening situations, hi such cases, in view of the minimization of extraneous substances and the relative nontoxic nature of the peptides, it is possible and may be felt desirable by the treating physician to administer substantial excesses of these peptide compositions.
For therapeutic use, administration should begin at the first sign of viral infection or the detection or surgical removal of tumors or shortly after diagnosis in the case of acute infection. This is followed by boosting doses until at least symptoms are substantially abated and for a period thereafter. In chronic infection, loading doses followed by boosting doses may be required.
Treatment of an infected individual with the compositions of the invention may hasten resolution of the infection in acutely infected individuals. For those individuals susceptible (or predisposed) to developing chronic infection the compositions are particularly useful in methods for preventing the evolution from acute to chronic infection. Where the susceptible individuals are identified prior to or during infection, for instance, as described herein, the composition can be targeted to them, minimizing need for administration to a larger population.
The peptide compositions can also be used for the treatment of chronic infection and to stimulate the immune system to eliminate virus-infected cells in carriers. It is important to provide an amount of iinmuno-potentiating peptide in a formulation and mode of administration sufficient to effectively stimulate a cytotoxic T cell response. Thus, for treatment of chronic infection, a representative dose is in the range of about 1.0 μg to about 50,000 μg, preferably about 5 μg to 10,000 μg for a 70 kg patient per dose. Immunizing doses followed by boosting doses at established intervals, e.g., from one to four weeks, may be required, possibly for a prolonged period of time to effectively immunize an individual, hi the case of chronic infection, administration should continue until at least clinical symptoms or laboratory tests indicate that the viral infection has been eliminated or substantially abated and for a period thereafter.
The pharmaceutical compositions for therapeutic treatment are intended for parenteral, topical, oral or local administration. Preferably, the pharmaceutical compositions are administered parenterally, e.g., intravenously, subcutaneously, intradermally, or intramuscularly. Thus, the invention provides compositions for parenteral administration which comprise a solution of the immunogenic peptides dissolved or suspended in an acceptable carrier, preferably an aqueous carrier. A variety of aqueous carriers maybe used, e.g., water, buffered water, 0.9% saline, 0.3% glycine, hyaluronic acid and the like. These compositions may be sterilized by conventional, well known sterilization techniques, or may be sterile filtered. The resulting aqueous solutions may be packaged for use as is, or lyophilized, the lyophilized preparation being combined with a sterile solution prior to administration. The compositions may contain pharmaceutically acceptable auxiliary substances as required to approximate physiological conditions, such as pH adjusting and buffering agents, tonicity adjusting agents, wetting agents and the like, for example, sodium acetate, sodium lactate, sodium chloride, potassium chloride, calcium chloride, sorbitan monolaurate, triethanolamine oleate, etc. The concentration of CTL stimulatory peptides of the invention in the pharmaceutical formulations can vary widely, i.e., from less than about 0.1%, usually at or at least about 2% to as much as 20% to 50%> or more by weight, and will be selected primarily by fluid volumes, viscosities, etc., in accordance with the particular mode of administration selected.
The peptides of the invention may also be administered via liposomes, which target the peptides to a particular cells tissue, such as lymphoid tissue. Liposomes are also useful in increasing the half-life of the peptides. Liposomes include emulsions, foams, micelles, insoluble monolayers, liquid crystals, phospholipid dispersions, lamellar layers and the like. In these preparations the peptide to be delivered is incorporated as part of a liposome, alone or in conjunction with a molecule which binds to, e.g., a receptor prevalent among lymphoid cells, such as monoclonal antibodies which bind to the CD45 antigen, or with other therapeutic or immunogenic compositions. Thus, liposomes filled with a desired peptide of the invention can be directed to the site of lymphoid cells, where the liposomes then deliver the selected therapeutic/immunogenic peptide compositions. Liposomes for use in the invention are formed from standard vesicle-forming lipids, which generally include neutral and negatively charged phospholipids and a sterol, such as cholesterol. The selection of lipids is generally guided by consideration of, e.g., liposome size, acid lability and stability of the liposomes in the blood stream. A variety of methods are available for preparing liposomes, as described in, e.g., Szoka et al, Ann. Rev. Biophys. Bioeng. 9:467 (1980), U.S. Patent Nos. 4,235,871, 4,501,728, 4,837,028, and 5,019,369, incorporated herein by reference.
For targeting to the immune cells, a ligand to be incorporated into the liposome can include, e.g., antibodies or fragments thereof specific for cell surface determinants of the desired immune system cells. A liposome suspension containing a peptide may be administered intravenously, locally, topically, etc. in a dose which varies according to, inter alia, the manner of administration, the peptide being delivered, and the stage of the disease being treated.
For solid compositions, conventional nontoxic solid carriers may be used which include, for example, pharmaceutical grades of mannitol, lactose, starch, magnesium stearate, sodium saccharin, talcum, cellulose, glucose, sucrose, magnesium carbonate, and the like. For oral administration, a pharmaceutically acceptable nontoxic composition is formed by incorporating any of the normally employed excipients, such as those carriers previously listed, and generally 10-95%) of active ingredient, that is, one or more peptides of the invention, and more preferably at a concentration of 25%-75%. For aerosol administration, the immunogenic peptides are preferably supplied in finely divided form along with a surfactant and propellant. Typical percentages of peptides are 0.01%-20% by weight, preferably 1%-10%. The surfactant must, of course, be nontoxic, and preferably soluble in the propellant. Representative of such agents are the esters or partial esters of fatty acids containing from 6 to 22 carbon atoms, such as caproic, octanoic, lauric, palmitic, stearic, linoleic, linolenic, olesteric and oleic acids with an aliphatic polyhydric alcohol or its cyclic anhydride. Mixed esters, such as mixed or natural glycerides may be employed. The surfactant may constitute 0.1%-20% by weight of the composition, preferably 0.25-5%>. The balance of the composition is ordinarily propellant. A carrier can also be included, as desired, as with, e.g., lecithin for intranasal delivery. Upon immunization with a peptide composition as described herein, via injection, aerosol, oral, transdermal or other route, the immune system of the host responds to the vaccine by producing large amounts of CTLs specific for the desired antigen, and the host becomes at least partially immune to later infection, or resistant to developing chronic infection. In some instances it may be desirable to combine the peptide vaccines of the invention with vaccines which induce neutralizing antibody responses to the virus of interest, particularly to viral envelope antigens.
Antigenic peptides may be used to elicit CTL ex vivo, as well. The resulting CTL, can be used to treat chronic infections (viral or bacterial) or tumors in patients that do not respond to other conventional forms of therapy, or will not respond to a peptide vaccine approach of therapy. Ex vivo CTL responses to a particular pathogen (infectious agent or tumor antigen) are induced by incubating in tissue culture the patient's CTL precursor cells (CTLp) together with a source of antigen-presenting cells (APC) and the appropriate immunogenic peptide. After an appropriate incubation time (typically 1-4 weeks), in which the CTLp are activated and mature and expand into effector CTL, the cells are infused back into the patient, where they will destroy their specific target cell (an infected cell or a tumor cell). In order to optimize the in vitro conditions for the generation of specific cytotoxic T cells, the culture of stimulator cells is maintained in an appropriate serum-free medium.
Prior to incubation of the stimulator cells with the cells to be activated, e.g., precursor CD8+ cells, an amount of antigenic peptide is added to the stimulator cell culture, of sufficient quantity to become loaded onto the human Class I molecules to be expressed on the surface of the stimulator cells. In the present invention, a sufficient amount of peptide is an amount that will allow about 200, and preferably 200 or more, human Class I MHC molecules loaded with peptide to be expressed on the surface of each stimulator cell. Often, the stimulator cells are incubated with >20 μg/ml peptide. Resting or precursor CD 8+ cells are then incubated in culture with the appropriate stimulator cells for a time period sufficient to activate the CD8+ cells. Preferably, the CD8+ cells are activated in an antigen-specific manner. The ratio of resting or precursor CD8+ (effector) cells to stimulator cells may vary from individual to individual and may further depend upon variables such as the amenability of an individual's lymphocytes to culturing conditions and the nature and severity of the disease condition or other condition for which the within-described treatment modality is used. Preferably, however, the lymphocyte: stimulator cell ratio is in the range of about 30: 1 to 300: 1. The effector/stimulator culture may be maintained for as long a time as is necessary to stimulate a therapeutically useable or effective number of CD8+ cells. The induction of CTL in vitro requires the specific recognition of peptides that are bound to allele specific MHC class I molecules on APC. The number of specific MHC/peptide complexes per APC is crucial for the stimulation of CTL, particularly in primary immune responses. While small amounts of peptide/MHC complexes per cell are sufficient to render a cell susceptible to lysis by CTL, or to stimulate a secondary CTL response, the successful activation of a CTL precursor (pCTL) during primary response requires a significantly higher number of MHC/peptide complexes. Peptide loading of empty major histocompatability complex molecules on cells allows the induction of primary cytotoxic T lymphocyte responses. Peptide loading of empty major histocompatability complex molecules on cells enables the induction of primary cytotoxic T lymphocyte responses.
Since mutant cell lines do not exist for every human MHC allele, it is advantageous to use a technique to remove endogenous MHC-associated peptides from the surface of APC, followed by loading the resulting empty MHC molecules with the immunogenic peptides of interest. The use of non-transformed (non-tumorigenic), non- infected cells, and preferably, autologous cells of patients as APC is desirable for the design of CTL induction protocols directed towards development of ex vivo CTL therapies. This application discloses methods for stripping the endogenous MHC- associated peptides from the surface of APC followed by the loading of desired peptides.
A stable MHC class I molecule is a trimeric complex formed of the following elements: 1) a peptide usually of 8 - 10 residues, 2) a transmembrane heavy polymorphic protein chain which bears the peptide-binding site, and 3) a non-covalently associated non-polymorphic light chain, β2 microglobulin. Removing the bound peptides and/or dissociating the β2 microglobulin from the complex renders the MHC class I molecules nonfunctional and unstable, resulting in rapid degradation. All MHC class I molecules isolated from peripheral blood monocytic cells (PBMC) have endogenous peptides bound to them. Therefore, the first step is to remove all endogenous peptides bound to MHC class I molecules on the APC without causing their degradation before exogenous peptides can be added to them.
Two possible ways to free up MHC class I molecules of bound peptides include lowering the culture temperature from 37°C to 26°C overnight to destablize β2microglobulin and stripping the endogenous peptides from the cell using a mild acid treatment. The methods release previously bound peptides into the extracellular environment allowing new exogenous peptides to bind to the empty class I molecules. The cold-temperature incubation method enables exogenous peptides to bind efficiently to the MHC complex, but requires an overnight incubation at 26°C which may slow the cell's metabolic rate. It is also likely that cells not actively synthesizing MHC molecules (e.g. , resting PBMC) would not produce high amounts of empty surface MHC molecules by the cold temperature procedure.
Harsh acid stripping involves extraction of the peptides with trifluoroacetic acid, pH 2, or acid denaturation of the immunoaffinity purified class I-peptide complexes. These methods are not feasible for CTL induction, since it is important to remove the endogenous peptides while preserving APC viability and an optimal metabolic state which is critical for antigen presentation. Mild acid solutions of pH 3 such as glycine or citrate-phosphate buffers have been used to identify endogenous peptides and to identify tumor associated T cell epitopes. The treatment is especially effective, in that only the MHC class I molecules are destabilized (and associated peptides released), while other surface antigens remain intact, including MHC class II molecules. Most importantly, treatment of cells with the mild acid solutions do not affect the cell's viability or metabolic state. The mild acid treatment is rapid since the stripping of the endogenous peptides occurs in two minutes at 4°C and the APC is ready to perform its function after the appropriate peptides are loaded. The technique is utilized herein to make peptide- specific APCs for the generation of primary antigen-specific CTL. The resulting APC are efficient in inducing peptide-specific CD8+ CTL. Activated CD8+ cells may be effectively separated from the stimulator cells using one of a variety of known methods. For example, monoclonal antibodies specific for the stimulator cells, for the peptides loaded onto the stimulator cells, or for the CD8+ cells (or a segment thereof) may be utilized to bind their appropriate complementary ligand. Antibody-tagged molecules may then be extracted from the stimulator-effector cell admixture via appropriate means, e.g., via well-known immunoprecipitation or immunoassay methods.
Effective, cytotoxic amounts of the activated CD8+ cells can vary between in vitro and in vivo uses, as well as with the amount and type of cells that are the ultimate target of these killer cells. The amount will also vary depending on the condition of the patient and should be determined via consideration of all appropriate factors by the practitioner. Preferably, however, about 1 X 10 to about 1 X 10 , more preferably about 1 X 108 to about 1 X 1011, and even more preferably, about 1 X 109 to about 1 X 1010 activated CD8+ cells are utilized for adult humans, compared to about 5 X 106 - 5 X 107 cells used in mice. Preferably, as discussed above, the activated CD8+ cells are harvested from the cell culture prior to administration of the CD8+ cells to the individual being treated. It is important to note, however, that unlike other present and proposed treatment modalities, the present method uses a cell culture system that is not tumorigenic. Therefore, if complete separation of stimulator cells and activated CD8+ cells is not achieved, there is no inherent danger known to be associated with the administration of a small number of stimulator cells, whereas administration of mammalian tumor-promoting cells may be extremely hazardous. Methods of re-introducing cellular components are known in the art and include procedures such as those exemplified in U.S. Patent No. 4,844,893 to Honsik, et al and U.S. Patent No. 4,690,915 to Rosenberg. For example, administration of activated CD8+ cells via intravenous infusion is appropriate.
Use of Peptide Epitopes as Diagnostic Agents for Evaluating Immune Responses
In one embodiment of the invention, HLA class I and class II binding peptides can be used as reagents to evaluate an immune response. The evaluated immune response can be induced by any immunogen. For example, the immunogen may result in the production of antigen-specific CTLs or HTLs that recognize the peptide epitope(s) employed as the reagent. Thus, a peptide of the invention may or may not be used as the immunogen. Assay systems that can be used for such analyses include tetramer-based protocols, staining for intracellular lymphokines, interferon release assays, or ELISPOT assays. For example, following exposure to a putative immunogen, a peptide of the invention can be used in a tetramer staining assay to assess peripheral blood mononuclear cells for the presence of any antigen-specific CTLs. The HLA-tetrameric complex is used to directly visualize antigen-specific CTLs and thereby determine the frequency of such antigen-specific CTLs in a sample of peripheral blood mononuclear cells (see, e.g., Ogg et al, Science 279:2103-2106, 1998; and Altinan et al, Science 174:94-96, 1996).
A tetramer reagent comprising a peptide of the invention is generated as follows: A peptide that binds to an HLA molecule is refolded in the presence of the corresponding HLA heavy chain and β2-microglobulin to generate a trimolecular complex. The complex is biotinylated at the carboxyl terminal end of the HLA heavy chain, at a site that was previously engineered into the protein. Tetramer formation is then induced by adding streptavidin. When fluorescently labeled streptavidin is used, the tetrameric complex is used to stain antigen-specific cells. The labeled cells are then readily identified, e.g., by flow cytometry. Such procedures are used for diagnostic or prognostic purposes; the cells identified by the procedure can be used for therapeutic purposes. Peptides of the invention are also used as reagents to evaluate immune recall responses, (see, e.g., Bertoni et al, J. Clin. Invest. 100:503-513, 1997 and Penna et al, J. Exp. Med. 174:1565-1570, 1991.) For example, a PBMC sample from an individual expressing a disease-associated antigen (e.g. a tumor-associated antigen such as CEA, p53, MAGE2/3,HER2neu, or an organism associated with neoplasia such as HPV or HS V) can be analyzed for the presence of antigen-specific CTLs or HTLs using specific peptides. A blood sample containing mononuclear cells may be evaluated by cultivating the PBMCs and stimulating the cells with a peptide of the invention. After an appropriate cultivation period, the expanded cell population may be analyzed, for example, for CTL or for HTL activity.
Thus, the peptides can be used to evaluate the efficacy of a vaccine. PBMCs obtained from a patient vaccinated with an immunogen may be analyzed by methods such as those described herein. The patient is HLA typed, and peptide epitopes that are bound by the HLA molecule(s) present in that patient are selected for analysis. The immunogenicity of the vaccine is indicated by the presence of CTLs and/or HTLs directed to epitopes present in the vaccine, o
The peptides of the invention may also be used to make antibodies, using techniques well known in the art (see, e.g. CURRENT PROTOCOLS IN IMMUNOLOGY, Wiley/Greene, NY; and Antibodies A Laboratory Manual Harlow, Harlow and Lane, Cold Spring Harbor Laboratory Press, 1989). Such antibodies are useful as reagents to determine the presence of disease-associated antigens or may be used therapetucially. Antibodies in this category include those that recognize a peptide when bound by an HLA molecule, i.e., antibodies that bind to a peptide-MHC complex.
Epitopes in accordance with the present invention were successfully used to induce an immune response. Immune responses with these epitopes have been induced by administering the epitopes in various forms. The epitopes have been administered as peptides, as nucleic acids, and as viral vectors comprising nucleic acids that encode the epitope(s) of the invention. Upon administration of peptide-based epitope forms, immune responses have been induced by direct loading of an epitope onto an empty HLA molecule that is expressed on a cell, and via intemalization of the epitope and processing via the HLA class I pathway; in either event, the HLA molecule expressing the epitope was then able to interact with and induce a CTL response. Peptides can be delivered directly or using such agents as liposomes. They can additionally be delivered using ballistic delivery, in which the peptides are typically in a crystalline form. When DNA is used to induce an irnmuiie response, it is administered either as naked DNA, generally in a dose range of approximately 1-5 mg, or via the ballistic "gene gun" delivery, typically in a dose range of approximately 10-100 μg. The DNA can be delivered in a variety of conformations, e.g., linear, circular etc. Various viral vectors have also successfully been used that comprise nucleic acids which encode epitopes in accordance with the invention. Accordingly compositions in accordance with the invention exist in several forms. Embodiments of each of these composition forms in accordance with the invention have been successfully used to induce an immune response.
One composition in accordance with the invention comprises a plurality of peptides. This plurality or cocktail of peptides is generally admixed with one or more pharmaceutically acceptable excipients. The peptide cocktail can comprise multiple copies of the same peptide or can comprise a mixture of peptides. The peptides can be analogs of naturally occurring epitopes. The peptides can comprise artificial amino acids and/or chemical modifications such as addition of a surface active molecule, e.g., lipidation; acetylation, glycosylation, biotinylation, phosphorylation etc. The peptides can be CTL or HTL epitopes. hi a preferred embodiment the peptide cocktail comprises a plurality of different CTL epitopes and at least one HTL epitope. The HTL epitope can be naturally or non-naturally (e.g., PADRE®, Epimmune Inc., San Diego, CA). The number of distinct epitopes in an embodiment of the invention is generally a whole unit integer from one through one hundred fifty (e.g., 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64, 65, 66, 67, 68, 69, 70, 71, 72, 73, 74, 75, 76, 77, 78, 79, 80, 81, 82, 83, 84, 85, 86, 87, 88, 89, 90, 91, 92, 93, 94, 95, 96, 97, 98, 99, or, 100).
An additional embodiment of a composition in accordance with the invention comprises a polypeptide multi-epitope construct, i.e., a polyepitopic peptide. Polyepitopic peptides in accordance with the invention are prepared by use of technologies well-known in the art. By use of these known technologies, epitopes in accordance with the invention are connected one to another. The polyepitopic peptides can be linear or non-linear, e.g., multivalent. These polyepitopic constructs can comprise artificial amino acids, spacing or spacer amino acids, flanking amino acids, or chemical modifications between adjacent epitope units. The polyepitopic construct can be a heteropolymer or a homopolymer. The polyepitopic constructs generally comprise epitopes in a quantity of any whole unit integer between 2-150 (e.g., 2, 3, , 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64, 65, 66, 67, 68, 69, 70, 71, 72, 73, 74, 75, 76, 77, 78, 79, 80, 81, 82, 83, 84, 85, 86, 87, 88, 89, 90, 91, 92, 93, 94, 95, 96, 97, 98, 99, or, 100). The polyepitopic construct can comprise CTL and/or HTL epitopes. One or more of the epitopes in the construct can be modified, e.g., by addition of a surface active material, e.g. a lipid, or chemically modified, e.g., acetylation, etc. Moreover, bonds in the multiepitopic construct can be other than peptide bonds, e.g., covalent bonds, ester or ether bonds, disulfide bonds, hydrogen bonds, ionic bonds etc.
Alternatively, a composition in accordance with the invention comprises construct which comprises a series, sequence, stretch, etc. , of amino acids that have homology to ( i.e., corresponds to or is contiguous with) to a native sequence. This stretch of amino acids comprises at least one subsequence of amino acids that, if cleaved or isolated from the longer series of amino acids, functions as an HLA class I or HLA class II epitope in accordance with the invention. In this embodiment, the peptide sequence is modified, so as to become a construct as defined herein, by use of any number of techniques known or to be provided in the art. The polyepitopic constructs can contain homology to a native sequence in any whole unit integer increment from 70-100%, e.g., 70, 71, 72, 73, 74, 75, 76, 77, 78, 79, 80, 81, 82, 83, 84, 85, 86, 87, 88, 89, 90, 91, 92, 93, 94, 95, 96, 97, 98, 99, or, 100 percent. A further embodiment of a composition in accordance with the invention is an antigen presenting cell that comprises one or more epitopes in accordance with the invention. The antigen presenting cell can be a "professional" antigen presenting cell, such as a dendritic cell. The antigen presenting cell can comprise the epitope of the invention by any means known or to be determined in the art. Such means include pulsing of dendritic cells with one or more individual epitopes or with one or more peptides that comprise multiple epitopes, by nucleic acid administration such as ballistic nucleic acid delivery or by other techniques in the art for administration of nucleic acids, including vector-based, e.g. viral vector, delivery of nucleic acids.
Further embodiments of compositions in accordance with the invention comprise nucleic acids that encode one or more peptides of the invention, or nucleic acids which encode a polyepitopic peptide in accordance with the invention. As appreciated by one of ordinary skill in the art, various nucleic acids compositions will encode the same peptide due to the redundancy of the genetic code. Each of these nucleic acid compositions falls within the scope of the present invention. This embodiment of the invention comprises DNA or RNA, and in certain embodiments a combination of DNA and RNA. It is to be appreciated that any composition comprising nucleic acids that will encode a peptide in accordance with the invention or any other peptide based composition in accordance with the invention, falls within the scope of this invention.
It is to be appreciated that peptide-based forms of the invention (as well as the nucleic acids that encode them) can comprise analogs of epitopes of the invention generated using priniciples aheady known, or to be known, in the art. Principles related to analoging are now known in the art, and are disclosed herein; moreover, analoging principles are disclosed in co-pending application serial number U.S.S.N. 09/226,775 filed 6 January 1999. Generally the compositions of the invention are isolated or purified.
All publications and patent applications cited in this specification are herein incorporated by reference as if each individual publication or patent application were specifically and individually indicated to be incorporated by reference.
Although the foregoing invention has been described in some detail by way of illustration and example for purposes of clarity of understanding, it will be readily apparent to one of ordinary skill in the art in light of the teachings of this invention that certain changes and modifications may be made thereto without departing from the spirit or scope of the appended claims.
EXAMPLES The following examples are provided by way of illustration only and not by way of limitation. Those of skill in the art will readily recognize a variety of noncritical parameters that could be changed or modified to yield essentially similar results. Example 1 HLA class I supermotif and motif analysis of antigens of interest was performed as described herein and in the related applications, noted above. Peptides comprising the appropriate HLA I motif or supermotif were then synthesized and assayed for binding activity. A detailed description of the protocol utilized to measure the binding of peptides to Class I and Class II MHC has been published (Sette et al, Mol. Immunol. 31:813, 1994; Sidney et al., in Current Protocols in Immunology, Margulies, Ed., John Wiley & Sons, New York, Section 18.3, 1998).
Since under these conditions [label]<[HLA] and ICso≥fHLA], the measured IC50 values are reasonable approximations of the true KD values. To allow comparison of the data obtained in different experiments, a relative binding figure is calculated for each peptide by dividing the IC50 of a positive control for inhibition by the IC50 for each tested peptide (typically unlabeled versions of the radiolabeled probe peptide). For inter-experiment comparisons, relative binding values are compiled. These values can subsequently be converted back into IC50 nM values by dividing the IC50 nM of the positive controls for inhibition by the relative binding of the peptide of interest. This method of data compilation has proven to be the most accurate and consistent for comparing peptides that have been tested on different days, or with different lots of purified MHC. HLA class I supermotif and motif-bearing peptides from HIV regulatory proteins, e.g., nef, rev, vif, tat, and vpr, are shown in Tables 2-11. hi these tables, "% conserv" refers to percent conservance, which is the degree to which the sequences are conserved in the strains evaluated to identify the sequences. The "A" designation indicates that the peptide is an analog of the native sequence, hi the motif column, the designation "i" refers to individual motif and "s" refers to supermotif.
HLA class I supermotif and motif-bearing peptides from other antigens, e.g., cancer antigens such as CEA, p53, Her2/neu, MARTI, MAGE2, MAGE3, tyrosinase, flu, gp 100, HB V, HCV, HIV, HPV (including the strain designation), Epstein Barr Virus (EBV), prostate cancer-associated antigens, gliadin, Mycobacterium leprae, Mycobacterium tuberculosis, T. cruzi, Candida antigens, and malaria (Plasmodium falciparum) antigens are shown in Tables 12-24.
Tables 12 and 13 show peptides bearing an HLA-Al supermotif and/or motif. Tables 14-17 shows peptides bearing an HLA-A2 supennotif. Tables 18 and 19 show peptides bearing an HLA- A3 supermotif and/or motif. Tables 20 and 21 show peptides bearing an HLA-A24 supermotif and/or motif. Tables 22 and 23 show peptides bearing an HLA-B7 supermotiff. Table 24 shows peptides bearing an HLA-B44 supermotif.
Peptide binding data for the designated HLA molecules are provided as IC50 values unless otherwise indicated. The "A" designation indicates that the peptide is an analog of the native sequence.
Example 2 Using the HLA class II supermotif and motifs identified in related applications and as described above, sequences from various pathogens and tumor-related proteins were analyzed for the presence of these motifs. Screening and binding assays was carried out as described in the related applications designated herein.
HLA class II DR supermotif and DR3 motif-bearing peptides from HIV regulatory proteins, e.g. , nef, rev, vif, tat, and vpr, are shown in Tables 25 and 31. The term "% conserv" refers to percent conservance, which is the degree to which the sequences are conserved in the strains evaluated to identify the sequences. In Table 31, in the "sequence" column, the core sequence of the motif-bearing peptide is in lower case. Tables 26-31 shows HLA class II DR supermotif and DR 3 motif bearing peptides and the antigens from which they are derived. The peptide reference number, sequence, antigen protein position of the sequence in the antigen, and binding data are shown in the tables. Table 27a shows binding data for DRB1*0101, *0301, *0401, *0404, and *0405. Table 27b shows binding data for DRB1*0701, *0802, *0901, *1101, 1201, *1302, *1501, DRB3*0101, DRB4*0101, DRB5*0101, and DQBl*0301. Table 28a and 29a provide the peptide reference number sequence and protein antigen/position of sequence in antigen for the peptides. Binding data are provided in Tables 28b and 29B.
Peptide binding data for the designated HLA molecules are provided as IC50 values unless otherwise indicated. The "A" designation indicates that the peptide is an analog of the native sequence. TABLE 2
%
Motif Sequence Source Analog Consv.
AOli ARELHPEY HIV.nef.322 38
AOl i ATELHPEY HIV.nef.322 A 38
AOli ARDLHPEY HIV.nef.322 A 38
AOli ARELHPEYY HIV.nef.322 33
AOli ATELHPEYY HIV.nef.322 A 33
AOli ARDLHPEYY HIV.nef.322 A 33
AOls DILDLWVΎ HlV.nef.185 31
AOls DTLDLWVY HlV.nef.185 A 31
AOls DLWVYHTQGY HlV.nef.188 33
AOls DTWVYHTQGY HlV.nef.188 A 33
AOls DLWVYHTQGYF HlV.nef.188 33
AOls DTWVYHTQGYF HlV.nef.188 A 33
AOls DLWVYHTQGYY HlV.nef.188 A 33
AOls EILDLWVY HlV.nef.185 52
AOls ETLDLWVY HIN.nef.185 A 52
AOls PLTFGWCF HIV.nef.219 67
AOls PTTFGWCF HIV.nef.219 A 67
AOls PLTFGWCY HIV.nef.219 A 67
AOls QVPLRPMTY HlV.nef.100 72
AOls QTPLRPMTY HlV.nef.100 A 72
AOli RQEILDLWVY HlV.nef.182 50
AOli RTEILDLWVY HlV.nef.182 A 50
AOl i RQDILDLWVY HlV.nef.182 A 50
AOli RQDILDLWVY HlV.nef.182 31
AOli RTDILDLWVY HlV.nef.182 A 31
AOls WSKSSIVGW HIV.nef.5 31
AOls WTKSSIVGW HIV.nef.5 A 31
AOls WSKSSIVGY HIV.nef.5 A 31
AOls WVYHTQGY HlV.nef.191 33
AOls WTYHTQGY HIV.nef.191 A 33
AOls WVYHTQGYF HlV.nef.191 33
AOls WTYHTQGYF HlV.nef.191 A 33
AOls WVYHTQGYY HlV.nef.191 A 33
AOli YTPGPGIRY HIV.nef.207 27
AOli YTDGPGIRY HIV.nef.207 A 27
AOls ΠKILYQSNPY HIV.rev.20 28
AOls ITKILYQSNPY HIV.rev.20 A 28
AOls ILYQSNPY HIV.rev.23 42
AOls ITYQSNPY HIV.rev.23 A 42
AOls KILYQSNPY HIV.rev.22 41
AOls KTLYQSNPY HIV.rev.22 A 41
AOls PVDPNLEPW HIV.tat.3 31
AOls PTDPNLEPW HIV.tat.3 A 31
AOls PVDPNLEPY HIV.tat.3 A 31 TABLE 3
%
Motif Sequence Source Analog Consv.
A02i/s AAEGVGAV HIV.nef.42 28
A02i/s ALEGVGAV HIV.nef.42 A 28
A02i/s AITSSNTA HIV.nef.63 42
A02i/s ALTSSNTA HIV.nef.63 A 42
A02i/s AITSSNTV HIV.nef.63 A 42
A02i/s AQEEEEVGFPV HIV.nef.83 27
A02i/s ALEEEEVGFPV HlV.nef.83 A 27
A02i/s EAQEEEEV HlV.nef.82 25
A02i/s ELQEEEEV HIV.nef.82 A 25
A02i/s EVGFPVRPQV HIV.nef.91 63
A02i/s ELGFPVRPQV HTV.nef.91 A 63
A02i/s EILDLWVYHT HlV.nef.185 34
A02i/s ELLDLWVYHT HlV.nef.185 A 34
A02i s EILDLWVYHV HlV.nef.185 A 34
A02i/s FLKEKGGL HlV.nef.117 88
A02i/s FLKEKGGV HIV.nef.117 A 88
A02i/s FLKEKGGLEGL HIV.nef.117 45
A02i/s FLKEKGGLEGV HlV.nef.117 A 45
A02i/s FLKEKGGLDGL HlV.nef.117 41
A02i/s FLKEKGGLDGV HlV.nef.117 A 41
A02i/s GVGAVSRDL HIV.nef.45 27
A02i s GLGAVSRDL HIV.nef.45 A 27
A02i/s GVGAVSRDV HIV.nef.45 A 27
A02i/s GAITSSNT HIV.nef.62 50
A02i/s GLITSSNT HTV.nef.62 A 50
A02i s GAITSSNV HIV.nef.62 A 50
A02i/s GAITSSNTA HIV.nef.62 42
A02i/s GLITSSNTA HIV.nef.62 A 42
A02i/s GAITSSNTV HIV.nef.62 A 42
A02i/s GLIYSK RQEI HTV.nef.173 28
A02i s GLIYSKKRQEV HlV.nef.173 A 28
A02i/s ILDLWVYHT HlV.nef.186 53
A02i/s ILDLWVYHV HlV.nef.186 A 53
A02i/s ILDLWVYNT HTV.nef.186 30
A02i/s ILDLWVYNV HTV.nef.186 A 30
A02i/s LIYSKKRQEI HlV.nef.174 28
A02i/s LLYSKKRQEI HlV.nef.174 A 28
A02i/s LIYSKKRQEV HIV.nef.174 A 28
A02i/s LIYSKKRQEIL HlV.nef.174 28
A02i s LLYSKKRQEIL HIV.nef.174 A 28
A02i/s LlYSKKRQETV HlV.nef.174 A 28
A02i/s LTFGWCFKL HIV.nef.221 61
A02i/s LLFGWCFKL HIV.nef.221 A 61
A02i/s LTFGWCFKV HIV.nef.221 A 61
A02i s LTFGWCFKLV HIV.nef.221 55
A02i/s LLFGWCFKLV HIV.nef.221 A 55 TABLE 3
%
Motif Sequence Source Analog Consv.
A02i/s NADCAWLEA HIV.nef.73 27
A02i/s NLDCAWLEA HIV.nef.73 A 27
A02i/s NADCAWLEV HIV.nef.73 A 27
A02i/s PAAEGVGA HIV.nef.41 33
A02i/s PLAEGVGA HIV.nef.41 A 33
A02i/s PAAEGVGV HIV.nef.41 A 33
A02i s PVRPQVPL HIV.nef.95 75
A02i s PLRPQVPL HIV.nef.95 A 75
A02i/s PVRPQVPV HIV.nef.95 A 75
A02i s PVRPQVPLRPM HIV.nef.95 73
A02i s PLRPQVPLRPM HIV.nef.95 A 73
A02i/s PVRPQVPLRPV HIV.nef.95 A 73
A02i/s PQVPLRPM HIV.nef.99 88
A02i/s PLVPLRPM HIV.nef.99 A 88
A02i s PQVPLRPV HIV.nef.99 A 88
A02i s PQVPLRPMT HIV.nef.99 88
A02i s PLVPLRPMT HIV.nef.99 A 88
A02i s PQVPLRPMV HIV.nef.99 A 88
A02i/s PLRPMTYKGA HlV.nef.102 39
A02i/s PLRPMTYKGV HlV.nef.102 A 39
A02i/s PLRPMTYKA HlV.nef.102 33
A02i s PLRPMTYKV HlV.nef.102 A 33
A02i/s PLRPMTYKAA HlV.nef.102 31
A02i/s PLRPMTYKAV HlV.nef.102 A 31
A02i s PLTFGWCFKL HIV.nef.219 61
A02i s PLTFGWCFKV HIV.nef.219 A 61
A02i/s PLTFGWCFKLV HIV.nef.219 55
A02i s QAEPAAAGV HIV.nef.34 33
A02i/s QLEPAAAGV HIV.nef.34 A 33
A02i s QAEPAAAGVGA HIV.nef.34 33
A02i s QLEPAAAGVGA HIV.nef.34 A 33
A02i/s QAEPAAAGVGV HIV.nef.34 A 33
A02i/s QVPLRPMT HlV.nef.100 89
A02i/s QLPLRPMT HlV.nef.100 A 89
A02i/s QVPLRPMV HlV.nef.100 A 89
A02i/s QVPLRPMTYKA HlV.nef.100 31
A02i/s QLPLRPMTYKA HlV.nef.100 A 31
A02i/s QVPLRPMTYKV HlV.nef.100 A 31
A02i/s RQEILDLWV HlV.nef.182 55
A02i/s RLEILDLWV HlV.nef.182 A 55
A02i/s RQDILDLWV HTV.nef.182 31
A02i/s RLDILDLWV HIV.nef.182 A 31
A02i/s WQNYTPGPGT HIV.nef.204 33
A02i/s WLNYTPGPGT HIV.nef.204 A 33
A02i/s WQNYTPGPGV HIV.nef.204 A 33
A02i/s WQNYTPGPGI HIV.nef.204 29 TABLE 3
%
Motif Sequence Source Analog Consv.
A02i/s WLNYTPGPGI HIV.nef.204 A 29
A02i/s WQNYTPGPGV HIV.nef.204 A 29
A02i/s YTPGPGIRYPL HIV.nef.207 25
A02i s YLPGPGIRYPL HIV.nef.207 A 25
A02i/s YTPGPGIRYPV HIV.nef.207 A 25
A02i s GTSGTQGV HIV.rev.94 33
A02i s GLSGTQGV HIV.rev.94 A 33
A02i/s LQLPPLERL HIV.rev.77 56
A02i/s LLLPPLERL HIV.rev.77 A 56
A02i/s LQLPPLERV HIV.rev.77 A 56
A02i/s LQLPPLERLT HIV.rev.77 27
A02i/s LLLPPLERLT HIV.rev.77 A 27
A02i/s LQLPPLERLV HIV.rev.77 A 27
A02i/s LQLPPLERLTL HIV.rev.77 27
A02i/s LLLPPLERLTL HIV.rev.77 A 27
A02i/s LQLPPLERLTV HIV.rev.77 A 27
A02i/s PAEPVPLQL HIV.rev.71 33
A02i s PLEPVPLQL HTV.rev.71 A 33
A02i s PAEPVPLQV HIV.rev.71 A 33
A02i s PVPLQLPPL HIV.rev.74 55
A02i s PLPLQLPPL HIV.rev.74 A 55
A02i/s PVPLQLPPV HIV.rev.74 A 55
A02i/s PLQLPPLERL HIV.rev.76 53
A02i/s PLQLPPLERV HIV.rev.76 A 53
A02i/s QLPPLERLT HIV.rev.78 28
A02i/s QLPPLERLV HIV.rev.78 A 28
TABLE 4
%
Motif Sequence Source Analog Consv.
A03i ADCAWLEA HIV.nef.74 27
A03i AVCAWLEA HIV.nef.74 A 27
A03i ADCAWLEK HIV.nef.74 A 27
A03i AFDLSFFLK HIV.nef.l l l 28
A03i AVDLSFFLK fflV.nef.l l l A 28
A03i AFDLSFFLKEK fflV.nef.l l l 27
A03i AVDLSFFLKEK HIV.nef.l l l A 27
A03i DLSHFLKEK HTV.nef.113 42
A03i DVSHFLKEK HlV.nef.113 A 42
A03i DLSFFLKEK HlV.nef.113 34
A03i DVSFFLKEK HlV.nef.113 A 34
A03i EAQEEEEVGF HIV.nef.82 25
A03i EVQEEEEVGF HTV.nef.82 A 25
A03i EAQEEEEVGK HTV.nef.82 A 25
A03i EILDLWVYH HlV.nef.185 34
A03i EVLDLWVYH HTV.nef.185 A 34
A03i EILDLWVYK HlV.nef.185 A 34
A03s ELHPEYYK HIV.nef.324 34
A03s EVHPEYYK HIV.nef.324 A 34
A03i FDLSFFLK HlV.nef.112 28
A03i FVLSFFLK HlV.nef.112 A 28
A03i FDLSFFLKEK HlV.nef.112 27
A03i FVLSFFLKEK HlV.nef.112 A 27
A03i FFPDWQNY HlV.nef.199 27
A03i FVPDWQNY HlV.nef.199 A 27
A03i FFPDWQNK HlV.nef.199 A 27
A03i GFPVRPQVPLR HIV.nef.93 75
A03i GVPVRPQVPLR HIV.nef.93 A 75
A03i GFPVRPQVPLK HTV.nef.93 A 75
A03i GGLEGLIY HlV.nef.124 30
A03i GVLEGLIY HlV.nef.124 A 30
A03i GGLEGLIK HlV.nef.124 A 30
A03i GGLDGLIYSK HlV.nef.124 25
A03i GVLDGLIYSK HlV.nef.124 A 25
A03i GLDGLIYSK HlV.nef.125 25
A03i GVDGLIYSK HlV.nef.125 A 25
A03i GLIYSKKR HlV.nef.173 36
A03i GVIYSKKR HlV.nef.173 A 36
A03i GLIYSKKK HlV.nef.173 A 36
A03i GFFPDWQNY HlV.nef.198 27
A03i GVFPDWQNY HlV.nef.198 A 27
A03i GFFPDWQNK HlV.nef.198 A 27
A03i HGAITSSNTA HTV.nef.61 42
A03i HVAITSSNTA HIV.nef.61 A 42
A03i HGAITSSNTK HTV.nef.61 A 42
A03i ILDLWVYH HlV.nef.186 53 TABLE 4
%
Motif Sequence Source Analog Consv.
A03i IVDLWVYH HlV.nef.186 A 53
A03i ILDLWVYK HlV.nef.186 A 53
A03i KGGLEGLIY HlV.nef.122 30
A03i KVGLEGLIY HlV.nef.122 A 30
A03i KGGLEGLIK HlV.nef.122 A 30
A03i LSHFLKEK HlV.nef.114 42
A03i LVHFLKEK HlV.nef.114 A 42
A03i LSFFLKEK HlV.nef.114 34
A03i LVFFLKEK HIV.nef.114 A 34
A03i LDGLIYSK HlV.nef.171 25
A03i LVGLIYSK HlV.nef.171 A 25
A03i LDLWVYHTQGY HlV.nef.187 33
A03i LVLWVYHTQGY HlV.nef.187 A 33
A03i LDLWVYHTQGK HlV.nef.187 A 33
A03i LTFGWCFK HIV.nef.221 61
A03i LLHPICQH HIV.nef.257 28
A03i LVHPICQH HIV.nef.257 A 28
A03i LLHPICQK HIV.nef.257 A 28
A03i LLHPMSQH HTV.nef.257 27
A03i LVHPMSQH HIV.nef.257 A 27
A03i LLHPMSQK HIV.nef.257 A 27
A03i PVRPQVPLR HIV.nef.95 75
A03i PVRPQVPLK HTV.nef.95 A 75
A03i PLRPMTYK HlV.nef.102 77
A03i PVRPMTYK HlV.nef.102 A 77
A03i PLTFGWCFK HTV.nef.219 61
A03i PVTFGWCFK HIV.nef.219 A 61
A03i QVPLRPMTYK HlV.nef.100 72
A03i QDILDLWVY HIV.nef.184 31
A03i QVILDLWVY HlV.nef.184 A 31
A03i QDILDLWVK HlV.nef.184 A 31
A03i QGFFPDWQNY HlV.nef.196 27
A03i QVFFPDWQNY HlV.nef.196 A 27
A03i QGFFPDWQNK HlV.nef.196 A 27
A03i RDLEKHGA HTV.nef.51 25
A03i RVLEKHGA HIV.nef.51 A 25
A03i RDLEKHGK HIV.nef.51 A 25
A03i RFPLTFGWCF HIV.nef.216 27
A03i RVPLTFGWCF HIV.nef.216 A 27
A03i RFPLTFGWCK HIV.nef.216 A 27
A03i RFPLTFGWCFK HIV.nef.216 27
A03i RVPLTFGWCFK HIV.nef.216 A 27
A03i YTPGPGTR HIV.nef.207 33
A03i YTPGPGTK HIV.nef.207 A 33
A03i YTPGPGIR HIV.nef.207 31
A03i YTPGPGIK HIV.nef.207 A 31 TABLE 4
%
Motif Sequence Source Analog Consv.
A03i EGTRQARR HIV.rev.35 42
A03i EVTRQARR HIV.rev.35 A 42
A03i EGTRQARK HIV.rev.35 A 42
A03i EGTRQARRNR HIV.rev.35 42
A03i EVTRQARRNR HIV.rev.35 A 42
A03i EGTRQARRNK HIV.rev.35 A 42
A03i EGTRQARRNRR HIV.rev.35 42
A03i EVTRQARKNRR HIV.rev.35 A 42
A03i EGTRQARRNRK HIV.rev.35 A 42
A03i GTRQARRNR HIV.rev.36 53
A03i GTRQARRNK HIV.rev.36 A 53
A03i GTRQARRNRR HIV.rev.36 53
A03i GTRQARRNRK HIV.rev.36 A 53
A03i GTRQARRNRRR HTV.rev.36 53
A03i GTRQARRNRRK HIV.rev.36 A 53
A03i GTRQTRKNR HIV.rev.37 50
A03i GTRQTRKNK HIV.rev.37 A 50
A03i GTRQTRKNRR HIV.rev.37 50
A03i GTRQTRKNRK HTV.rev.37 A 50
A03i GTRQTRKNRRR HIV.rev.37 50
A03i GTRQTRKNRRK HIV.rev.37 A 50
A03i PVPLQLPPLER HIV.rev.74 53
A03i PVPLQLPPLEK HIV.rev.74 A 53
A03i PLQLPPLER HIV.rev.76 55
A03i PVQLPPLER HIV.rev.76 A 55
A03i PLQLPPLEK HIV.rev.76 A 55
A03i QARRNRRR HIV.rev.40 59
A03i QVRRNRRR HIV.rev.40 A 59
A03i QARRNRRK HIV.rev.40 A 59
A03i QARRNRRRR HIV.rev.40 59
A03i QVRRNRRRR HIV.rev.40 A 59
A03i QARRNRRRK HIV.rev.40 A 59
A03i QARRNRRRRWR HIV.rev.40 58
A03i QVRRNRRRRWR HIV.rev.40 A 58
A03i QARRNRRRRWK HTV.rev.40 A 58
A03i QARKNRRR HTV.rev.40 27
A03i QVRKNRRR HTV.rev.40 A 27
A03i QARKNRRK HTV.rev.40 A 27
A03i QARKNRRRR HIV.rev.40 25
A03i QVRKNRRRR HIV.rev.40 A 25
A03i QARKNRRRK HIV.rev.40 A 25
A03i QARKNRRRRWR HIV.rev.40 25
A03i QVRKNRRRRWR HIV.rev.40 A 25
A03i QARKNPvRRRWK HIV.rev.40 A 25
A03i TTRQARRNRRR HIV.rev.37 50
A03i TTRQARRNRRK HIV.rev.37 A 50 TABLE 4
%
Motif Sequence Source Analog Consv.
A03i ACNNCYCK HIV.tat.24 27
A03i AVNNCYCK HIV.tat.24 A 27
A03i AGPGGYPRR HIV.tat.102 50
A03i AVPGGYPRR HIV.tat.102 A 50
A03i AGPGGYPRK HIV.tat.102 A 50
A03i AGPGGYPRRK HIV.tat.102 50
A03i AVPGGYPRRK HIV.tat.102 A 50
A03i ETGPSGQPCH fflV.tat.101 50
A03i ETGPSGQPCK HIV.tat.101 A 50
A03i GGYPRRKGSCH HIV.tat.105 50
A03i GVYPRRKGSCH HIV.tat.105 A 50
A03i GGYPRRKGSCK HIV.tat.105 A 50
A03i ISYGRKKRRQR HIV.tat.48 61
A03i IVYGRKKRRQR HIV.tat.48 A 61
A03i ISYGRKKRRQK HIV.tat.48 A 61
A03i KAGPGGYPRR HIV.tat.101 50
A03i KVGPGGYPRR fflV.tat.101 A 50
A03i KAGPGGYPRK fflV.tat.101 A 50
A03i KAGPGGYPRRK HTV.tat.101 50
A03i KVGPGGYPRRK HTV.tat.101 A 50
A03i LGISYGRKKRR HIV.tat.46 70
A03i LVISYGRKKRR HIV.tat.46 A 70
A03i LGISYGRKKRK HIV.tat.46 A 70
A03i PGSQPKTA HIV.tat.17 41
A03i PVSQPKTA HIV.tat.17 A 41
A03i PGSQPKTK HTV.tat.17 A 41
A03i PTGPKESK HIV.tat.88 31
A03i PTGPKESKK HTV.tat.88 28
A03i PGGYPRRK HTV.tat.104 50
A03i PVGYPRRK HTV.tat.104 A 50
A03s PTGPKESKK HIV.tat.88 28
A03i RGDPTGPK HIV.tat.84 25
A03i RVDPTGPK HIV.tat.84 A 25
A03i TACNNCYCK HIV.tat.23 27
A03i TVCNNCYCK HIV.tat.23 A 27
A03i TGPKESKK HIV.tat.89 30
A03i TVPKESKK HIV.tat.89 A 30
A03i TGPSGQPCH HIV.tat.102 50
A03i TVPSGQPCH HIV.tat.102 A 50
A03i TGPSGQPCK HTV.tat.102 A 50
A03i VDPNLEPWNH HTV.tat.4 25
A03i WPNLEPWNH HTV.tat.4 A 25
A03i VDPNLEPWNK HTV.tat.4 A 25
A03i YGRKKRRQR HTV.tat.50 64
A03i YVRKKRRQR HTV.tat.50 A 64
A03i YGRKKRRQK HTV.tat.50 A 64 TABLE 4
%
Motif Sequence Source Analog Consv. .
A03i YGRKKRRQRR HIV.tat.50 59
A03i YVRKKRRQRR HIV.tat.50 A 59
A03i YGRKKRRQRK HIV.tat.50 A 59
A03i YGRKKRRQRRR HIV.tat.50 34
A03i YVRKKRRQRRR HIV.tat.50 A 34
A03i YGRKKRRQRRK HIV.tat.50 A 34
TABLE 5
%
Motif Sequence Source Analog Consv.
All i QNYTPGPGTR HIV.nef.205 31
All QVYTPGPGTR HIV.nef.205 A 31
All L QNYTPGPGTK HIV.nef.205 A 31
All QNYTPGPGTR HIV.nef.205 28
All L QVYTPGPGTR HIV.nef.205 A 28
All QNYTPGPGTK HIV.nef.205 A 28
All i KNRRRRWR HIV.rev.43 33
All KVRRRRWR HIV.rev.43 A 33
All L KNRRRRWK HIV.rev.43 A 33
All KNRRRRWRAR HIV.rev.43 30
All KVRRRRWRAR HIV.rev.43 A 30
AIL KNRRRRWRAK HIV.rev.43 A 30
All RNRRRRWR HIV.rev.43 63
AIL RVRRRRWR HIV.rev.43 A 63
All RNRRRRWK HIV.rev.43 A 63
AIL RNRRRRWRAR HIV.rev.43 36
All RVRRRRWRAR HIV.rev.43 A 36
AIL RNRRRRWRAK HIV.rev.43 A 36
All PNLEPWNH HIV.tat.9 27
AIL PVLEPWNH HIV.tat.9 A 27
Alii PNLEPWNK HIV.tat.9 A 27
TABLE 6
%
Motif Sequence Source Analog Consv.
A24i AFDLSFFL fflV.nef.l l l 28
A24i AYDLSFFL HrV.nef.lll A 28
A24i AFDLSFFF HIV.nef.l ll A 28
A24i DWQNYTPGPGI HIV.nef.203 28
A24i DYQNYTPGPGI HIV.nef.203 A 28
A24i DWQNYTPGPGF HIV.nef.203 A 28
A24i FFLKEKGGL HlV.nef.116 41
A24i ϊFYLKEKGGL HIV.nef.116 A 41
A24i FFLKEKGGF HIV.nef.116 A 41
A24i GFPVRPQVPL HIV.nef.93 75
A24i GYPVRPQVPL HIV.nef.93 A 75
A24i GFPVRPQVPF HIV.nef.93 A 75
A24s GVGAVSQDL HIV.nef.45 33
A24s GYGAVSQDL HIV.nef.45 A 33
A24s GVGAVSQDF HIV.nef.45 A 33
A24i HFLKEKGGL HlV.nef.116 45
A24i HYLKEKGGL HIV.nef.116 A 45
A24i HFLKEKGGF HlV.nef.116 A 45
A24i IYSKKRQEI HIV.nef.175 29
A24i IYSKKRQEF HlV.nef.175 A 29
A24i IYSKKRQEIL HTV.nef.175 29
A24i IYSKKRQEIF HlV.nef.175 A 29
A24i KWSKSSIVGW HIV.nef.4 31
A24i KYSKSSIVGW HTV.nef.4 A 31
A24i KWSKSSIVGF HIV.nef.4 A 31
A24i LWVYHTQGYF HIV.nef.190 33
A24i LYVYHTQGYF HlV.nef.190 A 33
A24s LWVYHTQGY HTV.nef.190 33
A24s LYVYHTQGY HIV.nef.190 A 33
A24s LWVYHTQGF HlV.nef.190 A 33
A24i NYTPGPGI HIV.nef.206 31
A24i NYTPGPGF HIV.nef.206 A 31
A24s NYTPGPGΓRY HIV.nef.206 27
A24s NYTPGPGIRF HIV.nef.206 A 27
A24i RYPLTFGW HTV.nef.216 43
A24i RYPLTFGF HIV.nef.216 A 43
A24i RYPLTFGWCF HIV.nef.216 33
A24i RFPLTFGW HIV.nef.216 32
A24i RYPLTFGW HIV.nef.216 A 32
A24i RFPLTFGF HIV.nef.216 A 32
A24i SFFLKEKGGL HlV.nef.115 34
A24i SYFLKEKGGL HlV.nef.115 A 34
A24i SFFLKEKGGF HIV.nef.115 A 34
A24i TFGWCFKL HTV.nef.222 63
A24i TYGWCFKL HIV.nef.222 A 63
A24i TFGWCFKF HIV.nef.222 A 63 TABLE 6
%
Motif Sequence Source Analog Consv.
A24i VYHTQGYF HIV.nef.192 33
A24i VYHTQGYFPDW HlV.nef.192 33
A24i VYHTQGYFPDF HlV.nef.192 A 33
A24s QLPPLERL HIV.rev.78 58
A24s QYPPLERL HIV.rev.78 A 58
A24s QLPPLERF HIV.rev.78 A 58
A24s QLPPLERLTL HTV.rev.78 28
A24s QYPPLERLTL HIV.rev.78 A 28
A24s QLPPLERLTF HIV.rev.78 A 28
A24i RWRARQRQI HIV.rev.48 55
A24i RYRARQRQI HIV.rev.48 A 55
A24i RWRARQRQF HIV.rev.48 A 55
TABLE 7
%
Motif Sequence Source Analog Consv.
B07s APTAAKGV HIV.nef.34 33
B07s APTAAKGI HIV.nef.34 A 33
B07s APTAAKGVGA HIV.nef.34 33
B07s APTAAKGVGI HIV.nef.34 A 33
B07s APTAAKGVGAV HIV.nef.34 33
B07s APTAAKGVGAI HTV.nef.34 A 33
B07s FPVRPQVPL HIV.nef.94 75
B07s FPVRPQVPI HIV.nef.94 A 75
B07s FPLTFGWCF HIV.nef.217 27
B07s FPLTFGWCI HIV.nef.217 A 27
B07s FPLTFGWCFKL HIV.nef.217 27
B07s FPLTFGWCFKI HIV.nef.217 A 27
B07s GPGIRYPL HIV.nef.210 27
B07s GPGIRYPI HIV.nef.210 A 27
B07s RPQVPLRPM HIV.nef.98 73
B07s RPQVPLRPI HTV.nef.98 A 73
B07s RPQVPLRPMTY HIV.nef.98 56
B07s RPQVPLRPMTI HIV.nef.98 A 56
B07s RPMTYKAA HlV.nef.104 36
B07s RPMTYKAI HlV.nef.104 A 36
B07s TPGPGTRY HIV.nef.208 27
B07s TPGPGTRI HIV.nef.208 A 27
B07s VPLRPMTY HTV.nef.101 73
B07s VPLRPMTI HIV.nef.101 A 73
B07s VPLRPMTYKGA HTV.nef.101 37
B07s VPLRPMTYKGI HIV.nef.101 A 37
B07s VPLRPMTYKA HlV.nef.101 32
B07s VPLRPMTYKI HTV.nef.101 A 32
B07s VPLRPMTYKAA HTV.nef.101 30
B07s VPLRPMTYKAI Hrv.nef.101 A 30
B07s YPLTFGWCF HIV.nef.217 38
B07s YPLTFGWCI HIV.nef.217 A 38
B07s LPPLERLTL HIV.rev.79 30
B07s LPPLERLTI HIV.rev.79 A 30
B07s PPLERLTL HIV.rev.80 30
B07s PPLERLTI HIV.rev.80 A 30
B07s RPAEPVPL HIV.rev.70 31
B07s RPAEPVPI HIV.rev.70 A 31
B07s RPAEPVPLQL HIV.rev.70 31
B07s RPAEPVPLQI HIV.rev.70 A 31
B07s VPLQLPPL HIV.rev.75 56
B07s VPLQLPPI HIV.rev.75 A 56
B07s HPGSQPKTA HTV.tat.16 41
B07s HPGSQPKTI HTV.tat.16 A 41 TABLE 8
%
Motif Sequence Source Analog Consv.
B27s EKGGLEGL HlV.nef.121 53
B27s EKGGLEGLI HlV.nef.121 42
B27s EKGGLDGL HIV.nef.121 41
B27s EKGGLDGLI HIV.nef.121 36
B27s EKGGLEGLIY HIV.nef.121 30
B27s GKWSKSSI HIV.nef.3 28
B27s GKWSKSSIVGW HIV.nef.3 28
B27s KKRQEILDL HIV.nef.179 39
B27s KKRQEILDLW HlV.nef.179 39
B27s KRQEILDL HTV.nef.181 50
B27s KRQEILDLW HIV.nef.181 50
B27s KRQEILDLWVY HIV.nef.181 45
B27s KRQDILDL HlV.nef.181 28
B27s KRQDILDLW HTV.nef.181 28
B27s KRQDILDLWVY HIV.nef.181 25
B27s LKEKGGLDGL HlV.nef.118 42
B27s LKEKGGLDGLI HIV.nef.118 37
B27s SKSSIVGW HTV.nef.6 31
B27s SKKRQEIL HlV.nef.177 39
B27s SKKRQEILDL HIV.nef.177 39
B27s SKKRQEILDLW HlV.nef.177 39
B27s VRPQVPLRPM HIV.nef.97 73
B27s ARKNRRRRW HIV.rev.41 28
B27s GRSGDSDEEL HIV.rev.3 27
B27s GRSGDSDEELL HTV.rev.3 25
B27s GRPAEPVPL HIV.rev.69 31
B27s GRPAEPVPLQL HIV.rev.69 31
B27s IKILYQSNPY HIV.rev.21 39
B27s RKNRRRRW HTV.rev.42 33
B27s RRWRARQRQI HIV.rev.47 53
B27s VRIIKILY HIV.rev.18 28
B27s TKGLGISY HIV.tat.43 30
TABLE 9
%
Motif Sequence Source Analog Consv.
B44s AEPAAEGV HIV.nef.34 33
B44s AEPAAEGVGA HIV.nef.34 33
B44s AEPAAEGVGAV HIV.nef.34 33
B44s DEEVGFPV HIV.nef.89 50
B44s EEEEVGFPV HIV.nef.86 27
B44s EEEVGFPV HIV.nef.87 33
B44s EEVGFPVRPQV HIV.nef.88 31
B44s EEVGFPVRPQI HIV.nef.89 50
B44s EEVGFPVRPQV HIV.nef.90 60
B44s KEKGGLDGL HlV.nef.120 41
B44s KEKGGLDGLI HIV.nef.120 37
B44s KEKGGLEGLIY HlV.nef.120 27
B44s QEEEEVGF HIV.nef.84 27
B44s QEEEEVGFPV HIV.nef.84 27
B44s QEILDLWV HTV.nef.184 55
B44s QEILDLWVY HlV.nef.184 50
B44s QDILDLWV HlV.nef.184 31
B44s QEILDLWV HIV.nef.184 31
B44s TEPAAVGV HIV.nef.33 33
B44s TEPAAVGVGA HIV.nef.33 33
B44s TEPAAVGVGAV HIV.nef.33 33
B44s AEPVPLQL HTV.rev.72 52
B44s EDCGTSGTQGV HIV.rev.91 30
B44s EECGTSGTQGV HIV.rev.91 30
B44s GDSDEELL HTV.rev.6 25
B44s GESDEELL HIV.rev.6 25
B44s VDPNLEPW HTV.tat.4 34 B44s VEPNLEPW HTV.tat.4 34
Table 10
Sequence Organism Protein Position Length Motif
RTEILDLWNY HΓV ΝEF 182 10 AOli
RQDILDLWVY HIV KEF 182 10 AOli
RTDILDLWVY HΓV ΝEF 182 10 AOli
YTDGPGΓRY HΓV ΝEF 207 9 AOli
ATELHPEY HΓV ΝEF 322 8 AOli
ARDLHPEY H1N ΝEF 322 8 AOli
ATELHPEYY HΓV ΝEF 322 9 AOli
ARDLHPEYY HIN ΝEF 322 9 AOli
PTDQGPQREPY HΓV VPR 5 11 AOli
WTKSSΓVGW HΓV ΝEF 5 9 AOls
WSKSSΓVGY HΓV ΝEF 5 9 AOls
QTPLRPMTY HΓV ΝEF 100 9 AOls
ETLDLWNY HΓV ΝEF 185 8 AOls
DTLDLWVY HΓV ΝEF ' 185 8 AOls
DTWVYHTQGY HΓV ΝEF 188 10 AOls
DTWVYHTQGYF HIV ΝEF 188 11 AOls
DLWVYHTQGYY HΓV ΝEF 188 11 AOls
WTYHTQGY HIV ΝEF 191 8 AOls
WTYHTQGYF HΓV ΝEF 191 9 AOls
WNYHTQGYY HΓV ΝEF 191 9 AOls
PTTFGWCF HΓV ΝEF 219 8 AOls
PLTFGWCY HΓV ΝEF 219 8 AOls
ETLDLWVY HIN ΝEF 185 8 AOls
QTPLRPMTY HIN ΝEF 100 9 AOls
ITKILYQS PY HΓV REV 20 11 AOls
KTLYQSΝPY HΓV REV 22 9 , AOls
ITYQSΝPY HΓV REV 23 8 AOls
PTDPΝLEPW HΓV TAT 3 9 AOls
PVDPΝLEPY HΓV TAT 3 9 AOls
STVKHHMY HΓV VΓF 23 8 AOls Table 10
Peptide Sequence Organism Protein Segment 1st Analog AA Position
QLEPAAAGV HIV EF 34 9
QLEPAAAGVGA HIV ΝEF 34 11
QAEPAAAGVGV HΓV ΝEF 34 11
PLAEGVGA HΓV ΝEF 41 8
PAAEGVGV HIV ΝEF 41 8
ALEGVGAV HΓV ΝEF 42 8
GLGAVSRDL HIV ΝEF 45 9
GVGAVSRDV HΓV ΝEF 45 9
GLITSSNT HIV ΝEF 62 8
GAITSSNV HIV ΝEF 62 8
GLITSSNTA HΓV ΝEF 62 9
GAITSSNTV HΓV ΝEF 62 9
ALTSSNTA HIN ΝEF 63 8
AITSSNTV HIN ΝEF 63 8
NLDCAWLEA HΓV ΝEF 73 9
NADCAWLEV ' HΓV ΝEF 73 9
ELQEEEEV HΓV ΝEF 82 8
ALEEEEVGFPV HΓV ΝEF 83 11
ELGFPVRPQV HΓV ΝEF 91 10
PLRPQVPL HΓV ΝEF 95 8
PVRPQVPV HIN ΝEF 95 8
PLRPQVPLRPM HΓV ΝEF 95 11
PVRPQVPLRPV HΓV ΝEF 95 11
PLVPLRPM HΓV ΝEF 99 8
PQVPLRPV HΓV EF 99 8
PLVPLRPMT HΓV ΝEF 99 9
PQVPLRPMV HΓV ΝEF 99 9
QLPLRPMT HΓV ΝEF 100 8
QVPLRPMV HΓV ΝEF 100 8
QLPLRPMTYKA HΓV ΝEF 100 11 Peptide Sequence Organism Protein/Segment 1st Analog AA Position
QVPLRPMTYKV HIV NEF 100 11
PLRPMTYKGV HΓV NEF 102 10
PL?PMTYKV HΓV NEF 102 9
PLRPMTYKAV HΓV NEF 102 10
FLKEKGGV HΓV NEF 117 8
FLKEKGGLEGV HΓV NEF 117 11
FLKEKGGLDGV HΓV NEF 117 11
GLIYSKKRQEV HΓV NEF 173 11
LLYSKKRQEI HΓV NEF 174 10
LΓYSKKRQEV HΓV NEF 174 10
LLYSKKRQEIL HΓV NEF 174 11
LΓYSKKRQEΓV HΓV NEF 174 11
RLEILDLWN HΓV NEF 182 9
RLDILDLWV HΓV NEF 182 9
ELLDLWVYHT HΓV NEF 185 10
EILDLWVYHV HΓV NEF 185 10
ILDLWVYHV HΓV NEF 186 9
ILDLWVYΝV HΓV NEF 186 9
WLΝYTPGPGT HΓV NEF 204 10
WQNYTPGPGV HΓV NEF 204 10
WLNYTPGPGI HΓV NEF 204 10
WQNYTPGPGV HΓV NEF 204 10
YLPGPGΓRYPL HΓV NEF 207 11
YTPGPGΓRYPV HΓV NEF 207 11
PLTFGWCFKV HΓV NEF 219 10
LLFGWCFKL HΓV NEF 221 9
LTFGWCFKV HΓV NEF 221 9
LLFGWCFKLV HΓV NEF 221 10
PVRPQVPV HΓV NEF 95 8
FLKEKGGV HΓV NEF 117 8
PQVPLRPV HΓV NEF 99 8 Peptide Sequence Organism Protein Segment 1st Analog AA
Position
PQVPLRPMV HΓV ΝEF 99 9
QVPLRPMV HΓV ΝEF 100 8
PLRPQVPL HΓV ΝEF 95 8
FVKEKGGL HIN ΝEF 117 8
PLVPLRPM HIN ΝEF 99 8
PLVPLRPMT HIN ΝEF 99 9
QLPLRPMT HΓV ΝEF 100 8
PVVPLRPM HΓV ΝEF 99 8
PVVPLRPMT HΓV ΝEF 99 9
PLEPVPLQL HIN REV 71 9
PAEPVPLQV HIN REV 71 9
PLPLQLPPL HΓV REV 74 9
PVPLQLPPV HΓV REV 74 9
PLQLPPLERV HΓV REV 16 10
LLLPPLERL HΓV REV 11 9
LQLPPLERV HΓV REV 11 9
LLLPPLERLT HΓV REV 11 10
LQLPPLERLV HΓV REV 11 10
LLLPPLERLTL HΓV REV 11 11
LQLPPLERLTV HIN REV 11 11
QLPPLERLV HΓV REV 78 9
GLSGTQGV HΓV REV 94 8
WQVDRMRV HIV VΓF 11 8
KVGSLQYLAV HΓV VΓF 146 10
KVGSLQYV HΓV VΓF 146 8
KVGSLQYLV HΓV VΓF 146 9
ΓVWQVDRV HΓV VIF 9 8
WLVDRMRI HΓV VΓF 11 8
KLGSLQYLAL HΓV VΓF 146 10
KLGSLQYL HΓV VΓF 146 8
KLGSLQYLA HΓV VIF 146 9 Peptide Sequence Organism Protein/Segment 1st Analog AA
Position
ILWQVDRM HTV VTF 9 8~~ wNVDRMRi HΓV VIF 11 8
Sequence Organism Protein Position Length Motif
RVLEKHGA HΓV NEF 51 8 A03i
RDLEKHGK HΓV NEF 51 8 A03i
HVAITSSNTA HΓV NEF 61 10 A03i
HGAITSSNTK HΓV NEF 61 10 A03i
AVCAWLEA HΓV NEF 74 8 A03i
ADCAWLEK HΓV NEF 74 8 A03i
EVQEEEEVGF HΓV NEF 82 10 A03i
EAQEEEEVGK HΓV NEF 82 10 A03i
GVPVRPQVPLR HΓV NEF 93 11 A03i
GFPVRPQVPLK HΓV NEF 93 11 A03i
PVRPQVPLK HΓV NEF 95 9 A03i
PVRPMTYK HΓV NEF 102 8 A03i
AVDLSFFLK HΓV NEF 111 9 A03i
AVDLSFFLKEK HΓV NEF 111 11 A03i
FVLSFFLK HΓV NEF 112 8 A03i
FVLSFFLKEK HΓV NEF 112 10 A03i
DVSHFLKEK HΓV NEF 113 9 A03i
DVSFFLKEK HIV NEF 113 9 A03i
LVHFLKEK HIN NEF 114 8 A03i
LVFFLKEK HΓV NEF 114 8 A03i
KVGLEGLΓY HΓV NEF 122 9 A03i
KGGLEGLΓK HΓV NEF 122 9 A03i
GVLEGLΓY HΓV NEF 124 8 A03i
GGLEGLΓK HΓV NEF 124 8 A03i
GVLDGLΓYSK HΓV NEF 124 10 A03i
GVDGLΓYSK HΓV NEF 125 9 A03i
LVGLΓYSK HΓV NEF 171 8 A03i
GVΓYSKKR HΓV NEF 173 8 A03i
GLΓYSKKK HΓV NEF 173 8 A03i
QVILDLWVY HΓV NEF 184 9 A03i
QDILDLWVK HΓV NEF 184 9 A03i Sequence Organism Protein Position Length Motif
EVLDLWVYH HIV NEF 185 9 A03i
EILDLWVYK HΓV NEF 185 9 A03i
ΓVDLWVYH HΓV NEF 186 8 A03i
ILDLWVYK HΓV NEF 186 8 A03i
LVLWVYHTQGY HΓV NEF 187 11 A03i
LDLWVYHTQGK HΓV NEF 187 11 A03i
QVFFPDWQNY HΓV NEF 196 10 A03i
QGFFPDWQNK HΓV NEF 196 10 A03i
GVFPDWQNY HΓV NEF 198 9 A03i
GFFPDWQNK HΓV NEF 198 9 A03i
FVPDWQNY HIV NEF 199 8 A03i
FFPDWQNK HIV NEF 199 8 A03i
YTPGPGTK HΓV NEF 207 8 A03i
YTPGPGΓK HΓV NEF 207 8 A03i
RVPLTFGWCF HΓV NEF 216 10 A03i
RFPLTFGWCK HΓV NEF 216 10 A03i
RVPLTFGWCFK HΓV NEF 216 11 A03i
PVTFGWCFK HΓV NEF 219 9 A03i
LVHPICQH HΓV NEF 257 8 A03i
LLHPICQK HΓV NEF 257 8 A03i
LVHPMSQH HΓV NEF 257 8 A03i
LLHPMSQK HΓV NEF 257 8 A03i
PTRPQVPLR HΓV NEF 95 9 A03i
GTPVRPQVPLR HΓV NEF 93 11 A03i
PTRPMTYK HΓV NEF 102 8 A03i
EVTRQARR HΓV REV 35 8 A03i
EGTRQARK HΓV REV 35 8 A03i
EVTRQARRNR HΓV REV 35 10 A03i
EGTRQARRNK HΓV REV 35 10 A03i
EVTRQARRNRR HΓV REV 35 11 A03i
EGTRQARRNRK HΓV REV 35 11 A03i
GTRQARRNK HΓV REV 36 9 A03i Sequence Organism Protein Position Length Motif
GTRQARRNRK HΓV REN 36 10 A03i
GTRQARRNRRK HΓV REN 36 11 A03i
GTRQTRKNK HΓV REN 37 9 A03i
GTRQTRKNRK HΓV REN 37 10 A03i
GTRQTRKNRRK HΓV REN 37 11 A03i
TTRQARRNRRK HΓV REN 37 11 A03i
QVRRNRRR HΓV REN 40 8 A03i
QARRNRRK HΓV REN 40 8 A03i
QVRRNRRRR HΓV REN 40 9 A03i
QARRNRRRK HΓV REN 40 9 A03i
QVRRNRRRRWR HIV REN 40 11 A03i
QARRNRRRRWK HIV REN 40 11 A03i
QVRKNRRR HIN REN 40 8 A03i
QARKNRRK HΓV REN 40 8 A03i
QVRKNRRRR HΓV REN 40 9 A03i
QARKNRRRK HΓV REN 40 9 A03i
QVRKNRRRRWR HIN REN 40 11 A03i
QARKNRRRRWK HΓV REN 40 11 A03i
PVPLQLPPLEK HIN REN 74 11 A03i
PVQLPPLER HIN REN 76 9 A03i
PLQLPPLEK HIN REN 16 9 A03i
VVPNLEPWNH HΓV TAT 4 10 A03i
VDPNLEPWNK HIV TAT 4 10 A03i
PVSQPKTA HΓV TAT 17 8 A03i
PGSQPKTK HIN TAT 17 8 A03i
TVCNNCYCK HIN TAT 23 9 A03i
AVNNCYCK HIN TAT 24 8 A03i
LV1SYGRKKRR HIN TAT 46 11 A03i
LGISYGRKKRK HΓV TAT 46 11 A03i
IVYGRKKRRQR HΓV TAT 48 11 A03i
ISYGRKKRRQK HIN TAT 48 11 A03i
YVRKKRRQR HIN TAT 50 9 A03i Sequence Organism Protein Position Length Motif
YGRKKRRQK HΓV TAT 50 9 A03i
YVRKKRRQRR HΓV TAT 50 10 A03i
YGRKKRRQRK HΓV TAT 50 10 A03i
YVRKKRRQRRR HΓV TAT 50 11 A03i
YGRKKRRQRRK HΓV TAT 50 11 A03i
RVDPTGPK HΓV TAT 84 8 A03i
TVPKESKK HΓV TAT 89 8 A03i
ETGPSGQPCK HΓV TAT 101 10 A03i
KVGPGGYPRR HΓV TAT 101 10 A03i
KAGPGGYPRK HΓV TAT 101 10 A03i
KVGPGGYPRRK HΓV TAT 101 11 A03i
AVPGGYPRR HΓV TAT 102 9 A03i
AGPGGYPRK HΓV TAT 102 9 A03i
TVPSGQPCH HΓV TAT 102 9 A03i
TGPSGQPCK HΓV TAT 102 9 A03i
AVPGGYPRRK HΓV TAT 102 10 A03i
PVGYPRRK HΓV TAT 104 8 A03i
GVYPRRKGSCH HΓV TAT 105 11 A03i
GGYPRRKGSCK HΓV TAT 105 11 A03i
KTLGISYGR HΓV TAT 44 9 A03i
KTLGISYGRK HΓV TAT 44 10 A03i
GTGISYGRKKR HΓV TAT 45 11 A03i
KTLGISYGRKK HΓV TAT 44 11 A03i
GTGISYGR HΓV TAT 45 8 A03i
GTGISYGRK HΓV TAT 45 9 A03i
GTGISYGRKK HΓV TAT 45 10 A03i
GTSYGRKKR HΓV TAT 47 9 A03i
LTISYGRKKR HΓV TAT 46 10 A03i
GTSYGRKK HΓV TAT 47 8 A03i
ITYGRKKR HΓV TAT 48 8 A03i
LTISYGRK HΓV TAT 46 8 A03i
LTISYGRKK HΓV TAT 46 9 A03i Sequence Organism Protein Position Length Motif
KTGSLQYLA HTV VΓF 146 9 A03i
VTSLQYLA HΓV VΓF 147 8 A03i
KVGSLQYLK HΓV VΓF 146 9 A03i
VGSLQYLK HIV VIF 147 8 A03i
ETVRHFPR HΓV VPR 29 8 A03i
EVHPEYYK HΓV NEF 324 8 A03s
PTRPQVPLR HΓV NEF 95 9 A03s
PTRPMTYK HΓV NEF 102 8 A03s
GTGISYGRKKR HΓV TAT 45 11 A03s
GTGISYGR HΓV TAT 45 8 A03s
GTGISYGRK HΓV TAT 45 9 A03s
GTGISYGRKK HΓV TAT 45 10 A03s
GTSYGRKKR HΓV TAT 47 9 A03s
GTSYGRKK HIV TAT 47 8 A03s
ITYGRKKR HΓV TAT 48 8 A03s
ETVRHFPR HΓV VPR 29 8 A03s
QVYTPGPGTR HΓV NEF 205 10 Alii
QNYTPGPGTK HIV NEF 205 10 Alii
QVYTPGPGΓR HIV NEF 205 10 Alii
QNYTPGPGΓK HΓV NEF 205 10 Alii
PTRPQVPLR HΓV NEF 95 9 Alii
GTPVRPQVPLR HΓV NEF 93 11 Alii
PTRPMTYK HΓV NEF 102 8 Alii
RVRRRRWR HΓV REV 43 8 Alii
RNRRRRWK HΓV REV 43 8 Alii
RVRRRRWRAR HΓV REV 43 10 Alii
RNRRRRWRAK HΓV REV 43 10 Alii
KVRRRRWR HΓV REV 43 8 Alii
KNRRRRWK HΓV REV 43 8 Alii
KVRRRRWRAR HΓV REV 43 10 Al ii
KNRRRRWRAK HΓV REV 43 10 Alii
PVLEPWNH HΓV TAT 9 8 Alii Sequence Organism Protein Position Length Motif
PNLEPWNK HΓV TAT 9 8 Al ii
KTLGISYGR HΓV TAT 44 9 Al ii
KTLGISYGRK HΓV TAT 44 10 Al ii
GTGISYGRKKR HΓV TAT 45 11 Alii
KTLGISYGRKK HΓV TAT 44 11 Alii
GTGISYGR HΓV TAT 45 8 Al ii
GTGISYGRK HΓV TAT 45 9 Al ii
GTGISYGRKK HΓV TAT 45 10 Alii
GTSYGRKKR HΓV TAT 47 9 Alii
LTISYGRKKR HΓV TAT 46 10 Alii
GTSYGRKK HΓV TAT 47 8 Alii
ITYGRKKR HΓV TAT 48 8 Al ii
LTISYGRK HΓV TAT 46 8 Alii
LTISYGRKK HΓV TAT 46 9 Alii
ETVRHFPR HΓV VPR 29 8 Alii
KYSKSSΓVGW HΓV NEF 4 10 A24i
KWSKSSΓVGF HΓV NEF 4 10 A24i
GYPVRPQVPL HΓV NEF 93 10 A24i
GFPVRPQVPF HΓV NEF 93 10 A24i
AYDLSFFL HΓV NEF 111 8 A24i
AFDLSFFF HΓV NEF 111 8 A24i
SYFLKEKGGL HΓV NEF 115 10 A24i
SFFLKEKGGF HΓV NEF 115 10 A24i
HYLKEKGGL HΓV NEF 116 9 A24i
HFLKEKGGF HΓV NEF 116 . 9 A24i
FYLKEKGGL HΓV NEF 116 9 A24i
FFLKEKGGF HΓV NEF 116 9 A24i
ΓYSKKRQEF HΓV NEF 175 9 A24i
IYSKKRQEΓF HIV' NEF 175 10 A24i
LYVYHTQGYF HΓV NEF 190 10 A24i
VYHTQGYFPDF HΓV NEF 192 11 A24i
DYQNYTPGPGI HΓV NEF 203 11 A24i Sequence Organism Protein Position Length Motif
DWQNYTPGPGF HΓV ΝEF 203 11 A24i
NYTPGPGF HΓV ΝEF 206 8 A24i
RYPLTFGF HΓV ΝEF 216 8 A24i
RYPLTFGW HΓV ΝEF 216 8 A24i
RFPLTFGF HΓV ΝEF 216 8 A24i
TYGWCFKL HΓV ΝEF 222 8 A24i
TFGWCFKF HΓV ΝEF 222 8 A24i
GFPVRPQVPF HΓV ΝEF 93 10 A24i
GYPVRPQVPL HΓV ΝEF 93 10 A24i
RYRARQRQI HΓV REV 48 9 A24i
RWRARQRQF HΓV REV 48 9 A24i
VYQVDRMRI HΓV VΓF 10 9 A24i
VWQVDRMRF HΓV VIF 10 9 A24i
GYGAVSQDL HΓV ΝEF 45 9 A24s
GVGAVSQDF HΓV ΝEF 45 9 A24s
LYVYHTQGY HΓV ΝEF 190 9 A24s
LWVYHTQGF HIV ΝEF 190 9 A24s
NYTPGPGΓRF HΓV ΝEF 206 10 A24s
PYRPQVPL HΓV ΝEF 95 8 A24s
GYPVRPQVPL HΓV ΝEF 93 10 A24s
FYKEKGGL HIV ΝEF 117 8 A24s
QYPPLERL HΓV REV 78 8 A24s
QLPPLERF HΓV REV 78 8 A24s
QYPPLERLTL HIN REV 78 10 A24s
QLPPLERLTF HIN REV 78 10 A24s
VWQVDRMRF HΓV VIF 10 9 A24s
KYGSLQYLAL HIN VIF 146 10 A24s
KYGSLQYL HΓV VΓF 146 8 A24s
IYWQVDRM HΓV VΓF 9 8 A24s
ΓVWQVDRF HΓV VΓF 9 8 A24s
APTAAKGI HΓV ΝΈF 34 8 B07s
APTAAKGVGI HΓV ΝEF 34 10 B07s Sequence Organism Protein Position Length Motif
APTAAKGVGAI HΓV ΝEF 34 11 B07s
FPVRPQVPI HΓV ΝEF 94 9 B07s
RPQVPLRPI HΓV ΝEF 98 9 B07s
RPQVPLRPMTI HΓV ΝEF 98 11 B07s
VPLRPMTI HΓV ΝEF 101 8 B07s
VPLRPMTYKGI HΓV ΝΈF 101 11 B07s
VPLRPMTYKI HΓV ΝΈF 101 10 B07s
VPLRPMTYKAI HΓV ΝEF 101 11 B07s
RPMTYKAI HΓV ΝEF 104 8 B07s
TPGPGΓRI HIN ΝEF 208 8 B07s
GPGΓRYPI HΓV ΝEF 210 8 B07s
YPLTFGWCI HΓV ΝEF 217 9 B07s
FPLTFGWCI HΓV ΝEF 217 9 B07s
FPLTFGWCFKI HΓV ΝEF 217 11 B07s
RPQVPLRPMTI HΓV ΝEF 98 11 B07s
VPLRPMTI HΓV ΝEF 101 8 B07s
RPQVPLRPI HΓV ΝEF 98 9 B07s
FPVRPQVPI HΓV ΝEF 94 9 B07s
FPVRPQVPI HIN ΝEF 94 9 B07s
RPAEPVPI HIN REV 70 8 B07s
RPAEPVPLQI HIN REV 70 10 B07s
VPLQLPPI HΓV REV 75 8 B07s
LPPLERLTI HΓV REV 79 9 B07s
PPLERLTI HTV REV 80 8 B07s
EPNPLQLPPI HΓV REV 73 10 B07s
NPLQLPPLERI HΓV REV 75 11 B07s
VPLQLPPI HΓV REV 75 8 B07s
HPGSQPKTI HΓV TAT 16 9 B07s
GPQREPYΝEI HΓV VPR 9 10 B07s
QEILDLWV HΓV ΝEF 184 8 B44s
GESDEELL HΓV REV 6 8 B44s
EECGTSGTQGV HΓV REV 91 11 B44s VEPΝLEPW HΓV TAT 4 8 B44s Table 11
Motif Parent source Length Sequence
A24i Nef 4 10 KYSKSSΓVGW
A24i Nef 4 10 KWSKSSΓVGF
AOls Nef 5 9 WTKSSΓVGW
AOls Nef 5 9 WSKSSΓVGY
A02i/s Nef 34 9 QLEPAAAGV
A02i/s Nef 34 11 QLEPAAAGVGA
A02i/s Nef 34 11 QAEPAAAGVGV
B07s Nef 34 8 APTAAKGI
B07s Nef 34 10 APTAAKGVGI
B07s Nef 34 11 APTAAKGVGAI
A02i/s Nef 41 8 PLAEGVGA
A02i/s Nef 41 8 PAAEGVGV
A02i/s Nef 42 8 ALEGVGAV
A02i/s Nef 45 9 GLGAVSRDL
A02i/s Nef 45 9 GVGAVSRDV
A24s Nef 45 9 GYGAVSQDL
A24s Nef 45 9 GVGAVSQDF
A03i Nef 51 8 RVLEKHGA
A03i Nef 51 8 RDLEKHGK
A03i Nef 61 10 HVAITSSNTA
A03i Nef 61 10 HGAITSSNTK
A02i/s Nef 62 8 GLITSSNT
A02i/s Nef 62 8 GAITSSNV
A02i/s Nef 62 9 GLITSSNTA
A02i/s Nef 62 9 GAITSSNTV
A02i/s Nef 63 8 ALTSSNTA
A02i/s Nef 63 8 AITSSNTV
A02i/s Nef 73 9 NLDCAWLEA
A02i/s Nef 73 9 NADCAWLEV
A03i Nef 74 8 AVCAWLEA Motif Parent source Length Sequence
A03i Nef 74 8 ADCAWLEK
A02i/s Nef 82 8 ELQEEEEV
A03i Nef 82 10 EVQEEEEVGF
A03i Nef 82 10 EAQEEEEVGK
A02i/s Nef 83 11 ALEEEEVGFPV
A02i/s Nef 91 10 ELGFPVRPQV
A03i Nef 93 11 GVPVRPQVPLR
A03i Nef 93 11 GFPVRPQVPLK
A24i Nef 93 10 GYPVRPQVPL
A24i Nef 93 10 GFPVRPQVPF
B07s Nef 94 9 FPVRPQVPI
A02i/s Nef 95 8 PLRPQVPL
A02i/s Nef 95 8 PVRPQVPV
A02i/s Nef 95 11 PLRPQVPLRPM
A02i/s Nef 95 11 PVRPQVPLRPV
A03i Nef 95 9 PVRPQVPLK
B07s Nef 98 9 RPQVPLRPI
B07s Nef 98 11 RPQVPLRPMTI
A02i/s Nef 99 8 PLVPLRPM
A02i/s Nef 99 8 PQVPLRPV
A02i/s Nef 99 9 PLVPLRPMT
A02i/s Nef 99 9 PQVPLRPMV
AOls Nef 100 9 QTPLRPMTY
A02i/s Nef 100 8 QLPLRPMT
A02i/s Nef 100 8 QVPLRPMV
A02i/s Nef 100 11 QLPLRPMTYKA
A02i/s Nef 100 11 QVPLRPMTYKV
B07s Nef 101 8 VPLRPMTI
B07s Nef 101 11 VPLRPMTYKGI
B07s Nef 101 10 VPLRPMTYKI
B07s Nef 101 11 VPLRPMTYKAI
A02i/s Nef 102 10 PLRPMTYKGV Motif Parent source Length Sequence
A02i/s Nef 102 9 PLRPMTYKV
A02i/s Nef 102 10 PLRPMTYKAV
A03i Nef 102 8 PVRPMTYK
B07s Nef 104 8 RPMTYKAI
A03i Nef l l l 9 AVDLSFFLK
A03i Nef ll l 11 AVDLSFFLKEK
A24i Nef ll l 8 AYDLSFFL
A24i Nef ll l 8 AFDLSFFF
A03i Nef 112 8 FVLSFFLK
A03i Nef 112 10 FVLSFFLKEK
A03i Nef 113 9 DVSHFLKEK
A03i Nef 113 9 DVSFFLKEK
A03i Nef 114 8 LVHFLKEK
A03i Nef 114 8 LVFFLKEK
A24i Nef 115 10 SYFLKEKGGL
A24i Nef 115 10 SFFLKEKGGF
A24i Nef 116 9 HYLKEKGGL
A24i Nef 116 9 HFLKEKGGF
A24i Nef 116 9 FYLKEKGGL
A24i Nef 116 9 FFLKEKGGF
A02i/s Nef 117 8 FLKEKGGV
A02i/s Nef 117 11 FLKEKGGLEGV
A02i/s Nef 117 11 FLKEKGGLDGV
A03i Nef 122 9 KVGLEGLIY
A03i Nef 122 9 KGGLEGLΓK
A03i Nef 124 8 GVLEGLΓY
A03i Nef 124 8 GGLEGLΓK
A03i Nef 124 10 GVLDGLΓYSK
A03i Nef 125 9 GVDGLΓYSK
A03i Nef 171 8 LVGLΓYSK
A02i/s Nef 173 11 GLIYSKKRQEV
A03i Nef 173 8 GVIYSKKR Motif Parent source Length Sequence
A03i Nef 173 8 GLΓYSKKK
A02i/s Nef 174 10 LLYSKKRQEI
A02i/s Nef 174 10 LΓYSKKRQEV
A02i/s Nef 174 11 LLYSKKRQEIL
A02i/s Nef 174 11 LΓYSKKRQEΓV
A24i Nef 175 9 ΓYSKKRQEF
A24i Nef 175 10 ΓYSKKRQEΓF
AOli Nef 182 10 RTEILDLWVY
AOli Nef 182 10 RQDILDLWVY
AOli Nef 182 10 RTDILDLWVY
A02i/s Nef 182 9 RLEILDLWV
A02i/s Nef 182 9 RLDILDLWV
A03i Nef 184 9 QVILDLWVY
A03i Nef 184 9 QDILDLWVK
B44s Nef 184 8 QEILDLWV
AOls Nef 185 8 ETLDLWVY
AOls Nef 185 8 DTLDLWVY
A02i/s Nef 185 10 ELLDLWVYHT
A02i/s Nef 185 10 EILDLWVYHV
A03i Nef 185 9 EVLDLWVYH
A03i Nef 185 9 EILDLWVYK
A02i/s Nef 186 9 ILDLWVYHV
A02i/s Nef 186 9 ILDLWVYNV
A03i Nef 186 8 ΓVDLWVYH
A03i Nef 186 8 ILDLWVYK
A03i Nef 187 11 LVLWVYHTQGY
A03i Nef 187 11 LDLWVYHTQGK
AOls Nef 188 10 DTWVYHTQGY
AOls Nef 188 11 DTWVYHTQGYF
AOls Nef 188 11 DLWVYHTQGYY
A24i Nef 190 10 LYVYHTQGYF
A24s Nef 190 9 LYVYHTQGY Motif Parent source Length Sequence
A24s Nef 190 9 LWVYHTQGF
AOls Nef 191 8 WTYHTQGY
AOls Nef 191 9 WTYHTQGYF
AOls Nef 191 9 WVYHTQGYY
A24i Nef 192 11 VYHTQGYFPDF
A03i Nef 196 10 QVFFPDWQNY
A03i Nef 196 10 QGFFPDWQNK
A03i Nef 198 9 GVFPDWQNY
A03i Nef 198 9 GFFPDWQNK
A03i Nef 199 8 FVPDWQNY
A03i Nef 199 8 FFPDWQNK
A24i Nef 203 11 DYQNYTPGPGI
A24i Nef 203 11 DWQNYTPGPGF
A02i/s Nef 204 10 WLNYTPGPGT
A02i/s Nef 204 10 WQNYTPGPGV
A02i/s Nef 204 10 WLNYTPGPGI
A02i/s Nef 204 10 WQNYTPGPGV
Al ii Nef 205 10 QVYTPGPGTR
Alii Nef 205 10 QNYTPGPGTK
Alii Nef 205 10 QVYTPGPGΓR
Al ii Nef 205 10 QNYTPGPGΓK
A24i Nef 206 8 NYTPGPGF
A24s Nef 206 10 NΎTPGPGΓRF
AOli Nef 207 9 YTDGPGΓRY
A02i/s Nef 207 11 YLPGPGΓRYPL
A02i/s Nef 207 11 YTPGPGLRYPV
A03i Nef 207 8 YTPGPGTK
A03i Nef 207 8 YTPGPGLK
B07s Nef 208 8 TPGPGΓRI
B07s Nef210 8 GPGΓRYPI
A03i Nef216 10 RVPLTFGWCF
A03i Nef216 10 RFPLTFGWCK Motif Parent source Length Sequence
A03i Nef216 11 RVPLTFGWCFK
A24i Nef216 8 RYPLTFGF
A24i Nef216 8 RYPLTFGW
A24i Nef216 8 RFPLTFGF
B07s Nef217 9 YPLTFGWCI
B07s Nef217 9 FPLTFGWCI
B07s Nef217 11 FPLTFGWCFKI
AOls Nef219 8 PTTFGWCF
AOls Nef219 8 PLTFGWCY
A02i/s Nef219 10 PLTFGWCFKV
A03i Nef219 9 PVTFGWCFK
A02i/s Nef 221 9 LLFGWCFKL
A02i/s Nef221 9 LTFGWCFKV
A02i/s Nef 221 10 LLFGWCFKLV
A24i Nef 222 8 TYGWCFKL
A24i Nef 222 8 TFGWCFKF
A03i Nef 257 8 LVHPICQH
A03i Nef 257 8 LLHPICQK
A03i Nef 257 8 LVHPMSQH
A03i Nef 257 8 LLHPMSQK
AOli Nef 322 8 ATELHPEY
AOli Nef 322 8 ARDLHPEY
AOli Nef 322 9 ATELHPEYY
AOli Nef 322 9 ARDLHPEYY
A03s Nef 324 8 EVHPEYYK
AOls Nef 185 8 ETLDLWVY
B07s Nef 98 11 RPQVPLRPMTI
AOls Nef 100 9 QTPLRPMTY
B07s Nef 101 8 VPLRPMTI
B07s Nef 98 9 RPQVPLRPI
A02i/s Nef 95 8 PVRPQVPV
A24s Nef 95 8 PYRPQVPL Motif Parent source Length Sequence
B07s Nef 94 9 FPVRPQVPI
B07s Nef 94 9 FPVRPQVPI
A03i Nef 95 9 PTRPQVPLR
A03s Nef 95 9 PTRPQVPLR
Al ii Nef 95 9 PTRPQVPLR
A24i Nef 93 10 GFPVRPQVPF
A24s Nef 93 10 GYPVRPQVPL
A03i Nef 93 11 GTPVRPQVPLR
Al ii Nef 93 11 GTPVRPQVPLR
A03i Nef 102 8 PTRPMTYK
A03s Nef 102 8 PTRPMTYK
Alii Nef 102 8 PTRPMTYK
A02i/s Nef 117 8 FLKEKGGV
A24s Nef 117 8 FYKEKGGL
A02i/s Nef 99 8 PQVPLRPV
A02i/s Nef 99 9 PQVPLRPMV
A02i/s Nef 100 8 QVPLRPMV
A02i/s Nef 95 8 PLRPQVPL
A24i Nef 93 10 GYPVRPQVPL
A02i/s Nef 117 8 FVKEKGGL
A02i/s Nef 99 8 PLVPLRPM
A02i/s Nef 99 9 PLVPLRPMT
A02i/s Nef 100 8 QLPLRPMT
A02i/s Nef 99 8 PVVPLRPM
A02i/s Nef 99 9 PVVPLRPMT
B44s Rev 6 8 GESDEELL
AOls Rev 20 11 ITKILYQSNPY
AOls Rev 22 9 KTLYQSNPY
AOls Rev 23 8 ITYQSNPY
A03i Rev 35 8 EVTRQARR
A03i Rev 35 8 EGTRQARK
A03i Rev 35 10 EVTRQARRNR Motif Parent source Length Sequence
A03 Rev 35 10 EGTRQARRNK A03 Rev 35 11 EVTRQARRNRR A03 Rev 35 11 EGTRQARRNRK A03 Rev 36 9 GTRQARRNK A03 Rev 36 10 GTRQARRNRK A03 Rev 36 11 GTRQARRNRRK A03 Rev 37 9 GTRQTRKNK A03 Rev 37 10 GTRQTRKNRK A03 Rev 37 11 GTRQTRKNRRK A03 Rev 37 11 TTRQARRNRRK A03 Rev 40 8 QVRRNRRR A03 Rev 40 8 QARRNRRK A03 Rev 40 9 QVRRNRRRR A03 Rev 40 9 QARRNRRRK A03 Rev 40 11 QVRRNRRRRWR A03 Rev 40 11 QARRNRRRRWK A03 Rev 40 8 QVRKNRRR A03 Rev 40 8 QARKNRRK A03 Rev 40 9 QVRKNRRRR A03 Rev 40 9 QARKNRRRK A03 Rev 40 11 QVRKNRRRRWR A03 Rev 40 11 QARKNRRRRWK Al l Rev 43 8 RVRRRRWR All Rev 43 8 RNRRRRWK Al l Rev 43 10 RVRRRRWRAR All Rev 43 10 RNRRRRWRAK Al l Rev 43 8 KVRRRRWR All Rev 43 8 KNRRRRWK Al l Rev 43 10 KVRRRRWRAR Al l Rev 43 10 KNRRRRWRAK A24: Rev 48 9 RYRARQRQI A24: Rev 48 9 RWRARQRQF Motif Parent source Length Sequence
B07s Rev 70 8 RPAEPVPI
B07s Rev 70 10 RPAEPVPLQI
A02i/s Rev 71 9 PLEPVPLQL
A02i/s Rev 71 9 PAEPVPLQV
A02i/s Rev 74 9 PLPLQLPPL
A02i/s Rev 74 9 PVPLQLPPV
A03i Rev 74 11 PVPLQLPPLEK
B07s Rev 75 8 VPLQLPPI
A02i/s Rev 76 10 PLQLPPLERV
A03i Rev 76 9 PVQLPPLER
A03i Rev 76 9 PLQLPPLEK
A02i/s Rev 77 9 LLLPPLERL
A02i/s Rev 77 9 LQLPPLERV
A02i/s Rev 77 10 LLLPPLERLT
A02i/s Rev 77 10 LQLPPLERLV
A02i/s Rev 77 11 LLLPPLERLTL
A02i/s Rev 77 11 LQLPPLERLTV
A02i/s Rev 78 9 QLPPLERLV
A24s Rev 78 8 QYPPLERL
A24s Rev 78 8 QLPPLERF
A24s Rev 78 10 QYPPLERLTL
A24s Rev 78 10 QLPPLERLTF
B07s Rev 79 9 LPPLERLTI
B07s Rev 80 8 PPLERLTI
B44s Rev 91 11 EECGTSGTQGV
A02i/s Rev 94 8 GLSGTQGV
B07s Rev 73 10 EPVPLQLPPI
B07s Rev 75 11 VPLQLPPLERI
B07s Rev 75 8 VPLQLPPI
AOls Tat 3 9 PTDPNLEPW
AOls Tat 3 9 PVDPNLEPY
A03i Tat 4 10 VVPNLEPWNH Motif Parent source Length Sequence
A03i Tat 4 10 VDPNLEPWNK
B44s Tat 4 8 VEPNLEPW
Alii Tat 9 8 PVLEPWNH
Al ii Tat 9 8 PNLEPWNK
B07s Tat 16 9 HPGSQPKTI
A03i Tat 17 8 PVSQPKTA
A03i Tat 17 8 PGSQPKTK
A03i Tat 23 9 TVCNNCYCK
A03i Tat 24 8 AVNNCYCK
A03i Tat 46 11 LVISYGRKKRR
A03i Tat 46 11 LGISYGRKKRK
A03i Tat 48 11 IVYGRKKRRQR
A03i Tat 48 11 ISYGRKKRRQK
A03i Tat 50 9 YVRKKRRQR
A03i Tat 50 9 YGRKKRRQK
A03i Tat 50 10 YVRKKRRQRR
A03i Tat 50 10 YGRKKRRQRK
A03i Tat 50 11 YVRKKRRQRRR
A03i Tat 50 11 YGRKKRRQRRK
A03i Tat 84 8 RVDPTGPK
A03i . Tat 89 8 TVPKESKK
A03i Tat 101 10 ETGPSGQPCK
A03i Tat 101 10 KVGPGGYPRR
A03i Tat 101 10 KAGPGGYPRK
A03i Tat 101 11 KVGPGGYPRRK
A03i Tat 102 9 AVPGGYPRR
A03i Tat 102 9 AGPGGYPRK
A03i Tat 102 9 TVPSGQPCH
A03i Tat 102 9 TGPSGQPCK
A03i Tat 102 10 AVPGGYPRRK
A03i Tat 104 8 PVGYPRRK
A03i Tat 105 11 GVYPRRKGSCH Motif Parent source Length Sequence
A03i Tat 105 11 GGYPRRKGSCK
A03i Tat 44 9 KTLGISYGR
Alii Tat 44 9 KTLGISYGR
A03i Tat 44 10 KTLGISYGRK
Al ii Tat 44 10 KTLGISYGRK
A03i Tat 45 GTGISYGRKKR
A03s Tat 45 GTGISYGRKKR
Al ii Tat 45 GTGISYGRKKR
A03i Tat 44 KTLGISYGRKK
Alii Tat 44 KTLGISYGRKK
A03i Tat 45 8 GTGISYGR
A03s Tat 45 8 GTGISYGR
Al ii Tat 45 8 GTGISYGR
A03i Tat 45 9 GTGISYGRK
A03s Tat 45 9 GTGISYGRK
Al ii Tat 45 9 GTGISYGRK
A03i Tat 45 10 GTGISYGRKK
A03s Tat 45 10 GTGISYGRKK
Al ii Tat 45 10 GTGISYGRKK
A03i Tat 47 9 GTSYGRKKR
A03s Tat 47 9 GTSYGRKKR
Alii Tat 47 9 GTSYGRKKR
A03i Tat 46 10 LTISYGRKKR
Alii Tat 46 10 LTISYGRKKR
A03i Tat 47 8 GTSYGRKK
A03s Tat 47 8 GTSYGRKK
Al ii Tat 47 8 GTSYGRKK
A03i Tat 48 8 ITYGRKKR
A03s Tat 48 8 ITYGRKKR
Alii Tat 48 8 ITYGRKKR
A03i Tat 46 8 LTISYGRK
Al ii Tat 46 8 LTISYGRK Motif Parent source Length Sequence
A03i Tat 46 9 LTISYGRKK
Alii Tat 46 9 LTISYGRKK
AOls Vif 23 8 STVKHHMY
A02i/s Vif 11 8 WQVDRMRV
A24i Vif 10 9 VYQVDRMRI
A24s Vif 10 9 VWQVDRMRF
A02i/s Vif 146 10 KVGSLQYLAV
A24s Vif 146 10 KYGSLQYLAL
A02i/s Vif 146 8 KVGSLQYV
A24s Vif 146 8 KYGSLQYL
A02i/s Vif 146 9 KVGSLQYLV
A03i Vif 146 9 KTGSLQYLA
A03i Vif 147 8 VTSLQYLA
A02i/s Vif 9 8 IVWQVDRV
A24s Vif 9 8 ΓYWQVDRM
A02i/s Vif 11 8 WLNDRMRI
A24i Vif 10 9 VWQVDRMRF
A02i/s Vif 146 10 KLGSLQYLAL
A02i/s Vif 146 8 KLGSLQYL
A02i/s Vif 146 9 KLGSLQYLA
A03i Vif 146 9 KVGSLQYLK
A03i Vif 147 8 VGSLQYLK
A02i/s Vif 9 8 ILWQVDRM
A24s Vif 9 8 ΓVWQVDRF
A02i/s Vif 11 8 WVVDRMRI
B07s Vpr 9 10 GPQREPYΝEI
AOli Vpr 5 11 PTDQGPQREPY
A03i Vpr 29 8 ETVRHFPR
A03s Vpr 29 8 ETVRHFPR
Al ii Vpr 29 8 ETVRHFPR Table 12
HLA- A1 supertype binding affinity (IC50 nM)
Peptide Sequence Source Analog A*0101 A*2902 A*3002
57.0007 AADNPPAQY .CEA.261 A 9.2
57.0026 GGDVENPEY .Her2/neu.ll88 A 399
57.0021 VTAGVGSPY .Her2/neu.773 A 269
1074.17 AC-YTAWPLVY Jchain. A 37
1074.20 AYTAVVPLVY Jchain. A 455
1074.19 RYTAVVPLVY Jchain. A >296.17
1489.15 LVTCLGLSY .MAGE2.178 4132 18 4101
1489.16 LVQENYLEY .MAGE2.250 48 13 72
57.0029 STFSTTTNY .MAGE2.69 A 114
1461.06 MEVDPIGHLY .MAGE3.167 371 333 87
1489.18 FVQENYLEY .MAGE3.250 26 3.2 99
26.0224 SAEQSPPPY .MARTI.108 269
57.0128 VGDDCTTTHY .p53.225 A 465
1044.12 SEVDPIGHLY .PAP.135 A 395
26.0231 SMHNALfflY .Tyrosinase.361 345
26.0484 ISSKDLGYDY .Tyrosinase.440 185
954.06 AADAAAAKAY Artificial sequence PolyA 107
21.0009 AADAAAAKY Artificial sequence PolyA 20
954.07 AAEAAAAKY Artificial sequence PolyA 149
954.04 AAEKAAAAAY Artificial sequence PolyA 236
954.10 ALAKAAAAAY Artificial sequence PolyA 456
954.20 ALEKAAAAAY Artificial sequence PolyA 173
954.19 ALEKAAAAY Artificial sequence PolyA 151
26.0033 GMQNIYIKY Artificial sequence 294
26.0034 ITYFKKIYY Artificial sequence 285
Table 12
HLA- Al supertype binding affinity (IC50 nM)
Peptide Sequence Source An; alog A*0101 A*2902 A*3002
962.13 YTAQAAAKF Artificial sequence Poly 127
1489.10 LHGPTPLLY HCV.II.1623 >34879.01 180 1075
1489.11 AQPGYPWPLY HCV.II.77 >31382.68 133 3.5
1489.06 AATLGFGAY HCV.IV.1264 44768 2240 491
1489.12 TCGFADLMGY HCV.IV.127 2321 - 350 356
1489.05 CSFSTFLLA HCV.IV.172 28906 153 11100
78.0359 RFTTNLRGRW HPV.16.E6.131 53191 18 58
78.0001 THDITLECVY HPV.16.E6.30 316 8873 8939
78.0002 YSKISEYRHY HPV.16.E6.77 151 6448 205
78.0177 EYRHYCYSLY HPV.16.E6.82 2564 2449 120
78.0006 LQDTEITCVY HPV.18.E6.25 1517 4044 148
78.0005 RFEDPTRRPY HPV.18.E6.3 19231 17839 145
78.0361 LFVVYRDSI HPV.18.E6.52 20921 464 100
78.0363 RFHNIGGRW HPV.31.E6.124 >35714.29 1595 9.5
78.0009 YSKVSEFRWY HPV.31.E6.70 539 4514 . 185
78.0366 RFHNISGRW HPY33.E6.124 48544 174 37
78.0364 VYDFAFADL HPV.33.E6.42 19763 163 579
78.0365 RFLSKISEY HPV.33.E6.68 >35714.29 34623 23
78.0243 ISEYRHYNY HPV.33.E6.73 25 1329 32
78.0180 EYRHYNYSVY HPV.33.E6.75 31447 16016 253
78.0348 LYPEPTDLY HPV.33.E7.15 31 36 71
78.0244 LKEYVLDLY HPV.33.E7.8 3270 127123 16
78.0246 ATLERTEVY HPV.45.E6.37 35 11383 175
78.0368 AFKDLCIVY HPV.45.E6.48 >35714.29 32 0.49
78.0349 AYAACHKCI HPV.45.E6.61 32895 3300 139
Table 12
HLA- Al supertype binding affinity (IC50 nM)
Peptide Sequence Source Analog A*0101 A*2902 A*3002
78.0182 FYSRTRELRY HPV.45.E6.71 10142 20 150
78.0247 YSRTRELRY HPV.45.E6.72 41 1991 22
78.0369 VYGETLEKI HPV.45.E6.85 >35714.29 12156 13
78.0017 ELDPVDLLCY HPV.45.E7.20 26 4291 12746
78.0371 VYKFLFTDL HPV.52.E6.42 >35714.29 1707 27
78.0372 LFTDLRIVY HPV.52.E6.46 >35714.29 25003 22
78.0019 LSKISEYRHY HPV.52.E6.70 14327 55190 186
78.0248 ISEYRHYQY HPV.52.E6.73 283 >84107.89 3765
78.0183 EYRHYQYSLY HPV.52.E6.75 2268 2372 130
78.0249 QAEQATSNY HPV.52.E7.46 74 4203 109
78.0022 QAEQATSNYY HPV.52.E7.46 101 39409 1436
78.0023 ATSNYYIVTY HPV.52.E7.50 2209 2117 118
78.0250 TSNYYIVTY HPV.52.E7.51 >74955.86 3313 76
78.0376 NFACTELKL HPV.56.E6.47 >35971.22 202 1.0
1488.11 AVCRVCLLFY HPV.56.E6.64 105
78.0378 LFYSKVRKY HPV.56.E6.71 1262 12 89
78.0176 FYSKVRKYRY HPV.56.E6.72 >32894.74 146 326
1497.15 KYRYYDYSVY HPV.56.E6.78 17797 2.3
78.0379 DYSVYGATL HPV.56.E6.83 >35971.22 1460 19
78.0252 LCDLLTRCY HPV.56.E6.99 656 557 26
78.0384 RFHNISGRW HPV.58.E6.124 >35971.22 201 35
78.0253 KTLQRSEVY HPV.58.E6.35 308 6276 566
78.0381 VYDFVFADL HPV.58.E6.42 >35971.22 27168 27
78.0027 LSKISEYRHY HPV.58.E6.70 17182 101409 159
78.0254 ISEYRHYNY HPV.58.E6.73 46 853 81
Table 12
HLA- A1 supertype binding affinity (IC50 nM)
Peptide Sequence Source Analog A*0101 A*2902 A*3002
78.0354 EYRHYNYSL HPV.58.E6.75 54348 268 1473
78.0185 EYRHYNYSLY HPV.58.E6.75 2405 1774 67
26.0271 RMAWHAAGTY MT.104 423
26.0075 VTPEQRPLY MT.1752 331
26.0283 QMGLGWKSSY MT.294 340
26.0037 RTGLYGAQY MT.344 116
1489.22 ALFQEYQCY Pf.CSP.18 >38534.16 149 1032
1489.55 YYGKQENWY Pf.CSP.55 373 3155
1489.61 FYFΓLVNLLI Pf.LSA1.9 362 8591
1489.27 FVVPGAATPY Pf.SSP2.520 31338 317 4621 vo
Ul
TABLE 13
A*0101
Peptide Sequence AA Source Analog (IC50 nM)
57.0007 AADNPPAQY 9 CEA.261 A 46
57.0013 AADNPPAQY 9 CEA.439 A 46
57.0106 HSDSNPSPQY 10 CEA.616 A 46
57.0105 . HTASNPSPQY 10 CEA.616 A 134
57.0014 ITDKNSGLY 9 CEA.467 A 12
57.0008 ITDNNSGSY 9 CEA.289 A 110
57.0103 PTDSPLNTSY 10 CEA.240 A 292
57.0011 PTDSPSYTY 9 CEA.418 A 38
57.0104 PTDSPSYTYY 10 CEA.418 A 2.0
57.0004 QQDTPGPAY 9 CEA.87 A 57
57.0012 TIDPSYTYY 9 CEA.419 A 3.5
57.0010 VTDNDVGPY 9 CEA.383 A 4.5
26.0155 WSQKRSVPY 9 gplOO.143 242
57.0018 ATCVTACPY 9 Her2/neu.293 A 57
57.0024 ATPLDSTFY 9 Her2/neu.997 A 40
57.0113 CTQIAKGMSY 10 Her2/neu.826 A 20
57.0019 ETDEEITGY 9 Her2/neu.401 A 18
57.0111 ETMPNPEGRY 10 Her2/neu.280 A 4.1
57.0114 FTDQSDVWSY 10 Her2/neu.899 A 0.64
57.0027 FTPAFDNLY 9 Her2/neu.l213 A 9.1
57.0117 FTPAFDNLYY 10 Her2/neu.l213 A 0.82
57.0017 GTDLFEDNY 9 Her2/neu.l04 A 0.91
57.0107 GTDMKLRLPY 10 Her2/neu.28 A 50
57.0118 GTDTAENPEY 10 Her2/neu.l239 A 27
57.0016 HTDMLRHLY 9 Her2/neu.42 A 2.0
57.0023 LTDTDETEY 9 Her2/neu.869 A 6.5
57.0025 LTDSPQPEY 9 Her2/neu.ll31 A 36
57.0116 MTDLVDAEEY 10 Her2/neu.l014 A 2.5
57.0115 PADPLDSTFY 10 Her2/neu.996 A 19
57.0129 PTDCCHEQCAY 11 Her2/neu.232 A 18
57.0109 PTDCCHEQCY 10 Her2/neu.232 A 47
57.0028 SPDFDNLYY 9 Her2/neu.l214 A 73
57.0112 TLDEITGYLY 10 Her2/neu.402 A 3.6
57.0022 VMDGVGSPY 9 Her2/neu.773 A 41
57.0120 ASDFSTTINY 10 MAGE2.68 A 24
57.0123 ASDLPTTMNY 10 MAGE3.68 A 2.6
57.0119 ATSFSTTINY 10 MAGE2.68 A 476
57.0122 ATSLPTTMNY 10 MAGE3.68 A 214
57.0032 GTVVGNWQY 9 MAGE3.137 A 37
57.0034 ITGGPHTSY 9 MAGE3.293 A 36
57.0124 LTDHFVQENY 10 MAGE3.246 A 2.4
57.0121 LTQDLVQENY 10 MAGE2.246 A 64
57.0030 MTDLVQENY 9 MAGE2.247 A 0.79
57.0031 STLPTTMNY 9 MAGE3.69 A 58
57.0003 VTDLGLSY 8 MAGE2.179 A 2.7
26.0468 LSAEQSPPPY 10 MART 1.107 35 TABLE 13
A*0101
Peptide Sequence AA Source Analog (IC50 nM)
57.0035 GTDCTTIHY 9 p53.226 A 0.85
57.0126 GTDKSVTCTY 10 p53.117 A 43
57.0125 PTQKTYQGSY 10 p53.98 A 37
57.0127 RVDGNLRVEY 10 p53.196 A 47
1381.01 PSDKHIKEY 9 Pf.CSP.310 27
26.0480 DSDPDSFQDY 10 Tyrosinase.454 5.5
1074.17 YTAVVPLVY 10 Jchain. A 186
F011.03 ATDFKFAMY 9 Naturally processed 0.75
F011.06 DSDGSFFLY 9 Naturally processed 0.65
F020.01 DSGDSFFLY 9 Naturally processed 34
F011.07 GTDENRLLY 9 Naturally processed 1.3
F011.0T IADMGHLKY 9 Naturally processed 3.2
F023.04 YLDDPDLKY 9 Naturally processed 3.2
FO 11.02 YTDYGGLTFNSY 12 Naturally processed 2.0
F029.03 YTNPQFNVY 9 Naturally processed 25
FO 11.04 YTSDYFISY 9 Naturally processed 4.8
F023.02 YTSDYFYSY 9 Naturally processed 0.25
21.0009 AADAAAAKY 9 Artificial sequence Poly A 101
954.05 AADAAAAKY 9 Artificial sequence Poly A 64
962.10 AADAKAAAY 9 Artificial sequence Poly A 95
954.18 ALDKAAAAAY 10 Artificial sequence Poly A 31
954.17 ALDKAAAAY 9 Artificial sequence Poly A 39
962.09 ATDAKAAAY 9 Artificial sequence Poly A 6.9
982.18 ATDKAAAAA 9 Artificial sequence Poly 73
962.08 ATDPKAAAY 9 Artificial sequence Poly A 6.5
954.22 ATEKAAAAAY 10 Artificial sequence Poly A 9.6
954.21 ATEKAAAAY 9 Artificial sequence Poly A 6.2
962.14 YTAQAAAKY 9 Artificial sequence Poly 4.2
1074.02 YTAVVPLVF 9 Artificial sequence A 21
962.11 YTDPKLINY 9 Artificial sequence Poly 8.2
962.12 YTDQAVIKY 9 Artificial sequence Poly 2.8
Table 14
HLA- A2 supertype binding affinity (IC50 nM)
Peptide Sequence Source Analog A*0201 A*0202 A*0203 A*0205 A*0206 A*6802
70.0094 FLLAQFTSAI HBV.Pol.503 65 1.9 4.8 148 533
70.0088 FLPSDYFPSV HBV.Core.18 A 8.5 3.3 3.2 2.2 276
1369.03 FVLSLGTHV HBV.pol.562 A 45 400 2837 1414 133 62
1369.01 GVLGWSPQV HBV.env.62 A 22 157 393 37 28 9357
1369.02 HVYSHPHV HBV.pol.1076 A 151 1921 14 11026 1200 122
1369.26 IVRGTSFWV HBV.pol.773 A 36765 5298 68 1828 5386 1222
1369.13 PVLPTFFCV HBV.env.377 A 8.7 3140 13643 43000 22 1814
924.201 QFLPSDFFPSV HBV.core.27 A 394
1369.14 VVQAGFFLV HBV.env.177 A 438 78 2484 785 81 624
1369.15 YVDDVVLGV HBV.pol.538 A 18 14 70 91 16 360
1489.30 FLLALLSCLT HCV.II.177 90 21 65 488 4235 vo oe 1472.05 RVLEDGVNYA HCV.Core.156 3785 24 3292 39 190167
1327.12 TLWARMTLM HCV.II.2871 11 36 118 204 519
1472.06 VLEDGVNYA HCV.Core.157 2141 53 64 10898 194602
1489.29 YQATVCARA HCV.IV.1594 405 13 23 118 4976
1482.09 ALETSVHEI HPV58.E6.18 1514 248 317 12546 >447213.6
1491.78. ALETSVHEV HPV.58.E6.18 265 114 148 2272 68376
1481.49 ALETTTHNI HPV33.E6.18 2122 189 894 2265 97129
1491.36 ALETTTHNV HPV.33.E6.18 A 286 34 272 2070 42534
1482.04 ALTVTCPLCA HPV56.E7.93 8382 1310 335 157625 >165379.65
1481.60 AQPATADYYI HPV33.E7.45 17763 224 21164 5272 318546
1482.20 AQPATANYYI HPV58.E7.46 9604 141 3584 2190 15996
1090.75 CVYCKQQLL HPV.16.E6.37 38396 425 9535 43026 9097
1481.10 DLLMGTLGIV HPV16.E7.81 857 70 71 607 12006
1481.42 ELLMGSFGIV HPV31.E7.81 996 202 26 273 10648
Table 14
HLA- A2 supertype binding affinity (IC50 nM)
Peptide Sequence Source Analog A*0201 A*0202 A*0203 A*0205 A*0206 A*6802
1481.13 ELTEVFEFA HPV18.E6.40 8079 47 6241 396 51
1481.76 ELYNLLΓRCL HPV45.E6.97 11777 1351 425 15935 2191
1481.86 EVLEΓPLΓDL HPV56.E6.20 144749 2625 18829 6013 484
1481.51 EVYDFAFADL HPV33.E6.41 36182 16188 2710 80 25
1482.11 EVYDFVFADL HPV58.E6.41 49309 12065 3138 60 9.8
1481.89 FACTELKLV HPV56.E6.48 4173 3200 38 186 62013
1481.52 FAFADLTVV HPV33.E6.45 42 16 5.3 22 277
1481.70 FAFKDLCIV HPV45.E6.47 142 1817 12 62 2618
1481.14 FAFKDLFW HPV18.E6.47 20 191 5.8 12 35
1481.32 FAFTDLTIV HPV31.E6.45 137 75 10 24 179
1491.61 FLCTELKLV HPV.56.E6.48 A 247 88 143 379 50150
1491.79 FLFADLRΓV HPV.58.E6.45 A 32 9.4 5.7 85 4744
1491.38 FLFADLTVV HPV.33.E6.45 A 12 0.3 2.5 23 327
1491.48 FLFKDLCIV HPV.45.E6.47 A 12 1.3 5.5 9.3 2446
1491.14 FLFKDLFVV HPV.18.E6.47 A 6.0 0.9 3.5 8.4 274
1491.07 FLFRDLCIV HPV.16.E6.52 A 16 3.2 8.2 50 582
1483.01 FLFTDLRIV HPV.52.E6.45 18 1.7 3.3 34 3803
1491.29 FLFTDLTIV HPV.31.E6.45 A 17 1.3 3.5 20 1904
1491.18 FLQLFLNTL HPV.18.E7.86 A 17 1.4 2.5 54 12994
1481.24 FQQLFLNTL HPV18.E7.86 572 18 11 20 280745
1491.19 FQQLFLNTV HPV.18.E7.86 A 104 18 2.7 21 23131
1482.12 FVFADLRIV HPV58.E6.45 98 98 4.0 85 334
1482.03 GALTVTCPL HPV56.E7.92 1271 1969 7183 140 67111
1491.72 GALTVTCPV HPV.56.E7.92 A 281 3341 3059 105 8374
1481.53 GICKLCLRFL HPV33.E6.61 733 199 310 2089 11432
Table 14
HLA- A2 supertype binding affinity (IC50 nM)
Peptide Sequence Source Analog A*0201 A*0202 A*0203 A*0205 A*0206 A*6802
1491.40 GICKLCLRFV HPV.33.E6.61 A 132 32 28 404 19028
1491.39 GLCKLCLRFL HPV.33.E6.61 A 127 2.5 18 4135 15406
1491.08 GLLGΓVCPI HPV.16.E7.85 A 13 3.0 14 61 4758
1491.71 GLLTVTCPL HPV.56.E7.92 A 45 18 256 83 68853
1481.19 GLYNLLTRCL HPV18.E6.97 1757 18 6.9 2336 9405
1491.22 GLYNLLTRCV HPV.18.E6.97 A 167 13 5.3 1221 3203
1491.09 GTLGIVCPV HPV.16.E7.85 A 20 49 68 33 32
1481.85 HLSEVLEIPL HPV56.E6.17 1032 3.3 586 2063 486
1491.59 HLSEVLEIPV HPV.56.E6.17 A 508 15 65 507 176
1491.49 ΓLYRDCIAYA HPV.45.E6.54 A 108 1.5 3.3 118 3627
1483.07 ΓMCLRFLSKI HPV.52.E6.64 1857 483 239 4398 17904
© © 1491.89 ΓMCLRFLSKV HPV.52.E6.64 A 2713 574 81 2357 5259
1481.63 IQQLLMGTV HPV33.E7.79 6592 17489 36 805 >379509.93
1481.75 ITNTELYNL HPV45.E6.93 9682 52 3456 2002 6153
1481.71 IVYRDCIAYA HPV45.E6.54 1162 16 3.9 63 1096
1491.50 IVYRDCIAYV HPV.45.E6.54 A 697 16 4.3 68 74
1481.74 KITNTELYNL HPV45.E6.92 3256 18 3310 293 378556
1491.56 KITNTELYNV HPV.45.E6.92 A 199 109 19 114 80759
1481.54 KLCLRFLSKI HPV33.E6.64 1588 8581 335 1006 17208
1491.41 KLCLRELSKV HPV.33.E6.64 A 1759 594 83 5124 8915
1481.26 KLHELSSAL HPV31.E6.il 178 1.1 3.8 992 >223606.8
1491.24 KLHELSSAV HPV.31.E6.il A 144 2.5 3.7 1168 47805
1491.62 KLHTCYLΓHV HPV.56.E7.54 A 235 71 94 115 6991
1491.12 KLPDLCTEV HPV. 18/45.E6.13 A 65 2.7 11 101 40670
1491.05 KLPQLCTEV HPV.16.E6.18 A 93 17 37 92 72458
Table 14
HLA- A2 supertype binding affinity (IC50 nM)
Peptide Sequence Source Analog A*0201 A*0202 A*0203 A*0205 A*0206 A*6802
1481.34 KLTNKGICDL HPV31.E6.90 205 440 585 484 >96308.68
1491.30 KLTNKGICDV HPV.31.E6.90 A 344 25 54 190 >41894
1491.55 KLTNTELYNL HPV.45.E6.92 A 1412 8.0 34 11272 >41369.22
1491.20 KLTNTGLYNV HPV.18.E6.92 A 106 2.9 4.7 83 688
1491.13 KLVLELTEV HPV.18.E6.36 A 88 16 24 226 >52914.06
1481.97 KQHTCYLIHV HPV56.E7.54 1137 1688 39 79 36431
1481.12 KTVLELTEV HPV18.E6.36 496 3715 41 96 7576
1481.88 LIDLRLSCV HPV56.E6.26 496 96 44 165 4413
1491.60 LLDLRLSCV HPV.56.E6.26 A 256 1445 708 139 1905
1491.45 LLDVSIACV HPV.45.E6.25 A 61 48 387 41 3379
1482.02 LLMGALTVT HPV56.E7.89 140 52 33 164 139561
1491.70 LLMGALTVV HPV.56.E7.89 A 40 6.9 18 103 1537
1481.44 LLMGSFGIV HPV31.E7.82 138 42 3.0 20 64853
1482.25 LLMGTCTIV HPV58.E7.83 76 3.3 6.0 138 29355
1481.65 LLMGTVNIV HPV33.E7.82 56 2.4 4.2 128 21582
1491.53 LLQLFLSTL HPV.45.E7.87 A 98 1.5 3.4 181 4252
1491.63 LLYRDDFPYA HPV.56.E6.55 A 162 3.6 145 25 4031
1481.67 LQDVSIACV HPV45.E6.25 192 3106 6013 108 199469
1481.82 LQQLFLSTL HPV45.E7.87 4398 146 81 185 115466
1491.54 LQQLFLSTV HPV.45.E7.87 A 180 39 5.4 67 24253
1481.17 LTNTGLYNL HPV18.E6.93 13609 20 4987 1835 1580
1481.90 LVYRDDFPYA HPV56.E6.55 914 178 628 12 305
1491.64 LVYRDDFPYV HPV.56.E6.55 A 331 2487 693 53 161
1481.21 MLCMCCKCEA HPV18.E7.61 1728 178 346 750 3782
1491.15 MLCMCCKCEV HPV.18.E7.61 A 383 123 235 928 1374
Table 14
HLA- A2 supertype binding affinity (IC50 nM)
Peptide Sequence Source Analog A*0201 A*0202 A*0203 A*0205 A*0206 A*6802
1483.03 MLLGTLQVV HPV.52.E7.84 36 14 9.9 52 2775
1481.87 PLIDLRLSCV HPV56.E6.25 569 39 6.0 146 1965
1482.08 QALETSVHEI HPV58.E6.17 1144 123 346 9600 163332
1491.77 QALETSVHEV HPV.58.E6.17 A 1785 298 925 7345 6502
1481.48 QALETTIHNI HPV33.E6.17 4288 181 965 3309 247293
1491.35 QALETTIHNV HPV.33.E6.17 A 1217 155 475 1509 19421
1481.83 QLFLSTLSFV HPV45.E7.89 106 3.8 11 75 362
1491.76 QLLETSVHEI HPV.58.E6.17 A 2427 189 923 11863 39909
1491.34 QLLETTIHNI HPV.33.E6.17 A 1702 168 474 1128 44525
1491.86 QLLLGTLQVV HPV.52.E7.83 A 85 26 6.3 137 7677
1482.01 QLLMGALTV HPV56.E7.88 201 990 149 1360 68105
1481.99 QLLMGALTVT HPV56.E7.88 1235 238 147 1163 97963
1491.69 QLLMGALTVV HPV.56.E7.88 162 12 4.7 208 1358
1482.24 QLLMGTCTIV HPV58.E7.82 304 20 41 835 119377
1481.64 QLLMGTVNIV HPV33.E7.81 502 25 158 3476 99642
1491.91 QLMLLGTLQV HPV.52.E7.82 77 95 68 1298 9110
1483.04 QMLLGTLQV HPV.52.E7.83 374 186 251 1523 32794
1483.05 QMLLGTLQVV HPV.52.E7.83 77 12 6.0 120 2977
1483.09 QQMLLGTLQV HPV.52.E7.82 675 331 344 71 2012
1481.04 QQYNKPLCDL HPV16.E6.97 25370 12085 52 2166 121435
1481.23 RAFQQLFLNT HPV18.E7.84 170400 0 4270 114 142375
1481.06 RLCVQSTHV HPV16.E7.66 1883 250 128 725 25116
1481.41 RLCVQSTQV HPV31.E7.66 1416 1941 152 2084 78507
1491.93 RLLHELCEV HPV.52.E6.10 A 25 18 61 93 >63492.06
1491.65 RLVQQLLMGA HPV.56.E7.84 A 873 1626 9.4 875 >37331.55
Table 14
HLA- A2 supertype binding affinity (IC50 nM)
Peptide Sequence Source Analog A*0201 A*0202 A*0203 A*0205 A*0206 A*6802
1481.07 RTLEDLLMGT HPV16.E7.77 17556 701 7397 102 >60329.7
1481.46 RTLHDLCQA HPV33.E6.10 8121 34 678 96 61604
1482.06 RTLHDLCQA HPV58.E6.10 5274 142 473 73 >447213.6
1483.11 RTLHELCEV HPV.52.E6.10 82 46 341 7.0 5670
1481.98 RVVQQLLMGA HPV56.E7.84 1587 7065 372 102 13817
1491.66 RVVQQLLMGV HPV.56.E7.84 A 254 2412 8.8 69 2336
1481.27 SALEIPYDEL HPV31.E6.17 11239 2263 111943 306 135671
1481.68 SIACVYCKA HPV45.E6.29 8938 31 599 8665 2724
1491.87 SLHEIRLQCV HPV.52.E6.22 A 1003 12 10 7923 11701
1481.66 SLQDVSIACV HPV45.E6.24 67 22 27 251 82033
©
Uι 1491.67 SLYGATLESI HPV.56.E6.85 A 451 23 23 401 2114
1491.16 SLYGDTLEKL HPV.18.E6.84 A 139 2.5 11 275 7640
1482.15 SLYGDTLEQT HPV58.E6.82 408 9.7 65 1005 261482
1491.82 SLYGDTLEQV HPV.58.E6.82 A 251 9.2 27 306 257
1491.51 SLYGETLEKI HPV.45.E6.84 A 301 4.0 25 358 3491
1491.42 SLYGNTLEQT HPV.33.E6.82 A 216 2.5 9.5 513 4712
1482.10 SVHEIELKCV HPV58.E6.22 12550 1214 1636 871 351
1483.06 SVHEIRLQCV HPV.52.E6.22 1262 ' 130 262 369 38
1481.93 SVYGATLESI HPV56.E6.85 813 25 27 110 470
1491.68 SVYGATLESV HPV.56.E6.85 A 248 12 19 131 35
1481.16 SVYGDTLEKL HPV18.E6.84 2238 19 82 130 909
1491.17 SVYGDTLEKV HPV.18.E6.84 A 198 9.6 5.6 130 29
1481.73 SVYGETLEKI HPV45.E6.84 995 14 23 241 1529
1491.52 SVYGETLEKV HPV.45.E6.84 A 320 7.8 23 171 30
1481.55 SVYGNTLEQT HPV33.E6.82 1056 75 32 560 3065
Table 14
HLA- A2 supertype binding affinity (IC50 nM)
Peptide Sequence Source Analog A*0201 A*0202 A*0203 A*0205 A*0206 A*6802
1491.43 SVYGNTLEQV HPV.33.E6.82 157 3.5 12 70 10.2 1481.33 SVYGTTLEKL HPV31.E6.82 11249 40 932 240 1095 1481.50 TIHNΓELQCV HPV33.E6.22 3411 231 273 301 2630 1481.62 TIQQLLMGTV HPV33.E7.78 6902 5860 26 7943 3844 1481.09 TLEDLLMGT HPV16.E7.78 13241 317 1162 2126 >67134.51 1481.08 TLEDLLMGTL HPV16.E7.78 12724 474 3738 81842 >60329.7 1491.10 TLGIVCPV HPV.16.E7.86 A 9.0 3.2 7.2 24 165 1491.06 TLHDIILECV HPV.16.E6.29 A 3.6 0.5 1.9 92 2947 1481.47 TLHDLCQAL HPV33.E6.i l 1404 2.7 40 2182 70390 1482.07 TLHDLCQAL HPV58.E6.i l 1043 8.3 46 11185 130225 1491.73 TLHDLCQAV HPV.58.E6.i l A 331 13 15 10585 2288 1491.01 TLHEYMLDV HPV.16.E7.7 A 74 4.4 9.8 78 2424 1491.37 TLHNIELQCV HPV.33.E6.22 A 206 3.4 7.5 584 2475 1481.57 TLKEYVLDL HPV33.E7.7 8004 70 12 117530 615105 1491.11 TLQDIVLHV HPV.18.E7.7 A 20 23 7.0 684 1683 1481.95 TLQDVVLEL HPV56.E7.7 24 7.8 23 649 13838 1491.58 TLQDVVLEV HPV.56.E7.7 A 52 73 25 90 2275 1481.36 TLQDYVLDL HPV31.E7.7 209 32 90 2294 91800 1491.23 TLQDYVLDV HPV.31.E7.7 A 28 30 6.1 711 6181 1481.77 TLQEIVLHL HPV45.E7.7 124 20 155 2692 254071 1491.44 TLQEIVLHV HPV.45.E7.7 A 19 30 5.1 309 2457 1481.81 TLQQLFLSTL HPV45.E7.86 10329 145 173 1917 295602 1482.23 TLQQLLMGT HPV58.E7.79 5407 4161 343 19328 355458 1483.08 TLQQMLLGT HPV.52.E7.80 3994 1876 47 940 66940 1483.15 TLQQMLLGTL HPV.52.E7.80 11590 1207 82 94848 63961
Table 14
HLA- A2 supertype bind ling affinity (IC50 nM)
Peptide Sequence Source Analog A*0201 A*0202 A*0203 A*0205 A*0206 A*6802
1491.90 TLQQMLLGV HPV.52.E7.80 A 42 17 4.6 28 454
1483.20 TLQVVCPGCA HPV.52.E7.88 173805 8146 446 226554 48401
1482.17 TLREYTLDL HPV58.E7.7 13653 1372 6.2 148231 >389869.03
1483.19 TLRLCIHSTA HPV.52.E7.66 69139 5407 329 59923 9270
1481.40 TLRLCVQST HPV31.E7.64 6394 22268 136 28285 4163
1481.25 TLSFVCPWCA HPV18.E7.93 1611 221 521 27321 13228
1481.84 TLSFVCPWCA HPV45.E7.94 1499 292 763 3657 7714
1491.57 TLSFVCPWCV HPV.45.E7.94 A 786 91 370 4357 348
1491.21 TLSFVCPWCV HPV.18.E7.93 A 368 118 255 7573 2299
1483.10 VLEESVHEI HPV.52.E6.18 426 22 354 831 >56545.93
© 1491.92 VLEESVHEV HPV.52.E6.18 A 236 30 163 1283 198762
UX
1481.15 VVYRDSIPHA HPV18.E6.54 20174 261 393 702 15021
1481.91 YAVCRVCLL HPV56.E6.63 9827 27573 937 327 6152
1482.18 YILDLHPEPT HPV58.E7.i l 136 639 28 1236 219394
1491.75 YΓLDLHPEPV HPV.58.E7.i l A 91 69 5.8 64 335
1483.02 YΓLDLQPET HPV.52.E7.i l 449 2778 467 186 67516
1483.16 YILDLQPETT HPV.52.E7.i l 428 1684 336 7730 66404
1491.94 YILDLQPETV HPV.52.E7.i l A 35 11 10 131 264
1491.84 YILDLQPEV HPV.52.E7.i l A 145 166 245 78 6387
1491.80 YLCGTTVRL HPV.58.E7.60 A 246 12 43 1369 2553
1491.46 YLFAFKDLCI HPV.45.E6.45 A 24 2.2 8.1 81 4067
1491.74 YLLDLHPEPT HPV.58.E7.i l A 82 15 29 1456 100474
1491.25 YLLDLQPEA HPV.31.E7.i l A 20 2.2 6.6 136 46519
1491.27 YLLDLQPEAT HPV.31.E7.i l A 24 16 6.4 975 >57908.91
1491.02 YLLDLQPET HPV.16.E7.i l A 16 57 78 159 >47202.54
Table 14
HLA- A2 supertype binding affinity (IC50 nM)
Peptide Sequence Source Analog A*0201 A*0202 A*0203 A*0205 A*0206 A*6802
1491.03 YLLDLQPETT HPV.16.E7.i l A 93 18 16 565 39475
1491.04 YMLDLQPETV HPV.16.E7.i l A 19 1.9 4.5 86 5446
1202.13 YMLDLQPEV HPV.16.E7.i l A 19 1.6 14 25 18840
1481.69 YQFAFKDLCI HPV45.E6.45 87 95 23 41 68211
1491.47 YQFAFKDLCV HPV.45.E6.45 15 1.3 4.2 10.0 3698
1483.18 YQYSLYGKTL HPV.52.E6.79 91919 2095 297 4709 74927
1482.21 YTCGTTVRL HPV58.E7.60 841 32 950 530 376
1491.81 YTCGTTVRV HPV.58.E7.60 2301 845 353 1061 42
1481.37 YVLDLQPEA HPV31.E7.i l 822 385 3342 92 7409
1491.28 YVLDLQPEAV HPV.31.E7.i l A 28 26 6.4 115 222
1491.26 YVLDLQPEV HPV.31.E7.i l A 27 169 430 76 849
1481.58 YVLDLYPEPT HPV33.E7.i l 118 2490 324 332 44993
1491.33 YVLDLYPEPV HPV.33.E7.i l 25 12 3.4 29 29
1419.61 ALFPPEGVSV PAP. 15 1.1 18 119 4444
F063.58 ALGIGILTV MARTI.27 A 11
1389.14 ALGTTCYV PSA.143 A 93 6.7 12 288 29169
F188.048 ALLTTLGGGL 8.7
F188.039 ALNIWDRFDV 386
F188.010 ALVCNTLWGV 18
F188.033 ALWECGCATL 14
F063.59 AMGIGTLTV MARTI.27 A 15
63.0109 DLMLLRLSEPV Kallikrein2.120 A 70 66 31 119 2759
1485.06 ELCCEHLWQI Gliadin.155 A 1440 25427 5727 133 32
1485.07 ELCCQHLWEI Gliadin.155 A 1161 1257 1639 147 37
1485.04 ELIPCMDVV Gliadin.123 A 5190 1491 101 L361 75
Table 14
HLA- A2 supertype binding affinity (IC50 nM)
Peptide Sequence Source Analog A*0201 A*0202 A*0203 A*0205 A*0206 A*6802
1485.05 ELIPCMDVVL Gliadin.123 A 4678 1917 15851 2081 329
1485.08 ELQPFLQPQL Gliadin.57 A 14568 1707 5444 170276 477
FI 88.052 FTLEYQDSL 218
F188.077 FIPLGLFWV 131
F188.030 FLDSGFVGL 21
F188.057 FLLFFEFLL 81
F188.075 FLLGLTFFI 166
F188.011 FLLRGSNNYV 134
F188.024 FLNTPWΓLGI 186
F188.086 FLPLALLWV 17
©
-4 F188.009 GIGLDLPFV 434
F188.001 GLAATHMCV 195
F188.089 GLFERENCV 214
F188.037 GLFGVKGTTV 221
FI 88.027 GLFLGFSSL 449
1419.62 GLHGQDLFGV PAP. 12 2.3 3.1 18 80000
F188.080 GLTFFIPLGL 111
FI 88.045 GLLPAVPMFI 29
F188.050 GLLVGLLPAV 19
F188.051 GLPEELPPV 25
F188.091 HLNPLSPNV 113
F188.029 ILALIQTPL 16
F188.083 ILFLPLALL 94
F188.076 ILIFNYPGV 146
F188.093 ILIYNYPGV 174
Table 14
HLA- A2 supertype binding affinity (IC50 nM)
Peptide Sequence Source Analog A*0201 A*0202 A*0203 A*0205 A*0206 A*6802
F188.058 ILQEAEQMV 237
1485.13 ILQEQLIPCM Gliadin.119 366 1501 535C 2058 >75515.83
F188.082 ILSDDVIKEV 196
F188.098 ILVYNYPGV 461
F188.044 ILYRSTAHL 487
1389.06 ILYSAHDTTV PAP.384 A 391 1.1 13 1471 6218
1418.26 ITYSAHDTTV PAP.284 A 4167 115 238 154 82
1389.07 IVYSAHDTTV PAP.284 A 7710 91 623 671 745
1489.31 KILSVFFLAL Pf.EXP1.2 311 18 499 53 1940
F188.100 KLIGANILV 134
© F188.094 KLLGANILI 122 oe F188.085 KLVGWNIDSV 46
1419.58 LLALFPPEGV PAP. 5.0 0.7 1.6 148 163
F188.061 LLFFEFLLV 209
F188.095 LLIGLIIPPL 34
F188.070 LLLDVIPLSL 19
F189.10 LLMWITQCFL NY-ESO-1.158 43
F188.043 LLPAVPMFI 353
1419.64 LLPPYASCHV PAP. 88 15 16 97 5333
F188.063 LLQAALLQSV 117
F188.047 LLVGLLPAV 47
1419.69 LLWQPIPVHV PAP. 25 1.8 18 285 62
F189.08 LMWITQCFL NY-ESO-1.159 78
1419.59 LVALFPPEGV PAP. 156 17 4.8 463 28
1389.10 MLLRLSEPV PSA.118 48 29 48 686 432
Table 14
HLA- A2 supertype binding affinity (IC50 nM)
Peptide Sequence Source Analog A*0201 A*0202 A*0203 A*0205 A*0206 A*6802
7.0045 MPSLTMACM LCMV.NP.175 323
F188.087 NLLVFNYPGI 485
63.0128 PLVCNGVLQGV Kallikrein2.216 A 92 421 36 210 1633
1419.17 PLVCNGVLQGV Kallikrein2.216 A 26 126 19 264 4211
1485.09 QLEPFLQPQL Gliadin.57 A 2741 35 4200 4061 41451
F188.013 QLFSLLKITV 215
1485.10 QLQPFLEPQL Gliadin.57 A 2417 103 2899 6540 >74461.3
1485.11 QLQPFLQPEL Gliadin.57 A 216 20 638 3760 5514
F188.105 RLATLSFSM 35
F188.101 RLFGWGTKAV 136
F188.031 RLIEKQSQV 378
© vo F188.078 RLLEITWGV 16
F188.007 RLLNLSFFV 25
F188.036 RLNSLVPYI 118
F188.056 RLQEENAQL 252
F188.065 SLADIQAALV 63
F188.067 SLQDAVTNI 194
1419.52 SLSLGFLFLV PAP. 1.9 3.9 17 42 348
1419.50 SLSLGFLFV PAP. 77 25 21 93 26667
F188.035 SLSNGWEL 261
F188.017 SLWGSFSDI 211
F096.13 SVYDFFVWL 36 169 226 10.0 1.2
F001.02 SXPSGGXGV A 234
1389.03 TLMSAMTNV PAP.112 A 628 14 35 2159 482
F188.020 TLTGLSTPV 23
Table 14
HLA- A2 supertype binding affinity (IC50 nM)
Peptide Sequence Source Analog A*0201 A*0202 A*0203 A*0205 A*0206 A*6802
F001.01 TXWVDPYEV A 24
1485.01 VLEQSTYQL Gliadin.144 A 929 15 11311 2183 24884
F188.016 VLGQFVFEV 9.7
F188.102 VLIGLIILPL 140
F188.069 VLLLDVIPL 29
1485.02 VLQESTYQL Gliadin.144 A 88 2.3 147 267 16437
1485.03 VLQQSTYEL Gliadin.144 A 147 8.5 302 356 12794
63.0105 VLVHPQWVLTV Kallikrein2.53 A 11 1.6 3.0 13 4444
1419.11 VLVHPQWVLTV Kalli rein2.53 A 11 1.5 16 31 8889
60.0180 VLVHPQWVV Kalli rein2.53 A 564 65 1982 3199 16000
F188.106 VLWKDGVSFV 117
F188.025 VMNNVPVML 255
1418.24 VTAKELKFV PAP.30 7143 2688 40 137 26667
F189.09 WITQCFLPV NY-ESO-1.161 173
F188.015 YAFSPMFEV 16
F188.107 YLNDYVLPYA 13
F188.059 YMYGITDSL 112
F188.040 YVFDRILKV 43
F188.108 YVLPYASVSI 234
TABLE 15
HLA- A2 supertype binding affinity (IC50 nM)
Peptide Sequence Source Analog A*0201 A*0202 A*0203 A*0205 A*0206 A*0207 A*6802
F108.09 FVNHRFTLV Clone4.551 373
F108.13 GIRPYEΓLA Clone4.135 34
F108.15 WVFPESISPV Clone4.302 120
36.0132 ALKMTMASV Flu.NSl.76 230
36.0148 ALLKHRFEI Flu.RRP2.70 128
36.0189 ALLKHRFEII Flu.RRP2.70 226
36.0149 CLLQSLQQI Flu.RRP2.584 160
36.0138 FLEESHPGI Flu.RRPl.94 118
36.0133 FLWHVRKRV Flu.NSl.14 205
36.0128 GLISLILQI Flu.NRAM.18 38
36.0139 GMFNMLSTV Flu.RRPl .410 28
36.0129 GMGWLTIGI Flu.NRAM.172 143
36.0135 LLLEVEQEI Flu.NS2.105 239
36.0190 LLMDALKLSI Flu.RRP2.283 38
36.0158 LMDALKLSI Flu.RRP2.284 41
36.0185 MLSTVLGVSI Flu.RRPl.414 252
36.0186 NLYNIRNLHI Flu.RRP 1.597 63
36.0144 RLTDFLKDV Flu.RRPl.162 58
36.0145 RLNKRSYLI Flu.RRPl.211 90
36.0167 RMQFSSFTV Flu.RRP3.630 28
36.0161 SMTEAESSV Flu.RRP2.594 185
36.0172 WMMAMKYPI Flu.RRP3.49 73
F063.12 ALWGQYWQV gpl00.154 A 2.3
F063.08 ATWGQYWQV gpl00.154 A 7.7
F063.37 FLDQVPFSV gp 100.209 A 2.4
F063.43 FLEPGPVTA gp 100.280 A 113
F063.15 FLWGQYWQV gpl00.154 A 2.9
TABLE 15
HLA- A2 supertype binding affinity (IC50 nM)
Peptide Sequence Source Analog A*0201 A*0202 A*0203 A*0205 A*0206 A*0207 A*6802
F063.21 FTDQVPFSV gp 100.209 A 61
F063.06 FTWGQYWQV gplOO.154 A 1.8
F063.20 IIDQVPFSV gp 100.209 A 46
F063.33 TLAQVPFSV gp 100.209 A 11
F063.18 ILDQVPFSV gpl00.209 A 13
F063.31 ΓLFQVPFSV gp 100.209 A 2.1
F063.34 ILMQVPFSV gp 100.209 A 7.6
F063.35 ΓLSQVPFSV gp 100.209 A 20
F063.30 ILWQVPFSV gp 100.209 A 1.7
F063.32 ILYQVPFSV gp 100.209 A 6.9
F063.19 IMDQVPFSV gp 100.209 A 21
F063.27 ITAQVPFSV gp 100.209 A 134
F063.25 ITFQVPFSV gp 100.209 A 68
F063.28 ITMQVPFSV gp 100.209 A 42
F063.24 ITWQVPFSV gp 100.209 A 35
F063.26 ITYQVPFSV gp 100.209 A 33
F063.04 KIWGQYWQV gp 100.154 A 4.9
F063.02 KLWGQYWQV gpl00.154 A 2.1
F063.03 KMWGQYWQV gpl00.154 A 6.6
F063.i l KTFGQYWQV gp 100.154 A 48
F063.10 KTYGQYWQV gp 100.154 A 32
F063.13 LLWGQYWQV gpl00.154 A 1.6
F063.09 LTWGQYWQV gp 100.154 A 3.5
F063.36 WLDQVPFSV gpl00.209 A 12
F063.14 WLWGQYWQV gp 100.154 A 4.6
F063.05 WTWGQYWQV gp 100.154 A 72
F063.50 YLAPGPVTA gpl00.280 A 9.4
TABLE 15
HLA- A2 supertype binding affinity (IC50 nM)
Peptide Sequence Source Analog A*0201 A*0202 A*0203 A*0205 A*0206 A*0207 A*6802
F063.53 YLAPGPVTV gp 100.280 A 15
F063.38 YLDQVPFSV gp 100.209 A 2.6
F063.42 YLEPGPVTI gplOO.280 A 68
F063.41 YLEPGPVTL gp 100.280 A 146
F063.40 YLEPGPVTV gp 100.280 A 56
F063.47 YLFPGPVTA gpl00.280 A 3.7
F063.55 YLFPGPVTV gp 100.280 A 5.9
F063.48 YLMPGPVTA gpl00.280 A 4.4
F063.51 YLMPGPVTV gplOO.280 A 12
F063.49 YLSPGPVTA gplOO.280 A 48
F063.52 YLSPGPVTV gplOO.280 A 24
F063.16 YLWGQYWQV gpl00.154 A 1.7
F063.46 YLWPGPVTA gplOO.280 A 3.4
F063.56 YLWPGPVTV gplOO.280 A 7.5
F063.45 YLYPGPVTA gplOO.280 A 17
F063.54 YLYPGPVTV gplOO.280 A 9.1
F063.23 YTDQVPFSV gplOO.209 A 94
F063.07 YTWGQYWQV gpl00.154 A 3.5
33.0038 FFPSDYFPSV HBV.core.18 A 1553 1496 739 2171 225 1538 33.0037 FIPSDYFPSV HBV.core.18 A 29 3 28 4 2 133 33.0027 FLKSDYFPSV HBV.core.18 A 15 11 1 16 22 3636 33.0028 FLPKDYFPSV HBV.core.18 A 5.6 5.3 4.8 7.3 3.0 1860 33.0030 FLPSDKFPSV HBV.core.18 A 9.4 6.26 1.62 11.05 9.58 500 33.0032 FLPSDYFKSV HBV.core.18 A 20 21 2 58 13 8889 33.0033 FLPSDYFPKV HBV.core.18 A 36 26 50 24 16 1905 33.0044 FLPSDYFPSI HBV.core.18 A 25 7 67 18 15 2051 33.0043 FLPSDYFPSL HBV.core.18 A 31 10 47 14 53 8889
TABLE 15
HLA- A2 supertype binding affinity (IC50 nM)
Peptide Sequence Source Analog A*0201 A*0202 A*0203 A*0205 A*0206 A*0207 A*6802
33.0048 FLPSDYFPSP HBV.core.18 A 220 10852 2122 11467 314 80000
33.0049 FLPSDYFPST HBV.core.18 A 166 96 301 155 27 80000
33.0031 FLPSDYKPSV HBV.core.18 A 555 1254 136 2107 2301 80000
33.0029 FLPSKYFPSV HBV.core.18 A 8.5 5.74 0.63 7.23 5.63 1038.96
33.0042 FTPSDYFPSV HBV.core.18 A 423 5.5 419 15 12 73
1369.32 FVGPLLVLQV HBV.env.171 A 927 51 176 35 21 241
1369.31 FVLLLCLΓFV HBV.env.249 A 1992 306 9032 7246 9027 11364
1369.03 FVLSLGIHV HBV.poI.562 A 45 400 2837 1414 133 62
1369.08 FVLSLGΠTV HBV.pol.573 A 439 885 18018 14098 487 1303
33.0036 FVPSDYFPSV HBV.core.18 A 77 2 101 3 4 80
55.0123 GLSRYVPRL HBV.pol.455 A 94
1369.01 GVLGWSPQV HBV.env.62 A 22 157 393 37 28 9357
1369.09 GVLGWSPQV HBV.env.73 A 21 134 637 52 21 9886
1369.28 GVSPTVWLSV HBV.env.359 A 197 77 4.8 81 55 549
1369.02 HVYSHPIIV HBV.pol.1076 A 151 1921 14 11026 1200 122
1369.10 HVYSHPIIV HBV.pol.502 A 255 3562 11 9038 1043 204
1369.26 IVRGTSFVYV HBV.pol.773 A 36765 5298 68 1828 5386 1222
1369.34 IVRGTSFVYV HBV.pol.773 A 15661 4367 88 2440 2468 1085
1369.24 IVSTLPETTV HBV.core.168 A 7447 38 554 403 994 4538
33.0025 KLPSDYFPSV HBV.core.18 A 24 6 14 12 2 40000
1172.01 KQYLNLYPV HBV.poI.668 85 22 35 28 >30237.16
1369.23 LVDYQGMLPV HBV.env.271 A 994 1037 510 1118 188 9863
1369.30 LVVLQAGFFV HBV.env.175 A 1999 1105 6107 732 191 900
1369.12 LVWFHISCV HBV.core.129 t A 177 272 97 2179 385 467
1369.07 MVWYWGPSV HBV.env.360 A 169 532 903 416 45 17
1369.13 PVLPTFFCV HBV.env.377 A 8.7 3140.36 13642.6 43000 21.88 1813.99
1369.18 PVLPTFFCV HBV.env.388 A 16 3538 23419 43000 17 1621
TABLE 15
HLA- A2 supertypi s binding affinity (IC50 nM)
Peptide Sequence Source Analog A*0201 A*0202 A*0203 A*0205 A*0206 A*0207 A*6802
924.20 QFLPSDFFPSV HBV.core.27 A 394
924.17 RFLPSDFFPSV HBV.core.27 A 481
1369.14 VVQAGFFLV HBV.env.177 A 438 78 2484 785 81 624
1369.17 VVQAGFFLV HBV.env.177 A 1708 226 2244 855 28 753
1369.19 WVLRGTSFV HBV.pol.770 A 500 1023 125 495 86 351
924.19 YFLPSDFFPSV HBV.core.27 A 151
1369.15 YVDDVVLGV HBV.pol.538 A 18 14 70 91 16 360
1369.20 YVDDVVLGV HBV.pol.549 A 16 2 108 112 16 412
1369.25 YVHTLWKAGV HBV.pol.147 A 1826 324 62 429 1081 169
1369.16 YVVSFGVWV HBV.core.147 A 54 76 .33 32 64 8
35.0083 ALVAYQATV HCV 68 632 4 521 167 1778 1369.05 AVSTGLIHV HCV.NS 1.686 A 2497 891 336 1506 120 4855 1369.04 IVSPGALVV HCV.NS4.1891 A 19305 3749 184 2115 2990 11495 35.0060 KLVAYQATV HCV 73 282 6 265 76 8889 1369.27 RVHGLSAFSV HCV.NS5.2918 512 389 398 39 51 684 35.0071 YFVAYQATV HCV 1071 15739 139 7049 16645 186 35.0070 YIVAYQATV HCV 58 57 3 41 27 31 35.0062 YLKAYQATV HCV 32 166 3 83 318 2222 35.0084 YLQAYQATV HCV 36 140 4 52 36 80 35.0086 YLVAAQATV HCV 40 77 4 61 70 174 35.0064 YLVAKQATV HCV 183 516 5.9 243 208 6154 35.0087 YLVAYAATV HCV 72 34 3 63 40 276 35.0065 YLVAYKATV HCV 33 423 7 218 205 808 35.0089 YLVAYQAFV HCV 9.1 19.08 2.65 9.58 22.92 38.1 35.0067 YLVAYQAKV HCV 70 104 5 65 144 381 35.0078 YLVAYQATF HCV 232 6806 53 3457 3322 40000 35.0077 YLVAYQATI HCV 78 305 4 97 166 1270
TABLE 15
HLA- A2 supertype binding affinity (IC50 nM)
Peptide Sequence Source Analog A*0201 A*0202 A*0203 A*0205 A*0206 A*0207 A*6802
35.0076 YLVAYQATL HCV 17 44 3 26 75 1538
35.0082 YLVAYQATT HCV 97 3774 20 1475 953 26667
35.0066 YLVAYQKTV HCV 303 875 5.5 380 310 1127
35.0088 YLVAYQQTV HCV 40 82 5 41 57 727
35.0063 YLVKYQATV HCV 45 75 4 50 48 276
35.0085 YLVQYQATV HCV 15 44 2 35 29 250
35.0073 YQVAYQATV HCV 19 25 4 10 35 3636
35.0075 YTVAYQATV HCV 29 56 16 31 28 1
35.0069 YVVAYQATV HCV 60 49 27 39 2
1390.01 ALBRWGLLL Her2/neu.5 A 245 0.6 12 5983 8071
1382.03 ATBRWGLLV Her2/neu.5 A 14994 240 372 2221 1759
1382.04 AVBRWGLLV Her2/neu.5 A 9517 249 146 2166 4778
F106.05 CLLTLLGSYI HIV 167
F106.29 FIISLSLLI HIV 76
F106.34 FITVLTFKV HIV 115
F106.14 FLSLQIMDYL HIV 142
F106.19 IIFSIAFITV HIV 34
F106.l l ΠSLSLLΓGV HIV 161
54.0063 ILHEPVHGV HIV.pol.476 A 50
55.0158 ILKDPVHGV HIV.pol.476 A 355
55.0170 ILKEFVHGV HIV.pol.476 A 58
1304.09 ILKEPVMGV HIV.pol.476 A 218
55.0169 ILKESVHGV HIV.pol.476 A 150
55.0168 ILKETVHGV HIV.pol.476 A 295
55.0167 ILKFPVHGV HIV.pol.476 A 136
55.0166 TLKYPVHGV HIV.pol.476 A 306
55.0155 ILLEPVHGV HIV.pol.476 A 49
TABLE 15
HLA- A2 supertype binding affinity (IC50 nM)
Peptide Sequence Source Analog A*0201 A*0202 A*0203 A*0205 A*0206 A*0207 A*6802
55.0153 ILVEPVHGV HIV.pol.476 A 459
1304.07 ILYEPVHGV HIV.pol.476 A 34
1304.15 IMHEPVHGV HIV.pol.476 A 83
1304.10 TMKEPVHGV HIV.pol.476 A 280
1304.17 TMKEPVYGV HIV.pol.476 A 187
1304.14 IMYEPVHGV HIV.pol.476 A 32
1304.01 KLTPLCVTV HIV.env.134 A 20
F106.31 KMMIIFSIA HIV 251
1304.02 KMTPLCVTL HIV.env.134 A 20
1304.03 KMTPLCVTV HIV.env.134 A 9.3
F106.04 LLGSYIELPA HIV 499
F106.16 MLFIISLSL HIV 38
1304.04 MLKEPVHGV HIV.pol.476 A 110
1304.11 MMKEPVHGV HIV.pol.476 A 91
F106.10 QIMDYLLCL HIV 3.9
F106.03 QLLDFCLSI HIV 0.56
11.0050 RLHIGPGRA HIV.gp 160.311 386
F106.33 RLIKCMNSV HIV 387
F106.12 SLQIMDYLL HIV 67
F106.36 TLLGSYIEL HIV 19
F106.26 TLQLLDFCL HIV 17
F106.20 TMLFIISLSL HIV 155
1304.06 WLKEPVHGV HIV.pol.476 A 350
F106.35 YLLCLLTLL HIV 21
F106.18 YLLPFLSLQI HIV 3.2
1304.12 YMKEPVHGV HIV.pol.476 A 70
Hafler C LLNGYPVYV HTLV.ll A 23 302
TABLE 15
HLA- A2 supertype binding affinity (IC50 nM)
Peptide Sequence Source Analog A*0201 A*0202 A*0203 A*0205 A*0206 A*0207 A*6802
FO 18.03 LLLDVPTAAVQ IP30-P15 41 F018.02 LLLDVPTAAV IP30-P16 8.6
71.0001 ALGTTAYV Kallikrein2.147 A 479 27 62 37000 6970
1418.12 ALGTTCYV Kallikrein2.147 A 18 5 16 1028 80000
71.0002 ALGTTPYV Kallikrein2.147 A 879 1232 273 37000 80000
71.0003 ALGTTSYV Kallikrein2.147 A 1753 120 96 37000 3508
71.0004 ALGTTTYV Kallikrein2.147 A 422 72 46 18500 10518
71.0005 ALGTTVYV Kallikrein2.147 A 59 12 15 16547 >80000
1418.36 ALPLIQSRIV Kallikrein2.17 A 8333 1870 233 7400 80000
71.0006 ALSVGATGV Kallikrein2.9 A 774 94 40 3482 11795
1418.15 ALSVGCTGV Kallikrein2.9 A 24 17 9 264 40000
71.0007 ALSVGPTGV Kallikrein2.9 A 770 176 119 37000 >80000
71.0008 ALSVGSTGV Kallikrein2.9 A 2428 72 77 12827 >80000
71.0009 ALSVGTTGV Kallikrein2.9 A 2250 47 142 12333 >80000
71.0010 ALSVGVTGV Kallikrein2.9 A 26 14 8 671 >80000
1418.34 ATSVGCTGAV Kallikrein2.9 A 7143 8600 385 3364 8889
1418.16 AVPLIQSRV Kallikrein2.17 A 3846 1536 127 2313 73
1418.33 AVSVGCTGAV Kalli rein2.9 A 2381 2688 189 740 20000
1418.68 DLCARAYSEKV Kallikrein2.182 A 16667 2263 1282 12333 211
71.0079 DLLLLRLSEPV Kallikrein2.120 A 1070 528 115 870 10000
63.0109 DLMLLRLSEPV Kallikrein2.120 A 70 66 31 119 2759
1418.70 DTCARAYSEKV Kallikrein2.182 A 50000 1792 1786 7400 421
1418.32 DTVLSIALSV Kallikrein2.3 A 3571 1000 192 712 178
1418.69 DVCARAYSEKV Kallikrein2.182 A 50000 1593 67 5286 308
71.0011 FLLAAGLWT Kallikrein2.195 A 17 368 112 302 40000
71.0012 FLLPAGLWT Kallikrein2.195 A 2.7 375 70 134 >80000
71.0013 FLLSAGLWT Kallikrein2.195 A 41 374 239 66 32660
' TABLE 15
HLA- A2 supertype binding affinity (IC50 nM)
Peptide Sequence Source Ana) log A*0201 A*0202 A*0203 A*0205 A*0206 A*0207 A*6802
71.0014 FLLTAGLWT Kallikrein2.195 A 14 193 190 259 40000
71.0077 FLRPRSLQAV Kallrkrein2.165 A 353 30 12 1013 80000
1419.44 FLRPRSLQBV Kallikrein2. 38 2 6 1850 80000
1435.02 FLRPRSLQPV Kallikrein2. 4545 113 111 3700 80000
1435.01 FLRPRSLQSV Kallikreirώ. 1389 36 26 5286 80000
71.0076 FLRPRSLQTV Kallikrein2.165 A 741 112 220 1379 21036
71.0075 FLRPRSLQVV Kallikrein2.165 A 363 16 19 254 26667
71.0016 FMLAAGLWV Kallikrein2.195 A 2.2 34 2.8 11 40000
1418.22 FMLCAGLWV Kallikrein2.195 A 29 12 91 51 80000
71.0017 FMLPAGLWV Kallikrein2.195 A 7.3 41 8.9 6.3 27734
71.0018 FMLSAGLWV Kallikrein2.195 A 3.0 15 4.4 10 19230
71.0019 FMLTAGLWV Kallikrein2.195 A 5.0 47 17 15 26667
71.0020 FMLVAGLWV Kallikrein2.195 A 13 277 14 25 40000
71.0022 FTLPAGLWT Kallikrein2.195 A 1469 21500 18257 149 18566
1418.51 FTRPRSLQCV Kallikrein2.165 A 4167 1000 4 514 5333
71.0026 FVLAAGLWT Kallikrein2.195 A 1150 1669 1601 166 34943
71.0027 FVLPAGLWT Kallikrein2.195 A 719 24826 6276 115 46188
71.0028 FVLSAGLWT Kallikrein2.195 A 1578 13598 8771 304 56569
1418.50 FVRPRSLQCV Kallikreiπ2.165 A 1389 269 11 474 8000
1418.63 GLPTQEPALGV Kallikrein2.140 A 1136 796 91 3700 80000
67.0063 GTVPLIQSRI Kallikrein2.16 A >61224.1( 6448 11919 6678 "85
1419.46 HLLSNDMBARA Kallikrein2. A 3571 143 105 2313 80000
1418.67 HLLSNDMCARV Kallikrein2.177 A 26 1 5 37 860
1418.20 HLLSNDMCV Kallikrein2.177 A 119 102 278 176 80000
71.0031 ILLRLSEPV Kallikrein2.122 A 112 61 177 244 24228
71.0080 TLLSVGATGAV Kallikrein2.8 A 2129 1882 187 2383 33193
1418.57 ILLSVGCTGAV Kallikrein2.8 A 36 33 36 308 10000
TABLE 15
HLA- A2 supertype binding affinity (IC50 nM)
Peptide Sequence Source Analog A*0201 A*0202 A*0203 A*0205 A*0206 A*0207 A*6802
71.0081 ILLSVGPTGAV Kallikrein2.8 A 971 205 85 7400 11795
71.0082 ILLSVGSTGAV Kallikrein2.8 A 1927 1749 214 15105 >56568.54
71.0083 ILLSVGTTGAV Kallikrein2.8 A 2221 986 144 5286 >56568.54
71.0084 ILLSVGVTGAV Kallikrein2.8 A 229 136 22 481 10053
1418.59 ITLSVGCTGAV Kallikrein2.8 A 294 134 40 206 121
1418.58 IVLSVGCTGAV Kallikrein2.8 A 1351 705 208 597 2162
67.0039 KITDVVKVV Kallikrein2.131 A 476 586 84 859 29314
67.0036 KLTDVVKVL Kallikrein2.131 A 712 15 20 2439 81679
67.0037 KVTDVVKVL Kallikrein2.131 A 5158 686 259 2372 3835
1435.05 KVTEFMLAAGV Kallikrein2. 179 33 13 52 308
1418.71 KVTEFMLCAGV Kallikrein2.191 A 56 10 26 28 143
© 1418.21 KVTEFMLCV Kallikrein2.191 A 53 27 31 34 6667
1435.07 KVTEFMLPAGV Kallikreirώ. 2381 935 137 385 13333
1435.06 KVTEFMLSAGV Kallikrein2. 1786 430 56 394 3333
1435.04 KVTEFMLTAGV Kallikreiiώ. 7143 1536 119 2643 10000
71.0059 LLLLRLSEPA Kallil rein2.121 A 1130 748 96 1097 11547
71.0060 LLLLRLSEPV Kallikreirώ.121 A 379 361 56 317 26667
71.0042 LLLRLSEPV Kallikrein2.122 A 35 82 90 179 25746
1418.13 LLLSIALSV Kallikrein2.4 A 88 179 147 185 80000
1418.44 LLRLSEPAKV Kallikreirώ.123 A 2174 518 23 9250 80000
1418.53 LLSNDMCARV Kallikreirώ.178 A 5.3 0.69 4.4 10.3 1702
1418.43 LMLLRLSEPV Kallikrein2.121 A 114 67 29 25 6154
71.0062 LTLLRLSEPV Kallikreirώ.121 A 1761 6207 860 424 949
1418.14 LTLSIALSV Kallikreirώ.4 A 641 287 313 949 2051
71.0063 LVANGVLQGV Kallikreirώ.121 A 125 25 3 26 12
1419.47 LVBNGVLQGI Kallikreirώ. A 1282 215 9.1 43 118
1418.72 LVCNGVLQGIV Kallikreirώ.217 A 1923 1593 500 370 13333
TABLE 15
HLA- A2 supertype binding affinity (IC50 nM)
Peptide Sequence Source Analog A*0201 A*0202 A*0203 A*0205 A*0206 A*0207 A*6802
1418.55 LVCNGVLQGV Kallikreirώ.217 A 10 3 12 6 3
1418.60 LVHPQWVLTAV Kallikrein2.54 A 2083 148 370 148 2424
1418.40 LVHPQWVLTV Kallikrein2.54 A 3571 1049 67 77 13333
71.0066 LVPNGVLQGV Kallikreirώ.217 A 28 15 4 7 20
71.0067 LVSNGVLQGV Kallikreirώ.217 A 133 11 1 23 9
71.0068 LVTNGVLQGV Kallikreirώ.217 A 182 56 2.2 10 17
71.0069 LVVNGVLQGV Kallikreirώ.217 A 55 50 5 40 19
1418.18 MLLRLSEPV Kallikreirώ.122 A 79 31 40 161 1778
1418.42 NMSLLKHQSV Kallikreirώ.102 A 8333 1000 455 18500 40000
67.0040 PLLGTTCYA Kallikreiιώ.146 A 3541 434 114 6111 46839
71.0085 PLVANGVLQGV Kallikreirώ.216 A 45 683 75 212 2843
63.0128 PLVCNGVLQGV Kallikreirώ.216 A 92 421 36 210 1633
1419.17 PLVCNGVLQGV Kallikreirώ.216 A 26 126 19 264 4211
71.0086 PLVPNGVLQGV Kallikreirώ.216 A 26 93 18 40 17889
71.0087 PLVSNGVLQGV Kallikreirώ.216 A 57 227 76 287 5234
71.0088 PLVTNGVLQGV Kallikreirώ.216 A 138 1267 137 882 11507
71.0089 PLVVNGVLQGV Kallikreirώ.216 A 348 5852 774 683 10000
67.0042 PTLGTTCYA Kallrkreirώ.146 A 9690 1268 223 54852 9485
67.0041 PVLGTTCYA Kallikreirώ.146 A 8211 756 196 6836 10645
1418.38 QVAVYSHGWV Kallikrein2.39 A 12500 331 714 3083 333
1418.17 QVWLGRHNV Kallikrein2.72 A 1351 6143 2222 1480 103
67.0093 SIALSVGCTGV Kallikreirώ.7 A 3959 544 136 2137 587
67.0090 SLALSVGCTGA Kallikreirώ.7 A 4789 125 214 3142 5095
71.0090 SLHLLSNDMAA Kallikreirώ.175 A 65 3 89 1165 20435
1419.45 SLHLLSNDMBA Kallikreirώ. 12 1 36 12333 20000
1418.66 SLHLLSNDMCV Kallikreirώ.175 A 8.6 0.78 10.2 2312.5 2162.16
71.0091 SLHLLSNDMPA Kallikreirώ.175 A 1687 41 717 37000 >80000
TABLE 15
HLA- A2 supertype binding affinity (IC50 nM)
Peptide Sequence Source Analog A*0201 A*0202 A*0203 A*0205 A*0206 A*0207 A*6802
71.0092 SLHLLSNDMSA Kallikreirώ.175 A 346 4.0 84 9250 >80000
71.0093 SLHLLSNDMTA Kallikreirώ.175 A 93 2 44 26163 80000
71.0094 SLHLLSNDMVA Kallikreirώ.175 A 112 5 74 7126 40000
71.0070 SLQAVSLHLV Kallikreirώ.170 A 142 13 8 219 1404
1418.52 SLQCVSLHLV Kallikreiιώ.170 A 13 6 3 5 205
1418.19 SLQCVSLHV Kallikreirώ.170 A 56 165 48 4111 1600
71.0071 SLQPVSLHLV Kallikreirώ.170 A 346 21 35 95 5521
71.0072 SLQSVSLHLV Kallikreirώ.170 A 202 37 73 78 6963
71.0073 SLQTVSLHLV Kallikreiιώ.170 A 170 42 11 82 2464
71.0074 SLQVVSLHLV Kallikreirώ.170 A 138 56 11 63 3036
1418.35 SVGCTGAVPV Kallikrein2.i l A 104 287 154 552 216
1418.64 TTCYASGWGSV Kallikreiιώ.150 A 6250 2150 769 2467 500
1418.56 VLSIALSVGCV Kallikreirώ.5 A 1020 1103 83 1947 3333
63.0105 VLVHPQWVLTV Kallikreirώ.53 A 11 2 3 13 4444
1419.11 VLVHPQWVLTV Kallikreirώ.53 A 11 2 16 31 8889
60.0180 VLVHPQWVV Kallikreirώ.53 A 564 65 1982 3199 16000
1418.54 VTEFMLCAGV Kallikreirώ.192 A 625 1483 714 137 131
1369.36 FVEEQMTWV KSHV.105 A 46 172 552 326 27 6425
1369.35 LVYFΠYSKV KSHV.153 A 319 133 16 1370 328 152
7.0025 HLNLTMPNA LCMV.GP.83 188
7.0045 MPSLTMACM LCMV.NP.175 323
7.0039 SAYLVSTFL LCMV.GP.445 130
55.0234 YLQLFFGIEV MAGE2.157 A 133 68 511 482 3497
54.0084 YLQLΓFGIEV MAGE2.157 A 259 58 791 462 19372
F063.65 AAFIGILTV MARTI.27 A 76
F063.64 AAWIGILTV MARTI.27 A 67
F063.66 AAYIGILTV MARTI.27 A 102
TABLE 15
HLA- A2 supertype binding affinity (IC50 nM)
Peptide Sequence Source Analog A*0201 A*0202 A*0203 A*0205 A*0206 A*0207 A*6802
F063.60 AIGIGILTV MART 1.27 A 86
F063.74 ALFIGILTV MART 1.27 A 2.1
F063.58 ALGIGILTV MARTI.27 A 11
F063.73 ALWIGILTV MART 1.27 A 5.8
F063.75 ALYIGILTV MARTI.27 A 3.9
F063.59 AMGIGILTV MARTI.27 A 15
F063.62 FAGIGILTV MARTI.27 A 268
F063.71 FLGIGILTV MARTI.27 A 1.4
F063.69 KIGIGILTV MARTI.27 A 103
F063.67 KLGIGILTV MART1.27 A 20
F063.68 KMGIGILTV MARTI.27 A 27
F063.70 WLGIGILTV MART 1.27 A 9.8
F063.63 YAGIGTLTV MARTI.27 A 304
F063.72 YLGIGILTV MARTI.27 A 2.5
39.0188 KTCPVQLWVSA mp53.136 458
1413.13 LLDRDSFEV mp53.261 A 4.0
1413.20 LLGRDSHEV mp53.261 A 8.3
1413.18 LLGRDSLEV mp53.261 A 177
1413.19 LLGRDSMEV mp53.261 A 417
1413.17 LLGRGSFEV mp53.261 A 192
1413.16 LLGRQSFEV mp53.261 A 76
1413.14 LLHRDSFEV mp53.261 A 2.8
1413.12 LLSRDSFEV mp53.261 A 29
F097.02 SIIDPLIYA MSH.291 A 455 5.4 25 17 2.3 F097.01 SVMDPLIYA MSH.291 A 63 6 7 F097.12 TMLLGVFTV MSH.244 A 3.1
31.0143 LIANNTRVWV MT.242 239
TABLE 15
HLA- A2 supertype binding affinity (IC50 nM)
Peptide Sequence Source Analog A*0201 A*0202 A*0203 A*0205 A*0206 A*0207 A*6802
54.0005 CMPPPGTRV p53.149 A 788 1611 100 2303 7851
1326.04 ELAPPVAPV p53.68 A 60
1323.28 FLHSGTAKSW p53.113 A 1222 568 28 9087 11001
1413.08 GLAPPQQLIRV p53.187 A 11
1413.10 GLAPPQSLIRV p53.187 A 3.3
1413.04 GLVPPAHLIRV p53.187 A 20
55.0049 SMPPPGPRV p53.149 A 641 429 1144 3222 702
1323.23 YLCNSSCV p53.236 A 14814 31114 138 >21361.9( >35777.09
63.0040 ALFPPEGVSV PAP.122 11 1 3 12 138 1419.61 ALFPPEGVSV PAP. 15 1 18 119 4444 60.0203 FLFLLFFVW PAP.18 A 42 307 625 308 90 63.0047 GLHGQDLFGV PAP.196 A 19 4 4 6 976 1419.62 GLHGQDLFGV PAP. 12 2 3 18 80000 63.0041 GVSIWNPILV PAP.128 A 250 93 23 451 2286 60.0207 GVSIWNPIV PAP.128 A 455 269 909 308 80000 71.0051 ILYSAHDTTV PAP.284 A 991 9.1 100 1871 24228 1389.06 ILYSAHDTTV PAP.384 A 391 1.1 13 1471 6218 1418.25 ITLWQPIPV PAP.135 A 33 1720 6 26 32 71.0052 ITYSAHDTTV PAP.284 A 25000 181 848 1818 733 1418.26 ITYSAHDTTV PAP.284 A 4167 115 238 154 82 1389.05 IVLWQPIPV PAP.135 A 391 1865 289 17607 831 71.0053 IVYSAHDTTV PAP.284 A 16667 289 7001 1149 1552 1389.07 IVYSAHDTTV PAP.284 A 7710 91 623 671 745 63.0048 KLRELSELSV PAP.234 A 263 9.2 7.1 49 1818 63.0046 KLSGLHGQDV PAP.193 A 1064 69 385 1057 26667 63.0038 LLALFPPEGV PAP.120 A 31 0 5 37 160 1419.58 LLALFPPEGV PAP. 5.0 0.7 1.6 148 163
TABLE 15
HLA- A2 supertype binding affinity (IC50 nM)
Peptide Sequence Source Analog A*0201 A*0202 A*0203 A*0205 A*0206 A*0207 A*6802
63.0031 LLARAASLSV PAP.7 A 109 10 21 378 727
60.0201 LLLARAASV PAP.6 A 18 215 7 95 20000
63.0053 LLPPYASCHV PAP.306 A 94 18 15 218 2963
1419.64 LLPPYASCHV PAP. 88 15 16 97 5333
63.0044 LLWQPIPVHV PAP.136 A 5.8 2.1 18 116 42
1419.69 LLWQPIPVHV PAP. 25 2 18 285 62
1418.23 LTFFWLDRSV PAP.21 A 116 11 10 43 16
63.0039 LVALFPPEGV PAP.120 A 116 14 12 47 3
1419.59 LVALFPPEGV PAP. 156 17 5 463 28
1389.01 LVFFWLDRSV PAP.31 A 1424 259 80 64 82
63.0042 PLLLWQPIPV PAP.134 A 238 47 19 336 3333
63.0045 RLHPYKDFIV PAP.180 A 862 24 1887 1609 80000
63.0033 SLLAKELKFV PAP.29 A 64 6 4 38 6667
63.0032 SLSLGFLFLV PAP.13 A 33 11 27 40 842
1419.52 SLSLGFLFLV PAP. 1.9 3.9 17 42 348
60.0202 SLSLGFLFV PAP.13 A 42 6 5 28 4706
1419.50 SLSLGFLFV PAP. A 77 25 21 93 26667
63.0037 TLMSAMTNLV PAP.112 A 63 4 12 43 242
1389.03 TLMSAMTNV PAP.112 A 628 14 35 2159 482
1419.56 TLMSAMTNV PAP. 9.6 2.39 3.57 54.41 61.54
60.0213 TVSGLQMAV PAP.292 A 294 12 122 195 5.7
63.0034 VLAKELKFVV PAP.30 A 31 12 189 86 2286
1418.24 VTAKELKFV PAP.30 A 7143 2688 40 137 26667
1419.53 VTAKELKFV PAP. 6250 1024 53 137 40000
1419.54 VVAKELKFV PAP. 926 478 22 119 40000
1369.21 IVSVSSFLFV Pf.CSP.7 A 1066 797 200 993 77 437
F103.01 ALYGALLLA PLP.80 7.8
TABLE 15
HLA- A2 supertype binding affinity (IC50 nM)
Peptide Sequence Source Anal og A*0201 A*0202 A*0203 A*0205 A*0206 A*0207 A*6802
F103.05 FLYGAALLA PLP.80 A 3.6
F103.06 FLYGALALA PLP.80 A 2.4
F103.07 FLYGALLAA PLP.80 A 6.4
F103.08 FLYGALRLA PLP.80 A 7.2
F103.09 FLYGALVLA PLP.80 A 41
F103.10 FLYGALYLA PLP.80 A 2.6
F103.04 FLYGGLLLA PLP.80 A 1.1
1419.34 ALGTTBYA PSA. 50 13 0 18500 80000 .
1419.35 ALGTTBYV PSA. 6.7 3.6 2.8 3083 80000
939.09 ALGTTCYAS PSA. 417 741 667 435 80000
1389.14 ALGTTCYV PSA.143 A 93 7 12 288 29169
63.0195 DLMLLRLSEPV PSA.116 A 359 180 183 1746 5000
63.0186 FLTLSVTWIGV PSA.3 A 5.2 3.5 20 74 114
60.0216 FLTLSVTWV PSA.3 A 96 9 12 58 13333
1419.36 FLTPKKLQBV PSA. 71 3 4 137 80000
71.0047 FLTPKKLQPV PSA.161 A 5270 204 65 1232 >80000
71.0048 FLTPKKLQSV PSA.161 A 607 51 52 836 >80000
71.0049 FLTPKKLQTV PSA.161 A 876 55 57 1318 >80000
71.0050 FLTPKKLQVV PSA.161 A 1548 33 48 1230 >80000
1418.27 FTTPKKLQCV PSA.161 A 5000 1387 15 308 26667
1389.16 FVTPKKLQCV PSA.161 A 24628 2737 30 7102 >23094.01
63.0203 HLISNDVCAQV PSA.173 A 2724 84 426 15321 308
71.0032 KLQAVDLHV PSA.166 A 504 471 818 9553 40000
71.0054 KLQAVDLHVV PSA.166 A 92 9 32 211 >40000
1419.37 KLQBVDLHV PSA. 31 36 67 712 80000
1419.38 KLQBVDLHVI PSA. 217 27 20 264 80000
1419.39 KLQBVDLHVV PSA. 38 20 5 86 80000
TABLE 15
HLA- A2 ', supertype binding affinity (IC50 nM)
Peptide Sequence Source Analog A*0201 A*0202 A*0203 A*0205 A*0206 A*0207 A*6802
63.0058 KLQCVDLHVV PSA.166 A 13 89 29 528 26667
71.0055 KLQPVDLHVV PSA.166 ' A 1023 58 30 130 >80000
71.0056 KLQSVDLHVV PSA.166 A 526 27 23 446 >80000
71.0057 KLQTVDLHVV PSA.166 A 233 47 34 171 30526
71.0036 KLQVVDLHV PSA.166 A 1135 350 554 12333 >80000
71.0058 KLQWDLHVV PSA.166 A 49 41 4 92 34943
71.0037 KVTKFMLAV PSA.187 A 144 136 11 34 7628
1419.40 KVTKFMLBA PSA. 1786 139 20 58 40000
1419.41 KVTKFMLBV PSA. 128 226 5 31 6667
60.0220 KVTKFMLCV PSA.187 A 70 456 80 143 16000
71.0038 KVTKFMLPV PSA.187 A 33 71 9 15 1827
-4
71.0039 KVTKFMLSV PSA.187 A 90 180 2 33 11547
71.0040 KVTKFMLTV PSA.187 A 83 95 9 48 11547
71.0041 KVTKFMLVV PSA.187 A 223 371 11 67 18267
1389.12 MLLRLSEPAEV PSA.118 A 255 367 130 2627 4905
1389.10 MLLRLSEPV PSA.118 A 48 29 48 686 432
1419.43 PLVBNGVLQGV PSA. 14 269 185 394 6154
63.0194 SVFHPEDTGQV PSA.75 A 1725 50 57 2064 32
60.0217 TLSVTWIGV PSA.5 A 27 4 33 777 229
63.0191 VLVHPQWVLTV PSA.49 A 68 14 36 360 10000
60.0218 VLVHPQWVV PSA.49 A 267 206 1877 4696 6154
63.0185 VVFLTLSVTWV PSA.l A 101 202 78 885 13333
F108.33 FVNHDFTVV pSI2.508 305 F108.29 IAGGVMAVV pSI2.71 204 F108.44 LLGLWGLTGL pSI2.668 1.4 F108.35 LLLLGLWGL pSI2.666 22 F108.31 SVYVDAKLV pSI2.589 117
TABLE 15
HLA- A2 supertype binding affinity (IC50 nM)
Peptide Sequence Source Analog A*0201 A*0202 A*0203 A*0205 A*0206 A*0207 A*6802
F108.30 VLAKDGTEV pSI2.50 51
60.0232 ALGLPSΓPV PSM.286 A 71 6 13 3147 5477
63.0063 ALVLAGGFFV PSM.25 A 713 65 798 1404 28522
1418.30 ATFDΓESKV PSM.711 A 238 27 43 82 258
1389.34 AVFDΓESKV PSM.711 A 850 62 41 111 207
60.0229 ELAHYDVLV PSM.109 A 4412 40 221 111874 86
63.0068 FLDELKAENV PSM.61 A 419 24 262 4800 43248
60.0239 GLLGSTEWV PSM.427 A 415 87 138 393 >84187.21
1389.22 GLPEGDLVYV PSM.168 A 43 2 2 113 1000
1389.24 GLPSTPVHPV PSM.288 A 77 1 1 315 155
1418.29 GTPEGDLVYV PSM.168 A 313 134 53 40 571 oe 1389.23 GVPEGDLVYV PSM.168 A 1401 258 836 214 711
63.0065 LLGFLFGWFV PSM.34 A 55 9 100 2696 88410
63.0079 LLQERGVAYV PSM.441 A 535 8 19 616 9038
71.0043 LLYSLVHNL PSM.469 A 13 1 10 61 376
71.0044 LTYSLVHNL PSM.469 A 20 2 14 15 2
63.0064 LVLAGGFFLV PSM.26 A 781 44 151 182 734
60.0224 LVLAGGFFV PSM.26 A 95 81 1031 37 592
71.0045 LVYSLVHNL PSM.469 A 272 7.4 147 53 18
63.0085 MLEELANSIV PSM.583 A 42 4 13 440 837
60.0247 MVFELANSV PSM.583 A 75 7 11 50 2
63.0060 NVLHETDSAV PSM.3 A 6300 97 583 5087 11149
60.0244 PLFKYHLTV PSM.568 A 962 119 167 1779 90571
1389.32 QLMFLERAFV PSM.667 A 553 12 50 739 2
60.0251 QLYVAAFTV PSM.731 A 2328 122 1233 4039 198
60.0252 QVYVAAFTV PSM.731 A 9602 6544 7795 733 26
63.0090 SLFSAVKNFV PSM.631 A 598 8 85 2203 1024
TABLE 15
HLA- A2 supertype binding affinity (IC50 nM)
Peptide Sequence Source Analo; g A*0201 A*0202 A*0203 A*0205 A*0206 A*0207 A*6802
60.0242 SLYETYELV PSM.554 A 71 6 17 86 5178
60.0240 TLRVDCTPV PSM.461 A 5851 598 146 10706 47483
1389.20 VLAGGFFLV PSM.27 A 28 0 8 57 244
63.0086 VLPFDCRDYV PSM.592 A 806 76 392 1546 8033
63.0062 WLCAGALVLV PSM.20 A 4252 74 214 2510 39011
53.0065 AANPHATFGV T.cruzi.74 15
53.0083 AASTLLYATV T.cruzi.FL160.377 477
53.0034 AIVFDHYDV T.cruzi.FL160.108 332
53.0038 ALKNNGKW T.cruzi.FL160.230 409
53.0004 ALSLAAVLV T.cruzi.7 113
53.0062 ALSLAAVLW T.cruzi.7 101
53.0091 AMALIGDSTV T.cruzi.FL160.972 356
53.0048 FANSKFTLV T.cruzi.FL160.529 377
53.0087 FANSKFTLVA T.cruzi.FL160.529 214
53.0011 FLARLHAAA T.cruzi.67 48
53.0068 GLMNNAFEWI T.cruzi.188 47
53.0088 ΠLNGSLLTL T.cruzi.FL160.581 62
53.0045 KLYCSYEVA T.cruzi.FL160.401 256
53.0061 LLGLWGTAA T.cruzi.FL160.993 333
53.0090 LLLEHGQFDL T.cruzi.FL160.961 37
53.0094 LLLLGLWGTA T.cruzi.FL160.991 245
53.0021 LLVGYNDSA T.cruzi.287 195
53.0013 LMNNAFEWI T.cmzi.189 447
53.0067 LTNLSEQMLV T.cruzi.167 175
53.0018 MTYTGGVMT T.cruzi.267 356
53.0089 QMDYSNGLFV T.cruzi.FL160.610 94
53.0042 RLHLWLSDM T.cruzi.FL160.352 72
TABLE 15
HLA- A2 supertype binding affinity (IC50 nM)
Peptide Sequence Source Analog A*0201 A*0202 A*0203 A*0205 A*0206 A*0207 A*6802
53.0092 RVFGLLLLGL T.cruzi.FL160.987 62 53.0026 RVFTSAVLL T.cruzi.FL160.4 11 53.0010 SVFRENLFL T.cruzi.60 59 53.0028 VLLLVVVMM T.cruzi.EL160.10 55 53.0008 VMACLVPAA T.cruzi.16 10
41.0161 AACDQRVLIV TRP1 44
41.0173 AVVAALLLVA TRP1 13
41.0159 DLLPSSGPGT TRP1 420
41.0188 DLLPSSGPGV TRP1 94
41.0113 ELPNPNHSM TRP1 44
Uι 41.0156 FLMLFYQVWA TRP1 62
©
41.0179 LTFGTASYLI TRP1 160
41.0064 LLLFQQARA TRP1 211
41.0182 LLTDHYQRYA TRP1 16
41.0176 LLVALΓFGTA TRP1 91
41.0069 MAKRTTHPL TRP1 22
41.0185 PLLLFQQARV TRP1 6.2
41.0144 PLTNTEMFV TRP1 21
41.0081 QLERDMQEM TRP1 7.5
41.0128 QLERDMQEV TRP1 3.3
41.0089 RLPEPQDVT TRP1 369
41.0165 SLEEYDTLGT TRP1 13
41.0076 SVKKTFLGV TRP1 9.2
41.0074 SVYNYFVWT TRP1 3.5
41.0087 TLGTLCNST TRP1 283
41.0095 VLLHTFTDA TRP1 21
F096.41 ALVGLFVLL TRP2.482 28 13544 3208 4447 2731
TABLE 15
HLA- A2 : supertype binding affinity (IC50 nM)
Peptide Sequence Source Analog A*0201 A*0202 A*0203 A*0205 A*0206 A*0207 A*6802
F096.14 FVWLHYYSV TRP2.185 15 13544 974 24 1
F096.18 LIGNESFAL TRP2.234 400 1817 8513 2855 4000
F096.32 NMVPFFPPV TRP2.431 6.1 28 23 7.1 1.1
F096.22 SLDDYNHLV TRP2.288 26 1159 441 735 2582
F096.48 SLHNLVHSFL TRP2.367 277 139 8.4 37000 252
F096.13 SVYDEFVWL TRP2.180 36 169 226 10 1
F096.26 TLDSQVMSL TRP2.360 167 43000 646 1217 >10596.26
F096.50 TLLVVMGTLV TRP2.472 361 10750 363 1818 596
F096.51 TLVALVGLFV TRP2.479 34 21500 35 57 6
F096.30 VLHSFTDAI TRP2.394 424 623 45 9889 1527
F096.38 VMGTLVALV TRP2.476 31 585 6 404 267
F096.16 VTWHRYHLL TRP2.217 164 1087 9410 760 38
F096.37 VVMGTLVAL TRP2.475 67 66 163 51 43
F096.33 YATDLPVSV TRP2.455 16 46 14 14 1
F096.08 YVITTQHWL TRP2.156 105 41 417 44 1
980.05 AAAKAAAAV Artificial sequence A 8333 861 68 345 8273 3
980.13 ACAKAAAAV Artificial sequence A 25000 >8600 640 46237 >1321.43 314
980.10 AGAKAAAAV Artificial sequence A 25000 4389 418 3202 37000 1960
953.15 AIAKAAAAAL Artificial sequence A >217.39
953.23 AIAKAAAAAT Artificial sequence A >217.39
953.11 AIAKAAAAL Artificial sequence A 50000 281 133 37000 121
953.19 AIAKAAAAT Artificial sequence A >238.1 43000 2113 >1321.43 2333
953.03 AIAKAAAAV Artificial sequence A 1786 253 4.9 185 1277 19
980.17 ALAEAAAAV Artificial sequence A 72
980.31 ALAKAAAAA Artificial sequence A 1563 21500 59 6604 >1321.43 6532
980.29 ALAKAAAAI Artificial sequence A 625 377 11 385 13081 433
953.09 ALAKAAAAL Artificial sequence A 2778 80 4.2 109 15105 320
TABLE 15
HLA- A2 supertype binding affinity (IC50 nM)
Peptide Sequence Source Anal og A*0201 A*0202 A*0203 A*0205 A*0206 A*0207 A*6802
980.30 ALAKAAAAM Artificial sequence A 4545 624 149 797 37000 >3468.44
953.17 ALAKAAAAT Artificial sequence A 25000 14333 175 9840 >1321.43 14142
980.28 ALAKAAALV Artificial sequence A 122
980.26 ALAKAAAQV Artificial sequence A 278
980.27 ALAKAAATV Artificial sequence A 294
980.24 ALAKAAYAV Artificial sequence A 64
980.22 ALAKAIAAV Artificial sequence A 93
980.19 ALAKKAAAV Artificial sequence A 294
980.21 ALAKLAAAV Artificial sequence A 114
980.20 ALAKYAAAV Artificial sequence A 119
980.18 ALASAAAAV Artificial sequence A 139
1266.02 ALDKAYVLL Artificial sequence A 59 212
1266.01 ALDKYTVLL Artificial sequence A 80 648
980.14 ALFKAAAAV Artificial sequence A 119
980.15 ALSKAAAAV Artificial sequence A 294
1037.02 AMAKAAAAA Artificial sequence A 2529 3011 5.9 37000 2818
953.22 AMAKAAAAAT Artificial sequence A >217.39
953.10 AMAKAAAAL Artificial sequence A 22 123 4 18500 320
1037.03 AMAKAAAAM Artificial sequence A 6455 1344 106 >1321.43 7807
1037.13 AMAKAAAAS Artificial sequence A 25000 >10750 166 >1321.43 >4588.31
953.18 AMAKAAAAT Artificial sequence A 16667 12413 84 >1321.43 10000
953.02 AMAKAAAAV Artificial sequence A 273 196 6.7 69 1485 177
953.02 AMAKAAAAV Artificial sequence A 131
953.02 AMAKAAAAV Artificial sequence A 167
980.06 ANAKAAAAV Artificial sequence A 25000 >8600 4454 50000 >1321.43 109
980.12 APAKAAAAV Artificial sequence A 25000 >8600 15430 >24826.0f >1321.43 60
980.04 ASAKAAAAV Artificial sequence A 16667 1109 241 2847 26163 14
TABLE 15
HLA- A2 supertype binding affinity (IC50 nM)
Peptide Sequence Source Analog A*0201 A*0202 A*0203 A*0205 A*0206 A*0207 A*6802
953.16 AVAKAAAAAL Artificial sequence A >217.39
953.12 AVAKAAAAL Artificial sequence A >238.1 90 241 8273 4.1
953.20 AVAKAAAAT Artificial sequence A 50000 8600 2595 >1321.43 157
953.04 AVAKAAAAV Artificial sequence A 2362 105 12 30 863 1.2
953.25 AXAKAAAAL Artificial sequence A 50000 467 3226 37000 11429
953.25 AXAKAAAAL Artificial sequence A >25000 469 3300 37000 >3468.44
980.03 FLAKAAAAV Artificial sequence A 114
1266.07 FLDSDYFPSI Artificial sequence A 196 3240
1266.06 FLDSDYFPSL Artificial sequence A 321 1571
1266.05 FLDSDYFPSV Artificial sequence A 11 668
1266.08 FLDSYIAPL Artificial sequence A 25 60
Uι Ui 980.02 KLAKAAAAV Artificial sequence A 238
Table 16
Sequence Protein/Segment 1st Position Analog AA A*0201 A*0202 A*0203 A*0206 A*6802 A2 Cross- reactivity
LQCVSLHLL Kallikreirώ 171 9 0.0018 0.010 0.0094 0.17 0.0002 2
ALGTTCYV Kallikreirώ 147 A 8 0.28 0.93 0.63 0.0036 0.0001 3
LLLSIALSV Kallikreirώ 4 A 9 0.057 0.024 0.068 0.020 0.0001 4
LTLSIALSV Kallikreirώ 4 A 9 0.0078 0.015 0.032 0.0039 0.0039 2
ALSVGCTGV Kallikreirώ 9 A 9 0.21 0.26 1.1 0.014 0.0002 4
AVPLIQSRV Kallikreirώ 17 A 9 0.0013 0.0028 0.079 0.0016 0.11 2
QVWLGRHNV Kallikre ώ 72 A 9 0.0037 0.0007 0.0045 0.0025 0.078 1
MLLRLSEPV Kallikreirώ 122 A 9 0.063 0.14 0.25 0.023 0.0045 4
SLQCVSLHV Kallikreirώ 170 A 9 0.089 0.026 0.21 0.0009 0.0050 3
HLLSNDMCV Kallikreirώ 177 A 9 0.042 0.042 0.036 0.021 0.0001 4
KVTEFMLCV Kallikreirώ 191 A 9 0.095 0.16 0.32 0.11 0.0012 4
FMLCAGLWV Kallikreirώ 195 A 9 0.17 0.37 0.11 0.073 0.0001 4
LTFFWLDRSV PAP 21 A 10 0.043 0.40 1.0 0.086 0.49 5
VTAKELKFV PAP 30 A 9 0.0007 0.0016 0.25 0.027 0.0003 2
ITLWQPBPV PAP 135 A 9 0.15 0.0025 1.6 0.14 0.25 4
ITYSAHDTTV PAP 284 A 10 0.0012 0.0375 0.042 0.024 0.097 4
FTTPKKLQCV PSA 161 A 10 0.0010 0.0031 0.65 0.012 0.0003 2
GTPEGDLVYV PSM 168 A 10 0.016 0.032 0.19 0.093 0.014 4
ATFDIESKV PSM 711 A 9 0.021 0.16 0.23 0.045 0.031 5
DTVLSIALSV Kallikreirώ 3 A 10 0.0014 0.0043 0.052 0.0052 0.045 2
Sequence Protein/Segment 1st Position Analog AA A*0201 A*0202 A*0203 A*0206 A*6802 A2 Cross- reactivity
SVGCTGAVPV Kallikreirώ 11 A 10 0.048 0.015 0.065 0.0067 0.037 4
QVAVYSHGWV Kallikreirώ 39 A 10 0.0004 0.013 0.014 0.0012 0.024 2
LVHPQWVLTV Kallikreirώ 54 A 10 0.0014 0.0041 0.15 0.048 0.0006 2
LMLLRLSEPV Kallikreirώ 121 A 10 0.044 0.064 0.35 0.15 0.0013 4
FVRPRSLQCV Kallikreirώ 165 A 10 0.0036 0.016 0.92 0.0078 0.0010 3
SLQCVSLHLV KalTikreirώ 170 A 10 0.39 0.68 3.6 0.71 0.039 5
LLSNDMCARV Kallikreirώ 178 A 10 0.94 6.2 2.3 0.36 0.0047 4
VTEFMLCAGV Kallikreirώ 192 A 10 0.0080 0.0029 0.014 0.027 0.061 2
LVCNGVLQGV Kallikreirώ 217 A 10 0.48 1.5 0.84 0.66 2.3 5
ILLSVGCTGAV Kallikreirώ 8 A 0.14 0.13 0.28 0.012 0.0008 4
Uι ITLSVGCTGAV KalTikreirώ 8 A 0.017 0.032 0.25 0.018 0.066 5
LVHPQWVLTAV KalTikreirώ 54 A 0.0024 0.029 0.027 0.025 0.0033 3
SLHLLSNDMCV KalTikreirώ 175 A 0.58 5.5 0.98 0.0016 0.0037 3
HLLSNDMCARV KalTikreirώ 177 A 0.19 3.3 1.9 0.099 0.0093 4
DVCARAYSEKV Kallikreirώ 182 A 0.0001 0.0027 0.15 0.0007 0.026 2
KVTEFMLCAGV Kallikreirώ 191 A 0.089 0.45 0.39 0.13 0.056 5
ALGTTCYA KalTikreirώ 147 8 0.33 0.23 0.75 0.0066 O.0001 3
MLLRLSEPA Kallikreirώ 122 9 0.026 0.0058 0.069 0.076 0.0003 3
ALSVGCTGAV Kallikreirώ 9 10 0.095 0.058 0.57 0.0068 0.0001 3
FLRPRSLQCV Kallikreirώ 165 10 0.027 0.89 2.4 0.0003 <0.0001 3
VLVHPQWVLTA Kallikreirώ 53 11 - 0.017 0.56 0.099 0.0018 0.0001 3
VLVHPQWVLTV KalTikreirώ 53 A 11 0.45 2.8 0.64 0.12 0.0009 4
Sequence Protein/Segment 1st Position Analog AA A*0201 A*0202 A*0203 A*0206 A*6802 A2 Cross- reactivity
SLHLLSNDMCA Kallikreirώ 175 11 0.070 0.90 0.14 O.0001 O.0001 3
HLLSNDMCARA Kallikreirώ 177 11 0.012 0.011 0.040 0.0099 0.0001 4
PLVCNGVLQGI Kallikreirώ 216 11 0.0059 0.0089 0.023 0.0023 0.0001 2
PLVCNGVLQGV Kallikreirώ 216 A 11 0.19 0.034 0.53 0.014 0.0019 4
PLVBNGVLQGV PSA 212 A 11 0.36 0.016 0.054 0.0094 0.0013 4
FLRPRSLQBV Kallikreirώ 165 A 10 0.13 2.5 1.6 0.0020 <0.0001 3
SLHLLSNDMBA KalTikreirώ 175 A 11 0.43 3.6 0.28 0.0003 0.0004 3
LLLARAASL PAP 6 9 0.024 0.32 0.35 0.0087 0.0001 4
SLSLGFLFLL PAP 13 10 0.087 0.66 0.0035 0.073 0.0093 3
LLARAASLSL PAP 7 10 0.010 0.82 0.16 0.0004 0.0014 2
Uι SVLAKELKFV PAP 29 10 0.0023 0.0009 0.024 0.012 0.0002 2
Ox
LAALFPPEGV PAP 120 10 0.0022 0.023 0.23 0.0012 0.024 3
TLMSAMTNLA PAP 112 10 0.013 1.2 0.27 0.0010 0.0012 3
GLHGQDLFGI PAP 196 10 0.20 4.7 4.0 0.012 <0.0001 4
WFLTLSVTWI PSA 1 11 0.013 0.027 0.16 0.0013 0.0001 3
ALGTTBYA PSA 143 A 8 0.10 0.34 22 0.0002 O.0001 3
ALGTTBYV PSA 143 A 8 0.75 1.2 3.6 0.0012 O.0001 3
FLTPKKLQBV PSA 161 A 10 0.070 1.7 2.4 0.027 O.0001 4
KLQBVDLHV PSA 166 A 9 0.16 0.12 0.15 _ 0.0052 <0.0001 3
KLQBVDLHVI PSA 166 A 10 0.023 0.16 0.51 0.014 O.0001 4
KLQBVDLHW PSA 166 A 10 0.13 0.22 2.0 0.043 O.0001 4
KVTKFMLBA PSA 187 A 9 0.0028 0.031 0.51 0.064 0.0002 3
Sequence Protein/Segment 1st Position Analog AA A*0201 A*0202 A*0203 A*0206 A*6802 A2 Cross- reactivity
KVTKFMLBV PSA 187 A 9 0.039 0.019 2.0 0.12 0.0012 4
HLLSNDMBARA Kallikreirώ 177 A 11 0.0014 0.030 0.095 0.0016 0.0001 2
LVBNGVLQGI Kallikrein2 217 A 10 0.0039 0.020 1.1 0.086 0.068 4
LLLARAASLSL PAP 6 11 0.19 0.018 0.013 0.0010 0.0005 2
LLARAASLSL PAP 7 10 0.0035 0.24 0.13 0.0002 0.0010 2
SLSLGFLFV PAP 13 A 9 0.065 0.17 0.47 0.040 0.0003 4
SLSLGFLFLL PAP 13 10 0.13 0.33 0.025 0.17 0.0009 4
SLSLGFLFLV PAP 13 A 10 2.7 1.1 0.59 0.088 0.023 5
VTAKELKFV PAP 30 A 9 0.0008 0.0042 0.19 0.027 0.0002 2
WAKELKFV PAP 30 A 9 0.0054 0.0090 0.46 0.031 0.0002 3
-~l
FLNESYKHEQV PAP 92 11 0.17 3.0 1.8 0.0097 0.0013 4
TLMSAMTNV PAP 112 A 9 0.52 1.8 2.8 0.068 0.13 5
LAALFPPEGV PAP 120 10 0.0025 0.023 0.60 0.0015 0.035 3
LLALFPPEGV PAP 120 A 10 1.0 5.9 6.2 0.025 0.049 5
LVALFPPEGV PAP 120 A 10 0.032 0.25 2.1 0.0080 0.29 5
ALFPPEGVSI PAP 122 10 0.018 0.39 0.075 0.0014 0.0005 3
ALFPPEGVSV PAP 122 A 10 0.33 4.1 0.55 0.031 0.0018 4
GLHGQDLFGV PAP 196 A 10 0.43 1.9 3.2 0.21 O.0001 4
LLPPYASCHL PAP 306 10 0.0062 0.22 0.062 0.011 0.0002 3
LLPPYASCHV PAP 306 A 10 0.057 0.29 0.63 0.038 0.0015 4
SLQCVSLHLL Kallikreirώ 170 10 0.019 0.88 0.14 0.0083 0.0016 4
LLWQPIPVHT PAP 136 10 0.0082 0.098 0.017 0.0003 0.0018 1
Sequence Protein/Segment 1st Position Analog AA A*0201 A*0202 A*0203 A*0206 A*6802 A2 Cross- reactivity
LLWQPIPVHV PAP 136 A 10 0.20 2.4 0.57 0.013 0.13 5
FLRPRSLQSV Kallikreirώ 165 A 10 0.0036 0.12 0.38 0.0007 <0.0001 2
FLRPRSLQPV Kallikreirώ 165 A 10 0.0011 0.038 0.090 0.0010 O.0001 2
KVTEFMLAAGV Kallikreirώ 191 A 11 0.028 0.13 0.76 0.071 0.026 5
KVTEFMLSAGV Kallikreύώ 191 A 11 0.0028 0.010 0.18 0.0094 0.0024 3
KVTEFMLPAGV Kallikreήώ 191 A 11 0.0021 0.0046 0.073 0.0096 0.0006 2
ALGTTAYV Kallikreirώ 147 A 8 0.010 0.16 0.17 0.0002 0.0013 3
ALGTTSYV Kallikrein2 147 A 8 0.0029 0.027 0.10 0.0001 0.0018 2
ALGTTTYV Kallikreirώ 147 A 8 0.0064 0.044 0.24 0.0002 0.0008 2
ALGTTVYV Kallikreirώ 147 A 8 0.0857 0.40 0.97 0.0003 0.0001 3 oe
ALSVGATGV Kallikreirώ 9 A 9 0.0077 0.055 0.39 0.0012 0.0024 2
ALSVGPTGV Kallikreirώ 9 A 9 0.0069 0.029 0.13 0.0001 0.0001 2
ALSVGSTGV KalTikreirώ 9 A 9 0.0027 0.076 0.14 0.0003 0.0014 2
FLLAAGLWT Kallikreirώ 195 A 9 0.30 0.012 0.092 0.014 0.0002 4
FLLPAGLWT KalTikreirώ 195 A 9 2.1 0.024 0.15 0.030 <0.0001 4
FLLSAGLWT Kallikreirώ 195 A 9 7.96 0.038 0.047 0.028 0.0002 4
FLLTAGLWT Kallikreirώ 195 A 9 0.53 0.017 0.069 0.022 0.0003 4
ALSVGTTGV Kallikreirώ 9 A 9 0.0043 0.11 0.19 0.0002 O.0001 2
ALSVGVTGV Kallikreirώ 9 A 9 0.15 0.38 1.4 0.0061 0.0001 3
FMLAAGLWV Kallikreirώ 195 A 9 2.9 0.33 4.8 0.55 0.0002 4
FMLPAGLWV Kallikreirώ 195 A 9 0.94 0.12 1.5 0.65 0.0003 4
FMLSAGLWV Kallikreirώ 195 A 9 1.2 0.35 2.5 0.42 0.0004 4
Sequence Protein/Segment 1st Position Analog AA A*0201 A*0202 A*0203 A*0206 A*6802 A2 Cross- reactivity
FMLTAGLWV Kallikreirώ 195 A 9 0.75 0.13 0.59 0.26 0.0003 4
FMLVAGLWV Kallikreirώ 195 A 9 0.39 0.021 0.31 0.19 0.0002 4
KLQAVDLHV PSA 166 A 9 0.012 0.015 0.022 0.0014 0.0002 3
KVTKFMLAV PSA 187 A 9 0.042 0.034 1.0 0.12 0.0009 4
KVTKFMLPV PSA 187 A 9 0.17 0.096 2.6 0.39 0.0048 4
KVTKFMLSV PSA 187 A 9 0.047 0.025 2.7 0.11 0.0011 4
KVTKFMLTV PSA 187 A 9 0.056 0.038 1.2 0.081 0.0006 4
KVTKFMLW PSA 187 A 9 0.029 0.012 0.93 0.061 0.0004 4
FLTPKKLQAV PSA 161 A 10 0.0009 0.0093 0.030 0.0028 O.0001 2
FLTPKKLQPV PSA 161 A 10 0.0007 0.027 0.83 0.0068 O.0001 2
FLTPKKLQSV PSA 161 A 10 0.011 0.11 0.14 0.0045 0.0001 3
FLTPKKLQTV PSA 161 A 10 0.0062 0.12 0.19 0.0031 O.0001 2
FLTPKKLQW PSA 161 A 10 0.0071 0.11 0.21 0.0033 O.0001 2
KLQAVDLHW PSA 166 A 10 0.044 0.51 0.70 0.020 0.0002 4
KLQPVDLHW PSA 166 A 10 0.0054 0.11 0.36 0.030 <0.0001 3
KLQSVDLHW PSA 166 A 10 0.017 0.12 0.43 0.011 0.0001 4
KLQTVDLHW PSA 166 A 10 0.018 0.11 0.35 0.022 0.0004 4
KLQWDLHW PSA 166 A 10 0.077 0.22 2.8 0.0377 0.0003 4
LVANGVLQGV Kallikrein2 217 A 10 0.040 0.19 4.3 0.15 0.66 5
LVPNGVLQGV KalTikreirώ 217 A 10 0.25 0.35 2.8 0.62 0.41 5
LVSNGVLQGV KalTikreirώ 217 A 10 0.045 0.40 8.6 0.13 1.3 5
LVTNGVLQGV Kallikreirώ 217 A 10 0.028 0.12 6.6 0.30 0.89 5
Sequence Protein/Segment 1st Position Analog AA A*0201 A*0202 A*0203 A*0206 A*6802 A2 Cross- reactivity
LWNGVLQGV Kallikreirώ 217 A 10 0.12 0.087 2.9 0.096 0.46 5
SLQAVSLHLV Kallikreirώ 170 A 10 0.019 0.39 1.6 0.021 0.0053 4
SLQPVSLHLV Kallikreirώ 170 A 10 0.012 0.16 0.31 0.032 0.0013 4
SLQSVSLHLV Kallikreirώ 170 A 10 0.020 0.12 0.18 0.035 0.0022 4
SLQTVSLHLV Kallikreiiώ 170 A 10 0.023 0.19 0.69 0.037 0.0036 4
SLQWSLHLV Kallikreirώ 170 A 10 0.049 0.15 0.93 0.046 0.0033 4
FLRPRSLQW Kallikreirώ 165 A 10 0.014 0.33 0.40 0.015 0.0003 4
FLRPRSLQTV Kallikreirώ 165 A 10 0.0057 0.083 0.067 0.0039 0.0006 2
FLRPRSLQAV KalTikreirώ 165 A 10 0.023 0.33 0.63 0.0038 0.0002 3
ILLSVGPTGAV Kallikreirώ 8 A 0.0056 0.016 0.17 0.0004 0.0008 2
ILLSVGVTGAV Kallikreirώ 8 A 0.023 0.037 0.33 0.0091 0.0009 4
PLVANGVLQGV Kallikreirώ 216 A 0.11 0.012 0.13 0.018 0.0028 4
PLVPNGVLQGV Kallikreirώ 216 A 0.19 0.050 0.55 0.11 0.0006 4
PLVSNGVLQGV Kallikreirώ 216 A 0.088 0.019 0.13 0.022 0.0019 4
PLVTNGVLQGV Kallikreirώ 216 A 0.038 0.0046 0.077 0.0090 0.0008 3
SLHLLSNDMAA Kallikreirώ 175 A 0.11 1.8 0.36 0.0033 0.0004 3
SLHLLSNDMSA Kallikreirώ 175 A 0.015 1.1 0.22 0.0003 0.0001 3
SLHLLSNDMTA Kallikreirώ 175 A 0.058 2.4 0.33 0.0002 0.0001 3
SLHLLSNDMVA Kallikreirώ 175 A 0.047 0.88 0.30 0.0006 0.0003 3
ALGTTCYA HuK2 147 8 0.048 0.054 0.27 0.0008 ' 0.012 3
MLLRLSEPA HuK2 122 9 0.053 0.018 0.013 0.0081 0.0016 3
SLQCVSLHL HuK2 170 9 0.01 0.084 0.024 0.0006 0.0031 3
Sequence Protein/Segment 1st Position Analog AA A*0201 A*0202 A*0203 A*0206 A*6802 A2 Cross- reactivity
KVTEFMLCA HuK2 191 9 0.0035 0.0092 0.19 0.16 0.0004 3
LLLARAASV PAP 6 A 9 0.28 0.02 1.5 0.039 0.0004 4
SLSLGFLFV PAP 13 A 9 0.12 0.73 2.2 0.13 0.0017 4
FLFLLFFWV PAP 18 A 9 0.12 0.014 0.016 0.012 0.0887 4
GVSΓWNPΓV PAP 128 A 9 0.011 0.016 0.011 0.012 0.0001 3
TVSGLQMAV PAP 292 A 9 0.017 0.35 0.082 0.019 1.4 5
FLTLSVTWV PSA 3 A 9 0.095 0.51 1.2 0.076 0.0006 4
TLSVTWIGV PSA 5 A 9 0.19 0.88 0.25 0.0052 0.035 4
KVTKFMLCV PSA 187 A 9 0.072 0.0083 0.19 0.029 0.0005 3
ALSVGCTGAV HuK2 9 10 0.018 0.26 0.4 0.0051 0.0012 3
QVAVYSHGWA HuK2 39 10 0.0004 0.0097 0.02 0.0005 0.0252 3
LMLLRLSEPA HuK2 121 10 0.025 0.26 0.15 0.004 0.0016 3
FLRPRSLQCV HuK2 165 10 0.041 0.094 1.1 0.0068 0.0036 3
LVCNGVLQGI HuK2 217 10 0.0068 0.096 0.11 0.03 0.016 4
RAAPLLLARA PAP 2 10 0.0026 0.17 0.2 0.16 0.0007 3
LLARAASLSV PAP 7 A 10 0.046 0.44 0.47 0.0098 0.011 4
SLSLGFLFLV PAP 13 A 10 0.15 0.38 0.37 0.093 0.0095 4
SLLAKELKFV PAP 29 A 10 0.078 0.76 2.6 0.098 0.0012 4
VLAKELKFW PAP 30 A 10 0.16 0.36 0.053 0.043 0.0035 4
TLMSAMTNLV PAP 112 A 10 0.08 1.1 0.83 0.086 0.033 5
LLALFPPEGV PAP 120 A 10 0.16 11 2 0.1 0.05 5
LVALFPPEGV PAP 120 A 10 0.043 0.31 0.86 0.078 2.4 5
Sequence Protein/Segment 1st Position Analog AA A*0201 A*0202 A*0203 A*0206 A*6802 A2 Cross- reactivity
ALFPPEGVSV PAP 122 A LO 0.44 8 3.4 0.31 0.058 5
GVSIWNPILV PAP 128 A 10 0.02 0.046 0.43 0.0082 0.0035 4
PLLLWQPΓPV PAP 134 A 10 0.021 0.092 0.52 0.011 0.0024 4
LLWQPIPVHV PAP 136 A 10 0.87 2.1 0.57 0.032 0.19 5
GLHGQDLFGV PAP 196 A 10 0.27 1.2 2.6 0.63 0.0082 4
KLRELSELSV PAP 234 A 10 0.019 0.47 1.4 0.075 0.0044 4
EILNHMKRAT PAP 266 [0 0.0019 0.012 0.064 0.016 0.0028 3
DTTVSGLQMA PAP 290 10 0.005 0.11 0.082 0.012 0.011 3
LLPPYASCHV PAP 306 A ] L0 0.053 0.24 0.67 0.017 0.0027 4
LTLSVTWIGA PSA 4 L0 0.0018 0.045 0.082 0.011 0.091 4
KLQCVDLHW PSA 166 A L0 0.4 0.051 1.1 0.0074 0.0003 4
VLVHPQWVLTA HuK2 53 0.012 2.1 0.14 0.019 0.0008 4
VLVHPQWVLTV HuK2 53 A ] 0.68 2.9 3.8 0.34 0.0018 4
LVHPQWVLTAA HuK2 54 0.003 0.015 0.49 0.03 0.0034 3
DLMLLRLSEPV HuK2 120 A 1 0.1 0.075 0.35 0.025 0.0029 4
SLHLLSNDMCA HuK2 175 0.039 1.9 0.69 0.0005 0.0004 3
HLLSNDMCARA HuK2 177 0.029 0.052 0.11 0.0088 0.0004 4
KVTEFMLCAGL HuK2 191 0.001 0.028 0.028 0.016 0.0036 3
PLVCNGVLQGV HuK2 216 A ] 0.22 0.017 0.36 0.03 0.0049 4
RAAPLLLARAA PAP 2 0.0001 0.18 0.14 0.047 0.0037 3
LLLARAASLSL PAP 6 0.62 1.4 1.9 0.046 0.056 5
AASLSLGFLFL PAP 11 0.022 0.19 0.19 0.039 0.0006 4
Sequence Protein/Segment 1st Position Analog AA A*0201 A*0202 A*0203 A*0206 A*6802 A2 Cross- reactivity
FLLFFWLDRSV PAP 20 1 0.37 0.26 3.6 0.013 0.022 5
LLFFWLDRSVL PAP 21 1 0.077 1.5 3.7 0.0045 0.0018 3
VLAKELKFVTL PAP 30 1 0.72 0.53 0.47 0.15 -0.0002 4
FLNESYKHEQV PAP 92 1 0.049 1.9 1.2 0.37 0.001 4
WFLTLSVTWV PSA 1 A 1 1 0.056 0.049 0.14 0.011 0.0006 4
FLTLSVTWIGV PSA 3 A 1 1 0.73 1.4 0.56 0.057 0.07 5
VLVHPQWVLTV PSA 49 A 1 1 0.1 0.6 0.44 0.019 0.0008 4
SVFHPEDTGQV PSA 75 A 1 1 0.0038 0.13 0.19 0.0018 0.25 3
DLMLLRLSEPV PSA 116 A 1 1 0.023 0.017 0.091 0.0022 0.0016 3
HLISNDVCAQV PSA 173 A 1 1 0.0035 0.6 0.15 0.0028 0.026 3
PLVCNGVLQGV PSA 212 A 1 1 0.13 0.022 0.44 0.035 0.0075 4
RAAPLLLA PAP 2
PLLLARAA PAP 5
LLARAASL PAP 7
SLGFLFLL PAP 15
WLDRSVLA PAP 25
LAKELKFV PAP 31
ELKFVTLV PAP 34
DTFPTDPI PAP 51
GMEQHYEL PAP 74
STDVDRTL PAP 106
RTLMSAMT PAP 111
Sequence Protein/Segment 1st Position Analog AA A*0201 A*0202 A*0203 A*0206 A*6802 A2 Cross- reactivity
LMSAMTNL PAP 113
SAMTNLAA PAP 115
AMTNLAAL PAP 116
ALFPPEGV PAP 122
GVSIWNPI PAP 128
STWNPTLL PAP 130
PILLWQPI PAP 134
LLWQPIPV PAP 136
PLSEDQLL PAP 147
FIATLGKL PAP 187
TLGKLSGL PAP 190
FTLPSWAT PAP 221
WATEDTMT PAP 226
TMTKLREL PAP 231
KLRELSEL PAP 234
ELSELSLL PAP 237
SLLSLYGI PAP 242
RLQGGVLV PAP 257
GVLVNEIL PAP 261
ILNHMKRA PAP 267
HMKRATQI PAP 270
QTPSYKKL PAP 276
Sequence Protein Segment 1st Position Analog AA A*0201 A*0202 A*0203 A*0206 A*6802 A2 Cross- reactivity
IMYSAHDT PAP 284
TTVSGLQM PAP 291
TVSGLQMA PAP 292
GLQMALDV PAP 295
ALDVYNGL PAP 299
EMYYRNET PAP 328
PLERFAEL PAP 352
FAELVGPV PAP 356
VTPQDWST PAP 363
TTNSHQGT PAP 374
LLHETDSA PSM 4
ETDSAVAT PSM 7
TARRPRWL PSM 14
WLCAGALV PSM 20
CAGALVLA PSM 22
VLAGGFFL PSM 27
LAGGFFLL PSM 28
FTKSSNEA PSM 42
NITPKHNM PSM 51
FLYNFTQI PSM 73
FTQEPHLA PSM 77
QIPHLAGT PSM 79
Sequence Protein/Segment 1st Position Analog AA A*0201 A*0202 A*0203 A*0206 A*6802 A2 Cross- reactivity
GTEQNFQL PSM 85
GLDSVELA PSM 104
ELAHYDVL PSM 109
LAHYDVLL PSM 110
LLSYPNKT PSM 116
DTVPPFSA PSM 156
SAFSPQGM PSM 162
GMPEGDLV PSM 168
DLVYVNYA PSM 173
RTEDFFKL PSM 181
KLERDMKI PSM 187
KTNCSGKI PSM 193
VLARYGKV PSM 201
KVFRGNKV PSM 207
KVKNAQLA PSM 213
QLAGAKGV PSM 218
LAGAKGVI PSM 219
VILYSDPA PSM 225
GVQRGNIL PSM 252
NILNLNGA PSM 257
PLTPGYPA PSM 267
YAYRRGIA PSM 277
Sequence Protein/Segment 1st Position Analog AA A*0201 A*0202 A*0203 A*0206 A*6802 A2 Cross- reactivity
GIAEAVGL PSM 282
EAVGLPSI PSM 285
SLKVPYNV PSM 322
HIHSTNEV PSM 345
STNEVTRI PSM 348
EVTRIYNV PSM 351
VTRTY VT PSM 352
RIYNVTGT PSM 354
VIGTLRGA PSM 358
AVEPDRYV PSM 365
GTDPQSGA PSM 385
GAAWHEI PSM 391
AAWHEIV PSM 392
ETVRSFGT PSM 397
IVRSFGTL PSM 398
ILFASWDA PSM 416
DAEEFGLL PSM 422
LLGSTEWA PSM 428
WAEENSRL PSM 434
RLLQERGV PSM 440
LLQERGVA PSM 441
YTNADSSI PSM 449
Sequence Protein/Segment 1st Position Analog AA A*0201 A*0202 A*0203 A*0206 A*6802 A2 Cross- reactivity
SIEGNYTL PSM 455
YTLRVDCT PSM 460
RVDCTPLM PSM 463
CTPLMYSL PSM 466
GMPRISKL PSM 508
SVYETYEL PSM 554
PMFKYHLT PSM 568
VAQVRGGM PSM 576
ELANSTVL PSM 586
AWLRKYA PSM 601
YADKIYSI PSM 607
SMKHPQEM PSM 615
AVKNFTEI PSM 635
RMMNDQLM PSM 662
QLMFLERA PSM 667
EVKRQTYV PSM 727
QTYVAAFT PSM 731
VAAFTVQA PSM 734
AAFTVQAA PSM 735
TVQAAAET PSM 738
AAETLSEV PSM 742
LVHETDSAV PSM 4 A
Sequence Protein Segment 1st Position Analog AA A*0201 A*0202 A*0203 A*0206 A*6802 A2 Cross- reactivity
ETDSAVATA PSM 7 9
WLCAGALW PSM 20 A 9
LVLAGGFFV PSM 26 A 9
FIKSSNEAT . PSM 42 9
ITPKHNMKA PSM 52 9
KAFLDELKA PSM 59 9
GTEQNFQLA PSM 85 9
ELAHYDVLV PSM 109 A 9
LVYVNYART PSM 174 9
GVTLYSDPA PSM 224 9
ALGLPSTPV PSM 286 A 9
DAQKLLEKM PSM 301 9
KVKMHTHST PSM 341 9
HTHSTNEVT PSM 345 9
NVIGTLRGA PSM 357 9
GTDPQSGAA PSM 385 9
TILFASWDA PSM 415 9
GLLGSTEWV PSM 427 A 9
TLRVDCTPV PSM 461 A 9
IASGRARYT PSM 530 9
SLYETYELV PSM 554 A 9
LVEKFYDPM PSM 561 9
Sequence Protein/Segment 1st Position Analog AA A*0201 A*0202 A*0203 A*0206 A*6802 A2 Cross- reactivity
PLFKYHLTV PSM 568 A 9
PVFKYHLTV PSM 568 A 9
TVAQVRGGM PSM 575 9
MVFELANSV PSM 583 A 9
YAWLRKYA PSM 600 9
AVKNFTEIA PSM 635 9
EVKRQIYVA PSM 727 9
QLYVAAFTV PSM 731 A 9
QVYVAAFTV PSM 731 A 9 μμ YVAAFTVQA PSM 733 9 U
©
VAAFTVQAA PSM 734 9
AAFTVQAAA PSM 735 9
FTVQAAAET PSM 737 9
AAETLSEVA PSM 742 9
NVLHETDSAV PSM 3 A 10
TARRPRWLCA PSM 14 10
WLCAGALVLV PSM 20 A 10
ALVLAGGFFV PSM 25 A 10
LVLAGGFFLV PSM 26 A 10
LLGFLFGWFV PSM 34 A 10
ATNITPKHNM PSM 49 10
MTPKHNMKA PSM 51 10
Sequence Protein/Segment 1st Position Analog AA A*0201 A*0202 A*0203 A*0206 A*6802 A2 Cross- reactivity
FLDELKAENV PSM 61 A 10
NΓKKFLYNFT PSM 69 10
FTQΓPHLAGT PSM 77 10
DVLLSYPNKT PSM 114 10
KVKNAQLAGA PSM 213 10
YAYRRGIAEA PSM 277 10
PVHPIGYYDA PSM 293 10
KLHΓHSTNEV PSM 343 A 10
KVHTHSTNEV PSM 343 A 10
VTRTYNVIGT PSM 352 10
RTILFASWDA PSM 414 10
LLQERGVAYV PSM 441 A 10
KVGSGNDFEV PSM 514 A 10
EVFFQRLGIA PSM 522 10
GIASGRARYT PSM 529 10
RARYTKNWET PSM 534 10
LTVAQVRGGM PSM 574 10
MLFELANSTV PSM 583 A 10
VLPFDCRDYV PSM 592 A 10
YADKIYSISM PSM 607 10
SISMKHPQEM PSM 613 10
SVSFDSLFSA PSM 626 10
Sequence Protein/Segment 1st Position Analog AA A*0201 A*0202 A*0203 A*0206 A*6802 A2 Cross- reactivity
SLFSAVKNFV PSM 631 A 10
SAVKNFTEIA PSM 634 10
FLERAFIDPV PSM 670 A 10
YAPSSHNKYA PSM 692 10
EVKRQTYVAA PSM 727 10
YVAAFTVQAA PSM 733 10
VAAFTVQAAA PSM 734 10
AAAETLSEVA PSM 741 10
DVDRTLMSAMT PAP 108
RTLMSAMTNLA PAP 111 ux
IO TLMSAMTNLAA PAP 112
LMSAMTNLAAL PAP 113
NLAALFPPEGV PAP 119
AALFPPEGVSI PAP 121
ILLWQPTPVHT PAP 135
LLWQPΓPVHTV PAP 136
HTVPLSEDQLL PAP 144
TLKSEEFQKRL PAP 171
RLHPYKDFIAT PAP 180
FIATLGKLSGL PAP 187
KVYDPLYCESV PAP 208
PLYCESVHNFT PAP 212
Sequence Protein/Segment 1st Position Analog AA A*0201 A*0202 A*0203 A*0206 A*6802 A2 Cross- reactivity
SVHNFTLPSWA PAP 217
FTLPSWATEDT PAP 221
TLPSWATEDTM PAP 222
TMTKLRELSEL PAP 231
KLRELSELSLL PAP 234
GTHKQKEKSRL PAP 248
RLQGGVLVNEI PAP 257
GVLVNEΓLNHM PAP 261
ILNHMKRATQI PAP 267 μμ RATQΓPSYKKL PAP 273 U
OJ
ATQΓPSYKKLI PAP 274
KLΓMYSAHDTT PAP 282
LΓMYSAHDTTV PAP 283
DTTVSGLQMAL PAP 290
TVSGLQMALDV PAP 292
QMALDVYNGLL PAP 297
DVYNGLLPPYA PAP 301
GLLPPYASCHL PAP 305
LLPPYASCHLT PAP 306
ELYFEKGEYFV PAP 317
ETQHEPYPLML PAP 334
MLPGCSPSCPL PAP 343
Sequence Protein/Segment 1st Position Analog AA A*0201 A*0202 A*0203 A*0206 A*6802 A2 Cross- reactivity
VTPQDWSTECM PAP 363
NLLHETDSAVA PSM 3
LLHETDSAVAT PSM 4
AVATARRPRWL PSM 11
ATARRPRWLCA PSM 13
GALVLAGGFFL PSM 24
ALVLAGGFFLL PSM 25
LAGGFFLLGFL PSM 28
FLLGFLFGWFI PSM 33
FTKSSNEATNI PSM 42
EATNITPKHNM PSM 48
ITPKHNMKAFL PSM 52
NMKAFLDELKA PSM 57
ELKAENTKKFL PSM 64
FLYNFTQTPHL PSM 73
HLAGTEQNFQL PSM 82
LAGTEQNFQLA PSM 83
QIQSQWKEFGL PSM 95
SVELAFTYDVLL PSM 107
NVSDΓVPPFSA PSM 153
DMKΓNCSGKΓV PSM 191
KΓNCSGKΓVIA PSM 193
Sequence Protein Segment 1st Position Analog AA A*0201 A*0202 A*0203 A*0206 A*6802 A2 Cross- reactivity
KVFRGNKVKNA PSM 207
NAQLAGAKGVT PSM 216
ILYSDPADYFA PSM 226
GVKSYPDGWNL PSM 238
ILNLNGAGDPL PSM 258
LTPGYPANEYA PSM 268
PANEYAYRRGI PSM 273
YAYRRGIAEAV PSM 277
GIAEAVGLPSI PSM 282
PIGYYDAQKLL PSM 296 μμ ux KVPYNVGPGFT PSM 324 ux
KMHIHSTNEVT PSM 343
HTHSTNEVTRI PSM 345
STNEVTRIYNV PSM 348
EVTRTYNVIGT PSM 351
VTRIYNVIGTL PSM 352
GAVEPDRYVIL PSM 364
VILGGHRDSWV PSM 372
GTDPQSGAAW PSM 385
WHETVRSFGT PSM 394
FASWDAEEFGL PSM 418
DAEEFGLLGST PSM 422
Sequence Protein/Segment 1st Position Analog AA A*0201 A*0202 A*0203 A*0206 A*6802 A2 Cross- reactivity
STEWAEENSRL PSM 431
RLLQERGVAYI PSM 440
GVAYINADSSI PSM 446
NADSSIEGNYT PSM 451
YTLRVDCTPLM PSM 460
RVDCTPLMYSL PSM 463
PLMYSLVHNLT PSM 468
HLTVAQVRGGM PSM 573
LTVAQVRGGMV PSM 574
QVRGGMVFELA PSM 578
GMVFELANSTV PSM 582
MVFELANSIVL PSM 583
TVLPFDCRDYA PSM 591
VLPFDCRDYAV PSM 592
AWLRKYADKI PSM 601
SVSFDSLFSAV PSM 626
RLQDFDKSNPI PSM 649
PTVLPJvIMNDQL PSM 658 rVLRMMNDQLM PSM 659
GLPDRPFYRHV PSM 680
DIESKVDPSKA PSM 714
KVDPSKAWGEV PSM 718
Sequence Protein/Segment 1st Position Analog AA A*0201 A*0202 A*0203 A*0206 A*6802 A2 Cross- reactivity
QIYVAAFTVQA PSM 731 11
YVAAFTVQAAA PSM 733 11
AAFTVQAAAET PSM 735 11
QAAAETLSEVA PSM 740 11
PQGFGQLT PAP 64
GQLTQLGM PAP 68
EQVYTRST PAP 100
WQPΓPVHT PAP 138
FQELESET PAP 164
KQKEKSRL PAP 251
TQHEPYPL PAP 335
HQGTEDST PAP 378
SQPWQVLV PSA 31
LQCVDLHV PSA 167
AQVHPQKV PSA 181
PQKVTKFM PSA 185
SQWKEFGL PSM 98
AQKLLEKM PSM 302
TQKVKMHI PSM 339
PQSGAAW PSM 388
AQVRGGMV PSM 577
VQAAAETL PSM 739
Sequence Protein/Segment 1st Position Analog AA A*0201 A*0202 A*0203 A*0206 A*6802 A2 Cross- reactivity
WQPIPVHTV PAP 138 9
FQELESETL PAP 164 9
TQTPSYKKL PAP 275 9
TQHEPYPLM PAP 335 9
PQDWSTECM PAP 365 9
SQPWQVLVA PSA 31 9
LQCVDLHVI PSA 167 9
AQVHPQKVT PSA 181 9
PQKVTKFML PSA 185 9
TQIPHLAGT PSM 78 9
PQGMPEGDL PSM 166 9
AQLAGAKGV PSM 217 9
VQRGNILNL PSM 253 9
LQERGVAYI PSM 442
PQEMKTYSV PSM 619 9
DQLMFLERA PSM 666 9
RQIYVAAFT PSM 730 9
KLTDWKVL HuK2 131 9
KVTDWKVL HuK2 131 9
KTTDWKVL HuK2 131 9
KITDWKW HuK2 131 9
PLLGTTCYA HuK2 146 9
Sequence Protein/Segment 1st Position Analog AA A*0201 A*0202 A*0203 A*0206 A*6802 A2 Cross- reactivity
PVLGTTCYA HuK2 146 9
PTLGTTCYA HuK2 146 9
PALGTTCYV HuK2 146 9
PQGFGQLTQL PAP 64 10
EQHYELGEYI PAP 76 10
EQVΎΓRSTDV PAP 100 10
LQGGVLVNEI PAP 258 10
TQTPSYKKLI PAP 275 10
TQHEPYPLML PAP 335 10 μμ PQDWSTECMT PAP 365 10 U vo
EQNFQLAKQI PSM 87 10
IQSQWKEFGL PSM 96 10
PQGMPEGDLV PSM 166 10
AQLAGAKGVI PSM 217 10
LQDFDKSNPI PSM 650 10
RQΓYVAAFTV PSM 730 10
ILLSVGCTGA HuK2 8 10
TVLSVGCTGA HuK2 8 10
ITLSVGCTGA HuK2 8 10
IALSVGCTGV HuK2 8 10
GLVPLIQSRI HuK2 16 10
GWPLIQSRI HuK2 16 10
Sequence Protein/Segment 1st Position Analog AA A*0201 A*0202 A*0203 A*0206 A*6802 A2 Cross- reactivity
GTVPLIQSRI HuK2 16 10
GAVPLIQSRV HuK2 16 10
CLRAYSEKVT HuK2 184 10
CVRAYSEKVT HuK2 184 10
CTRAYSEKVT HuK2 184 10
CARAYSEKW HuK2 184 10
TQLGMEQHYEL PAP 71
WQPTPVHTVPL PAP 138
GQDLFGΓWSKV PAP 199
LQGGVLVNEIL PAP 258
TQΓPSYKKLΓM PAP 275
LQMALDVYNGL PAP 296
PQDWSTECMTT PAP 365
WQVLVASRGRA PSA 34
PQWVLTAAHCI PSA 53
FQVSHSFPHPL PSA 86
PQKVTKFMLCA PSA 185
SQWKEFGLDSV PSM 98
AQLAGAKGVIL PSM 217
TQKVKMHΓHST PSM 339
PQSGAAWHEI PSM 388
LQERGVAYTNA PSM 442 ]
Sequence Protein Segment 1st Position Analog AA A*0201 A*0202 A*0203 A*0206 A*6802 A2 Cross- reactivity
FQRLGIASGRA PSM 525
AQVRGGMVFEL PSM 577
LQDFDKSNPΓV PSM 650
DQLMFLERAFI PSM 666
VQAAAETLSEV PSM 739
SLALSVGCTGA HuK2 7
SVALSVGCTGA HuK2 7
STALSVGCTGA HuK2 7
SIALSVGCTGV HuK2 7
Table 17
Peptide Sequence Organism Protein/Segment 1st Position Analog AA A*0201 Analog type
1413.08 GLAPPQQLIRN Human p53 187 A 11 0.45 Heteroclitics
1413.10 GLAPPQSLΓ V Human p53 187 A 11 1.5 Heteroclitics
1413.11 LLGRDSFEN Human mp53 261 A 9 1.6
1413.12 LLSRDSFEN Human mp53 261 A 9 0.17 Heteroclitics
1413.13 LLDRDSFEN Human mp53 261 A 9 1.1 Heteroclitics
1413.14 LLFLRDSFEN Human mp53 261 A 9 1.5 Heteroclitics
1413.15 LLGR SFEN Human p53 264 A 9 0.035
1413.16 LLGRQSFEN Human mp53 264 A 9 0.066 Heteroclitics
©V
1413.17 LLGRGSFEN Human mp53 264 A 9 0.026 Heteroclitics
1413.18 LLGRDSLEN Human mp53 264 A 9 0.025 Heteroclitics
1413.19 LLGRDSMEN Human mp53 264 A 9 0.012 Heteroclitics
1413.20 LLGRDSHEN Human mp53 264 A 9 0.60 Heteroclitics
54.0078 YLQLVFGLEN Human MAGE2 157 A 10 0.018
54.0084 YLQLΓFGΓEV Human MAGE2 157 A 10 0.013 Heteroclitics
55.0234 YLQLFFGΓEV Human MAGE2 157 A 10 0.046 Heteroclitics
54.0003 SMPPPGTRN Human p53 149 A 9 0.079 Heteroclitics
54.0005 CMPPPGTRN Human p53 149 A 9 0.182 Heteroclitics
55.0049 SMPPPGPRN Human p53 149 A 9 0.011 Heteroclitics
Peptide Sequence Organism Protein/S egment 1st Position Analog AA A*0201 Analog type
55.0155 ILLEPNHGN HIN POL 476 A 9 0.0075 Heteroclitics
54.0063 ILHEPNHGN HIN POL 476 A 9 0.019 Heteroclitics
55.0123 GLSRYVPRL HIN POL 455 A 9 0.098 Heteroclitics
54.0042 GLSRYNARL HIN POL 455 A 9 0.057 Heteroclitics
55.0153 ILNEPVHGN HIN POL 476 A 9 0.0060 Heteroclitics
55.0158 ILKDPVHGN HIN POL 476 A 9 0.026 Heteroclitics
55.0159 ILKQPVHGN HIN POL 476 A 9 0.0063 Heteroclitics
55.0160 ILK PVHGN HIN POL 476 A 9 0.0055 Heteroclitics
55.0161 ILKHPNHGN HIN POL 476 A 9 0.0005 Heteroclitics
Ox OJ 55.0162 LLKTPVHGN HIN POL 476 A 9 0.0011 Heteroclitics
55.0163 ILKRPNHGN HIN POL 476 A 9 0.015 Heteroclitics
55.0164 LLKNPVHGV HIN POL 476 A 9 0.0048 Heteroclitics
55.0165 ILKLPVHGN HIN POL 476 A 9 0.010 Heteroclitics
55.0166 ILKYPVHGN HIN POL 476 A 9 0.032 Heteroclitics
55.0167 ILKFPNHGN HIN POL 476 A 9 0.077 Heteroclitics
55.0168 ILKETNHGN HIN POL 476 A 9 0.011 Heteroclitics
55.0169 ILKESVHGN HIN POL 476 A 9 0.19 Heteroclitics
55.0170 ILKEFNHGN HIN POL 476 A 9 0.024 Heteroclitics
Table 18
HLA - A3 supertype binding i affinity (IC50 nM)
Peptide Sequence Source A*0301 A*1101 A*3101 A*3301 A*6801
78.0064 AACHKCΓDFY HPV45.E6.63 7769 356 4830 10647 4958
78.0048 AACHKCΓDFΎ HPV18.E6.63 18824 306 20643 >97403.22 31622
78.0316 AACWRSRRR HPV33.E6.137 13039 9433 407 913 983
78.0058 AFADLTVVYR HPV33.E6.46 24059 5093 140 249 39
78.0063 AFKDLCIVYR HPV45.E6.48 13166 3661 26 29 548
78.0093 AFKDLFVVYR HPV18.E6.48 46161 10358 8.3 14 365
78.0079 AFRDLCIVYR HPV16.E6.53 3106 4377 13 41 600
78.0052 AFTDLTIVYR HPV31.E6.46 26603 300 810 817 210
78.0281 AQPATADYY HPV33.E7.45 43 15 10.3 32 23
78.0294 ATLESITKK HPV56.E6.89 302 160 261 >81119.6 >32130.33
78.0272 ATLQDIVLH HPV18.E7.6 76 251 >141552.48 >107282.02 3756
78.0023 ATSNYYIVTY HPV52.E7.50 2437 167 27613 154330 24292
78.0043 AVCDKCLKFY HPV16.E6.68 561 88 1959 47868 3323
78.0068 AVCRVCLLFY HPV56.E6.64 77 21 1978 4520 1302
78.0298 AVCWRPRRR HPV58.E6.137 3.9 13 395 799 23
78.0284 CIAYAACHK HPV45.E6.59 831 226 8103 17514 1011
78.0151 CLLFYSKVRK HPV56.E6.69 342 249 3343 9357 405
78.0061 CVYCKATLER HPV45.E6.32 24489 28088 334 963 4485
78.0095 DSrPHAACHK HPV18.E6.58 25343 1874 1886 14 69
78.0049 DSVYGDTLEK HPV18.E6.83 4717 415 51213 116894 408
78.0297 DTLEQTLKK HPV58.E6.86 446 139 714 5826 2488
78.0313 EGNPFGICK HPV33.E6.56 40696 2662 602 585 28
78.0322 ELQRREVYK HPV52.E6.36 5603 18788 407 17506 25869
78.0072 ETSVHEΓELK HPV58.E6.20 31644 5335 31702 98886 41
Table 18
HLA- A3 supertype binding affinity (IC50 nM)
Peptide Sequence Source A*0301 A*1101 A*3101 A*3301 A*6801
78.0335 FADLRIVYR HPV58.E6.47 5447 20911 86 24176 >30740.14
78.0115 FAFADLTVVY HPV33.E6.45 18592 5866 23676 26768 402
78.0103 FAFTDLTIVY HPV31.E6.45 40343 21161 42065 131202 346
78.0111 FCCQCKSTLR HPV31.E7.57 8975 8510 2056 96 15816
78.0293 GATLESITK HPV56.E6.88 187 300 861 1884 6558
78.0069 GATLESITKK HPV56.E6.88 1860 283 8619 8728 2487
78.0046 GIVCPICSQK HPV16.E7.88 2758 117 20749 93473 2714
78.0055 GTTLEKLTNK HPV31.E6.85 2049 176 3823 42078 16401
78.0044 GTTLEQQYNK HPV16.E6.92 10850 69 34193 101404 3935
78.0106 GVCTKCLRFY HPV31.E6.61 1482 244 7528 8360 24818
78.0326 GVDRPDGQA HPV52.E7.39 214 1290 3356 8720 >30740.14
78.0273 GVNHQHLPA HPV18.E7.43 816 26 862 1353 203
78.0100 GVNHQHLPAR HPV18.E7.43 3181 178 62 13039 2897
78.0134 GVSHAQLPAR HPV45.E7.44 3689 221 2788 46952 16649
78.0274 HTMLCMCCK HPV18.E7.59 636 274 6491 129386 3658
78.0265 ITLECVYCK HPV16.E6.33 1644 235 5656 8957 1594
78.0165 ΓLΓRCIICQR HPV58.E6.99 4366 490 379 4273 272
78.0117 ΓLΓRCΠCQR HPV33.E6.99 8550 5012 377 2480 537
78.0311 IVCPNCSTR HPV31.E7.89 18461 >25210.31 350 64095 28178
78.0278 IVTFCCQCK HPV31.E7.54 4511 152 15374 >107282.02 >16962.83
78.0283 IVYRDCIAY HPV45.E6.54 262 42 598 469 2555
78.0286 TVYRDNNPY HPV52.E6.52 9024 225 90928 8249 295
78.0081 KFYSKISEYR HPV16.E6.75 1684 18047 48 79 264
78.0082 KISEYRHYCY HPV16.E6.79 152 163 4847 2348 2004
Table 18
HLA- A3 supertype binding affinity (IC50 nM)
Peptide Sequence Source A*0301 A*1101 A*3101 A*3301 A*6801
78.0074 KISEYRHYNY HPV58.E6.72 197 136 1759 40765 10323
78.0059 KISEYRHYNY HPV33.E6.72 42 112 1426 35341 25077
78.0331 KQHTCYLIH HPV56.E7.54 39392 >18660.01 526 521 439
78.0329 KQLCDLLIR HPV56.E6.97 3513 9972 39 12 58
78.0156 KQLHCDRKRR HPV56.E6.118 31894 >4691.24 289 71431 >13447.56
78.0083 KQRFΉNΓRGR HPV16.E6.129 2037 11596 178 4441 10279
78.0288 KTLEERVKK HPV52.E6.86 2694 296 13241 54088 2353
78.0296 KVCLRLLSK HPV58.E6.64 9470 19 >69585.78 113285 . 4651
78.0275 KVSEFRWYR HPV31.E6.72 401 178 65947 >107282.02 43168
78.0053 KVSEFRWYRY HPV31.E6.72 248 23 11 7073 1908
78.0155 LCDLLXRCYR HPV56.E6.99 3984 273 856 405 2126
©\ ©\ 78.0137 LFTDLRIVYR HPV52.E6.46 57146 >4045.92 430 217 1890
78.0152 LFYSKVRKYR HPV56.E6.71 6622 6011 8.1 48 1892
78.0337 LTRCIICQR HPV58.E6.100 198 992 523 117540 >28524.17
78.0301 LΓRCΓNCQK HPV16.E6.107 2182 216 6859 >74670.44 >34318.65
78.0317 LΓRCLRCQK HPV45.E6.102 5501 1647 353 5723 1321
78.0292 LLFYSKVRK HPV56.E6.70 106 18 43151 70793 33
78.0045 LLΓRCΓNCQK HPV16.E6.106 296 71 556 5375 32
78.0108 LLΓRCΓTCQR HPV31.E6.99 3319 5272 168 739 30
78.0066 LLΓRCLRCQK HPV45.E6.101 270 226 2496 11367 44
78.0051 LLΓRCLRCQK HPV18.E6.101 437 211 6612 28936 78
78.0145 LQVVCPGCAR HPV52.E7.89 >55458.03 >14665.98 490 6225 19498
78.0306 LSFVCPWCA HPV18.E7.94 38337 10864 4289 4603 341
78.0047 LTEVFEFAFK HPV18.E6.41 8672 113 37879 47752 27
Table 18
HLA- A3 supertype binding affinity (IC50 nM)
Peptide Sequence Source A*0301 A*1101 A*3101 A*3301 A*6801
78.0086 MSCCRSSRTR HPV16.E6.144 571 829 324 1142 26
78.0324 NIMGRWTGR HPV52.E6.127 38678 1940 41 448 26230
78.0057 NIVTFCCQCK HPV31.E7.53 3072 1957 6005 10314 199
78.0065 NSVYGETLEK HPV45.E6.83 633 127 5749 8928 289
78.0280 NTLEQTVKK HPV33.E6.86 529 142 743 3428 224
78.0330 QQARQAKQH HPV56.E7.48 7172 2853 48 36 30
78.0327 QVVCPGCAR HPV52.E7.90 3819 16820 5080 92 5341
78.0119 RCAACWRSRR HPV33.E6.135 17390 28729 486 2394 6645
78.0338 RCAVCWRPR HPV58.E6.135 54398 21282 2829 438 1440
78.0109 RCIACWRRPR HPV31.E6.135 1231 6604 64 438 5855
78.0097 RFHNIAGHYR HPV18.E6.126 2463 2855 11 99 151
78.0133 FHSIAGQYR HPV45.E6.126 4278 3390 24 585 303
78.0140 RFLSKISEYR HPV52.E6.68 4860 >14665.98 27 749 36
78.0116 RFLSKISEYR HPV33.E6.68 1640 18468 33 436 172
78.0107 RFYSKVSEFR HPV31.E6.68 1382 17885 54 204 250
78.0098 RGQCHSCCNR HPV18.E6.135 22754 1938 192 318 4791
78.0163 RLLSKISEYR HPV58.E6.68 66 2507 42 1574 240
78.0320 RLQCVQCKK HPV52.E6.27 2200 1289 386 336 993
78.0062 RTEVYQFAFK HPV45.E6.41 285 111 1691 9180 3310
78.0291 RVCLLFYSK HPV56.E6.67 347 166 >77795.34 >81119.6 2622
78.0302 SCCRSSRTR HPV16.E6.145 288 230 525 106485 45541
78.0087 SCCRSSRTRR HPV16.E6.145 16439 21422 401 223 3608
78.0270 SΓPHAACHK HPV18.E6.59 736 268 63 7253 403
78.0142 SLYGKTLEER HPV52.E6.82 56 1728 435 5499 178
Table 18
HLA- A3 supertype binding affinity (IC50 nM)
Peptide Sequence Source A*0301 A*1101 A*3101 A*3301 A*6801
78.0271 SVYGDTLEK HPV18.E6.84 2575 273 32513 22456 >17538 78.0285 SVYGETLEK HPV45.E6.84 169 490 795 60127 33480 78.0276 SVYGTTLEK HPV31.E6.82 450 109 1595 1969 439 78.0076 TAMFQDPQER HPV16.E6.6 40463 2877 11713 8520 16 78.0303 TGLYNLLTR HPV18.E6.96 2737 2577 197 3780 2592 78.0333 TSVHETELK HPV58.E6.21 51582 3692 665 1305 312 78.0277 TTLEKLTNK HPV31.E6.86 72 14 41179 79901 17 78.0135 TVESSAEDLR HPV45.E7.76 >58998.41 9973 89136 55083 205 78.0073 VFADLRIVYR HPV58.E6.46 23042 2089 31 52 197 78.0321 VQCKKELQR HPV52.E6.31 54286 29279 366 6049 21290
©\ oe 78.0295 VQLDIQSTK HPV56.E7.72 153 378 1066 40091 7535 78.0318 VSHAQLPAR HPV45.E7.45 19181 9024 1784 310 39 78.0282 VSIACVYCK HPV45.E6.28 19 3.8 8875 33911 15 78.0071 VVQLDIQSTK HPV56.E7.71 1862 143 35232 83649 3704 78.0118 WAGRCAACWR HPV33.E6.132 10060 10975 445 49 50 78.0075 WTGRCAVCWR HPV58.E6.132 4397 4806 358 107 59 78.0056 WTGRCIACWR HPV31.E6.132 2260 1035 179 17 31 78.0084 WTGRCMSCCR HPV16.E6.139 11458 7557 3126 471 178 78.0067 WTGRCSECWR HPV52.E6.132 20400 1523 538 69 40 78.0070 WTGSCLGCWR HPV56.E6.135 25112 1624 208 60 23 78.0300 YAVCDKCLK HPV16.E6.67 56 18 3195 87230 1948 78.0334 YDFVFADLR HPV58.E6.43 61113 24098 64 153 1332 78.0054 YSVYGTTLEK HPV31.E6.81 357 100 >100076.57 >36296.57 36
TABLE 19
HLA- A3 supertype binding affinity (IC50 nM)
Peptide Sequence AA Source Analog A*0301 A*1101 A*3101 A*3301 A*6801
21.0073 GIIHFSFPF 9 Candida.aur .168 18333.3 293.5
21.0053 LTSQEFLPA 9 Candida.aur .98 6821.9 152.2
21.0201 STMYLTHHYF 10 Candida.aur .301 >31754.26 36.1
1371.13 FVSNLATGK 9 CEA.656 A 3315.0 280.2 >17162.33 >48333.33 7.5
1371.12 HVQVLFIAR 9 CEA.636 A 10357.1 11131.7 1627.8 319.7 479.5
1371.08 IVPSYTYYK 9 CEA.420 A 17.9 63.3 1550.8 4505.5 21.5
1371.07 TVPSYTYYR 9 CEA.420 A 91.4 14.4 49.6 118.7 1.9
1371.10 RVLTLFNVTK 10 CEA.554 A 20.9 31.2 234.1 42522.0 1738.1
1371.09 RVLTLFNVTR 10 CEA.554 A 298.3 75.1 17.7 7745.4 42.9
1371.04 RVLTLLSVTK 10 CEA.376 A 38.6 50.1 165.5 >48333.33 4466.8
1371.03 RVLTLLSVTR 10 CEA.376 A 340.9 248.2 12.4 6127.4 519.5
©\ vo 1371.02 TVSPLNTSYK 10 CEA.241 A 17.4 11.1 13258.6 30398.3 12.1
1371.01 TVSPLNTSYR 10 CEA.241 A 465.7 62.4 194.3 646.5 12.4
1371.06 TVSPSYTYYK 10 CEA.419 A 53.5 33.6 4172.3 30317.1 9.8
1371.05 TVSPSYTYYR 10 CEA.419 A 2495.9 3103.6 30.9 270.0 9.0
1120.17 TYQRTRALK 9 Flu.NP.147 A 32.0 66.5 16000.0
1.1076 GΓLYKRETTR 10 HBV.pol.729 >17614.1 >4615.38 2157.6 439.4 80000.0
1.0973 HLQEDΠNR 9 HBV.pol.657 >4032.8 >4670.99 65.0 15.7 1600.0
1150.34 LAACFARDR 9 HBV.pol.731 >27500 30000.0 4352.9 1435.7 40.0
1150.32 LAIGHQRMR 9 HBV.pol.708 >27500 30000.0 2964.8 2165.8 66.7
1150.33 LAIGQSGMR 9 HBV.pol.708 >27500 15000.0 16431.7 7259.1 47.1 28.0747 LΓMPARFYPK 10 HBV.pol.109 2.4 6.1
28.0397 LVMGHQRMR 9 HBV.pol.697 366.7 498.1 28.0396 LVNHYFQTR 9 HBV.pol.137 2053.4 363.7 1.0966 NVNMGLKTR 9 HBV.core.90 >4032.8 >4670.99 3728.2 366.9 4705.9
28.0398 PTNRPTDWK 9 HBV.pol.612 102.2 170.3 1.0984 VLKLKQCFR 9 HBV.pol.1186 15877.1 >5720.78 37.6 668.8
TABLE 19
HLA- A3 supertype binding affinity (IC50 nM)
Peptide Sequence AA Source Analog A*0301 A*1101 A*3101 A*3301 A*6801
28.0835 VSYVNTNMGLK 11 HBV.core.115 54.0 45.7 1150.28 WARVHSTTR 9 HBV.pol.244 >27500 >30000 10062.3 248.9 1126.8 1.0986 YLHLYPVAR 9 HBV.pol.1255 2948.3 8571.4 492.8 471.6
1371.62 AVPLDSTFYK 10 Her2/neu.997 A 630.7 33.5 1653.8 21481.5 179.0
1371.61 AVPLDSTFYR 10 Her2/neu.997 A >38890.87 92.0 29950.1 2940.4 54.4
1371.47 BVNBSQFLK 9 Her2/neu.528 A 35.6 22.1 70.0 4438.9 17.2
1371.46 BVNBSQFLR 9 Her2/neu.528 A 196.3 80.0 37.7 57.7 9.8
1371.45 HVVPWDQLFK 10 Her2/neu.478 A 184.2 410.1 >46475.8 38359.8 9.5
1371.44 HVVPWDQLFR 10 Her2/neu.478 A 7261.7 1434.1 397.5 205.2 3.9
1371.35 IVKGGVLIQK 10 Her2/neu.l48 A 26.5 74.7 470.3 18403.5 21.1
1371.34 IVKGGVLIQR 10 Her2/neu.l48 A 278.9 7349.1 70.7 125.1 32.5
~4 1371.38 IVWKDTFHK 9 Her2/neu.l67 A 23.9 45.8 265.6 970.1 165.8
©
1371.39 IVWKDΓFΉR 9 Her2/neu.l67 A 148.4 282.8 6.1 18.6 17.0
1371.43 IVWLGLRSLK 10 Her2/neu.450 A 4.0 128 293 2283 12
1371.42 IVWLGLRSLR 10 Her2/neu.450 A 235.3 2195.7 11.6 193.6 7.5
1371.57 KVTDFGLAK 9 Her2/neu.860 A 27.5 46.2 3495.9 >17985.04 1193.2
1371.56 KVTDFGLAR 9 Her2/neu.860 A 202.9 82.7 114.3 >17985.04 138.0
1371.53 LVARNVLVK 9 Her2/neu.846 A 44.3 217.4 8991.0 >17985.04 169.4
1371.54 LVARNVLVR 9 Her2/neu.846 A 281.2 3117.2 9144.6 20573.1 22.0
1371.52 LVDHVRENK 9 Her2/neu.806 A 299.4 768.2 >46475.8 >17985.04 3301.1
1371.55 LVKSPNHVR 9 Her2/neu.852 A 7898.3 12903.2 201.6 107.8 74.9
1371.60 LVSEFSRMAK 10 Her2/neu.972 A 285.6 78.2 1710.9 5318.2 51.8
1371.59 MVLESΓLRK 9 Her2/neu.889 A 62.6 16.4 20930.2 2848.9 290.1
1371.58 MVLESΓLRR 9 Her2/neu.889 A 235.7 272.5 208.1 121.5 20.5
1371.41 TVBAGGBAK 9 Her2/neu.218 A 24.2 29.2 41958.0 34523.8 7.8
1371.40 TVBAGGBAR 9 Her2/neu.218 A 350.2 114.3 248.3 201.4 7.9
1371.36 TVLWKDΓFHK 10 Her2/neu.l66 A 813.7 41.0 9970.4 5896.2 476.3
TABLE 19
HLA- A3 supertype binding affinity (IC50 nM)
Peptide Sequence AA Source Analog A*0301 A*1101 A*3101 A*3301 A*6801
1371.37 TVLWKDΓFHR 10 Her2/neu.l66 A 11439.2 298.9 593.0 83.8 44.7
1371.48 VVFGTLIKK 9 Her2/neu.669 A 32.9 19.9 3776.2 10066.0 28.2
1371.49 WRENTSPK 9 Her2/neu.754 A 98.1 335.9 753.8 1341.2 5698.0
1371.50 VVRENTSPR 9 Her2/neu.754 A 335.2 5618.7 374.5 127.2 203.3
940.08 AC-QVPLRPMTY] 10 HIV.nef.73 A 338.5 731.9
940.11 AQVPLRPMTYK 11 HIV.nef.73 A 56.6 82.6
940.10 RQVPLRPMTYK 11 HIV.nef.73 A 10.1 69.9
31.0116 KTWMDTEGR 9 Lassa.NP.385 8500.8 1131.8 125.7 1902.2 1818.2
31.0117 MLQKEYMER 9 Lassa.gp.414 >3990.12 1371.2 99.9 195.5 33.3
1150.47 EMLRKDYIK 9 LCMV.gp.419 >11595.02 20000.0 1477.1 64.5 >40000
1371.72 AVTETSYVK 9 MAGE2.277 A 410.2 72.8 14064.6 >40215.76 30.8
1371.73 AVΓETSYVR 9 MAGE2.277 A 31700.3 172.8 129.1 1177.5 18.8
1371.75 IVYPPLHEK 9 MAGE2.299 A 44.6 108.7 883.6 3025.6 47.5
1371.74 ΓVYPPLHER 9 MAGE2.299 A 121.3 391.1 102.1 37.2 17.7
1371.71 SVFAHPRR 8 MAGE2.237 A 678.3 1573.3 661.1 630.4 152.3
1371.63 SVFSTT NK 9 MAGE2.69 A 20.8 8.5 3626.3 18804.6 6.0
1371.64 SVFSTTΓNR 9 MAGE2.69 A 60.3 6.8 46.7 89.1 6.9
1371.66 TVΓNYTLWK 9 MAGE2.73 A 358.9 100.9 9126.4 > 17985.04 86.0
1371.65 TVINYTLWR 9 MAGE2.73 A 300.2 81.0 713.0 333.6 14.4
1371.68 LVHFLLLKR 9 MAGE2/3.116 A 340.4 368.3 246.3 92.2 24.3
1371.69 YVFPVΓFSK 9 MAGE3.138 A 24.8 3.3 2922.5 792.1 1.7
1371.70 YVFPVTFSR 9 MAGE3.138 A 37.4 2.8 8.4 13.3 0.5
1371.16 BVYSPALNK 9 p53.124 A 15.8 10.0 448.1 23027.5 801.8
1371.17 BVYSPALNR 9 p53.124 A 27.8 8.5 34.8 85.8 11.3
1371.20 GVRVRAMAIYK 11 p53.154 A 67.2 100.5 431.6 >48333.33 31620.6
1371.21 GVRVRAMAIYR 11 p53.154 A 2401.3 23166.0 136.6 5237.8 5305.0
1371.18 KVFBQLAK 8 p53.132 A 652.5 484.7 6529.2 >48333.33 8474.6
TABLE 19
HLA- A3 supertype binding affinity (IC50 nM)
Peptide Sequence AA Source Analog A*0301 A*1101 A*3101 A*3301 A*6801
1371.15 KVYQGSYGFK 10 p53.101 A 38.5 10.1 139.8 >48333.33 26.7
1371.14 KVYQGSYGFR 10 p53.101 A 37.9 64.2 74.1 10311.3 33.7
1371.31 RVBABPGRDRK 11 p53.273 A 324.7 225.2 4670.7 >48333.33 3530.5
1371.30 RVBABPGRDRR 11 p53.273 A 3195.1 5070.9 183.9 >48333.33 2463.8
1371.22 RVRAMAIYR 9 p53.156 A 45.4 1691.1 9.1 149.3 427.1
1371.24 SVBMGGMNK 9 p53.240 A 14.0 17.1 8933.0 >48333.33 38.0
1371.26 SVBMGGMNR 9 p53.240 A 162.4 96.6 119.3 885.0 11.6
1371.25 SVBMGGMNRK 10 p53.240 A 102.4 54.5 > 17162.33 i >48333.33 12.9
1371.27 SVBMGGMNRR 10 p53.240 A 1030.2 20.2 637.3 1515.0 11.0
1371.32 SVSRHKKLMFK 11 p53.376 A 34.5 61.9 295.8 18555.5 2531.7
1371.33 SVSRHKKLMFR 11 p53.376 A 211.9 2976.9 184.7 1571.2 499.8
-4 IO F029.09 AAMXDTVVFK 10 Naturally processed A 258.8 8.3
F020.06 ASFDKAKLK 9 Naturally processed 43.9 15.8
1023.01 EVAPPEYHR 9 Naturally processed >27500 60000.0 36000.0 78.4 36.4
1023.05 EVTLIDPFHK 10 Naturally processed >22000 4472.1 >180 11581.5 26.7
F023.05 KVVNPLFEK 9 Naturally processed 162.4 8.4
F020.07 KVVNPLPEK 9 Naturally processed 40.6 13.9
S3R RTQNVLGEK 9 Naturally processed 152.8 32.5
F029.l l RVEQAVESMVK 11 Naturally processed 1226.8 57.2
F020.08 SVLNLVIVK 9 Naturally processed 129.8 7.2
952.32 AAAAAAAAAK 10 Artificial sequence A 501.6 49.7
952.42 AAYAAAAAAK 10 Artificial sequence A 26.2 31.3
952.41 AAYAAAAAK 9 Artificial sequence A 23.6 14.7
952.43 AAYAAAAAR 9 Artificial sequence A 125.5 124.8
952.29 AIAAAAAAAK 10 Artificial sequence A 109.6 47.0
952.34 AIAAAAAAR 9 Artificial sequence A 141.6 107.6
952.30 ALAAAAAAAK 10 Artificial sequence A 149.8 50.0
TABLE 19
HLA- A3 supertype binding affinity (IC50 nM)
Peptide Sequence AA Source A Analog A*0301 A*1101 A*3101 A*3301 A*6801
952.39 ALAAAAAAAR 10 Artificial sequence A 366.5 2667.3
4.0105 ALAAAAADK 9 Artificial sequence A 57.7 148.3
981.31 ALAAAAAEK 9 Artificial sequence A 189.7 42.9
4.0106 ALAAAAAFK 9 Artificial sequence A 27.9 13.4
4.0111 ALAAAAANK 9 Artificial sequence A 31.8 17.5
4.0110 ALAAAAAPK 9 Artificial sequence A 19.3 8.3
981.30 ALAAAAAQK 9 Artificial sequence A 61.1 37.5
4.0104 ALAAAAARK 9 Artificial sequence A 21.6 10.5
4.0108 ALAAAAASK 9 Artificial sequence A 38.6 27.4
4.0109 ALAAAAATK 9 Artificial sequence A 19.9 23.3
981.32 ALAAAAAVK 9 Artificial sequence A 131.0 79.0
4.0107 ALAAAAAYK 9 Artificial sequence A 17.0 10.6
4.0094 ALAAAADAK 9 Artificial sequence A 169.1 53.4
4.0095 ALAAAAEAK 9 Artificial sequence A 126.5 65.1
4.0100 ALAAAAFAK 9 Artificial sequence A 15.2 5.7
981.27 ALAAAAIAK 9 Artificial sequence A 113.4 20.7
981.29 ALAAAAKAK 9 Artificial sequence A 100.0 133.3
4.0096 ALAAAALAK 9 Artificial sequence A 39.1 11.8
4.0101 ALAAAANAK 9 Artificial sequence A 51.9 22.9
4.0103 ALAAAAPAK 9 Artificial sequence A 11.7 5.5
981.28 ALAAAAQAK 9 Artificial sequence A 137.5 74.1
4.0102 ALAAAASAK 9 Artificial sequence A 27.6 37.5
4.0099 ALAAAAYAK 9 Artificial sequence A 47.9 10.5
4.0087 ALAAADAAK 9 Artificial sequence A 195.8 556.6
981.24 ALAAAIAAK 9 Artificial sequence A 100.0 15.8
981.25 ALAAAKAAK 9 Artificial sequence A 196.4 600.0
4.0093 ALAAAMAAK 9 Artificial sequence A 57.3 10.3
TABLE 19
HLA- A3 supertype binding affinity (IC50 nM)
Peptide Sequence AA Source A Analog A*0301 A*1101 A*3101 A*3301 A*6801
4.0090 ALAAANAAK 9 Artificial sequence A 35.6 19.3
4.0092 ALAAAPAAK 9 Artificial sequence A 31.2 29.4
4.0089 ALAAAQAAK 9 Artificial sequence A 23.8 13.3
981.26 ALAAASAAK 9 Artificial sequence A 78.6 46.2
4.0091 ALAAATAAK 9 Artificial sequence A 60.0 17.7
4.0088 ALAAAYAAK 9 Artificial sequence A 19.5 5.7
4.0076 ALAADAAAK 9 Artificial sequence A 61.2 113.3
4.0077 ALAAEAAAK 9 Artificial sequence A 46.9 132.5
4.0075 ALAAGAAAK 9 Artificial sequence A 18.8 36.5
1161.16 ALAAGAAAK 9 Artificial sequence A 29.1 32.7 63639.6 >27905.26 2285.7
4.0085 ALAAHAAAK 9 Artificial sequence A 33.1 33.3
4.0078 ALAAIAAAK 9 Artificial sequence A 20.4 13.7
981.22 ALAAKAAAK 9 Artificial sequence A 91.7 111.1
4.0086 ALAALAAAK 9 Artificial sequence A 38.0 61.6
4.0082 ALAANAAAK 9 Artificial sequence A 40.1 93.7
4.0084 ALAAPAAAK 9 Artificial sequence A 13.9 6.9
4.0081 ALAAQAAAK 9 Artificial sequence A 20.3 50.2
981.23 ALAASAAAK 9 Artificial sequence A 186.4 33.3
4.0083 ALAATAAAK 9 Artificial sequence A 38.4 6.8
981.21 ALAAVAAAK 9 Artificial sequence A 91.7 9.2
4.0079 ALAAYAAAK 9 Artificial sequence A 9.9 11
4.0069 ALADAAAAK 9 Artificial sequence A 32.1 13.6
981.17 ALAEAAAAK 9 Artificial sequence A 423.1 54.6
4.0070 ALAFAAAAK 9 Artificial sequence A 11.5 17.7
4.0068 ALAGAAAAK 9 Artificial sequence A 12.7 14.6
981.19 ALAKAAAAK 9 Artificial sequence A 25.6 82.2
981.18 ALANAAAAK 9 Artificial sequence A 78.6 4.7
TABLE 19
HLA- A3 supertype binding affinity (IC50 nM)
Peptide Sequence AA Source Analog A*0301 A*1101 A*3101 A*3301 A*6801
4.0072 ALAPAAAAK 9 Artificial sequence A 12.6 7.0
4.0074 ALAQAAAAK 9 Artificial sequence A 16.0 13.0
4.0073 ALARAAAAK 9 Artificial sequence A 7.3 14
4.0071 ALASAAAAK 9 Artificial sequence A 25.1 11.8
981.20 ALAVAAAAK 9 Artificial sequence A 40.7 18.2
4.0064 ALDAAAAAK 9 Artificial sequence A 121.0 500.0 >73484.69 >54804.85 80000.0
981.15 ALFAAAAAK 9 Artificial sequence A 25.0 22.2 2805.0 96666.7 898.9
4.0066 ALHAAAAAK 9 Artificial sequence A 25.6 28.4 9091.4 >54804.85 20000.0
4.0067 ALIAAAAAK 9 Artificial sequence A 36.7 31.0 >25980.76 >54804.85 2352.9
981.16 ALKAAAAAK 9 Artificial sequence A 122.2 779.2 1450.5 72500.0 80000.0
4.0065 ALMAAAAAK 9 Artificial sequence A 15.6 6.8 6266.8 >83715.79 824.7
-4 Ul 1012.11 ALNAAAAAK 9 Artificial sequence A 60.7 24.0 4751.7 >17985.04 20000.0
4.0060 ALNAAAAAK 9 Artificial sequence A 74.0 20.7 10954.5 >54804.85 80000.0
4.0063 ALPAAAAAK 9 Artificial sequence A 69.9 129.6 90000.0 >54804.85 26666.7
4.0080 ALQAAAAAK 9 Artificial sequence A 57.0 65.1 51961.5 >54804.85 80000.0
1012.10 ALQAAAAAK 9 Artificial sequence A 95.7 68.4 25714.3 >17985.04 80000.0
1012.08 ALRAAAAAK 9 Artificial sequence A 55.0 1474.4 2578.0 96666.7 80000.0
4.0061 ALSAAAAAK 9 Artificial sequence A 44.1 37.5 51961.5 >54804.85 20000.0
4.0062 ALTAAAAAK 9 Artificial sequence A 66.3 125.3 >73484.69 >54804.85 20000.0
981.14 ALYAAAAAK 9 Artificial sequence A 31.4 21.4 3541.0 96666.7 2726.4
952.40 AMAAAAAAAR 10 Artificial sequence A 482.4 2508.7
1022.03 AMAAAAAAH 9 Artificial sequence A 279.4 6396.0
952.36 AMAAAAAAR 9 Artificial sequence A 73.3 288.7
978.01 ASYAAAAAK 9 Artificial sequence A 28.2 11.5
955.04 ATAAAAAAAR 10 Artificial sequence A 662.1 280.5
1022.04 ATAAAAAAH 9 Artificial sequence A 1457.0 218.2
955.03 ATAAAAAAR 9 Artificial sequence A 55.1 39.3
TABLE 19
HLA- A3 supertype binding affinity (IC50 nM)
Peptide Sequence AA Source A Analog A*0301 A*1101 A*3101 A*3301 A*6801
952.28 AVAAAAAAAK 10 Artificial sequence A 456.0 83.0
952.37 AVAAAAAAAR 10 Artificial sequence A 405.5 193.1
952.33 AVAAAAAAR 9 Artificial sequence A 102.5 72.8
952.08 AVAAAAANAK 10 Artificial sequence A 129.6 40.8
952.05 AVAAAAANK 9 Artificial sequence A 11.0 41.4
952.07 AVAAAAIAAK 10 Artificial sequence A 26.9 28.3
952.04 AVAAAAIAK 9 Artificial sequence A 87.6 21.1
952.06 AVAAALAAAK 10 Artificial sequence A 191.5 36.5
952.03 AVAAALAAK 9 Artificial sequence A 65.8 31.5
952.18 AVAKAAAAAK 10 Artificial sequence A 128.3 52.6
952.15 AVAKAAAAK 9 Artificial sequence A 40.2 88.9
-4
©\ 952.02 AVAPAAAAAK 10 Artificial sequence A 48.5 21.8
952.01 AVAPAAAAK 9 Artificial sequence A 51.5 9.6
952.14 AVAPAAAANK 10 Artificial sequence A 44.4 36.4
952.13 AVAPAAAIAK 10 Artificial sequence A 51.6 11.4
952.11 AVAPAAANAK 10 Artificial sequence A 107.7 57.2
952.10 AVAPAAIAAK 10 Artificial sequence A 13.1 20.1
952.12 AVAPAALAAK 10 Artificial sequence A 82.5 10.8
952.09 AVAPALAAAK 10 Artificial sequence A 53.3 15.4
952.20 AVYAAAAAAK 10 Artificial sequence A 55.2 38.7
952.21 . AVYAAAAAAR 10 Artificial sequence A 143.5 76.5
952.19 AVYAAAAAK 9 Artificial sequence A 42.0 36.3
952.22 AVYAAAAAR 9 Artificial sequence A 12.7 40.4
981.03 ELAAAAAAK 9 Artificial sequence A 35.5 79.0 180000.0 72500.0 17.8
1012.01 BLAAAAAAK 9 Artificial sequence A 33.1 46.3
1012.02 MLAAAAAAK 9 Artificial sequence A 13.9 15.0
1012.07 NLAAAAAAK 9 Artificial sequence A 138.3 178.4
TABLE 19
HLA- A3 supertype binding affinity (IC50 nM)
Peptide Sequence AA Source Analog A*0301 A*1101 A*3101 A*3301 A*6801
1012.04 PLAAAAAAK 9 Artificial sequence A 294.0 8017.8 1012.06 QLAAAAAAK 9 Artificial sequence A 205.4 107.4
1012.05 SLAAAAAAK 9 Artificial sequence A 25.2 6.0 1012.03 TLAAAAAAK 9 Artificial sequence A 20.2 80.9
-4 -4
Table 201
HLA- A24 supertype binding affinity (IC50 nM)
Peptide Sequence Source A*2402 A*2301 A*2902 A*3002
1489.06 AATLGFGAY HCV..IV.1264 2240 491
1489.11 AQPGYPWPLY HCV..II.77 133 3.5
1489.05 CSFSIFLLA HCV..IV.172 153 11100
1489.1 LHGPTPLLY HCV..II.1623 180 1075
1489.12 TCGFADLMGY HCV..IV.127 350 356
F185.03 RYLRDQQLL HIV..gp41.583 30
FI 85.05 RYPLTFGWCF HIV..nef.l38 17
78.0346 AFADLTVVY HPV.33.E6.46 425 71 19408 58420
78.0368 AFKDLCrVY HPV.45.E6.48 44911 14034 32 0.49
78.0360 AFKDLFWY HPV.18.E6.48 419 123 37648 24961
78.0246 ATLERTEVY HPV.45.E6.37 >141441 >24519.62 11383 175
-4 oe 78.0023 ATSNYYIVTY HPV.52.E7.50 >65777.37 >22775.44 2117 118
78.0349 AYAACHKCI HPV.45.E6.61 73 60 3300 139
78.0358 CYSLYGTTL HPV.16.E6.87 88 133 13882 >21070.15
78.0379 DYSVYGATL HPV.56.E6.83 33359 2057 1460 19
78.0177 EYRHYCYSLY HPV.16.E6.82 117278 >18738.91 2449 120
78.0354 EYRHYNYSL HPV.58.E6.75 41671 23490 268 1473
78.0185 EYRHYNYSLY HPV.58.E6.75 8139 10625 1774 67
78.0180 EYRHYNYSVY HPV.33.E6.75 45280 22917 16016 253
78.0350 EYRHYQYSL HPV.52.E6.75 72 100 58321 1098
78.0183 EYRHYQYSLY HPV.52.E6.75 8378 1576 2372 130
78.0176 FYSKVRKYRY HPV.56.E6.72 2309 983 146 326
78.0172 FYSKVSEFRW HPV.31.E6.69 8.6 8.8 1777 15220
78.0182 FYSRTRELRY HPV.45.E6.71 356 105 20 150
78.0243 ISEYRHYNY HPV.33.E6.73 125794 >20304.18 1329 32
Table 20
HLA- A24 supertype binding affinity (IC50 nM)
Peptide Sequence Source A*2402 A*2301 A*2902 A*3002
78.0254 ISEYRHYNY HPV.58.E6.73 >99979.17 >24899.09 853 81
1497.13 KFLFTDLRI HPV.52.E6.44 2151 18 2319 1595
78.0357 KFYSKISEY HPV.16.E6.75 97 95 40636 14219
1497.15 KYRYYDYSVY HPV.56.E6.78 169334 86607 17797 2.3
78.0252 LCDLLTRCY HPV.56.E6.99 >113982.57 >25061.21 557 26
78.0372 LFTDLRIVY HPV.52.E6.46 377 156 25003 22
78.0361 LFVVYRDSI HPV.18.E6.52 60761 20899 464 100
78.0378 LFYSKVRKY HPV.56.E6.71 43591 12916 12 89
78.0244 LKEYVLDLY HPV.33.E7.8 >116712.75 >24519.62 127123 16
78.0006 LQDΓEITCVY HPV.18.E6.25 90823 27246 4044 148
78.0027 LSKISEYRHY HPV.58.E6.70 >65777.37 >22775.44 101409 159
78.0019 LSKISEYRHY HPV.52.E6.70 >68154.86 >22775.44 55190 186
78.0348 LYPEPTDLY HPV.33.E7.15 58956 21752 36 71
78.0376 NFACTELKL HPV.56.E6.47 48436 18695 202 1.02
78.0347 NYSVYGNTL HPV.33.E6.80 715 365 >31079.62 36210
78.0356 PYAVCDKCL HPV.16.E6.66 97 20 44214 5713
78.0377 PYAVCRVCL HPV.56.E6.62 51 129 40187 2092
78.0175 PYAVCRVCLL HPV.56.E6.62 133 79 11832 42021
78.0249 QAEQATSNY HPV.52.E7.46 250000 >20304.18 4203 109
1497.12 QFAFKDLCI HPV.45.E6.46 20636 370 >30457.25 >27675.94
78.0005 RFEDPTRRPY HPV.18.E6.3 >66361.54 >22463.51 17839 145
78.0363 RFHNIGGRW HPV.31.E6.124 71804 27530 1595 9.5
78.0375 RFTTNTMGRW HPV.52.E6.124 469 352 >24155.43 >18916.25
78.0359 FHNTRGRW HPV.16.E6.131 53237 11416 18 58
78.0366 RFHNISGRW HPV.33.E6.124 >76072.88 22871 174 37
Table 20
HLA- A24 supertype binding affinity (IC50 nM)
Peptide Sequence Source A*2402 A*2301 A*2902 A*3002
78.0384 RFHNISGRW HPV.58.E6.124 209657 28791 201 35
78.0370 RFHSIAGQY HPV.45.E6.126 52 250 32588 34549
78.0373 RFLSKISEY HPV.52.E6.68 65 93 32015 14086
78.0365 RFLSKISEY HPV.33.E6.68 472 121 34623 23
1497.04 TFCCKCDSTL HPV.16.E7.56 3627 427 >28937.69 22604
78.0250 TSNYYIVTY HPV.52.E7.51 >113982.57 >25061.21 3313 76
78.0174 TYCHSCDSTL HPV.52.E7.58 452 122 29791 30747
78.0353 VFADLRIVY HPV.58.E6.46 499 1336 >35952.44 >19018.22
78.0171 VFEFAFKDLF HPV.18.E6.44 69 8.9 1090 14434
78.0340 VYCKTVLEL HPV.18.E6.33 456 348 >31079.62 15605
78.0364 VYDFAFADL HPV.33.E6.42 >163846.38 >20985.44 163 579 oe © 78.0381 VYDFVFADL HPV.58.E6.42 385 93 27168 27
78.0369 VYGETLEKI HPV.45.E6.85 430 149 12156 13
78.0371 VYKFLFTDL HPV.52.E6.42 35396 1536 1707 27
78.0351 VYNFACTEL HPV.56.E6.45 366 114 >29714.57 12350
78.0002 YSKISEYRHY HPV.16.E6.77 >66361.54 >22463.51 6448 205
78.0009 YSKVSEFRWY HPV.31.E6.70 73696 >22249.75 4514 185
78.0247 YSRTRELRY HPV.45.E6.72 10906 7337 1991 22
1489.22 ALFQEYQCY Pf..CSP.18 149 1032
1489.27 FVVPGAATPY Pf.SSP2.520 317 4621
1489.61 FYFΓLVNLLI Pf..LSA1.9 20 3.7 362 8591
1489.55 YYGKQENWY Pf.CSP.55 2883 19195 373 3155
F185.04 AFLPWHRLF Tyrosinase. 20
1489.18 FVQENYLEY MAGE3.250 3.2 99
1489.16 LVQENYLEY MAGE2.250 13 72
Table 20
HLA- A24 supertype binding affinity (IC50 nM)
Peptide Sequence Source A*2402 A*2301 A*2902 A*3002
1489.15 LVTCLGLSY MAGE2.178 18 4101
1461.06 MEVDPIGHLY MAGE3.167 333 87
F185.06 SYLDSGTHF ..B-catenin.29 50
TABLE 21
A*2402
Peptide Sequence AA Source Analog (IC50 nM)
57.0073 FYNPPTTAKF 10 CEA.27 A 183
57.0037 IYPNASLLF 9 CEA.101 A 2.6
57.0039 LYGPDAPTF 9 CEA.234 A 65
57.0042 LYWVNGQSF 9 CEA.533 A 16
57.0038 LYWVNNQSF 9 CEA.177 A 64
57.0078 QYSWLIDGNF 10 CEA.446 A 63
57.0044 QYSWRINGF 9 CEA.624 A 108
57.0036 RYCIPWQRF 9 CEA.10 A 191
57.0072 RYCTPWQRLF 10 CEA.10 A 59
57.0079 SYLSGANLNF 10 CEA.604 A 11
57.0045 TYACFVSNF 9 CEA.652 A 9.9
57.0075 TYQQSTQELF 10 CEA.276 A 317
57.0041 TYYRPGVNF 9 CEA.425 A 54
57.0076 VYAEPPKPFF 10 CEA.318 A 27
57.0074 VYPELPKPSF 10 CEA.140 A 114
57.0077 YYRPGVNLSF 10 CEA.426 A 12
1081.05 SYVPSAEQI 9 Pf.CSP.280 69
1120.10 TYQRTRALF 9 Flu.NP.147 A 1.5
1120.12 TYQRTRALI 9 Flu.NP.147 A 33
1120.11 TYQRTRALL 9 Flu.NP.147 A 227
57.0049 AYPDSLPDF 9 Her2/neu.414 A 43
57.0050 AYSLTLQGF 9 Her2/neu.440 A 56
57.0048 CYGLGMEHF 9 Her2/neu.342 A 165
57.0051 EYVNARHCF 9 Her2/neu.553 A 150
57.0082 GYSYLEDVRF 10 Her2/neu.832 A 235
57.0053 KYMALESTF 9 Her2/neu.887 A 20
57.0080 LYISAWPDSF 10 Her2/neu.410 A 10
57.0052 PYVSRLLGF 9 Her2/neu.780 A 9.0
57.0059 RYARDPQRF 9 Her2/neu.978 A 120
57.0046 RYGLLLALF 9 Her2/neu.8 A 1.5
57.0058 RYRELVSEF 9 Her2/neu.968 A 37
57.0054 RYTHQSDVF 9 Her2/neu.898 A 60
57.0056 SYGVTVWEF 9 Her2/neu.907 A 28
57.0047 TYLPTNASF 9 Her2/neu.63 A 46
57.0057 VYMIMVKCF 9 Her2/neu.951 A 20
57.0055 VYSYGVTVF 9 Her2/neu.905 A 18
F171.13 NYKRCFPVI 9 Mage4.143 6.1
57.0063 EYLQLVFGF 9 MAGE2.156 A 6.5
57.0087 EYLWGPRALF 10 MAGE2.270 A 10
57.0062 IYSKASEYF 9 MAGE2.150 A 15
57.0061 KYVELVHFF 9 MAGE2.112 A 8.0
57.0085 LYTLVTCLGF 10 MAGE2.175 A 20
57.0060 MYPDLESEF 9 MAGE2.97 A 51
57.0084 SYSTTINYTF 10 MAGE2.70 A 17
57.0088 SYVKVLHHTF 10 MAGE2.282 A 60 TABLE 21
A*2402
Peptide Sequence AA Source Analog (IC50 nM)
57.0064 VYPKTGLLF 9 MAGE2.195 A 6.0
57.0086 VYPKTGLLIF 10 MAGE2.195 A 2.9
57.0068 IYPKAGLLF 9 MAGE3.195 A 9.0
57.0093 IYPKAGLLIF 10 MAGE3.195 A 1.4
57.0067 IYSKASSSF 9 MAGE3.150 A 415
57.0092 LYIFATCLGF 10 MAGE3.175 A 11
57.0066 NYQYEFPVF 9 MAGE3.142 A 3.8
57.0090 NYQYFFPVrF 10 MAGE3.142 A 23
57.0095 SYPPLHEWVF 10 MAGE3.300 A 5.8
57.0065 TYPDLESEF 9 MAGE3.97 A 220
57.0071 SYGFRLGFF 9 p53.106 A 124
57.0096 TYQGSYGFRF 10 p53.102 A 33
57.0070 TYSDLWKLF 9 p53.18 A 5.7
972.05 SYFPEITHI 9 458
996.01 AWAKAAAAF 9 Artificial sequence Poly 373
F030.01 AYAKAAAAAF 10 Artificial sequence Poly 38
1021.01 AYAKAAAAW 9 Artificial sequence Poly A 140
1079.01 KYNPMKTHI 9 Artificial sequence Consensus 56
1086.16 KYPDFVDAL 9 Artificial sequence Consensus 62
F020.09 AYVHMVTHF 9 Naturally processed 23
F020.12 KYPENFFLL 9 Naturally processed 5.5
F020.15 YYEEQHPEL 9 Naturally processed 115
Table 22
ΗLA- B7 supertype binding affinity (IC50 nM)
Peptide Sequence Source B*0702 B*3501 B*5101 B*5301 B*5401
1259.01 GPRLGVRAT HCV.Core.41 128 >39374.41 >23865.72 >48927.08 64167
1468.03 TPLVGAPL HCV.Core.137 25 295 134 7568 598
1468.01 LPALSTGLI HCV.E2.681 427 25792 2580 1036 5778
1468.02 LPCSFTTLPA HCV.NS1/E2.680 981 3145 1854 43849 2.2
78.0396 CPEEKQRHL HPV16.E6.118 10.3 >44991.38 91667 >79732.67 >60017.72
78.0399 CPEEKQRHL HPV31.E6.111 3.0 >44991.38 1982 >79732.67 15717
78.0395 DPQERPRKL HPV16.E6.il 92 >44278.57 4010 >79732.67 >60017.72
78.0397 DPTRRPYKL HPV18.E6.6 111 >44991.38 >35950.78 >79732.67 >69121.86
78.0191 EPQRHTMLCM HPV18.E7.55 337 5482 1824 3258 >53217.09
78.0195 FPYAVCRVCL HPV56.E6.61 148 2253 73 3580 193
78.0197 GPRETLQEIV HPV45.E7.3 348 >34241.87 >29418.5 >81260.68 41613
78.0028 HPEPTDLFCY HPV58.E7.16 >131287.73 3186 18391 346 >62894.33
7.8.0190 TPHAACHKCI HPV18.E6.60 246 >34241.87 2070 3661 3002
78.0398 KPLNPAEKL HPV18.E6.110 20 >44278.57 20215 >79732.67 >60017.72
78.0392 NPQERPRSL HPV56.E6.7 121 33015 246 34824 65361
78.0394 NPTLREYΓL HPV58.E7.5 21 >44991.38 21839 >79732.67 >58997.31
78.0189 NPYAVCDKCL HPV16.E6.65 6755 >34241.87 218 115379 97359
78.0194 NPYGVCTMCL HPV52.E6.58 382 38796 172 11237 30085
78.0402 RPDGQAQPA HPV33.E7.40 13912 11171 383 5497 >60017.72
1495.01 RPRKLPQLCT HPV16R.E6.15 38 >48807.02 >20249.86 >73228.35 79388
78.0393 RPRRRQTQV HPV58.E6.141 275 >44278.57 14963 >79732.67 >58997.31
78.0192 TPHGVCTKCL HPV31.E6.58 38 >34241.87 14667 44608 7724
1495.10 TPTLQDYVL HPV31.E7.5 3175 442 42577 34294 41338
78.0199 VPCCECKFVV HPV56.E7.63 464 21110 174 4882 20
78.0013 YPEPTDLYCY HPV33.E7.16 >131287.73 3133 16160 74 >62894.33
Table 22
HLA- B7 supertype binding affinity (IC50 nM)
Peptide Sequence Source B*0702 B*3501 B*5101 B*5301 B*5401
1143.05 LGFVFTLTV 55000 >72000 27500 24013 464
1125.02 LPFDFTPGF 27500 13 185
1143.04 TAVPWNASW >1018.52 5445 19445 15 20000
TABLE 23
HLA- B7 supertype binding affinity (IC50 nM)
Peptide Sequence AA Source Analog B*0702 B*3501 B*5101 B*5301 B*5401
1196.02 QPRAPΓRPΓPT 11 EBNA.881 109.6 14433.8 1196.03 RPPΓFΓRRL 9 EBNA.379 21.2 55000.0
36.0023 APΓMFSNKM 9 Flu.RRPl.340 91.0
36.0010 APSPYNSRF 9 Flu.NRAM.151 19.9
36.0072 CPVGEAPSPY 10 Flu.NRAM.146 70.3
36.0051 DPDEGTAGV 9 Flu.RRP3.678 119.6
36.0122 DPGNAEFEDL 10 Flu.VNUC.247 222.0
36.0119 DPLAIAANII 10 Flu.VMT2.24 86.4
36.0078 DPNTVSSFQV 10 Flu.NSl.2 10.5
36.0034 DPSHEGEGI 9 Flu.RRP2.294 10.9
36.0114 EPFQSLVPKA 10 Flu.RRP3.578 27.1 oe
©\ 36.0094 EPNGYΓEGKL 10 Hu.RRP2.237 293.7
36.0044 EPNEVGARI 9 Flu.RRP3.168 44.2
36.0107 FPNEVGARΓL 10 Flu.RRP3.168 365.2
36.0019 FPYTGDPPY 9 Flu.RRPl.22 11.3
36.0029 GPATAQMAL 9 Flu.RRPl.540 45.3
36.0024 ΓPAEMLASI 9 Flu.RRPl.368 310.7
36.0088 ΓPEVCLKWEL 10 Flu.RRPl.606 122.7
36.0080 ΓPKQKVAGPL 10 Flu.NS 1.106 42.3
36.0006 BPSIQSRGL 9 Flu.HEMA.338 350.7
36.0067 KPGDTΠFEA 10 Flu.HEMA.252 35.0
36.0059 LPFDRTTVM 9 Flu.VNUC.418 49.0
36.0028 LPSFGVSGI 9 Flu.RRPl.509 36.8
36.0015 LPSLPGHTA 9 Flu.NSl.163 41.3
36.0089 MPAHGPAKNM 10 Flu.RRPl.646 266.7
36.0058 NPAHKSQLV 9 Flu.VNUC.321 2.4
36.0062 NPECDPLLPV 10 Flu.HEMA.81 213.3
TABLE 23
HLA- B7 supertype binding affinity (IC50 nM)
Peptide Sequence AA Source Analog B*0702 B*3501 B*5101 B*5301 B*5401
36.0021 NPRMFLAMI 9 Flu.RRPl.314 25.1
36.0022 QPEWFRNVL 9 Flu.RRPl.329 12.9
36.0013 RPCFWVELI 9 Flu.NRAM.404 67.3
36.0025 RPLLΓEGTA 9 FluJ RP 1.393 140.0
36.0060 SPIVPSFDM 9 Flu.VNUC.473 50.0
36.0103 SPKGVEESSI 10 Flu.RRP2.624 219.0
36.0037 SPQLEGFSA 9 Flu.RRP2.652 63.1
36.0068 TPLGATNSSL 10 Flu.HEMA.298 376.8
36.0079 VPASRYLTDM 10 Flu.NSl.84 42.4
36.0075 YPDTGKVMCV 10 Flu.NRAM.267 422.7
36.0039 YPITADKRI 9 Flu.RRP3.55 40.2 oe
-4 36.0041 YPKIYKTYF 9 Flu.RRP3.lll 75.0
36.0005 YPKLKNSYV 9 Flu.HEMA.175 181.5
1372.03 TPTPSSWAFI 10 HBV.env.324 A 2147.3 767.3 10.7 87.9 1580.2
1372.01 LPSDFFPSI 9 HBV.core.19 A 7935.3 396.6 2.6 5.5 35.1
39.0045 APTLWARI 8 HCV.2869 A 452.5 > 12000 1142.4 >17897.86 13661.2
39.0086 FPYLVAYQI 9 HCV.NS3.1588 A 3990.3 101.5 7.5 5.8 1.1
39,.0044 ΓPLVGAPI 8 HCV.137 A 387.4 >12000 1.6 7282.7 209.3
39.0156 TPQAVVDMVI 10 HCV.E1.340 A 7439.2 1358.1 68.6 135.9 314.3
39.0159 LPATLSPGAI 10 HCV.NS4.1888 A 12114.5 >12000 270.5 >17897.86 167.6
39.0155 LPGCSFSTFI 10 HCV.core.168 A 11224.5 19354.8 144.8 313.3 954.2
39.0043 LPRRGPRI 8 HCV.37 A 49.5 >12000 276.7 >17897.86 3928.6
39.0158 YPCTVNFTII 10 HCV.NS1/E2.623 A 7087.6 1781.8 44.3 146.2 49.0
48.0019 FPGGLREI Her2/neu.l33 A 225.6 >12727.92 3736.2 >19827.67 2062.5 48.0020 FPGGLREL Her2/neu.l33 A 25.7 14814.8 >12963.62 >19827.67 10050.3 48.0144 FPGGLRELQL 10 Her2/neu.l33 A 132.1 >14696.94 >14699.37 2785.2 1625.3 48.0027 FPKANKEI Her2/neu.760 A 64.5 >12727.92 4913.5 >19827.67 3079.8
TABLE 23
HLA- B7 supertype binding affinity (IC50 nM)
Peptide Sequence AA Source Analog B*0702 B*3501 B*5101 B*5301 B*5401
45.0128 LPAARPAGATI 11 Her2/neu.ll57 A 7.0 >13606.72 27.2 5834.3 5952.4
45.0030 LPSETDGI 8 Her2/neu.l l20 A 530.5 >20784.61 496.4 >13152.19 29850.8
34.0264 SPGGLRELQI 10 Her2/neu.l33 A 90.4 >16099.69 7812.5 >10960.16 3587.6
45.0124 SPLDSTFYRSI 11 Her2/neu.998 A 242.8 >18000 2121.6 >93000 5527.9
1146.02 FAVRPQVPL 9 HIV.nef.84 A 1845.7 171.4 526.3 6576.1 4724.6
1146.07 FLVRPQVPL 9 HIV.nef.84 A 10041.6 >0 55000.0 93000.0 100000.0
1181.14 FPVRPQVPC 9 HIV.nef.84 A 7145.6 1623.0 55000.0 12427.7 71.4
1181.12 FPVRPQVPG 9 HIV.nef.84 A 969.3 78.6 55000.0 6711.7 1.9
1181.11 FPVRPQVPK 9 mv.nef.84 A 7489.7 7589.5 >152.78 93000.0 5058.0
1181.09 FPVRPQVPN 9 HTV.nef.84 A 55000.0 3087.0 55000.0 20795.4 6.3
1181.08 FPVRPQVPQ 9 HIV.nef.84 A 7367.7 353.0 >152.78 5858.5 2078.9 oe oe 1181.15 FPVRPQVPT 9 HIV.nef.84 A 830.2 307.0 18333.3 65760.9 1.9
1181.07 FPVRPQVPY 9 HIV.nef.84 A 1833.3 65.5 >152.78 140.9 1717.0
1146.06 FXVRPQVPL 9 HIV.nef.84 A 2690.1 1697.2 278.5 93000.0 5863.7
1372.05 ΓPΓHYCAPI 9 HIV.env.293 A 338.8 1705.6 38.1 190.6 162.8
1292.08 ΓPYNPQSQGI 10 HTV.POL.883 A 1354.8 >34046.7 159.6 56750.6 782.1
1292.04 LPPLERLTI 9 HIV.REV.77 A 2022.3 >32199.38 16.8 4230.7 20576.1
39.0047 SPΓETVPI 8 HIV.pol.174 A 30386.7 >12000 175.7 >17897.86 > 16666.67
1292.11 TPPLVKLWI 9 HtW.POL.601 A >19445.44 189473.7 10.4 >35150.7 >18898.22
39.0087 YPLASLRSI 9 HIV.gag.507 A 185.9 11303.0 13.2 1139.9 49.2
31.0124 ΓPYCNYSKY 9 Lassa.gp.361 >9166.67 189.1 >8109.31 311.1 25000.0
31.0188 ΓPYCNYSKYW 10 Lassa.gp.361 >15877.13 2571.4 >7627.13 262.0 50000.0
34.0186 EPHISYPPI 9 MAGE2.296 A 253.0 > 16099.69 84.6 1135.9 >1639.34 45.0135 GPRALΓETSYI 11 MAGE2.274 A 22.2 >13606.72 852.7 >24855.3 >7715.17 45.0134 HPRKLLMQDLI 11 MAGE2.241 A 66.1 >41569.22 2211.6 40611.4 6747.6 1205.09 VPFSHLYΓL 9 MAGE2.170 A 43.8 93.9 31.3 2649.6 1672.5 1205.11 VPISHLYIA 9 MAGE2.170 A 1184.5 2205.2 518.5 93000.0 1.1
TABLE 23
HLA- B7 supertype binding affinity (IC50 nM)
Peptide Sequence AA Source Analog B*0702 B*3501 B*5101 B*5301 B*5401
45.0139 GPRALVETSYI 11 MAGE3.274 A 11.8 >13606.72 2632.1 >24855.3 >7715.17 34.0188 YPPLHEWVI 9 MAGE3.301 A 124.0
45.0140 APRMPEAAPPI 11 p53.63 A 2.3 >13606.72 1917.1 >24855.3 >7715.17
48.0055 FPALNKMF 8 p53.127 A 228.0 3168.8 17027.9 6254.2 3888.0
48.0234 FPALNKMFCQL 11 p53.127 A 107.5 2714.2 5371.1 8024.2 524.7
48.0123 FPGTRVRAI 9 p53.152 A 5.2 >15350.45 694.2 24603.2 1723.0
48.0196 FPPGSTKRAL 10 p53.299 A 7.4 >8485.28 6395.4 >10960.16 >10000
48.0127 FPQPKKKPI 9 p53.315 A 9.0 >15350.45 >15254.26 >11195.88 16313.2
48.0128 EPQPKKKPL 9 P53.315 A 2.5 >15350.45 >15254.26 >11195.88 >26726.12
34.0191 PPGSTKRAI 9 p53.300 A 118.5 > 16099.69 >9722.72 >10960.16 >6401.84
45.0141 VPSQKTYQGSI 11 p53.97 A 246.6 >13606.72 25229.4 >24855.3 >7715.17 oe 1101.02 ΓPSLALMLI 9 Pf.SHEBA.7 190.7 2964.1 4714.1 vo
39.0048 LPYGRTNI 8 Pf.SSP2.126 A 6857.9 >12000 318.5 45812.8 2308.9
39.0049 TPFAGEPI 8 Pf.SSP2.524 A 5009.1 >12000 359.7 28792.6 633.8
1372.04 TPYAGEPAPI 10 Pf.SSP2.539 A 227.7 2457.2 14.5 162.2 170.3
F001.il APRTLVLYL 9 Naturally processed 5.0
F001.10 APRTYVLLL 9 Naturally processed 3.9
F020.14 YAFNMKATV 9 Naturally processed 55000.0 72000.0 12.7
F029.03 YTNPQFNVY 9 Naturally processed >5500 262.1 >16666.67
980.12 APAKAAAAV 9 Artificial sequence A 8.9 >7200
953.12 AVAKAAAAL 9 Artificial sequence A 32.6 >12000
1086.03 FATPNFYTL 9 Artificial sequence A >13750 200.8 35355.3
1021.04 FPFKYAAAY 9 Artificial sequence A 19445.4 22.6 8.6
1146.23 FPVTFFFAF 9 Artificial sequence A 1664.4 2.7 2.8 2.1 206.7
1146.20 FPVTMFFAA 9 Artificial sequence A >1018.52 450.0 1255.9 7508.7 14.2
1146.13 FPVTMFFAF 9 Artificial sequence A 1467.8 2.1 2.9 1.7 182.3
1146.17 FPVTMEFAI 9 Artificial sequence A 2961.1 20.7 2.4 4.6 1.2
TABLE 23
HLA- B7 supertype binding affinity (IC50 nM)
Peptide Sequence AA Source Analog B*0702 B*3501 B*5101 B*5301 B*5401
1146.18 FPVTMFFAV 9 Artificial sequence A 1897.7 5.8 2.1 114.5 0.2
1146.14 FPVTMFFAW 9 Artificial sequence A 18333.3 5.0 16.8 7.5 226.5
1146.15 FPVTMFFAY 9 Artificial sequence A 55000.0 3.3 19.3 2.9 148.4
1125.03 LPFDYTPGF 9 Artificial sequence A 55000.0 19.8 158.0
1125.06 LPGPYFLQF 9 Artificial sequence A 1672.8 265.1 100000.0
vo ©
Table 24
HLA- B44 supertype binding affinity (IC50 nM)
Peptide Sequence Source B*1801 B*4001 B*4002 B*4402 B*4403 B*4501
69.0007 DEEEAIVAY CMV.E1.379 5.9 >10490.63 >15694.12 6402 1175 12051 69.0066 DEEEAIVAYT CMV.E1.379 77 >910.43 4304 1909 276 91 69.0086 DEEEAJTVAYTL CMV.E1.379 34 95 103 2747 879 5140 69.0006 EEAIVAYTL CMV.E1.381 75 13 24 96 35 .213 69.0008 EEEAIVAYT CMV.E1.380 746 >10490.63 10292 1875 82 94 69.0065 EEEAIVAYTL CMV.E1.380 75 20 84 532 216 164 69.0005 SDEEEAIVA CMV.E1.378 152 8176 21319 2988 10596 666 69.0064 SDEEEAIVAY CMV.E1.378 38 3931 >2387.61 558 395 4721 69.0085 SDEEEAIVAYT CMV.E1.378 175 2462 874 973 616 150 69.0094 SDEEEAIVAYTL CMV.E1.378 193 23 91 862 726 5939 69.0009 DEVEFLGHY EBV.BMLF.376 0.8 >10490.63 19784 3158 96 3193 69.0077 EENLLDFVRF EBV.EBNA6.281 53 12425 5294 59 100 18779 69.0081 EENLLDFVRM EBV.EBNA6.281 824 5150 3191 369 845 8808 69.0034 TEDPPFNSL EBV.lmp2.200 13889 428 21900 >9235.11 >7424.95 >10971.25 69.0052 KEHVIQNAF EBV.EBNA6.335 123 2175 87 6670 1406 12324 69.0039 SENDRLRLL EBV.BZLF1.209 752 432 77 8303 455 5540 69.0055 VEITPYKPT EBV.EBNA4.657 6579 2668 130 9667 5432 1442 69.0054 FEDLRVLSF Hu.NP.338 54 1179 166 730 991 >13709.73 69.0053 GEISPLPSL Flu.NS 1.158 5682 108 124 9347 4158 10242 1479.45 AEDLNLGNLNV HBV.POL.38 >20833.33 3002 522 5210 2292 239 1479.04 AELLAACF HBV.POL.717 1.9 390 55 7.1 22 277 1479.17 AELLAACFA HBV.POL.717 4348 311 21 253 47 8.4 1479.27 DEAGPLEEEL HBV.POL.16 2242 3117 16606 >36027 14799 219 1479.35 EDLNLGNLNV HBV.POL.39 9259 >19.75 >27399.83 >12713.88 >36394.05 47430 1479.07 EEELPRLA HBV.POL.22 >31250 >54.39 >978.7 11201 30535 517
Table 24
HLA- B44 supertype binding affinity (IC5Q nM)
Peptide Sequence Source B*1801 B*4001 B*4002 B*4402 B*4403 B*4501
1479.16 EELGEEIRL HBV.X.121 41667 275 295 2158 251 230 1479.18 TDWKVCQRI HBV.POL.617 >34482.76 41395 303 >11630.67 >31732.28 448 1479.10 LDSWWTSL HBV.ENV.195 >31250 78143 422 >6146.26 37542 38333 1479.36 LDSWWTSLNF HBV.ENV.195 3559 381 534 3652 10321 14054 1479.41 LDSWWTSLNFL HBV.ENV.195 28571 4040 242 4148 5013 1567 1479.05 LDTASALY HBV.NUC.31 198 >43041.42 25994 922 7684 >39859.26 1479.11 LDVSAAFY HBV.POL.417 387 >46169.74 44544 1534 11913 50317 1479.21 LDYQGMLPV HBV.ENV.261 24390 >51.1 3.2 >29516.17 >30259.67 >32837.14 1479.12 LEEELPRL HBV.POL.21 174 27477 223 >6146.26 45455 3287 1479.22 LEEELPRLA HBV.POL.21 18519 >46371.3 2681 >29516.17 41432 196 1479.19 RDLLDTASA HBV.NUC.28 38462 40661 206 >11630.67 5077 382 o 1479.31 RDLLDTASAL HBV.NUC.28 >30303.03 1526 O 424 >17359.64 >28814.23 >35815.39 1479.40 RDLLDTASALY HBV.NUC.28 >27027.03 54528 1891 405 204 32522 1479.25 RDVLCLRPV HBV.X.13 >34482.76 538 36 >39949.81 624 52946 1479.01 RETVLEYL HBV.NUC.141 21739 303 30 18054 9268 15626 1479.15 RETVLEYLV HBV.NUC.141 20833 219 59 25309 3910 230 1479.44 TDNSVVLSRKY HBV.POL.736 >20833.33 269 12127 3452 2605 4269 1479.47 VELLSFLPSDF HBV.NUC.42 134 2956 283 227 333 8264 1479.03 WEELGEEI HBV.X.120 20000 305 370 9950 19970 30734 1479.29 WEELGEETRL HBV.X.120 >30303.03 27 226 2202 412 33947 64.0143 ADLEVVTSTW HCV.Entire.1656 863 >10429.64 9853 724 221 >12141.28 64.0060 ADLMGYLPL HCV.Entire.131 >2150.54 778 10 >15730.34 >6343.71 >9931.94 64.0022 AEAALENL HCV.Entire.749 >2132.2 620 109 20896 390 529 64.0061 AEAALENLV HCV.Entire.749 >2150.54 130 63 23179 250 40 64.0029 AETAGARL HCV.Entire.1341 >2132.2 109 132 >12635.38 3704 6484
Table 24
HLA- B44 supertype binding affinity (IC50 nM)
Peptide Sequence Source B*1801 B*4001 B*4002 B*4402 B*4403 B*4501
64.0069 AETAGARLV HCV.Entire.1341 >2188.18 7782 809 >15625 5629 116 64.0145 AETAGARLVV HCV.Entire.1341 >2024.29 4338 244 >11345.22 9910 110 64.0177 AETAGARLVVL HCV.Entire.1341 >2066.12 59 53 14433 2732 577 64.0030 CDELAAKL HCV.Entire.1405 219 7178 5587 1132 10185 >10913.04 64.0136 CECYDAGCAW HCV.Entire.1523 802 >10429.64 9798 948 317 16082 64.0168 CECYDAGCAWY HCV.Entire.1523 93 12623 20016 479 275 8594 64.0070 CEKMALYDV HCV.Entire.2623 2421 13063 644 8537 9291 109 64.0146 CEKMALYDVV HCV.Entire.2623 5587 9400 111 9211 10913 92 64.0063 EDLVNLLPA HCV.Entire.1882 >2188.18 >12687.98 1318 >15625 >6329.11 500 64.0031 GDLCGSVF HCV.Entire.278 1592 >11264.46 81 9818 9338 >10913.04 64.0187 GEGAVQWMNRL HCV.Entire.1914 >2066.12 402 422 >14613.78 15850 >12443.44 J 64.0076 GETPFYGKA HCV.Entire.1376 >2188.18 1196 68 21807 6440 46 64.0151 GETPFYGKAI HCV.Entire.1376 >2227.17 78 51 7761 91 6057 69.0038 GQIVGGVYL HCV.cAg.27 14286 15 37 681 1257 9032 64.0181 TEANLLWRQEM HCV.Entire.2236 213 76 69 1246 5647 15152 1472.01 LEDRDRSEL HCV.NS1/E2.654 >8621.97 129 184 >34204.99 46064 >40390.98 64.0034 LEVVTSTW HCV.Entire.1658 94 7549 913 742 2927 >10913.04 64.0074 LEVVTSTWV HCV.Entire.1658 2188 634 144 11345 10496 7890 64.0147 LEVVTSTWVL HCV.Entire.1658 1006 8.8 8.7 3338 2304 12472 64.0183 LEVVTSTWVLV HCV.Entire.1658 1101 128 99 4037 1634 874 64.0024 SELSPLLL HCV.Entire.665 2336 519 110 11094 553 7011 64.0077 TEAMTRYSA HCV.Entire.2793 1160 9053 145 1686 5832 60 64.0078 VDFSLDPTF HCV.Entire.1467 2304 >11338.36 145 16241 9565 >11766.22 64.0188 VDFSLDPTFTI HCV.Entire.1467 >2066.12 >10037.87 68 27778 17350 >12443.44 64.0040 VDYPYRLW HCV.Entire.614 >2136.75 34027 15625 >11146.5 417 >10913.04
Table 24
HLA- B44 supertype binding affinity (IC50 nM)
Peptide Sequence Source B*1801 B*4001 B*4002 B*4402 B*4403 B*4501
64.0018 AEHLKTAV HIV.POL.921 1289 6271 23 1019 1395 1267
64.0126 AEHLKTAVQM HTV.POL.921 >2096.44 96 78 7384 1008 943
64.0165 AEHLKTAVQMA HlV.POL.921 >1945.53 8411 982 >8951.41 7514 122
64.0162 AELELAENREI HIV.POL.488 > 1945.53 706 561 7675 90 98
69.0078 AENLWVTVYY HTV.gpl20.1 79 277 89 43 13 275
64.0048 AETFYVDGA mV.POL.629 >2136.75 11491 1131 >11146.5 5601 43
69.0062 AETFYVDGA HTV.RT.592 >9090.91 3350 1406 2587 3493 114
64.0016 AETGQETA HIV.POL.843 >2257.34 666 546 >11608.62 231 1064
64.0124 AETGQETAYF HIV.POL.843 >4504.5 6489 1287 7559 387 8634
64.0045 EEKAFSPEV HIV.GAG.181 2083 14512 112 6869 7597 57
64.0113 EEKAFSPEVI HIV.GAG.181 >1992.03 14811 4130 8537 7524 253
64.0115 EEMMTACQGV HIV.GAG.368 >1992.03 9474 6155 5613 2066 125
64.0053 GDAYFSVPL HIV.POL.301 2899 1430 7.5 16949 >6343.71 >15983.85
64.0014 GEAMHGQV HIV.POL.799 >2331 836 200 >11844.33 >9259.26 8943
64.0011 ΓEAEVΓPA HIV.POL.836 41 3166 36 654 8209 389
64.0001 ΓEAQQHLL HIV.ENV.645 58 31 28 6034 1252 > 12770
64.0010 TETVPVKL HIV.POL.191 >2013.01 34 79 1275 3205 >12770
64.0003 KDCTERQA HTV.GAG.457 >2012.07 >1762.29 553 >10401.19 41 42373
64.0133 KEPPFLWMGY HIV.POL.412 >2024.29 >9386.68 883 3045 10.0 14286
64.0119 LELAENRETL HIV.POL.490 >2096.44 9.3 233 > 12567.32 11555 17915
64.0017 NEQVDKLV HTV.POL.737 233 >3032.82 1297 >11608.62 >6699.15 15318
64.0009 NETPGΓRY HIV.POL.326 19 >1762.29 31250 12080 1911 > 12770
64.0117 NETPGΓRYQY mV.POL.326 58 >12044.75 >11524.1 57 50 11853
64.0012 QDFWEVQL HIV.POL.274 >2012.07 1080 165 1534 >9369.68 >28690.23
69.0010 RDYVDRFYK HIV.Gag.292 6250 >10972.49 >2119.25 339 >7635.83 >21942.68
Table 24
HLA- B44 supertype binding affinity (IC50 nM)
Peptide Sequence Source B*1801 B*4001 B*4002 B*4402 B*4403 B*4501
64.0046 REPRGSDIA HIV.GAG.250 >2136.75 >12747.77 863 >11146.5 >6970.85 402 64.0002 SELYKYKV HTV.ENV.559 >2012.07 284 135 4192 4808 8845 64.0044 SELYKYKVV HTV.ENV.559 3436 12904 97 10903 4898 988 64.0128 TDSQYALGΠ HIV.POL.689 308 6306 442 7830 11506 1218 64.0013 TEEKΓKAL HIV.POL.214 1339 356 769 723 >11506.28 >12770 64.0005 TERQANFL HTV.GAG.460 56 118 14 3319 266 10922 64.0052 WEFVNTPPL fflV.POL.606 1.9 1.4 5.0 55 305 5848 64.0121 WEFVNTPPLV HTV.POL.606 272 60 34 8304 9683 7237 64.0163 WEVQLGΓPHPA HIV.POL.277 14 697 73 5872 5972 532 64.0019 YELHPDKW HIV.POL.421 418 512 504 1547 159 >12767.93 64.0129 YELHPDKWTV HIV.POL.421 891 123 9.4 4411 11022 7453 vo 78.0225 HPV45.E7.81 >24738.53 95 107 3905 297 175
Ul AEDLRTLQQL 78.0215 AEPDTSNYNI HPV31.E7.45 >24738.53 1619 2024 1243 343 1398 78.0417 AEPQRHTML HPV18.E7.54 5.1 1781 22 51 20 21310 78.0440 AEQATSNYY HPV52.E7.47 12070 326 1486 3006 177 1608 78.0228 AEQATSNYYI HPV52.E7.47 10638 291 51 92 104 15.3 78.0210 AERPRKLHEL HPV31.E6.6 14213 23648 273 14997 21440 2945 78.0418 CEARIELVV HPV18.E7.68 0.1 132 1.4 14 16 2162 78.0446 CECKFVVQL HPV56.E7.66 660 6966 401 303 21 34 78.0420 DELRLNCVY HPV31.E6.24 >29424.49 >26772.48 29013 9304 25837 47 78.0217 EEKPRTLHDL HPV33.E6.6 >24738.53 19236 20016 11593 24273 470 78.0432 EENDEADGV HPV45.E7.37 5530 1429 422 13466 17582 4525 78.0416 EENDETDGV HPV18.E7.36 1848 172 674 33228 17141 42422 78.0434 EESVHEΓRL HPV52.E6.20 134 8354 49 1828 18444 44717 78.0239 FEDPTRRPY HPV18.E6.4 13 592 40 147 205 450
Table 24
HLA- B^ supertype binding affinity (IC50 nM)
Peptide Sequence Source B*1801 B*4001 B*4002 B*4402 B*4403 B*4501
78.0206 FEFAFKDLFV HPV18.E6.45 2.0 100 2.0 956 174 3006 78.0419 HELSSALEI HPV31.E6.13 16737 187 256 2022 20691 25882 78.0232 KEDLRVVQQL HPV56.E7.80 >7860.62 502 44 12913 2608 3447 78.0435 KELQRREVY HPV52.E6.35 19090 50 44 17557 >32308.25 29973 78.0442 KELTRAEVY HPV56.E6.38 7699 2122 275 25736 15174 >36998.68 78.0202 LECVYCKQQL HPV16.E6.35 6984 175 135 11658 1472 41639 78.0436 LEERVKKPL HPV52.E6.88 24398 3.0 5.4 18172 1347 4031 78.0226 LEESVHETRL HPV52.E6.19 12371 123 1679 16032 28988 18357 78.0230 LEΓPLΓDLRL HPV56.E6.22 4485 42 7.3 8457 206 30242 78.0211 LEΓPYDELRL HPV31.E6.19 11987 1495 303 27643 2325 31587 78.0421 LEKLTNKGI HPV31.E6.88 37139 5442 291 >20466.26 >33599.1 20543 78.0208 LEKLTNTGLY HPV18.E6.90 861 162 6702 622 2639 31186 78.0444 LELTPQTEI HPV56.E7.13 3998 6461 20 2540 2716 243 78.0447 LEQTLKKCL HPV58.E6.88 53 1411 16 2674 200 313 78.0424 LEQTVKKPL HPV33.E6.88 171 1110 164 4453 249 236 78.0428 LERTEVYQF HPV45.E6.39 3675 15300 7845 1772 222 >35147.94 78.0443 LESITKKQL HPV56.E6.91 74 122 6.1 242 55 176 78.0234 LETSVHEIEL HPV58.E6.19 627 25 38 11547 2247 6385 78.0218 LETTIFTNTEL HPV33.E6.19 4384 129 166 19310 16586 5337 78.0425 NEΓLIRCII HPV33.E6.97 1830 154 34 2071 209 3646 78.0448 NEΓLΓRCII HPV58.E6.97 88 34247 22716 465 1332 >37221.52 78.0414 NEKRRFΉNI HPV18.E6.122 212 150 31 2387 2336 2044 78.0431 NELDPVDLL HPV45.E7.19 25 384 41 2094 233 451 78.0423 PEATDLHCY HPV31.E7.17 >29424.49 237 2334 21016 25172 24308 78.0450 PEPTDLFCY HPV58.E7.17 5453 259 201 1723 3110 37844
Table 24
HLA- B44 supertype binding affinity (IC50 nM)
Peptide Sequence Source B*1801 B*4001 B*4002 B*4402 B*4403 B*4501
78.0426 QEKKRHVDL HPV33.E6.113 2.4 8491 37113 337 170 14157 78.0449 QEKKRHVDL HPV58.E6.113 >8621.97 1051 1869 2361 474 >37221.52 78.0216 QELLMGSFGI HPV31.E7.80 1699 285 180 204 153 259 78.0200 QERPRKLPQL HPV16.E6.13 >23870.5 15331 304 39234 28466 2241 78.0229 QERPRSLHHL HPV56.E6.9 >7860.62 5752 494 6089 13937 2590 78.0207 RELRHYSDSV HPV18.E6.76 7363 1196 29 68524 20650 2086 78.0221 RELRYYSNSV HPV45.E6.76 >8264.75 895 19 16950 17558 410 78.0430 RETLQEIVL HPV45.E7.5 2611 2025 55 388 255 32285 78.0213 SEFRWYRYSV HPV31.E6.74 9.4 274 2.8 197 21 35 78.0437 SEITTRCII HPV52.E6.97 3183 456 409 6602 1721 3763 78.0441 SEVLETPLI HPV56.E6.19 446 28851 6049 238 262 32935
VO ~4 78.0203 SEYRHYCYSL HPV16.E6.81 133 16 13 1498 175 202 78.0235 SEYRHYNYSL HPV58.E6.74 64 9.4 3.6 1124 185 181 78.0219 SEYRHYNYSV HPV33.E6.74 132 1312 17 15814 2842 30 78.0227 SEYRHYQYSL HPV52.E6.74 97 15 14 228 289 290 78.0205 TELNTSLQDI HPV18.E6.19 12897 180 1691 5408 1129 11464 78.0212 TETEVLDFAF HPV31.E6.38 25 2114 244 192 41 41087 70.0055 AEDLYGRLEI Pf.LSA1.1649 >1532.81 1095 940 447 366 913 64.0089 DEFKPIVQY Pf.LSA1.1783 1.2 >11338.36 >14084.51 9.2 324 >13736.27 70.0030 DEIKYREEV Pf.SSP2.34 250 >2015.33 7984 11200 >7003.42 3856 70.0057 DELSEDITKY Pf.LSA1.1896 131 >1553.5 >1992.04 5254 5756 >9479.14 70.0044 DENANANNAV Pf.CSPZ.333 120 >1811.7 2007 >8127.24 >7997.92 1106 70.0031 DEVDLYLLM Pf.SSP2.45 5.6 1555 603 787 68 >10605.18 70.0064 EENIGTYKEL Pf.LSA1.1797 >1728.24 1704 1776 31 460 367 70.0080 EEVCNDEVDL Pf.SSP2.40 2788 434 1870 5723 8026 10252
Table 24
HLA- B44 supertype binding affinity (IC50 nM)
Peptide Sequence Source BH801 B*4001 B*4002 B*4402 B*4403 B*4501
70.0081 GEPAPFDETL Pf.SSP2.531 >10869.57 7.6 13 10558 6848 >8615.59 70.0050 GEPLΓDVΉDL Pf.PfEXP-1.44 93 70.0069 KEGKLΓEHII Pf.LSA1.119 2086 631 124 360 3794 11531 70.0070 KEKEKFIKSL Pf.LSA1.1872 3732 1039 190 7933 >6331.06 >8900.42 64.0101 KEKFIKSLF Pf.LSA1.1874 >1968.5 7156 65 23810 814 11702 70.0071 LDEFKPΓVQY Pf.LSA1.1782 2019 96 111 7022 >6331.06 >8747.17 70.0072 LEEKAAKETL Pf.LSA1.149 156 >1491.97 >3937.13 >10838.73 6799 >8747.17 64.0103 LETVNTSDV Pf.LSA1.1744 >1968.5 7497 122 >16055.05 >6892.23 689 70.0034 NDEVDLYLL Pf.SSP2.44 181 27419 5292 10590 3782 >10343.38 70.0082 NDEVDLYLLM Pf.SSP2.44 7.3 1141 153 1616 296 16119 70.0048 NDΓEKKICKM Pf.CSPZ.401 1220 1947 937 4833 11254 429 vo oe 70.0046 NELNYDNAGI Pf.CSPZ.36 1486 2194 13820 80 58 513 64.0106 QDEENIGIY Pf.LSA1.1795 23 >12506.23 >11940.49 2088 10358 9016 70.0083 QDSLKESRKL Pf.SSP2.169 >1357.89 12 5.0 330 386 105 70.0014 QERLANEKL Pf.LSA1.1527 814 764 368 2882 766 7733 70.0015 QERRAKEKL Pf.LSA1.1578 >1901.31 1729 24 4159 4151 11761 70.0039 RENANQLW Pf.SSP2.150 244 92 12 564 388 42 70.0019 SDLEQDRLA Pf.LSA1.1387 235 >2000.2 4867 >20582.18 4864 >10316.53 70.0024 SEELSEEKI Pf.LSA1.1827 165 89 1486 545 126 4205 70.0041 SEKEVPSDV Pf.SSP2.371 153 >2015.33 122 8130 >7003.42 777 70.0025 SENERGYYI Pf.LSA1.1665 97 1983 133 114 74 378 64.0112 SESNGEPNA Pf.PfEXP-1.127 >2247.19 >12506.23 8207 >8805.03 >9632.22 121 70.0043 WDEWSPCSV Pf.SSP2.247 155 >2015.67 608 15002 6735 >10827.8 70.0026 YEDEISAEY Pf.LSA1.1760 11 2082 7805 3574 459 >10402.05 70.0027 YEKTKDNNF Pf.LSA1.1841 2318 >4032.11 152 958 11674 6691
Table 24
HLA- B44 supertype binding affinity (IC50 nM)
Peptide Sequence Source B*1801 B*4001 B*4002 B*4402 B*4403 B*4501
64.0086 YENDΓEKKI Pf.CSPZ.399 2278 933 133 10938 574 9481 69.0037 SESPIWVL Rat..45 144 16 72 505 619 881 69.0063 AEEAAGIGI >9090.91 23 565 492 140 67 69.0084 AEEAAGIGTL 12195 17 36 3085 926 73 69.0093 AEEAAGIGTLT >5780.35 418 524 4732 686 175 69.0025 AEIGEVIVL 9615 5.6 3.6 92 28 91 69.0070 AEIGEVIVLW 1026 38 18 369 17 97 69.0090 AEIGEVIVLWL 10530 13 39 3303 7.5 336 69.0027 AEIPGEIAL 9524 3.3 5.7 1114 150 1086 69.0075 AEVDKVTGRF 10638 1891 821 416 4152 2005 69.0051 DEAPAVISY 0.9 2977 17056 508 70 11189 69.0049 DEFIGVAIY 0.7 14509 1100 2677 14 16200 69.0050 DENPLVKQY 9.2 989 9799 312 124 >12676.78 69.0045 DEVGTVTKY 4.6 2597 >15074.52 651 45 >12676.78 69.0076 DEVPDLERKY 101 4688 186 69 286 >14076.63 69.0041 EEFQFIKKA 100 12484 37 129 60 73 69.0022 EEFYVDLER 12658 5173 14825 10360 367 6137 69.0058 EEKLIVVAF 1.0 863 184 68 52 806 69.0059 EEKLTVVLF 4.8 1430 208 44 17 709 69.0029 FETPLLDVA 115 704 7.8 3058 11766 61 69.0048 FEPTVVKKY 1294 >1905.51 882 678 63 >12676.78 69.0040 GEFGGFGSV 19608 1438 241 4580 1222 7707 69.0020 GEFTPGNDL 9524 20 146 10874 2299 14142 69.0018 GEFPGKΓFL 8264 30 107 11014 457 >14176.58 69.0069 GEFPGKTFLY 85 15 14 44 6.4 6986
Table 24
HLA- B44 supertype binding affinity (IC50 nM)
Peptide Sequence Source B*1801 B*4001 B*4002 B*4402 B*4403 B*4501
69.0089 GEFPGKΓFLYA 762 184 16 3793 14 1926 69.0017 GEFPNKNTL 20833 14 25 5117 872 31325 69.0068 GEFPNKNTLY 428 280 149 458 70 >12241.78 69.0088 GEFPNKNLLYA 7463 457 48 14551 971 2442 69.0004 GEFSITYK 10870 646 176 4102 782 11469 69.0002 GEFVDLYV 8696 362 1130 8873 14192 45707 69.0042 GEHGLΠRV >11363.64 39 3.2 3215 174 375 69.0028 GETLDVFDA 15625 419 15 12689 3939 56 69.0026 GEVIVLWLW 1230 652 9.0 178 26 5584 69.0073 HEATLRCWAL 106 16 12 1291 5512 8909 to
© 69.0092 TEVDPDTKEML >9009.01 409 4054 >8202.43 9586 >21808.92 © 69.0031 KESTLHLVL 12658 136 119 2251 1895 16607 69.0091 KEVGVDVALYA 12658 97 56 >8681.62 419 716 69.0057 MEVDPIGHL 434 24 23 850 188 1105 69.0079 MEVDPIGHLY 6.4 599 555 6.0 23 256 69.0033 REIAQDFKT >12658.23 67 119 7115 1408 1562 69.0072 REIAQDFKTD 13158 45 1497 8272 11532 2012 69.0003 REITTNAV 189 346 14 8136 7702 451 69.0043 REMTPFADI 8333 4.9 8.5 176 129 8.7 69.0015 REPVTKAEM >11363.64 167 138 8436 6021 24162 69.0044 SETDTVAKY 74 861 5709 367 338 1948 69.0056 SEIWRDTDF 47 30 44 205 10.1 197 69.0016 TEFPKERHL 8475 1248 100 10793 599 22219 69.0019 WEFLQPLLL 7.5 0.8 1.0 176 31 5200 69.0036 YETHDGMNL 12821 9.3 14 6897 1711 31404
TABLE 25
%
Sequence Source Motif Conservation
FPDWQNYTPGPGIRY HIV.nef.200 DRsuper 23
FPDWQNYTPGPGTRF HIV.nef.200 DRsuper 20
GFPVRPQVPLRPMTY HIV.nef.93 DRsuper 56
GGKWSKSSIVGWPAI HIV.nef.2 DRsuper 8
GPGIRYPLTFGWCFK HIV.nef.210 DRsuper 9
HGAITSSNTAATNAD HIV.nef.61 DRsuper 16
ILDLWVYHTQGFFPD HTV.nef.186 DRsuper 20
ILDLWVYHTQGYFPD HlV.nef.186 DRsuper 33
NNCLLHPMSQHGMDD HIV.nef.254 DRsuper 9
NNSLLHPICQHGMED HIV.nef.254 DRsuper 6
RFPLTFGWCFKLVPV HIV.nef.216 DRsuper 19
RPQVPLRPMTYKGAF HTV.nef.98 DRsuper 11
RQDILDLWVYHTQGY HlV.nef.182 DRsuper 14
RQDILDLWVYNTQGY HlV.nef.182 DRsuper 8
RQEILDLWVYHTQGF HlV.nef.182 DRsuper 16
RQEILDLWVYHTQGY HlV.nef.182 DRsuper 19
RYPLTFGWCFKLVPV HIV.nef.216 DRsuper 24
SRDLEKHGAITSSNT HIV.nef.50 DRsuper 20
TFGWCFKLVPVDPRE HIV.nef.222 DRsuper 11
AEPVPLQLPPLERLT HTV.rev.72 DRsuper 16
IKFLYQSNPPPSPEG HIV.rev.21 DRsuper 6
LKAVRirKILYQSNP HIV.rev.13 DRsuper 9
PVPLQLPPLERLTLD HTV.rev.74 DRsuper 20
LEPWKHPGSQPKTAC HIV.tat.l l DRsuper 17
LEPWNHPGSQPKTAC HIV.tat.ll DRsuper 17
LEPWNHPGSQPRTPC HIV.tat.l l DRsuper 5
LEPWNHPGSQPTTAC HIV.tat.ll DRsuper 11
NNCYCKKCCFHCQVC HIV.tat.26 DRsuper 6
QLCFLKKGLGISYGR HTV.tat.38 DRsuper 5
QVCFITKGLGISYGR HIV.tat.38 DRsuper 11
QVCFLNKGLGISYGR HIV.tat.38 DRsuper 6
TNCYCKKCCYHCQVC HIV.tat.26 DRsuper 3
LDGLIYSKKRQEILD HlV.nef.171 DR3 17 TABLE 25
LSFFLKEKGGLDGLI HlV.nef.114 DR3 22
LSHFLKEKGGLEGLI HTV.nef.114 DR3 23
QDAVSQDLDKCGAAA HIV.nef.51 DR3 2
TQGFFPDWQNYTPGP HlV.nef.195 DR3 27
TQGYFPDWQNYTPGP HIV.nef.195 DR3 52
TRQARKNRRRRWRAR HIV.rev.38 DR3 20
TRQARRNRRRRWRAR HIV.rev.38 DR3 28
TRQARRNRRRRWRER HIV.rev.38 DR3 19
KEKVERETETDPAVQ HIV.tat.95 DR3 2
Table 26
Peptide Sequence AA Source Analog DRB1*0101 DRB5*0101 DRB1*1501 DRB1*0301 DRB1*0401
58.0015 LWWVNNESLPVSPRL 15 CEA.177. A 310
F168.09 TRNLALQTLPAMCNVY 20 Gliadin.235.
F168.05 VQQQQFLGQQQPFPPQ 20 Gliadin.25.
F168.06 QFLGQQQPFPPQ 20 Gliadin.29.
FI 16.01 MDTDPYKEFGATVELLSFLPSDFFI 25 HBVcore.l. 1563 957
FI 64.04 LPETTVVRCRGRSPR 17 HBVcore.143.
F164.12 TNMGLKFRQLLWFHI 25 HBVcore.91.
F164.ll TNVGLKFRQLLWFH1 25 HBVcore.91. 1491 836
RS-21 GP41584-609 26 fflVlgp.. 1250 9100 ffi-θ PEFLEQRRAAVDTYC 15 LEBs2.. 5000
68.0001 MWDLVLSIALSVGCT 15 Kallikrein2.1. 205 11375 10386
68.0009 NMSLLKHQSLRPDED 15 Kalli rein2.102. 3131
IO
© 68.0010 SHDLMLLRLSEPAKI 15 Kalli rein2.118. 56 2031 365 2396 12622
OJ
'68.0011 HDLMLLRLSEPAKIT 15 Kallikrein2.119. 16 211 115 1406
68.0015 PEEFLRPRSLQCVSL 15 Kallikreirώ.162. 2001 3193
68.0016 PRSLQCVSLHLLSND 15 Kallikreirώ.168. 1111 1597
68.0140 LHLLSNDMCARAYSE 15 Kallikreirώ.176. 2104 938
68.0017 NGVLQGITSWGPEPC 15 Kallikreirώ.220. 1093 835
68.0018 KPAVYTKVVHYRKWI 15 Kallιkreirώ.239. 5000 23 401 8061
68.0002 DLVLSIALSVGCTGA 15 Kallikreirώ.3. 1197 18200
68.0003 HPQWVLTAAHCLKKN 15 Kallikrein2.56. 22 11 1219 1103 4922
68.0004 QWVLTAAHCLKKNSQ 15 Kallikrein2.58. 895 382
68.0005 GQRVPVSHSFPHPLY 15 Kallikrem2.87. 1563 3960
68.0006 RVPVSHSFPHPLYNM 15 Kallikreirώ.89. 67 11650 5518
68.0007 PHPLYNMSLLKHQSL 15 Kallikrein2.97. 1901 3873 4607
68.0008 HPLYNMSLLKHQSLR 15 Kallikreirώ.98. 232 219 472 13007 2807
FI 18.02 LVrPENAKEKPQEGT 15 M.leprae.28. 1876 827
Table 26
Peptide Sequence AA Source Analog DRB1*0101 DRB5*0101 DRB1*1501 DRB1*0301 DRB1*0401
F006.15 ENPVVHFFKNIVTPR 15 MBP.85. 463 5.2
F006.21 ENPVVAFFKNIVTPR 15 MBP.85.SAAS SAAS 302 2.8
F006.22 ENPVVHAFKNIVTPR 15 MBP.85.SAAS SAAS 910 2.7
F006.24 ENPVVHFFANΓVTPR 15 MBP.85.SAAS SAAS 6235 2.9
F006.30 ENPVVHFFKNIVTPA 15 MBP.85.SAAS SAAS 3333 2.5
F006.31 NPVVHFFKNTVT 12 MBP.86. 10000 23
F006.34 NPVVITRFKNTVTPR 14 MBP.86. 1890 3.7
F006.321 HFT^KNTVTPRTPPY 14 MBP.90. 377 460
68.0030 DRTLMSAMTNLAALF 15 PAP.110. 97 871 72
68.0031 MSAMTNLAALFPPEG 15 PAP.114. 1757 12384 3935
68.0032 MTNLAALFPPEGVSI 15 PAP.117. 24 10370
68.0033 PEGVSΓWNPΓLLWQP 15 PAP.126. 111 7.2 10000
IO
© 68.0034 GVSΓWNPΓLLWQPIP 15 PAP.128. 44 523 5.0
Ul
68.0022 SLSLGFLFLLFFWLD 15 PAP.13. 11417 11375
68.0035 WNPTLLWQPΓPVHTV 15 PAP.132. 208 14 3908
68.0036 NPΓLLWQPΓPVFTTVP 15 PAP.133. 31 4.6 1160
68.0037 PTLLWQPΓPVHTVPL 15 PAP.134. 44 6.9 1451
68.0038 ΓLLWQPΓPVHTVPLS 15 PAP.135. 45 65 957
68.0039 WQPTPVHTVPLSEDQ 15 PAP.138. 6386
68.0147 TVPLSEDQLLYLPFR 15 PAP.145. 4012 332
68.0040 LSGLHGQDLFGΓWSK 15 PAP.194. 148
68.0023 LLFFWLDRSVLAKEL 15 PAP.21. 2.9 134 34 6.3 15
68.0041 YDPLYCESVFTNFTLP 15 PAP.210. 1597 2136 16625
68.0042 LPSWATEDTMTKLRE 15 PAP.223. 343 5472
68.0043 LRELSELSLLSLYGI 15 PAP.235. 655 5185 235 2085
68.0044 LSELSLLSLYGΓHKQ 15 PAP.238. 482 7.3 45 8715
68.0045 LSLLSLYGΓHKQKEK 15 PAP.241. 656 3.4 58
Table 26
Peptide Sequence AA Source Analog DRB1*0101 DRB5*0101 DRB1*1501 DRB1*0301 DRB 1*0401
68.0046 KSRLQGGVLVNEΓLN 15 PAP.255.
68.0047 GGVLVNEΓLNHMKRA 15 PAP.260. 2165 8.7 576 700 2020
68.0024 DRSVLAKELKFVTLV 15 PAP.27. 705 2217 1359 3203
68.0048 TPSYKKLTMYSAHDT 15 PAP.277. 9.9 191 17 9728 2871
68.0049 YKKLΓMYSAHDTTVS 15 PAP.280. 17 5482 15 1166
68.0050 LTMYSAHDTTVSGLQ 15 PAP.283. 4496 184 134
68.0051 DTTVSGLQMALDVYN 15 PAP.290. 171 1042
68.0052 ALDVYNGLLPPYASC 15 PAP.299. 18 1091 2731
68.0019 AAPLLLARAASLSLG 15 PAP.3. 6.8 79 35 783
68.0053 LDVYNGLLPPYASCH 15 PAP.300. 15 3035 1959
68.0054 YNGLLPPYASCHLTE 15 PAP.303. 42 252
68.0153 LTELYFEKGEYFVEM 15 PAP.315. 2249 6655 4043 592
IO 68.0025 AKELKFVTLVFRHGD 15 PAP.32. 787 24 1529 4404
©
-4 68.0056 FAELVGPVTPQDWST 15 PAP.356. 12
68.0156 GPVΓPQDWSTECMTT 15 PAP.361.
68.0020 APLLLARAASLSLGF 15 PAP.4. 8.4 114 91 1138
68.0026 RSPTDTFPTDPIKES 15 PAP.47. 2373
68.0021 PLLLARAASLSLGFL 15 PAP.5. 10.3 151 118 2932
68.0028 FGQLTQLGMEQHYEL 15 PAP.67. 2259
F025.05 QKGRGYRGQHQAHSLERVCH 20 PLP.121. 9759 495
K-18 SAVPVYIYFNTWTTCQSIAF 20 PLP.171. 20000 92
F025.03 WTTCQSIAFPSKTSASIGSL 20 PLP.181. 400 277 17308 126
F025.08 AATYNFAVLKLMGRGTKF 18 PLP.260. 18 239 3000
K-09 FLYGALLLAEGFYTTGAVRQ 20 PLP.81. 256 45
68.0072 SHDLMLLRLSEPAEL 15 PSA.114. 532 1099 6215
68.0073 HDLMLLRLSEPAELT 15 PSA.115. 62 10541 662 2867
68.0074 TDAVKVMDLPTQEPA 15 PSA.129.
Table 26
Peptide Sequence AA Source Analog DRB 1*0101 DRB5*0101 DRB 1*1501 DRB 1*0301 DRB 1*0401
68.0077 LHVISNDVCAQVHPQ 15 PSA.172. 789 22750 8318 4443
68.0078 CAQVHPQKVTKFMLC 15 PSA.180. 10206 1229 809 14434
68.0079 GGPLVCNGVLQGITS 15 PSA.210. 3353 13417 383
68.0080 GPLVCNGVLQGITSW 15 PSA.211. 1724 6537 6310 170
68.0081 NGVLQGITSWGSEPC 15 PSA.216. 945 11619 258 3149
68.0082 RPSLYTKWHYRKWI 15 PSA.235. 6041 13 717 1904
68.0061 SQPWQVLVASRGRAV 15 PSA.31. 66 84 11259
68.0062 GRAVCGGVLVHPQWV 15 PSA.42. 386 12888
68.0063 GVLVHPQWVLTAAHC 15 PSA.48. 87 1062 66 378
68.0058 TLSVTWIGAAPLTLS 15 PSA.5. 3.1 31 97
68.0064 HPQWVLTAAHCΓRNK 15 PSA.52. 13 40 6500 3632 9117
68.0065 QWVLTAAHCΓRNKSV 15 PSA.54. 50 35 13565
IO
© vo 68.0066 AHCΓRNKSVΓLLGRH 15 PSA.60. 578 3630 88 387
68.0067 SVΓLLGRHSLFHPED 15 PSA.67. 717 16116 106 1400
68.0068 VΓLLGRHSLFHPEDT 15 PSA.68. 273 426 8744
68.0059 SVTWIGAAPLΓLSRI 15 PSA.7. 4.1 104 147
68.0158 HSLFHPEDTGQVFQV 15 PSA.74.
68.0060 VTWIGAAPLTLSRIV 15 PSA.8. 8.1 147 552
68.0069 GQVFQVSHSFPHPLY 15 PSA.83. 288 128 2172 46
68.0070 VFQVSHSFPHPLYDM 15 PSA.85. 16 897 2396 139
68.0071 PHPLYDMSLLKNRFL 15 PSA.93. 1315 3104 712
68.0088 WKEFGLDSVELAHYD 15 PSM.100. 1139 22750 85 540
68.0089 LAHYDVLLSYPNKTH 15 PSM.110. 79 172 82 6285
68.0165 YISITNEDGNEΓFNT 15 PSM.127. 498 2713 397 3511
68.0166 ISIINEDGNEΓFNTS 15 PSM.128. ' 507 3006 559
68.0090 GNEΓFNTSLFEPPPP 15 PSM.135.
68.0083 PRWLCAGALVLAGGF 15 PSM.18. 46 15167
SO o en oo SD vo so VO SO Table 26
Peptide Sequence AA Source Analog DRB1*0101 : DRB5*01
68.0167 EDFFKLERDMKΓNCS 15 PSM.183. 2710 3494 468 1270 68.0168 FFKLERDMKTNCSGK 15 PSM.185. 4419 3796 73 2719 68.0096 GKVFRGNKVKNAQLA 15 PSM.206. 612 1385 3373 6115 68.0097 GNKVKNAQLAGAKGV 15 PSM.211. 677 1218 68.0170 GVΓLYSDPADYFAPG 15 PSM.224. 1566 14168 965 17 68.0100 EYAYRRGIAEAVGLP 15 PSM.276. 5.1 1204 1197 68.0101 AEAVGLPSTPVHPIG 15 PSM.284. 5.4 56 68.0102 AVGLPSΓPVHPIGYY 15 PSM.286. 3.6 518 68.0103 IGYYDAQKLLEKMGG 15 PSM.297. 1923 506 1978 68.0105 TGNFSTQKVKMFΠHS 15 PSM.334. 11180 1927 3745 4688 68.0084 LGFLFGWFΓKSSNEA 15 PSM.35. 10.4 461 355 7524 68.0107 TRJYNVIGTLRGAVE 15 PSM.353. 14 32 1605 35 68.0173 GAAVVHEΓVRSFGTL 15 PSM.391. 12409 68.0176 NSRLLQERGVAYΓNA 15 PSM.438. 614 3473 1229 318 68.0109 ERGVAYTNADSSTEG 15 PSM.444. 2440 68.0110 GVAYΓNADSSΓEGNY 15 PSM.446. 1054 7610 823 68.0177 VAYΓNADSSΓEGNYT 15 PSM.447. 4716 531 2311 68.0111 DSSΓEGNYTLRVDCT 15 PSM.453. 16824 1202 68.0112 NYTLRVDCTPLMYSL 15 PSM.459. 6804 5056 45 56 68.0113 CTPLMYSLVHNLTKE 15 PSM.466. 93 36 426 19437 1378 68.0114 DFEVFFQRLGIASGR 15 PSM.520. 143 3559 10249 1245 68.0115 EVFFQRLGIASGRAR 15 PSM.522. 28 7.9 4556 124 68.0116 TNKFSGYPLYHSVYE 15 PSM.543. 3402 2942 489 68.0117 YDPMFKYHLTVAQVR 15 PSM.566. 9.0 62 1348 106 68.0118 DPMFKYHLTVAQVRG 15 PSM.567. 5.7 11 230 51 68.0119 MFKYHLTVAQVRGGM 15 PSM.569. 16 5.8 1198 99 68.0120 KYHLTVAQVRGGMVF 15 PSM.571. 137 86 1222 4532
Table 26
Peptide Sequence AA Source Analog DRB1*0101 DRB5*0101 DRB1*1501 DRB 1*0301 DRB 1*0401
68.0121 VAQVRGGMVFELANS 15 PSM.576. 228 117 3725
68.0122 RGGMVFELANSIVLP 15 PSM.580. 10.3 413 94 1288
68.0123 GMVFELANSTVLPFD 15 PSM.582. 15 903 83 4604 1295
68.0124 VEELANSIVLPFDCR 15 PSM.584. 19 10815 477 667 5618
68.0125 ADKIYSISMKHPQEM 15 PSM.608. 8273
68.0126 IYSISMKHPQEMKTY 15 PSM.611. 8452 2588 5025
68.0127 PQEMKTYSVSFDSLF 15 PSM.619. 15143 919
68.0085 LDELKAENIKKFLYN 15 PSM.62. 1136 150 414 1370
68.0128 TYSVSFDSLFSAVKN 15 PSM.624. 219 61 3223 110 410
68.0130 VLR MNDQLMFLERA 15 PSM.660. 118 85 127 183 162
68.0131 LRMMNDQLMFLERAF 15 PSM.661. 2704 758 1411 2204
68.0181 DQLMFLERAFIDPLG 15 PSM.666. w 68.0132 YPvHVIYAPSSHNKYA 15 PSM.687. 95 54 897 1598
£ 68.0133 RHVIYAPSSHNKYAG 15 PSM.688. 2174 88 1291 2705
68.0086 IKKFLYNFTQTPHLA 15 PSM.70. 449 658 305 8080 240
68.0087 KFLYNFTQTPHLAGT 15 PSM.72. 340 1600 227 13805 1222
68.0134 RQIYVAAFTVQAAAE 15 PSM.730. 3.7 143 166 6.9
68.0135 QIYVAAFTVQAAAET 15 PSM.731. 1.6 216 252 9.1
68.0136 VAAFTVQAAAETLSE 15 PSM.734. 14 378 18200 327
NASE011-30 PATLIKATDGDTVKLMYKGQ 20 Staph.Nase.ll. 278 1517 6429 1667
NASE121-140 HEQHLRKSEAQAKKEKLNIW 20 Staph.Nase.121. 4.8
NASE041-60 TPETKHPKKGVEKYGPEASA 20 Staph.Nase.41. 1000 1820 2813
NASE051-70 VEKYGPEASAFTKKMVENAK 20 Staph.Nase.51. 16 7500
NASE061-80 FTKKMVENAKKTEVEFDKGQ 20 Staph.Nase.61. 1000 455 11619 2813
NASE091-110 YIYADGKMVNEALVRQGLAK 20 Staph.Nase.91. 65 1820 2813
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl *0101 *0301 *0401 *0404 *0405
PTS-04 AAWSERAGEAMVLV B.pertussis.247 B. pertussis 625.0 22500.0 500000.0
582.02 DNVLDHLTGRSC B.pertussis.64 B.pertussis 454.6 90000.0 22500.0 50000.0
PTS-10 NH2-DNVLAHLTGRSCQ- B.pertussis.30 B. ertussis A 122.0
COOH PTS-17 NH2-DNVLDHLTGRSAQ- B.ρertussis.30 B.pertussis A 22.3
COOH PTS-18 NH2-DNVLDHLTGRSCA- B.pertussis.30 B.pertussis A 714.3
COOH 541.19 FTYTVDKSKPKVYQWRD BeeVenom.109 BeeVenom 1666.7 450000.0 500000.0
541.15 INTKCYKLEHPVTGCG BeeVenom.85 BeeVenom 227.3 3750.0 500000.0
541.04 NELGRFKHTDACCRTH BeeVenom.19 BeeVenom 357.1 450000.0 500000.0
541.11 NNDFYDNSADTISSYF BeeVenom.61 BeeVenom 1666.7 918.4 500000.0 541.20 SKPKVYQWFDLRKY BeeVenom.115 BeeVenom 1250.0 450000.0 2000.0 541.13 SSYFVGKMYFNLTNTK BeeVenom.73 BeeVenom 714.3 450000.0 500000.0
BMP PDTRPAPGSTAPPAHGVTSAP Breastmucin Breastmucin 50000.0 450000.0 50000.0
DTR-NH2 1136.18 ALPVFTWLALYFTSAK Candida.aurl768.106 Candida 178.7 1485.2 6675.9
1136.20 ALYFTSAKTPQEWKPA Candida.aurl768.114 Candida 2886.8 3763.1 47.6
1136.15 FATSFLTPLTSQFFLP Candida.aurl768.90 Candida 1.8 5683.0 518.5
1136.52 GLFCRWSYTEΓEKΓDI Candida.aurl768.338 Candida 15811.4 >9890.71 8079.6 608.0
1136.53 GLFSRWSYTEIEKΓDI Candida.aurl 768.338 Candida 25000.0 1288.2 >8101.63
1136.48 IGGAMLSLTVFEFTKY Candida.aurl 768.314 Candida 388.1 >9157.02 10978.9 4976.8
1136.13 ΓKLPΠLAFATSFLΓP Candida.aurl768.82 Candida 5.9 2602.4 16007.8
1136.43 ΓMEVLFLSWLFPRFKF Candida.aurl768.274 Candida 208.3 181.5 >25855.73
1136.67 LTNNDQVSGINEEDEE Candida.aurl768.418 Candida >20412.41 >17450.25 >64231.72
1136.01 MMASSILRSKΠQKPYQ Candida.aurl 768.1 Candida 1644.9 9236.6 >13693.06 >8101.63
1136.41 PSLHSGSSΓMEVLFLS Candida.aurl768.266 Candida 735.4 >18541.93 22391.7
1136.39 SSIΓFGAFPSLHSGSS Candida.aurl768.258 Candida 68.2 28.2 82.6
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl *0101 *0301 *0401 *0404 *0405
1136.10 VSILFFVFWFPASFF Candida.aurl768.66 Candida 2062.0 >9157.02 637.2 6088.8
58.0041 IAKITPDNNGTYACF CEA.642 CEA A 51.7
58.0022 TPNITVDNSGSYTCQ CEA.286 CEA A 109.9 58.0012 IQNIIQDDTGFYTLH CEA.109 CEA A 56.7 58.0037 LFNVTRDDARAYVCG CEA.558 CEA A 56.8 58.0017 LFNVTRDDTASYKCE CEA.202 CEA A 56.4 58.0028 LLSVTRDDVGPYECG CEA.380 CEA A 560.6 58.0015 LWWVNNESLPVSPRL CEA.177 CEA A 310.4 58.0027 LWWVNNESLPVSPRL CEA.355 CEA A 229.3 58.0021 QELFTPDITVNNSGS CEA.282 CEA A 449.8 w 58.0032 QELFISDITEKNSGL CEA.460 CEA A 302.3
£ 58.0009 REITYPDASLLIQNI CEA.98 CEA A 126.4
58.0020 SCHAASDPPAQYSWF CEA.258 CEA A 201.5
58.0023 TITVYADPPKPFITS CEA.315 CEA A 378.0 58.0005 VLLLVHDLPQHLFGY CEA.51 CEA A 4.9
58.0042 YACFVSDLATGRNNS CEA.653 CEA A 19.5
CMP PTTTPITTTTTVTPTPTPTGTQT Colonmucin Colonmucin 50000.0 1153.9 333.3 YC-NH2
722.01 YIAFLKQATAK CytC CytC 104.2 900000.0 7500.0 10000.0
500.02 FLRRIRPKLK Dynorphin.4 Dynorphin
199.02 GFLRRTRPKLK Dyno hin.3 Dynorphin
199.03 LRPJRPKLK Dynorphin.5 Dynorphin i99.oι YGGFLRRΓRPKLK D noφhin.l Dynorphin 50000.0 900000.0 450000.0 1923.1
510.12 DDNGPQDPDNTDDNG EBV.LMP.260 EBV 50000.0 51961.5 22500.0 25000.0
F166.01 PYYTGEHAKAIGN Flu.HA.308 Flu 317.1 >14463.55 >27317.92
897.07 FPQPQLPYSQPQPFRPQQPY- Gliadin.61 Gliadin 900000.0
NH2
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl
*0101 *0301 *0401 *0404 *0405
897.25 TPPYCTIAPFGTFGIN-NH2 Gliadin.261 Gliadin 900000.0
F168.09 πsJvTLALQTLPAMCNVY Gliadin.235 Gliadin
897.04 LGQQQPFPPQQPYPQPQPFP- Gliadin.31 Gliadin 900000.0
NH2
897.18 LHQQQKQQQQPSSQVSFQQP- Gliadin.181 Gliadin 900000.0
NH2
897.15 LLQELCCQHLWQTPEQSQCQ- Gliadin.151 Gliadin 900000.0
NH2
897.13 LQQHNIAHGRSQVLQQSTYQ- Gliadin.131 Gliadin
NH2
F168.04 PQPFRPQQPYPQ Gliadin.71 Gliadin
F168.03 PQPFRPQQPYPQPQPQ Gliadin.71 Gliadin > 897.08 PQPFRPQQPYPQPQPQYSQP- Gliadin.71 Gliadin 900000.0
-4 NH2
897.09 PQPQPQYSQPQQPISQQQQQ- Gliadin.81 Gliadin 900000.0
NH2
897.19 PSSQVSFQQPLQQYPLGQGS- Gliadin.191 Gliadin 4691.6
NH2
F168.12 QFEEIRNLALQT Gliadin.231 Gliadin
F168.ll QFEETRNLALQTLPAM Gliadin.231 Gliadin
897.23 QFEETRNLALQTLPAMCNVY- Gliadin.231 Gliadin 900000.0 NH2
F168.06 QFLGQQQPFPPQ Gliadin.29 Gliadin
897.22 QGSVQPQQLPQFEETRNLAL- Gliadin.221 Gliadin 900000.0 NH2
897.02 QNPSQQQPQEQVPLVQQQQF- Gliadin.ll Gliadin 900000.0
NH2
897.05 QPYPQPQPFPSQQPYLQLQP- Gliadin.41 Gliadin 900000.0
NH2
897.12 QQLIFCMDVVLQQHNIAHGR- Gliadin.121 Gliadin 9819.8 NH2
F168.08 QVPLVQQQQFLG Gliadin.21 Gliadin
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl 0101 *0301 *0401 *0404 *0405
F168.07 QVPLVQQQQFLGQQQP Gliadin.21 Gliadin
897.03 QVPLVQQQQFLGQQQPFPPQ- Gliadin.21 Gliadin
NH2
897.06 SQQPYLQLQPFPQPQLPYSQ- Gliadin.51 Gliadin 900000.0
NH2
F168.05 VQQQQFLGQQQPFPPQ Gliadin.25 Gliadin
897.01 VRVPVPQLQPQNPSQQQPQE- Gliadin.1 Gliadin 900000.0
NH2
897.50 YΓPPYCTIAPFGΓFGIN-NH2 Gliadin.261 Gliadin >45000
897.44 YPSSQVSFQQPLQQYPLGQGS Gliadin.191 Gliadin 445.5
-NH2
897.47 YQGSVQPQQLPQFEETRNLAL- Gliadin.221 Gliadin >30000
NH2 F160.26 EKVPVSEVMGTTLAEMSTPE gpl00.377 gplOO 10603.5 94.8 AT
F160.02 IYRRRLMKQDFSVPQLPHS gpl00.615 gplOO 58.6 13.0
F160.07 KRCLLHLAVIGALLAVGATK gpl00.6 gplOO >14411.53 408.8
V
F160.03 LCQPVLPSPACQLVLHQILKG gp 100.540 gplOO >14411.53 732.0
G
F160.14 MTPAEVSIWLSGTTAAQVTT gpl00.400 gplOO 129.3 31.6
T
F160.16 PGPVTAQWLQAAΓPLTSCGS gpl00.283 gplOO 2519.1 81.1
S
F160.01 VSGLSIGTGRAMLGTHTMEV gpl00.167 gplOO 10452.1 384.2
TVY
F167.01 VYVWKTTWGQYWQVLGGP gpl00.150 gplOO 114.9 >14248.07 >3387.8 27886.2
VS
F167.03 WNRQLYPEWTEAQR gp 100.44 gplOO 7800.3 361.8 145.6 538.4
F115.14 AKRKTVTAMDWYAL H4.76 H4 1.3
FI 15.02 KRHRKVLRDNIQGITKPAIRR H4.16 H4 258.0 LAR
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl
*0101 *0301 *0401 *0404 *0405
F115.15 KTVTAMDWYALKRQ H4.79 H4 26.0
F115.10 LRDNIQGITKPATRR H4.22 H4 16.4
F115.ll NIQGITKPATRRLAR H4.25 H4 234.7
F115.03 TYTEHAKRKTVTAMDWYA H4.71 H4 75.9 LKRQG
590.23 (2)KYVKQNTLKAT(SIC!) HA.307 HA A 15.2 5.9
752.01 (67)PKYVKQNTLKLAT HA.307 HA 3.9 72.6 25000.0
594.09 AJLAAIL AFIAAJ1AAFLAA HA. HA 263.2 450000.0 500000.0
F049.01 BIOTTN-A2- HA HA 6.5 33.4 PRYVRQNTLRATC
574.00 CPKYVRSAKLRM HA.302 HA 1666.7 36742.4 450000.0 500000.0
M 573.05 GACPKYVKQN HA.304 HA 50000.0 15000.0
S 573.04 GACPKYVKQNTL HA.304 HA 50000.0 1153.9
597.04 GACPKYVKQNTLK HA.304 HA 50000.0 3750.0
573.03 GACPKYVKQNTLKL HA.304 HA 2500.0 1184.2
30.1200 HNTNGVTAASSH HA.130 HA 50000.0 450000.0 500000.0
573.08 KQNTLKLATGMR HA.311 HA 50000.0 15000.0
711.03 LAKQNTLAKQNTLAKQNT HA.307 HA 50000.0 900000.0 150.0 86.2
573.09 NTLKLATGMR HA.313 HA 50000.0 15000.0
590.22 P(2)YVKQNTLKAT(SIC!) HA.307 HA A 454.6 20.5
864.10 PFFVKQNILKLAT HA.307 HA A 7.2 44.6 3571.4
864.07 PFFVKQNTLKLAT HA.307 HA A 1.4 10.7 344.8
864.06 PFΓVKQNTLKLAT HA.307 HA A 1.0 19.6 79.6
864.02 PFYVKQNTLKLAT HA.307 HA A 1.6 24.5 12500.0
864.09 PTFVKQNILKLAT HA.307 HA A 2.9 56.4 3846.2
864.05 PTFVKQNTLKLAT HA.307 HA A 2.9 32.1 649.4
864.04 PΠVKQNTLKLAT HA.307 HA A 7.6 68.1 160.3
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl
*0101 *0301 *0401 *0404 *0405
864.01 PIYVKQNTLKLAT HA.307 HA A 3.9 23.8 10000.0
590.10 PK(1)VKQNTLKAT(SIC!) HA.307 HA A 454.6 2368.4 590.21 PK(2)VKQNTLKAT(SIC!) HA.307 HA A 454.6 511.4
772.08 PK(31)VKQNTLKLAT-NH2 HA.307 HA A 5.6 136.4 8333.3
611.11 PKAVKQNTLKLAT HA.307 HA A 1000.0 15000.0 25000.0
601.09 PKEVKQNTLKLAT HA.307 HA A 50000.0 4500.0 500000.0
841.05 PKFQVETTKKLAT HA. HA A 185.2 900000.0 155.7 500000.0 864.03 PKΓVKQNTLKLAT HA.307 HA A 7.3 92.4 130.9
713.09 PKKVKQNTLKLAT HA.307 HA A 2500.0 9000.0 500000.0 792.03 PKQVKQNTLKLAT HA.307 HA A 1250.0 9000.0 500000.0
601.10 PKSVKQNTLKLAT HA.307 HA A 50000.0 57.7 500000.0 713.14 PKTVKQNTLKLAT HA.307 HA A 2500.0 5625.0 500000.0
590.09 PKY(1)KQNTLKAT(SIC!) HA.307 HA A 72.5 7.8 833.08 PKY(41)KQNTLKLAT HA.307 HA A 217.4 436.9 500000.0 590.08 PKYV(1)QNTLKAT(SIC!) HA.307 HA A 72.5 37.5 590.19 PKYV(2)QNTLKAT(SIC!) HA.307 HA A 138.9 11.8 833.07 PKYV(41)QNTLKLAT HA.307 HA A 50000.0 576.9 500000.0 590.07 PKYVK(1)NTLKAT(SIC!) HA.307 HA A 294.1 225.0 590.18 PKYVK(2)NTLKAT(SIC!) HA.307 HA A 147.1 463.9
713.10 PKYVKKNTLKLAT HA.307 HA A 89.3 3000.0 500000.0
590.06 PKYVKQ(1)TLKAT(SIC!) HA.307 HA A 50.0 6.9 590.17 PKYVKQ(2)TLKAT(SIC!) HA.307 HA A 116.3 13.6 833.05 PKYVKQ(41)TLKLAT HA.307 HA A 11.6 61.6 25000.0
590.05 PKYVKQN(1)LKAT(SIC!) HA.307 HA A 50000.0 450.0 590.16 PKYVKQN(2)LKAT(SIC!) HA.307 HA A 454.6 2368.4
772.06 PKYVKQN(24)LKLAT HA.307 HA A 6.8 88.2 25000.0
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl 0101 *0301 *0401 *0404 *0405
772.01 PKYVKQN(25)LKLAT HA.307 HA A 5.6 1071.4 500000.0
772.02 PKYVKQN(26)LKLAT HA.307 HA A 166.7 5625.0 500000.0
772.03 PKYVKQN(27)LKLAT HA.307 HA A 357.1 3000.0 16666.7
772.04 PKYVKQN(28)LKLAT HA.307 HA A 20.8 2812.5 25000.0
772.07 PKYVKQN(30)LKLAT HA.307 HA A 625.0 15000.0 25000.0 601.24 PKYVKQNELKLAT HA.307 HA A 714.3 15000.0 500000.0 515.09 PKYVKQNHLKLAT HA.307 HA A 96.2 4500.0 500000.0
864.08 PKYVKQNILKLAT HA.307 HA A 35.5 156.8 5000.0 713.12 PKYVKQNKLKLAT HA.307 HA A 2500.0 9000.0 500000.0
863.07 PKYVKQNNLKLAT HA.307 HA A 500.0 3214.3 500000.0 772.11 PKYVKQNPLKLAT HA.307 HA A 4.2 737.7 50000.0 713.13 PKYVKQNQLKLAT HA.307 HA A 45.5 5625.0 500000.0
590.04 PKYVKQNT(1)KAT(SIC!) HA.307 HA A 102.0 281.3
590.15 PKYVKQNT(2)KAT(SIC!) HA.307 HA A 147.1 264.7
833.03 PKYVKQNT(41)KLAT HA.307 HA A 714.3 7500.0 500000.0
601.27 PKYVKQNTKKLAT HA.307 HA A 13.9 2142.9 500000.0
590.03 PKYVKQNTL(1)AT(SIC!) HA.307 HA A 45.5 6.9
590.14 PKYVKQNTL(2)AT(SIC!) HA.307 HA A 66.7 11.0
833.02 PKYVKQNTL(41)LAT HA.307 HA A 56.8 232.0 500000.0
590.02 PKYVKQNTLK(1)T(SIC!) HA.307 HA A 454.6 2250.0
590.01 PKYVKQNTLKAT(SIC!) HA.307 HA A 108.7 21.4
713.06 PKYVKQNTLKEAT HA.307 HA A 2500.0 1097.6 500000.0
863.08 PKYVKQNTNKLAT HA.307 HA A 70.4 1097.6 500000.0 713.01 PKYVKQNYLKLAT HA.307 HA A 192.3 9000.0 25000.0 175.00 RTLYQNVGTYVSVGTSTLNK HA.187 HA 19.2 900000.0 450000.0 25000.0 597.06 VKQNTLKLATGMR HA.310 HA 50000.0 7500.0
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl
*0101 *0301 *0401 *0404 *0405
841.06 YPKFQVETTKKLAT HA HA A 45.5 111.4 500000.0
841.04 YPKFVKLNTKKLAT HA HA A 20.8 365.9 5000.0
771.04 YPKFVKQRTLKLAT HA HA A 3.6 46.9 357.1
771.02 YPKFVKQRTLKLAT-NH2 HA HA 4.6 37.5 172.4
771.06 YPKFVKRNTLKLAT HA.307 HA A 14.3 818.2 10000.0
771.03 YPKYVKQRTLKLAT HA HA A 2.8 51.7 10000.0
771.01 YPKYVKQRTLKLAT-NH2 HA HA A 5.0 60.0 1724.1
771.07 YPKYVKRNTLKLAT HA.307 HA A 23.8 1956.5 12500.0
841.02 YPSFQVQTTLLLAT HA HA A 1.1 2.7 12.2
27.0278 AAPFTQCGYPALMPL HBV.pol.643 HBV 160.8 >23985.08 39.09 AILCWGELMTLA HBV.core.58 HBV 6299.4 450000.0 >7462.69 to F0
K F076.05 ALRQAILCWGELM HBV.core.54 HBV >9183.67 >22727.27
F039.05 ALRQAILCWGELMTLA HBV.core.54 HBV 505.8 24549.5 >7462.69
799.04 GYRWMCLRRFITFLFILLLC HBV.env.71 HBV 2500.0 28460.5 424.5 12500.0
F039.02 HHTALRQAILCWGELMTLA HBV.core.51 HBV 1127.1 225000.0 >7462.69
F039.03 HTALRQAILCWGELMTLA HBV.core.52 HBV 512.7 35575.6 >7462.69
F039.10 ILCWGELMTLA HBV.core.59 HBV 50000.0 >818.18 >7462.69
F039.ll LCWGELMTLA HBV.core.60 HBV 50000.0 >900 >7462.69
F164.04 LPETTWRCRGRSPR HBV.core.143 HBV >1889.82 >504.69 >22680.46
F039.06 LRQAILCWGELMTLA HBV.core.55 HBV 896.6 225000.0 >7462.69
CF-09 LSTLPETTWRRRGRS HBV.core.140 HBV 50000.0 9000.0 25000.0
F164.14 MDΓDPYKEFGASVELLSFL HBV.core.l HBV 116.9 837.6 27.6
F164.13 MDTDPYKEFGASVELLSFLPS HBV.core.l HBV 34.6 2580.9 110.1 DFFP
F164.16 MDTDPYKEFGATVELLSFL HBV.core.l HBV 1356.7 308.0 108.8
F116.01 MDTDPYKEFGATVELLSFLPS HBV.core.l HBV 1562.5 957.5 DFFP
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl *0101 *0301 *0401 *0404 *0405
F164.15 MDTDPYKEFGATVELLSFLPS HBV.core.l HBV 113.8 145.4 17.3
DFFP F164.17 MDTDPYKEFGATVQLLSFLPS HBV.core.l HBV 411.6 33.9 10.2
DFFP F098.ll MGLKFRQLLWF HBV.core.94 HBV 240.6 3620.6 1350.7 206.3
1297.06 PFLLAQFTSAICSWRRA HBV.pol.523 HBV
F039.18 PHHTALRQAILCW HBV.core.50 HBV 16666.7 5489.4 >20000
F039.17 PHHTALRQAILCWG HBV.core.50 HBV 2130.1 450000.0 >20000
F039.16 PHHTALRQAILCWGE HBV.core.50 HBV 11180.3 >600 >20000
F039.15 PHHTALRQAILCWGEL HBV.core.50 HBV 2391.8 150000.0 >20000
F039.14 PHHTALRQAILCWGELM HBV.core.50 HBV 389.3 5669.5 >7462.69
F039.13 PHHTALRQAILCWGELMT HBV.core.50 HBV 1725.2 14230.3 >7462.69 F039.12 PHHTALRQAILCWGELMTL HBV.core.50 HBV 145.8 10062.3 >7462.69
795.01 PLGFFPDHQLDPAFGANSNNP HBV.PreS. HBV 50000.0 900000.0 6428.6 500000.0
DWDFNP F039.08 QAILCWGELMTLA HBV.core.57 HBV 1605.7 20539.6 >7462.69
CF-03 RDLLDTASALYRREALESPEH HBV.core.28 HBV 50000.0 7500.0 16666.7
CF-06 RDLWSYVNTNMGLKFRQLL HBV.core.82 HBV 1000.0 2250.0 2941.2
F039.07 RQAILCWGELMTLA HBV.core.56 HBV 3125.0 225000.0 >7462.69
801.01 RVRGLYFPAGGSSSGTVN HBV.env.16 HBV 294.1 900000.0 616.4 16666.7
799.02 SLDSWWTSLNFLGGTTVCLG HBV.env.31 SHBV 36.8 15667.0 1956.5 25000.0
F039.04 TALRQAILCWGELMTLA HBV.core.53 HBV 931.5 43301.3 >7462.69
F164.12 TNMGLKFRQLLWFHI HBV.core.91 HBV >1889.82 >7367.12 6273.9
F164.il TNVGLKFRQLLWFHI HBV.core.91 HBV 1491.4 835.7 149.6
F098.08 TTWRRRGRSPRRR HBV.core.145 HBV 98039.2 >100623.06 >62500 >66149.51
800.04 VGAGAFGLGFTPPHGGL HBV.env.47 HBV 5000.0 900000.0 26.5 3333.3
764.01 VSFGVWTRTPPA HBV.core. HBV 50000.0 900000.0 15000.0 5000.0
857.01 YPHHTALRQAILCWGELMTL HBV.core.50 HBV 1000.0 633.9 23622.8
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl
*0101 *0301 *0401 *0404 *0405
F134.07 GPGEGAVQWMNRLIAFASRG HCV.NS4.291 HCV 8.7 5328.0
Pape22 GRHLIFCHSKRKCDELATKL HCV.NS3.1388 HCV >50000 >18750 >62500 >66149.51
F134.06 LLFNILGGWVAAQLAAPGAA HCV.NS4.191 HCV 26.7 >3668.13
1283.40 PATLSPGALWGWCA HCV.NS4.1889 HCV 50.9 63469.7
221.06 AFVAWRNRCK HEL.107 HEL A
221.08 AWAAWRNRCK HEL.107 HEL A
221.10 AWEAWRNRCK HEL.107 HEL A
221.09 AWLAWRNRCK HEL.107 HEL A
221.15 AWVAARNRCK HEL.107 HEL A 221.16 AWVAFRNRCK HEL.107 HEL A 221.14 AWVAQRNRCK HEL.107 HEL A
221.19 AWVAWANRCK HEL.107 HEL A
221.17 AWVAWENRCK HEL.107 HEL A
221.18 AWVAWKNRCK HEL.107 HEL A
221.22 AWVAWRARCK HEL.107 HEL A
221.25 AWVAWRNACK HEL.107 HEL A
221.23 AWVAWRNECK HEL.107 HEL A
221.24 AWVAWRNKCK HEL.107 HEL A
221.32 AWVAWRNRCA HEL.107 HEL A
539.00 AWVAWRNRCK HEL.107 HEL 50000.0 >45000 3750.0 500000.0
221.01 AWVAWRNRCK HEL.107 HEL 50000.0 3750.0 500000.0
221.31 AWVAWRNRCR HEL.107 HEL A
221.28 AWVAWRNREK HEL.107 HEL A
221.29 AWVAWRNRKK HEL.107 . HEL A
221.26 AWVAWRNRQK HEL.107 HEL A
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl *0101 *0301 *0401 *0404 *0405
221.27 AWVAWRNRVK HEL.107 HEL A
221.20 AWVAWRQRCK HEL.107 HEL A
221.21 AWVAWRVRCK HEL.107 HEL A
221.12 AWVEWRNRCK HEL.107 HEL A
221.11 AWVSWRNRCK HEL.107 HEL A
221.13 AWVVWRNRCK HEL.107 HEL A
565.01 EFVAAKAAQK HEL.107 HEL 625.0 900000.0 11250.0 500000.0
221.02 EWVAWRNRCK HEL.107 HEL
AP23 LAAAMKRHGLDNYRGYSLG HEL.8 HEL 1250.0 900000.0 22500.0 500000.0
NWV AP12 RNRCKGTDVQAWTRGCRL HEL.112 HEL 500.0 900000.0 22500.0 1087.0
K AP38 SVNCAKKTVSDGNGMN HEL.91 HEL 50000.0 9449.4 1125.0 8333.3
221.04 SWVAWRNRCK HEL.107 HEL A
221.03 VWVAWRNRCK HEL.107 HEL A
560.02 WRNAKWRNAKWRNAK HEL.112 HEL A 1000.0 900000.0 22500.0 500000.0
AP37 YRGYSLGNWVCAAKFESNFN HEL.20 HEL 555.6 900000.0 22500.0 500000.0
TQ 58.0052 CWMTDSDCRPRFREL Her2/neu.958 Her2/neu A 5.1
58.0045 CYGLGMDHLREVRAV Her2/neu.342 Her2/neu A 180.5
58.0053 FRELVSDFSRMARDP Her2/neu.969 Her2/neu A 121.2
58.0051 TKWMALDSILRRRFT Her2/neu.886 Her2/neu A 1.7
58.0046 LALTHHDTHLCFVHT Her2/neu.465 Her2/neu A 17.0
58.0043 LTYLPTDASLSFLQD Her2/neu.62 Her2/neu A 106.8
58.0048 QMRILKDTELRKVKV Her2/neu.711 Her2/neu A 335.4
1385.03 SPYVSRLLGICLT Her2/neu.777 Her2/neu 12.8 >21096.33 >4494.22 172.5
1385.04 VPTKWMALESILRRRF Her2/neu.884 Her2/neu 12.1 117.7 1154.6 1035.9
58.0047 WDQLFRDPHQALLHT Her2/neu.482 Her2/neu 4.8
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl 0101 *0301 *0401 *0404 *0405
F159.13 DRVHPVHAGPIA HTV.gag.245 HTV 7704.2 >7905.69 55555.6 >11109.4
F159.12 DRVHPVHAGPIAPG HTV.gag.245 HTV 229.5 >6830.74 45454.6 >9354.95
F159.ll DRVHPVHAGPIAPGQM HTV.gag.245 HΓV 801.0 >5929.27 41666.7 >8413.34
F159.10 DRVHPVHAGPIAPGQMRE HTV.gag.245 HTV 332.5 >5303.3 35714.3 >7367.88
F159.09 DRVHPVHAGPIAPGQMREPR HTV.gag.245 HTV 1110.4 >4743.42 31250.0 >6555.62
FI70.01 DTEVHNVWATQACVPTDPNP HTV.env.6 HTV 753.1 >7694.84 >216.51 3104.3
F169.02 EGLTHSQRRQDILDL HTV.nef.98 HTV 26418.8 2014.4 >2598.08 >83333.33
F170.06 EPFRDYVDRFYKTLRAEQAS HTV.gag.30 HIV 15.2 1389.5 104.7 3733.3
F170.05 IYKXWIILGLNKIV'RMYSPV HTV.gag.27 HIV 1272.4 >15389.68 >435.44 5120.9
F170.02 PKISFEPΓPΓHYCAPAGFAI Hrv.env.20 HΓV 228.9 22675 163.6 1487.1
F169.01 TAATNAACAWLEA HTV.nef.48 HΓV 9806.6 >94868.33 >2598.08 83612.0
F170.04 TNNPPΓPVGEIYKRWIILGL Hτv.gag.26 HTV 13.9 87.8 298.0 155.7
F170.03 VWGTKQLQARVLAVERYLKD mV.env.54 HTV 2.3 3742.3 >435.44 1078.5
27.0374 AVQMAVFΓHNFKRKG HrVl.pol.917 HTVl 1589.4 1641.6
27.0299 DQQLLGΓWGCSGKLI Hivι.env.755 HΓVI 173.7 >22500
27.0287 DQSLKPCVKLTPLCV HTVl.env.126 HTVl 666.6 >22500
27.0284 EDΠSLWDQSLKPCV HrVl.env.119 HIV1 103.6 >23985.08
190.20 ERFAVNPGLLETSEGC HTVl.gp.48 HTVl 250.0 900000.0 450000.0 7142.9
190.15 GARASVLSGGELDKWE HTVl.gp.l HTVl 833.3 900000.0 450000.0 500000.0
190.16 GGELDKWEKTRLRPGG EDLVl.gp.9 HTVl 2500.0 900000.0 450000.0 500000.0
RS-21 GP41584-609 HTVl.gp. HTVl 1250.0
27.0320 IGGIGGFΓKVRQYDQ Hrvι.poi.127 HTVl 22026.7 >18766.3
181.11 ILKALGPAATLEEMMT(200.11 HIV1 HIV1 22.1 900000.0 22500.0 1562.5
)
200.10 INEEAAEWERVHPVHA HTVl.gp.73 HTVl 625.0 31819.8 450000.0 10000.0
27.0348 IQKLVGKLNWASQTY HTVl.pol.436 HΓVI 191.1 >16112.58
27.0286 ISLWDQSLKPCVKLT HTVl.env.122 HTVl 1269.7 >22500
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl 0101 *0301 *0401 *0404 *0405
190.19 IVWASRELERFAVNPG HIVl.gp.33 HIV1 2500.0 10392.3 450000.0 3846.2
200.17 IΎKRWIILGLNKΓVRN HTVl.gp.129 HTVl 2500.0 900000.0 450000.0 500000.0
F091.13 KQIΓNMWQEVGKAMYA HWl.env.428 HTVl 1813.7 2477.2 98.1
200.04 KWΈEKAFSPEVΓPMF HTVl.gp.25 HΓVI 2500.0 900000.0 450000.0 3125.0
190.08 LGKΓWPSYKGRPGNFL HTVl.gp.57 HΓVI 2500.0 31819.8 9000.0 151.5
F091.08 LKQΓVKKLREQFGNNK HTVl.env.342 HTVl 20412.4 >64951.91 62500.0
27.0300 LLGΓWGCSGKLICTT HTVl.env.758 HTVl 193.7 >23985.08
27.0302 LSΓVNRVRQGYSPLS HTVl.env.877 HTVl 1157.1 2793.9
200.01 PΓVQNLQGQMVHQAIS HIVl.gp.l HTVl 625.0 900000.0 450000.0 500000.0
F091.24 PLGVAPTKAKRRWQR HTVl.env.671 HTVl 50000.0 >64951.91 12659.2 , 190.23 PSLQTGSEELRSLYNT HTVl.gp.65 HTVl 50000.0 12480.8 450000.0 500000.0
^ F091.16 QARILAVERYLKDQQL HTVl.env.582 HTVl 1740.8 >64951.91 8751.8
27.0352 QGQWTYQIYQEPFKN HTVl.pol.516 HTVl 4594.9 13146.6
190.13 QKQEPTDKELYPLTSL HTVl.gp.97 HΓVI 125.0 >30000 450000.0 250.0
27.0375 QMAVFIHNFKRKGGI HTVl.pol.919 HΓVI 10331.1 14711.1
F091.07 RIQRGPGRAFVTIGKL HTVl.env.315 HΓVI 14433.8 >64951.91 >91287.09
190.22 RQILGQLQPSLQTGSE HTVl.gp.57 HΓVI 227.3 900000.0 7500.0 1000.0
F091.04 SLKPCVKLTPLCVTLN HTVl.env.115 HTVl 319.7 26892.6 4247.1
F091.26 SLWDQSLKPCVKLTPL HIVl.env.825 HTVl 4902.9 >64951.91 >91287.09
27.0359 SQIIEQLTKKEKVYL HTVl.pol.701 HTVl 5986.4 >16112.58
F091.22 SQNQQEKNEQELLELD HIVl.env.654 HTVl 50000.0 >64951.91 >91287.09
F091.ll SSGGDPETVMHSFNCG HIVl.env.369 HTVl 25000.0 >64951.91 >91287.09
27.0334 STKWRKLVDFRELNK HIVl.pol.247 HTVl 618.4 1547.7 >16112.58
F091.12 TITLPCPsJKQFTNMWQE HTVl.env.413 HTVl 50000.0 1636.6 826.7
27.0292 TVYYGVPVWKEATTT HIVl.env.49 HIV1 3603.9 3900.2
F091.23 VKIEPLGVAPTKAKRR HIVl.env.667 HTVl 1796.1 47434.2 729.3
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl
*0101 *0301 *0401 *0404 *0405
27.0301 VLSIVNRVRQGYSPL HIVl.env.876 HTVl 1624.8 3241.0
27.0356 VNIVTDSQYALGΠQ HTVl.pol.675 HTVl 80.9 4961.6
F091.03 WDQSLKPCVKLTPLCV HTVl.env.112 HTVl 637.1 >64951.91 >91287.09
27.0335 WRKLVDFRELNKRTQ HIVl.pol.250 HIV1 4543.9 >16112.58
F160.45 STORKUSP45 HPV16.e7. HPV16 >25339.89 237.2
106.00 APYTSTLLPPELSETP HSV.gD.245 HSV 555.6 >45000 450000.0 25000.0
F095.05 FRQLVHFVRDFAQLL HSV HSV
AP30 SLKMADPNRFRGKDLP HSV HSV 1666.7 900000.0 450000.0 25000.0
605.14 ACRVNHVTLSQPKTVK HumanB2-μglobulin.79 HumanB2-μglobulin 5000.0 900000.0 5625.0 4166.7
530.08 GKKΓPKVEMSDMSFSK HumanB2-μglobulin.43 HumanB2-μglobulin 50000.0 900000.0 7500.0 8333.3 833.3 900000.0 1500.0 5555.6 to 605.03 HPAENGKSNFLNCYVS HumanB2-μglobulin.13 HumanB2-μglobulin oe 530.06 HPPHIEIQMLKNGKKI HumanB2-μglobulin.31 HumanB2-μglobulin 1000.0 900000.0 450000.0 142.9 530.01 IQKTPQIQVΎSRHPPE HumanB2-μglobulin.1 HumanB2-μglobulin 50000.0 >30000 450000.0 500000.0 530.07 IQMLKNGKKΓPKVEMS HumanB2-μglobulin.37 HumanB2-μglobulin 50000.0 1875.0 450000.0 50000.0 605.01 IQRTPKIQVYSRHPAE HumanB2-μglobulin.1 HumanB2-μglobulin 1666.7 900000.0 375.0 500000.0 530.02 IQVΎSRHPPENGKPNI HumanB2-μglobulin.7 HumanB2-μglobulin 2500.0 900000.0 535.7 500000.0 530.04 KPNILNCYVTQFHPPH HumanB2-μglobulin.19 HumanB2-μglobulin 50000.0 >30000 15000.0 147.1 530.10 SFSKDWSFYILAHTEF HumanB2-μglobulin.55 HumanB2-μglobulin 2500.0 900000.0 343.5 500000.0 605.10 SFSYDWSFYLLYYTEF HumanB2-μglobulin.55 HumanB2-μglobulin 50000.0 900000.0 833.3 500000.0 605.11 SFYLLYYTEFTPTEKD HumanB2-μglobulin.61 HumanB2-μglobulin 50000.0 4647.6 957.5 10000.0 530.14 TETDTYACRVKHDSMA HumanB2-μglobulin.79 HumanB2-μglobulin 50000.0 900000.0 450000.0 500000.0 530.09 VEMSDMSFSKDWSFYI HumanB2-μglobulin.49 HumanB2-μglobulin 2500.0 0.0 22500.0 500000.0 544.02 YGSDTITLPCRIKQFΓNMWQE HumanB2-μglobulin.410 HumanB2-μglobulin 50000.0 900000.0 1607.1 568.2 JR-01 PEFLEQRRAAVDTYC IEBs2 TEBs2 5000.0 450000.0 500000.0 F073.01 MRGSHHHHHHGSVD-II72-216 Invariantchain Ii 375.0 57.3 734.01 FVNQHLSGSHLVEALYLVSG- TnsulinA TnsulinA 38.6 >30000 6495.2 18898.2 CONH2
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl *0101 *0301 *0401 *0404 *0405
68.0002 DLVLSIALSVGCTGA Kallikrein2.3 Kallikreirώ 1196.8 73340.2
68.0005 GQRVPVSHSFPHPLY Kaιlikreirώ.87 Kallikrehώ 1563.3 >142302.49
68.0011 HDLMLLRLSEPAKIT Kallikrein2.119 Kallikreirώ 15.7 1405.6 17231.4
68.0008 HPLYNMSLLKHQSLR Kallikrein2.98 Kallikrein2 232.1 13006.7 2806.6
68.0003 HPQWVLTAAHCLKKN Kallikrein2.56 Kallikreirώ 22.0 1102.9 4922.1
68.0018 KPAVYTKVVHYRKWI Kallikrein2.239 Kallikreirώ 5000.0 8060.5
68.0140 LHLLSNDMCARAYSE Kallikrein2.176 Kallikreirώ 2103.5 938.1 24058.1
68.0001 MWDLVLSIALSVGCT Kallikrein2.1 Kallikreirώ 205.2 10386.4
68.0017 NGVLQGITSWGPEPC Kallikrein2.220 Kallikreirώ 1092.9 47434.2
68.0009 NMSLLKHQSLRPDED Kallikrein2.102 Kallikreirώ 3131.1 >183711.73
^ 68.0015 PEEFLRPRSLQCVSL Kallikrein2.162 Kallikreirώ 2001.1 >150000
^ 58.0007 PHPLYNMSLLKHQSL Kallikrein2.97 Kallikreirώ 19078.6 4607.2
68.0016 PRSLQCVSLHLLSND Kallikrein2.168 Kallikreirώ 1111.3 90000.0
68.0004 QWVLTAAHCLKKNSQ Kallikrein2.58 Kallikreirώ 895.1 >142302.49
68.0006 RVPVSHSFPHPLYNM Kallikrein2.89 Kallikrehώ 66.7 >90000
68.0010 SHDLMLLRLSEPAKI Kallikrein2.118 Kallikreirώ 55.9 2396.3 12622.4
F090.02 ATGFKQSSKALQRPV Leukemia.15 Leukemia 4921.1 >22786.64
F090.01 TVHSATGFKQSSKALQRPVAS Leukemia.25 Leukemia 1458.6 5844.2 DFEP
F071.29 ΓKYNGEEYLILSARD M.leprae.79 M.leprae 31980.1
F071.26 IYSKYGGTETKYNGE M.leprae.70 M.leprae 12519.3
F118.06 LVΓPENAKEKPQ M.leρrae.28 M.leprae
FI 18.02 LVTPENAKEKPQEGT M.leρrae.28 M.leprae
F071.12 LVΓPENAKEKPQEGT M.leprae.28 M.leprae >64951.91
F071.30 NGEEYLILSARDVLA M.leprae.82 M.leprae 986.7
F071.l l PSGLVΓPENAKEKPQ M.leprae.25 M.leprae >64951.91
F071.22 RΓPVDVSEGDΓVΓYS M.leprae.58 M.leprae 45927.9
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl 0101 *0301 *0401 *0404 *0405
581.02 RKHRIEDAVRNAKAAVEEGI M.leprae.437 M.leprae 50000.0 871.5 5625.0 12500.0 VAG F071.24 SEGDΓVΓYSKYGGTE M.leprae.64 M.leprae >64951.91
572.03 TLLQAAPALDKY M.leprae.464 M.leprae 135.1 900000.0 450000.0 25000.0
F071.03 VAKVKIKPLEDKILV M.leprae.1 M.leprae 61237.2
F071.04 VKIKPLEDKILVQAG M.leprae.4 M.leprae 44126.1
F071.17 WAVGPGRWDEDGAK M.leprae.43 M.leprae >64951.91
581.01 YEKIGAELVKEVAKKTDDVA M.leprae.112 M.leprae 27.8 900000.0 9000.0 500000.0
G
F160.21 EKIWEELSVLEVFEGRED MAGE.219 MAGE 10741.3 320.2
F160.20 ETSYVKNLHHMVKISGG MAGE.280 MAGE >16678.11 958.3
58.0062 EEKIWEDLSMLEVFE MAGE2.218 MAGE2 A 257.2 w 58.0057 FPDLESDFQAAISRK MAGE2.98 MAGE2 A 374.9
58.0058 LESVLRDCQDFFPVT MAGE2.136 MAGE2 A 384.9
58.0064 MQDLVQDNYLEYRQV MAGE2.247 MAGE2 A 118.6
58.0063 PRKLLMEDLVQENYL MAGE2.242 MAGE2 A 614.3
58.0065 QDLVQEDYLEYRQVP MAGE2.248 MAGE2 A 599.8
58.0059 QLVFGΓDWΈWPIS MAGE2.159 MAGE2 A 770.1
58.0071 EEKTWEDLSVLEVFE MAGE3.218 MAGE3 A 657.1
58.0068 LGSWGDWQYFFPVI MAGE3.136 MAGE3 A 89.9
58.0074 QHFVQEDYLEYRQVP MAGE3.248 MAGE3 A 138.0
58.0073 TQHFVQDNYLEYRQV MAGE3.247 MAGE3 A 204.2
FI 67.06 LLKYRAREPVTKAEMLGSW Mage6.121 Mage6 13.2 465.3 725.5 300.4
GNWQ F167.08 MVKISGGPRISYPLLHEWALR Mage6.290 Mageδ 319.4 7108.8 >4242.64 14771.1
EGEE F167.07 QVPGSDPACYEFLWGPRALIE Mage6.260 Mage6 35.3 >11868.85 >2772.68 >20412.41
TSY F 160.27 VGNWQYFFPVTFSKASDSL MAGE6.140 MAGE6 5074.4 566.8
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl 0101 *0301 *0401 *0404 *0405
520.09 YKLNFYFDLLRAKL Malaria Malaria 1250.0 19655.6 22500.0 500000.0
520.07 YLDNTKDNVGKMED Malaria Malaria 50000.0 >45000 5000.0 1562.5
F160.15 AAGIGTLTVTLGVL MARTI.27 MARTI >19300.26 92.9
825.10 AC- MBP.l MBP 50000.0 900000.0 5000.0 25000.0
ASQKRPSQRHGSKYLATAST 765.17 AC- MBP.l MBP 1178.5 >30000 1527.4 25000.0
ASQKRPSQRSKYLATASTMD F006.16 ANPWHFFKNTVTPR MBP.85 MBP
825.01 ASQKRPSQRHGSKYLATAST MBP.l MBP 50000.0 900000.0 2368.4 50000.0
765.15 AYDAQGTLSKIFKLGGRDSR MBP.141 MBP 20.5 25980.8 2665.6 303.5
F006.14 DENPWHFFKN MBP.84 MBP
F006.13 DENPWHFFKNI MBP.84 MBP
£ F006.12 DENPWHFFKNΓV MBP.84 MBP
F006.l l DENPVVHFFKNΓVT MBP.84 MBP
F006.10 DENPWHFFKNΓVTPR MBP.84 MBP
F006.09 DENPWHFFKNIVTPRT MBP.84 MBP
F006.01 DENPWHFFKNTVTPRTPP MBP.84 MBP
F006.0202 DENPWHFFKNTVTPRTPPY MBP.84 MBP
F006.03 DENPVVHFFRNIVTPRTPPY MBP.84 MBP A
F006.17 EAPVVHFFKMVTPR MBP.85 MBP A
F006.18 ENAWHFFKNWTPR MBP.85 MBP A
F006.19 ENPAVHFFKNTVTPR MBP.85 MBP A
F038.01 ENPKVHFFKNΓVTPR MBP.85 MBP A
F006.20 ENPVAHFFKNΓVTPR MBP.85 MBP A
F038.02 ENPVΈΉFFKNΓVTPR MBP.85 MBP A
F006.21 ENPWAFFKNΓVTPR MBP.85 MBP A
F038.03 ENPWAFFKNΓVTPR MBP.85 MBP A
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl
*0101 *0301 *0401 *0404 *0405
F038.06 ENPVVDFFKNTVTPR MBP.85 MBP A
F038.05 ENPWFFFKNΓVTPR MBP.85 MBP A
F006.22 ENPVVHAFKNTVTPR MBP.85 MBP A
F038.07 ENPVVHAFKNTVTPR MBP.85 MBP A
F095.08 ENPVVHAFRNTVTPR MBP.85 MBP A
F038.09 ENPVVFΓDFKNΓVTPR MBP.85 MBP A
F006.23 ENPVVIΓFAKNΓVTPR MBP.85 MBP A
F095.06 ENPVYHFARNTVTPR MBP.85 MBP A
F006.24 ENPWHFFANWTPR MBP.85 MBP A
F038.14 ENPWHFFANIVTPR MBP.85 MBP A t Cr-8 ENPWHFFANTVTPRTP MBP.83 MBP A 8.6
£ F038.15 ENPWΉFFDNΓVTPR MBP.85 MBP A
F038.16 ENPWHFFHNΓVTPR MBP.85 MBP A
F006.25 ENPWHFFKA VTPR MBP.85 MBP A
Cr-9 ENPWHFFKAΓVTPRTP MBP.83 MBP A 11.4
F038.19 ENPWHFFKKΓVTPR MBP.85 MBP A
F006.26 ENPWTTFFKNAVTPR MBP.85 MBP A
Cr-10 ENPWHFFKNAVTPRTP MBP.83 MBP A 10.7
F006.27 ENPWHFFKNIATPR MBP.85 MBP A
F006.28 ENPVVHFFKNTVAPR MBP.85 MBP A
Cr-11 ENPVVHFFKNΓVAPRTP MBP.83 MBP A 13.1
¥006.29 ENPVVΉFFKNWTAR MBP.85 MBP A
F006.30 ENPWHFFKNIVTPA MBP.85 MBP A
F006.36 ENPWHFFKNΓVTPA MBP.85 MBP A
F006.15 ENPWHFFKNIVTPR MBP.85 MBP
Cr-7 ENPWHFFKNΓVTPRTP MBP.83 MBP 10.0
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl *0101 *0301 *0401 *0404 *0405
F006.04 ENPWHFFKNΓVTPRTPPY MBP.85 MBP
F038.20 ENPWHFFKNKVTPR MBP.85 MBP A
F038.17 ENPWHFFLNΓVTPR MBP.85 MBP A
F038.18 ENPWΉFFRNΓVTPR MBP.85 MBP A
F038.13 ENPVVHFKKNΓVTPR MBP.85 MBP A
F038.10 ENPVVHHFKNTVTPR MBP.85 MBP A
F095.10 ENPVVHHFRN TPR MBP.85 MBP A
F038.ll ENPVVHLFKNWTPR MBP.85 MBP A
F095.09 ENPWHLFRNΓVTPR MBP.85 MBP A
F038.12 ENPVVHWFKNTVTPR MBP.85 MBP A
^ F095.12 ENPVVHYFANTVTPR MBP.85 MBP A w F095.ll ENPVVHYFFTN TPR MBP.85 MBP A
F038.08 ENPVVHYFKNTVTPR MBP.85 MBP A
F095.13 ENPWHYFLNΓVTPR MBP.85 MBP A
F095.07 ENPVVIdYFRNrVTPR MBP.85 MBP A
F038.04 ENPWKFFKNTVTPR MBP.85 MBP A
613.02 FFKNIVTPFFKNTVTP MBP. MBP A 833.3 5000.0 6250.0
825.07 FSWGAEGQRPGFGYGGRASD MBP.114 MBP 50000.0 900000.0 2045.5 500000.0
765.13 GFGYGGRASDYKSAHKGFKG MBP.121 MBP 50000.0 900000.0 15000.0 500000.0
825.06 GKGRGLSLSRFSWGAEGQRP MBP.104 MBP 833.3 900000.0 725.8 2631.6
825.04 GSGKDSHHPARTAHYGSLPQ MBP.55 MBP 50000.0 900000.0 45000.0 500000.0
765.03 IiARHGFLPRlTRDTGILDSIG MBP.21 MBP 50000.0 >30000 450000.0 500000.0
F006.321 HFFKNTVTPRTPPY MBP.90 MBP
F006.322 HFFKNTVTPRTPPY MBP.90 MBP
765.16 TFKLGGRDSRSGSPMARR MBP.151 MBP 29.2 900000.0 22500.0 500000.0
765.06 KRGSGKDSHTRTTHYGSLPQ MBP.51 MBP 5000.0 >30000 11250.0 25000.0
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl
*0101 *0301 *0401 *0404 *0405
765.08 KSQHGRTQDENPWHFFKNI MBP.71 MBP 5000.0 >30000 2500.0 6250.0 F006.31 NPVVHFFKNΓVT MBP.86 MBP F006.37 NPWHFFKNTVTPA MBP.86 MBP F006.34 NPVVHFFKNTVTPR MBP.86 MBP F006.05 NPVVFTFFKNTVTPRTPPY MBP.86 MBP F006.39 PWHFFKN T MBP.87 MBP F006.38 PWHFFKNTVTPA MBP.87 MBP F006.35 PWHFFKNTVTPR MBP.87 MBP F006.06 PWHFFKNΓVTPRTPPY MBP.87 MBP 825.11 QKSHGRTQDENPWHFFKNI MBP.74 MBP 1250.0 900000.0 900.0 1562.5 w F121.03 RASDYKSAHKGFKGVDAQGT MBP.131 MBP F121.02 RASDYKSAHKGLKGHDAQGT MBP.131 MBP
825.02 RDTGILDSIGRFFGGDRGAP MBP.33 MBP 50000.0 1822.7 450000.0 500000.0
765.04 RDTGILDSIGRFFSGDRGAP MBP.31 MBP 50000.0 748.6 45000.0 25000.0
825.03 RFFGGDRGAPKRGSGKDSHH MBP.43 MBP 50000.0 45000.0 5000.0 500000.0
765.05 RFFSGDRGAPKRGSGKDSHT MBP.41 MBP 50000.0 7500.0 1046.8 >16666.67 825.05 RTAHYGSLPQKSHGRTQDEN MBP.65 MBP 50000.0 900000.0 450000.0 500000.0
825.09 VDAQGTLSKTFKLGGRDSRS MBP.144 MBP 25.4 1383.0 9000.0 314.5 FI 12.01 VDAQGTLSKIFKLGGRDSRS MBP.144 MBP FI 12.04 VDAQGTLSKLFKLGGRDSRS MBP.144 MBP A FI 12.03 VDAQGTLSRTFKLGGRDSRS MBP.144 MBP A F006.08 VHFFKNTVTPRTPPY MBP.89 MBP
765.10 VTPRTPPPSQGKGRGLSLSR MBP.91 MBP 50000.0 900000.0 5625.0 16666.7 F006.07 WHFFKNTVTPRTPPY MBP.88 MBP 765.14 YKSAHKGFKGAYDAQGTLSK MBP.131 MBP 3535.5 >30000 86.8 16666.7 825.08 YKSAHKGFKGVDAQGTLSKI MBP.134 MBP 70.4 900000.0 5000.0 25000.0
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl
*0101 *0301 *0401 *0404 *0405
9.00 ANERADLIAYLKQATK Moth.CytochromeC.88 Moth 1666.7 >30000 450000.0 8333.3
847.02 EFWEFDLPGΓKA Mouse.Lysoyzme.38 Mouse 50000.0 1773.3 330.9 500000.0
593.02 VITAFNEGLK Mouse.Hemoglobin.67 Mouse 50000.0 900000.0 22500.0 500000.0
847.01 YEFWEFDLPGTKA Mouse.Lysoyzme.38 Mouse 50000.0 40.9 2941.2
753.03 TAFNSGLEPGVVAEK-NH2 MT.451 MT 50000.0 900000.0 450000.0 500000.0
753.02 LLPLLEKVIGAGKPL-NH2 MT.231 MT 1666.7 900000.0 22500.0 12500.0
829.01 YKTIAYDEEARR MT.3 MT 50000.0 142.8 22500.0 500000.0
831.01 TWQRDGEDQTQDTELVETRP Naturallyprocessed Naturallyprocessed 555.6 592.1 1111.1
AG F009.04 VDDTLFVRFDSDAASPREEPR Naturallyprocessed Naturallyprocessed 122.3 3194.4
F009.01 VDDTLFVRFDSDATSPRKEPR Naturallyprocessed Naturallyprocessed 37.6 6201.7
& F009.06 VDDTQFVRFDSDAASPREEPR Naturallyprocessed Naturallyprocessed 68.1 2094.3
Ol
F009.02 VDDTQFVRFDSDAASPRMAP Naturallyprocessed Naturallyprocessed 44.6 1035.6
F009.05 VDDTQFVRFDSDAASPRTEPR Naturallyprocessed Naturallyprocessed 93.6 1737.6
536.00 AliAAHAAHAAHAAHAA Ova Ova 35.7 900000.0 22500.0 25000.0
N-3 AVTTAAHAETNEAGR Ova.326 Ova
151.00 HIATNAVLFFGR Ova.370 Ova 2500.0 90000.0 450000.0 500000.0
144.01 ISQAAHAAHAEINE Ova.323 Ova A
84.04 ISQADHAAHAEINE Ova.323 Ova A
85.04 ISQAVΈAAHAEΓNE Ova.323 Ova A
92.06 ISQAVHAAHAEDNE Ova.323 Ova A
92.05 ISQAVHAAHAEIIE Ova.323 Ova A
91.02 ISQAVHAAHAQINE Ova.323 Ova A
90.05 ISQAVHAALAEΓNE Ova.323 Ova A
144.08 ISQAVHAANAEΓNE Ova.323 Ova A
90.01 ISQAVHAARAEΓNE Ova.323 Ova A
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl 0101 *0301 *0401 *0404 *0405
747.01 LKISQAVTTAAHAEΓN Ova.321 Ova
705.05 MVYLGAKΓJSTRTQΓNKVVRF Ova.40 Ova 384.6 900000.0 11250.0 8333.3
521.00 NVMEERKIKVYLPRM Ova.271 Ova 1666.7 24053.5 45000.0 25000.0
560.04 VHAAHAEΓNVHAAHA Ova.327 Ova A 1250.0 >45000 500.0 7142.9
560.03 VTIAAHAVΉAAHAEIN Ova.327 Ova A 41.7 900000.0 22500.0 25000.0
560.05 VHAAHAVHAAHAVHA Ova.327 Ova A 12.2 900000.0 15000.0 1351.4
594.03 YTYTVHAAHAYTYT Ova Ova 45.5 5669.5 5625.0 25000.0
112.06 Y'TY'TVHAAHAY Y'T Ova Ova 45.5 5625.0 25000.0
58.0082 LΓRVEGDLRVEYLDD p53.194 p53 A 8.7
58.0081 QHLIRVDGNLRVEYL p53.192 p53 A 64.2
58.0091 RFEMFRDLNEALELK p53.337 p53 A 876.0 68.0019 AAPLLLARAASLSLG PAP.3 PAP 6.8 35410.0 782.7
68.0025 AKELKFVTLVFRHGD PAP.32 PAP 787.4 30000.0 4404.2
68.0052 ALDVYNGLLPPYASC PAP.299 PAP 18.4 2730.7
68.0020 APLLLARAASLSLGF PAP.4 PAP 8.4 56250.0 1138.5
68.0024 DRSVLAKELKFVTLV PAP.27 PAP 704.9 3203.4
68.0030 DRTLMSAMTNLAALF PAP.l lO PAP 97.2 64285.7 71.8
68.0051 DTTVSGLQMALDVYN PAP.290 PAP 171.2 24885.1
68.0056 FAELVGPVTPQDWST PAP.356 PAP 12.5 26379.5
68.0028 FGQLTQLGMEQHYEL PAP.67 PAP 2258.5 18057.9
68.0047 GGVLVNEILNHMKRA PAP.260 PAP 2165.4 699.6 2020.4
68.0156 GPVTPQDWSTECMTT PAP.361 PAP 52098.0
68.0034 GVSIWNPILLWQPTP PAP.128 PAP 44.2 56250.0 58094.8
68.0038 ILLWQPTPVHTVPLS PAP.135 PAP 45.1 >67840.05 957.0
68.0048 IPSYKKLIMYSAHDT PAP.277 PAP 9.9 9727.6 2870.9
68.0046 KSRLQGGVLVNEILN PAP.255 PAP 361.8 >129903.81
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl *0101 *0301 *0401 *0404 *0405
68.0053 LDVYNGLLPPYASCH PAP.300 PAP 15.4 1958.8
68.0050 LΓMYSAHDTTVSGLQ PAP.283 PAP 4496.4 134.4
68.0023 LLFFWLDRSVLAKEL PAP.21 PAP 2.9 6.3 14.8
68.0042 LPSWATEDTMTKLRE PAP.223 PAP 20274.0 5472.4
68.0043 LRELSELSLLSLYGI PAP.235 PAP 654.7 2084.6
68.0044 LSELSLLSLYGΓHKQ PAP.238 PAP 482.2 >67840.05 8715.3
68.0040 LSGLHGQDLFGIWSK PAP.194 PAP 147.7 >129903.81
68.0045 LSLLSLYGΓHKQKEK PAP.241 PAP 656.4 >67840.05 25000.0
68.0153 LTELYFEKGEYFVEM PAP.315 PAP 2248.9 591.8 45288.4
68.0031 MSAMTNLAALFPPEG PAP.114 PAP 1756.8 3935.5
MTNLAALFPPEGVSI PAP.117 PAP 24.4 >225000 to 68.0032
OJ -4 68.0036 NPILLWQPΓPVHTVP PAP.133 PAP 31.3 >67840.05 1160.3
68.0033 PEGVSΓWNPΓLLWQP PAP.126 PAP 111.2 10000.0
68.0037 PILLWQPΓPVHTVPL PAP.134 PAP 44.4 >67840.05 1450.7
68.0021 PLLLARAASLSLGFL PAP.5 PAP 10.3 >67840.05 2932.4
68.0026 RSPΓDTFPTDPIKES PAP.47 PAP >50000 73660.4
68.0022 SLSLGFLFLLFFWLD PAP.13 PAP 11416.8 26501.2
68.0147 TVPLSEDQLLYLPFR PAP.145 PAP 4012.0 332.2 60495.7
68.0035 WNPΓLLWQPIPVHTV PAP.132 PAP 208.2 >67840.05 3908.3
68.0039 WQPΓPVHTVPLSEDQ PAP.138 PAP 6385.9 >129903.81
68.0041 YDPLYCESVHNFTLP PAP.210 PAP 1597.4 16625.5 50000.0
68.0049 YKKLΓMYSAHDTTVS PAP.280 PAP 16.8 22677.9 1166.0
68.0054 YNGLLPPYASCHLTE PAP.303 PAP 41.6 34811.9
1188.24 AGGIAGGLALLACAG Pf.SSP2.498 Pf 359.7 38031.9 6742.0 >35906.62
1188.14 ATSVLAGLLGNVSTV Pf.EXP1.77 Pf 19.6 22116.3 943.9 >35906.62
1188.28 AVPLAMKLIQQLNLN Pf.SSP2.68 Pf 3768.9 22278.3 5750.6 30661.1
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl 0101 *0301 *0401 *0404 *0405
F143.02 EWSPCSVTCGNGIQVRTK Pf.CSP.345 Pf 771.9 >53033.01 60893.1
27.0396 FLALFFITFNKESLA Pf.EXPl.8 Pf 719.3 1225.8 4685.8
F143.09 IEQYLKKΓKNSISTEWSPCS Pf.CSP.331 Pf 72.7 >53033.01 110.2
1188.04 IFHΓNGKIΓKNSEKD Pf.LSAl.18 Pf 164.9 7595.4 >60133.78 >59761.43 10302.2
27.0401 KHILYISFYFILVNL Pf.LSAl.2 Pf 3380.1 892.8 >7615.25
1188.20 LΓDVHDLISDMΓKKE Pf.EXP1.47 Pf 401.4 9066.2 1517.0 45454.6 5019.6
F150.02 NAPSEIΓRLHSDASKNKEKAL Pf.SSP2. Pf 98.1 49342.1 2191.4
27.0414 NHAVPLAMKLIQQLN Pf.SSP2.66 Pf 266.1 3916.3 >7615.25
F107.12 TVLLGGVGLVLYNTE Pf.EXP1.90 Pf 10.3 16198.4 >25333.33
1188.47 VDLYLLMDCSGSΓRR Pf.SSP2.47 Pf 3125.0 3120.9 26688.0 >35906.62
^ 27.0410 VKNVSQTNFKSLLRN Pf.LSA1.89 Pf 2937.8 1669.1 6441.2 3182.2
* 1188.48 WILTDGΓPDSIQDS Pf.SSP2.157 Pf 50000.0 663.6 11707.3 >35906.62
F150.03 YADSAWENVKNVIGPFMKAV Pf.SSP2. Pf 69.7 >51961.52 >4008.92
191.16 ADLIAY'LKQATAK Pigeon. CytochromeC.92 Pigeon 80.7 12500.0
12.04 DLIAYLKQATAK Pigeon.CytochromeC. 88 Pigeon A 217.4 4166.7
12.05 ERADLIAYLKQATAK Pigeon.CytochromeC. 88 Pigeon A 57.5 1612.9
12.03 TAYLKQATAK Pigeon. CytochromeC. 88 Pigeon A 1000.0 12500.0
191.10 KAERADLIAY'LKQATA Pigeon. CytochromeC. 88 Pigeon 2500.0 12500.0
199.17 LIAY'LKQATAK Pigeon.CytochromeC. 94 Pigeon 172.4 4545.5
F025.08 AATYNFAVLKLMGRGTKF PLP.260 PLP >17256.71 3000.0
K-09 FLYGALLLAEGFYTTGAVRQ PLP.81 PLP
F050.02 FLYGALLLAEGFYTTGAVRQ PLP.81 PLP >37242.26 502.9
K-28 FNTWTTCQSIAFPS PLP.178 PLP
K-20 LCADARMYGVLPWNAFPGK PLP.201 PLP
V
K-05 LTGTEKLIETYFSKNYQDYE PLP.41 PLP
F025.05 QKGRGYRGQHQAHSLERVCH PLP.121 PLP >15389.68 495.3
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl *0101 *0301 *0401 *0404 *0405
K-18 SAVPVYIYFNTWTTCQSIAF PLP.171 PLP
F050.05 SAVPVYTYFNTWTTCQSIAF PLP.171 PLP 27272.7 202.7
K-16 TAEFQMTFHLFIAAFVGAAA PLP.231 PLP
F025.03 WTTCQSIAFPSKTSASIGSL PLP.181 PLP 17307.7 126.0
68.0066 AΉCTRNKSVILLGRH PSA.60 PSA 578.1 29704.4 386.8
68.0078 CAQVHPQKVTKFMLC PSA.180 PSA 10206.2 14433.8
68.0079 GGPLVCNGVLQGITS PSA.210 PSA 3353.3 382.9
68.0080 GPLVCNGVLQGITSW PSA.211 PSA 1724.0 169.9
68.0069 GQVFQVSHSFPHPLY PSA.83 PSA 288.4 45000.0 45.9 68.0062 GRAVCGGVLVHPQWV PSA.42 PSA 386.5 >129903.81
M 68.0063 GVLVHPQWVLTAAHC PSA.48 PSA 87.3 21320.1 378.4
« 68.0073 HDLMLLRLSEPAELT PSA.115 PSA 62.1 2867.5 34833.4
68.0064 HPQWVLTAAHCrRNK PSA.52 PSA 13.1 3631.5 9117.5 68.0158 HSLFHPEDTGQVFQV PSA.74 PSA 65260.2 68.0077 LHVISNDVCAQVHPQ PSA.172 PSA 789.0 8318.4 4443.4
68.0081 NGVLQGITSWGSEPC PSA.216 PSA 944.9 24942.3 3149.4
68.0071 PHPLYDMSLLKNRFL PSA.93 PSA 1315.5 116928.6
68.0065 QWVLTAAHCTRNKSV PSA.54 PSA 49.8 109141.0
68.0082 RPSLYTKWHYRKWI PSA.235 PSA 6041.0 53785.3 1904.2
68.0072 SHDLMLLRLSEPAEL PSA.114 PSA 531.8 6214.7 22786.6 68.0061 SQPWQVLVASRGRAV PSA.31 PSA 66.0 >67840.05 42905.8
68.0067 SVILLGRHSLFHPED PSA.67 PSA 717.2 1399.7 71151.3 68.0059 SVTWIGAAPLILSRI PSA.7 PSA 4.1 >67840.05 17732.5 68.0074 TDAVKVMDLPTQEPA PSA.129 PSA >50000 >225000 68.0058 TLSVTWIGAAPLILS PSA.5 PSA 3.1 >67840.05 40909.1
68.0070 VFQVSHSFPHPLYDM PSA.85 PSA 15.5 >63012.6 139.2
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl *oιoι *0301 *0401 *0404 *0405
68.0068 VILLGRHSLFHPEDT PSA.68 PSA 273.0 8743.6 46169.0
68.0060 VTWIGAAPLILSRΓV PSA.8 PSA 8.1 >67840.05 45000.0
68.0125 ADKΓYSISMKHPQEM PSM.608 PSM 22360.7 29867.8
68.0101 AEAVGLPSrPVHPIG PSM.284 PSM 5.4 55815.6
68.0102 AVGLPSTPVHPIGYY PSM.286 PSM 3.6 23586.4
68.0113 CTPLMYSLVHNLTKE PSM.466 PSM 92.9 19437.0 1378.3
68.0114 DFEVFFQRLGIASGR PSM.520 PSM 143.0 1244.5 68.0118 DPMFKYHLTVAQVRG PSM.567 PSM 5.7 >63012.6 51.2 68.0181 DQLMFLERAFTDPLG PSM.666 PSM >14078.28 68.0111 DSSIEGNYTLRVDCT PSM.453 PSM 16666.7 18898.2
68.0167 EDFFKLERDMKΓNCS PSM.183 PSM 2709.8 468.5 1269.5 to
4-
© 68.0109 ERGVAYTNADSSTEG PSM.444 PSM 2439.8 38031.9
68.0115 EVFFQRLGIASGRAR PSM.522 PSM 28.0 >63012.6 123.8 68.0100 EYAYRRGIAEAVGLP PSM.276 PSM 5.1 1196.9
68.0168 FFKLERDMKTNCSGK PSM.185 PSM 4419.2 73.0 2719.0 68.0173 GAAWHETVRSFGTL PSM.391 PSM 12409.1
68.0096 GKVFRGNKVKNAQLA PSM.206 PSM 611.6 6115.2 68.0123 GMVFELANSrVLPFD PSM.582 PSM 15.0 4603.7 1295.1 68.0090 GNEIFNTSLFEPPPP PSM.135 PSM 20412.4 >60133.78
68.0097 GNKVKNAQLAGAKGV PSM.211 PSM 677.0 75000.0
68.0110 GVAYLNADSSIEGNY PSM.446 PSM 1054.1 823.4 68.0170 GVTLYSDPADYFAPG PSM.224 PSM 1565.9 17.1 42232.7
68.0103 IGYYDAQKLLEKMGG PSM.297 PSM 1923.1 71151.3 68.0086 IKKFLYNFTQIPHLA PSM.70 PSM 449.1 8079.6 240.4 68.0166 ISITNEDGNETFNTS PSM.128 PSM 506.7 559.2 >51888.14
68.0126 TYSISMKHPQEMKTY PSM.611 PSM 8451.5 90000.0
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl *0101 *0301 *0401 *0404 *0405
68.0087 KFLYNFTQTPHLAGT PSM.72 PSM 340.2 13805.4 1221.8
68.0120 KYHLTVAQVRGGMVF PSM.571 PSM 136.9 33658.1 4531.8 68.0089 LAHYDVLLSYPNKTH PSM.110 PSM 78.6 37532.6 6284.8 68.0085 LDELKAENTKKFLY PSM.62 PSM 1136.4 1369.9 27235.2 68.0084 LGFLFGWFTKSSNEA PSM.35 PSM 10.4 >63012.6 7524.1 68.0131 LPJVIMNDQLMFLERAF PSM.661 PSM 2703.7 2204.1 68.0119 MFKYHLTVAQVRGGM PSM.569 PSM 15.8 29032.3 98.7
68.0176 NSRLLQERGVAYTNA PSM.438 PSM 613.6 317.8 28624.2 68.0112 NYTLRVDCTPLMYSL PSM.459 PSM 6804.1 45.1 55.8
68.0127 PQEMKTYSVSFDSLF PSM.619 PSM 15142.7 17010.0 68.0083 PRWLCAGALVLAGGF PSM.18 PSM 46.5 >60133.78
68.0135 QIYVAAFTVQAAAET PSM.731 PSM 1.6 26609.1 9.1 68.0122 RGGMVFELANSTVLP PSM.580 PSM 10.3 37117.9 1288.1
68.0133 RFfVTYAPSSHNKYAG PSM.688 PSM 2173.9 2705.3
68.0134 RQIYVAAFTVQAAAE PSM.730 PSM 3.7 28347.3 6.9 68.0105 TGNFSTQKVKMHTHS PSM.334 PSM 11180.3 4687.8
68.0116 TNKFSGYPLYHSVYE PSM.543 PSM 3402.1 31053.0 68.0107 TRTYNVIGTLRGAVE PSM.353 PSM 14.3 33333.3 35.4
68.0128 TYSVSFDSLFSAVKN PSM.624 PSM 219.1 110.1 410.0
68.0136 VAAFTVQAAAETLSE PSM.734 PSM 14.5 >63012.6 326.5
68.0121 VAQVRGGMVFELANS PSM.576 PSM 228.2 3724.7
68.0177 VAYINADSSΓEGNYT PSM.447 PSM 4716.5 530.9 2310.6 68.0124 VFELANSTVLPFDCR PSM.584 PSM 19.2 667.4 5617.5 68.0130 VLPsJvTMNDQLMFLERA PSM.660 PSM 117.6 182.7 161.7
68.0088 WKEFGLDSVELAHYD PSM.100 PSM 1138.8 84.8 540.1
68.0117 YDPMFKYHLTVAQVR PSM.566 PSM 9.0 >63012.6 106.2
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl *0101 *0301 *0401 *0404 *0405
68.0165 YISITNEDGNEIFNT PSM.127 PSM 497.9 397.1 3510.5
68.0132 YRHVTYAPSSHNKYA PSM.687 PSM 94.6 >63012.6 1597.6
FI 12.02 VDAQGTLSRLFKLGGRDSRS Rabbit.144 Rabbit
938.01 KVNNQWSLKPEITVDQEY Rabiesvirus. Rabiesvirus 23.6 7500.0 1752.5
F160.32 STORKUSP32 RAGE. RAGE 392.6 91.5
F160.34 STORKUSP34 RAGE. RAGE >24771.68 721.6
F160.36 STORKUSP36 RAGE. RAGE 658.5 7.5
F160.37 STORKUSP37 RAGE. RAGE 898.3 99.2
F160.39 STORKUSP39 RAGE. RAGE >19733.81 40.3
F047.09 DKLKQQRDTLSTQKET RHD.81 RHD t F047.16 EQKSKQNIGALKQEL RHD. RHD fe 938.06 SGGTNYAQKFQGRVTMTRDT Rheumatiodvector Rheumatiodvector 668.2 5625.0 >16666.67
-NH2
938.08 ELSRLSDDTAVYYCARAPG- Rheumatiodvector Rheumatiodvector 110.1 304.0 10000.0 NH2
938.09 ELSRLTSDDTAVYYCAIAPG- Rheumatiodvector Rheumatiodvector 130.0 653.6 2344.0 NH2
938.10 TISCSGSSSNIGSNTVN-NH2 Rheumatiodvector Rheumatiodvector 50000.0 147.1 2646.3
F015.05 APYHFDLSGHA Ryegrass.Lolpl Ryegrass
791.08 APYHFDLSGHAF Ryegrass.Lolp 1.101 Ryegrass 37.5
791.07 APYHFDLSGHAFGS Ryegrass.Lolpl.101 Ryegrass 10.0
791.06 APYHFDLSGHAFGSMA Ryegrass.Lolp 1.101 Ryegrass 28.1
791.05 APYHFDLSGHAFGSMAKK Ryegrass.Lolpl.101 Ryegrass 40.9
620.11 APYHFDLSGHAFGSMAKKGE Ryegrass.Lolpl Ryegrass 50000.0 25980.8 25.0 500000.0
620.05 CGYKDVDKAPFNGMTGCGN Ryegrass.Lolp 1.41 Ryegrass 50000.0 90.0 3750.0 500000.0
T
807.03 DLSGHAFGS Ryegrass.Lolpl.106 Ryegrass 450000.0
595.02 EDVΓPEGWKADTSYSAK Ryegrass.Lolp 1.80 Ryegrass 50000.0 60.8 500000.0
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl *0101 *0301 *0401 *0404 *0405
620.14 ELQFRRVKCKYPDDTKPTFH Ryegrass.Lolp 1.131 Ryegrass 50000.0 >30000 3750.0 500000.0
620.13 EQNVRSAGELELQFRRVKCK Ryegrass.Lolpl.121 Ryegrass 50000.0 3750.0 500000.0
620.20 ESWGAVWRTDTPDKLTGPFT Ryegrass.Lolpl Ryegrass 2500.0 3128.2 3750.0 333.3
791.02 FDLSGHAFGSMAKKGE Ryegrass.Lolp 1.105 Ryegrass 450000.0
620.18 GDWAWDIKEKGKDKWIEL Ryegrass.Lolpl Ryegrass 50000.0 321.6 3750.0 50000.0
K
MA-05 GEKRAYAASDPGRYC Ryegrass.Lolpl Ryegrass 50000.0 450000.0 500000.0
620.19 KGKDKWIELKESWGAVWRID Ryegrass.Lolp 1.181 Ryegrass 1666.7 >30000 3750.0 8333.3
791.03 LSGHAFGSMAKKGE Ryegrass.Lolp 1.107 Ryegrass 450000.0
620.23 SEVEDVTPEGWKADTSYSAK Ryegrass.Lolp 1.221 Ryegrass 5000.0 725.8 50000.0
MA-06 VAYESSEIASKKAG Ryegrass.Lolpl Ryegrass 50000.0 714.3 12500.0 620.16 VEKGSNPNYLAILVKYVDGD Ryegrass.Lolpl.151 Ryegrass 200.0 >30000 3750.0 500000.0
791.09 YHFDLSGHAFGS Ryegrass.Lolp 1.103 Ryegrass 19.6
791.01 YHFDLSGHAFGSMAKKGE Ryegrass.Lolpl.103 Ryegrass 38.1
620.15 YPDDTKPTFHVEKGSNPNYL Ryegrass.Lolp 1.141 Ryegrass 1000.0 >30000 1607.1 500000.0
F165.05 KSDNQΓKAVPASQALVA Sm.eggantigen.235 Sm 4.3 86.7 58.0
F165.01 PKSDNQΓKAVPAS Sm.eggantigen.234 Sm 4350.5 >504.69 2858.8
F165.03 PKSDNQΓKAVPASQA Sm.eggantigen.234 Sm 19.2 326.3 78.1
FI 65.02 VRPKSDNQΓKAVPAS Sm.eggantigen.232 Sm 5154.6 3324.4 375.6
213.16 FRKDIAAKYKELGY Spermwhale.Myoglobin.138 Spermwhale 1080.2 1000.0
213.15 LFRKDIAAKYKELGY Spermwhale.Myoglobin.137 Spermwhale 427.2 737.7
542.00 NKALELFRKDIAA Spermwhale.Myoglobin.132 Spermwhale 3500.2 2250.0
213.12 NKALELFRKDIAAK Spermwhale.Myoglobin.132 Spermwhale 2547.6 2045.5
213.11 NKALELFRKDIAAKY Spermwhale.Myoglobin.132 Spermwhale 2593.4 775.9
13.00 NKALELFRKDIAAKYKELGY Spermwhale.Myoglobin.132 Spermwhale 37.0 300.0
QG
213.17 RKDIAAKYKELGY Spermwhale.Myoglobin.139 Spermwhale >6634.89 2250.0
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl
*0101 *0301 *0401 *0404 *0405
NASE061-80 FTKKMVENAKKIEVEFDKGQ Staph..Nase.61 Staph. 1000.0 11619.0 2812.5 500000.0
F015.01 GLAKVAY KP StapL.Nase.101 Staph.
NASE121-140 HEQHLRKSEAQAKKEKLNTW Staρh..Nase.l21 Staph. 50000.0 90000.0 450000.0 16666.7
191.26 LVRQGLAKVAY Staph..Nase.l03 Staph. 166.7 450000.0 500000.0 NASE011-30 PATLIKAIDGDTVKLMYKGQ StapL.Nase.i l Staph. 277.8 6428.6 1666.7 3846.2 NASE031-50 PMTFRLLLVDTPETKHPKKG Staph..Nase.31 Staph. 104.2 45000.0 1216.2 574.7 191.29 QGLAKVAYVYK StapL.Nase.106 Staph. 50000.0 450000.0 500000.0
191.28 RQGLAKVAYW StapL.Nase.105 Staph. 50000.0 450000.0 10000.0
NASE041-60 TPETKHPKKGVEKYGPEASA Staph..Nase.41 Staph. 1000.0 900000.0 2812.5 500000.0
NASE051-70 VEKYGPEASAFTKXMVENAK Staph..Nase.51 Staph. 50000.0 900000.0 7500.0 500000.0
191.27 VRQGLAKVAYV StapL.Nase.104 Staph. 106.4 450000.0 5000.0 NASE091-110 YTYADGKMVNEALVRQGLAK Staph..Nase.91 Staph. 64.9 2812.5 4166.7 546.00 FTKKMVENAKKIEVEFDKGQ Staph.nuc.61 StapLnuc 50000.0 2676.2 22500.0 50000.0
866.05 HEQHLRKSEAQAKKEKLNΓW Staρh.nuc.121 StapLnuc 50000.0 6428.6 22500.0 50000.0 598.00 PATLIKAIDGDTVKLMYKGQ Staph.nuc.il StapLnuc 1250.0 63.1 937.5 1388.9
866.06 QAKKEKLNTWSEDNADSGQ Staph.nuc.131 StapLnuc 50000.0 >45000 473.7 5000.0
866.02 VEKYGPEASAFTKKMVENAK Staph.nuc.51 StapLnuc 5000.0 >45000 9000.0 500000.0 866.04 YTYADGKMVNEALVRQGLAK Staph.nuc.91 StapLnuc 119.1 260.9 22500.0 16666.7
835.03 YGAVDSILGGVATYGAA-NH2 Stp.dt...l Stp.dt. 59.5 >15000 1216.2 259.1 F178.08 AGTIAALNNSIGVLG Subtilisin.69 Subtilisin 43.1 >25139.39 2234.7 114.4 857.1 F178.10 GSISYPARYANAMAV Subtilisin.157 Subtilisin 1389.5 17180.3 11296.9 6016.0 8624.5 F178.06 GTVAALDNSAGVLGV Subtilisin.70 Subtilisin 163.2 2891.9 964.4 10.4 1283.8 F178.05 GTVAALDNSIGVLGV Subtilisin.70 Subtilisin 15.1 236.4 133.3 17.1 757.2 F178.03 GTVAALNNSAGVLGV Subtilisin.70 Subtilisin 19.5 11702.2 598.7 16.3 1304.3 F178.01 GTVAALNNSIGVLGV Subtilisin.70 Subtilisin 6.8 3999.2 156.0 7.1 186.9 F178.09 IAALNNSIGVLGVAP Subtilisin.72 Subtilisin 6.6 15938.9 283.5 10.0 1610.6
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl *0101 *0301 *0401 *0404 *0405
F178.04 NGIEWAIANNMDVAN Subtilisin.109 Subtilisin 7.7 21675.5 69.1 109.4 15.4
F178.02 NGIEWAIAxWQyTDVrN Subtilisin.109 Subtilisin 8.3 32040.0 77.4 168.4 37.4
F178.i l SYPARYANAMAVGAT Subtilisin.160 Subtilisin 11.0 >25139.39 142.4 6091.5 1437.1
F178.07 TGSGVKVAVLDTGIS Subtilisin.22 Subtilisin >10270.85 35587.8 >28708.41 2709.1 5964.0
573.13 ANSKFIGITELKK TetTox.834 TetTox 50000.0 11250.0
573.12 IKANSKFIGITELKK TetTox.832 TetTox 50000.0 11250.0
597.10 ILMQYΓKANS TetTox.827 TetTox 5000.0 1875.0
L-05 QAΓKANSKFIGΠΈ TetTox.830 TetTox A 50000.0 450000.0
650.05 QEΓKANSKFIGITE TetTox.830 TetTox A 5000.0 1748.3 11250.0 50000.0
650.06 QSΓKANSKFIGITE TetTox.830 TetTox A 5000.0 4880.9 11250.0 50000.0
650.21 QYΓKANQKFIGITE TetTox.830 TetTox A 5000.0 958.3 11250.0 50000.0
650.29 QYΓKANSKFKGITE TetTox.830 TetTox A 5000.0 135.4 7500.0 500000.0
650.14 QYIKKNSKFIGITE TetTox.830 TetTox A 2000.0 36.0 11250.0 500000.0
650.16 QYTKSNSKFIGITE TetTox.830 TetTox A 2500.0 4330.1 11250.0
650.13 QYTRANSKFIGITE TetTox.830 TetTox A 100.0 798.0 11250.0 500000.0
573.14 SKFIGITELKK TetTox.836 TetTox 1250.0 15000.0
548.02 YNGQIGNDPNRDIL TetTox. TetTox 1666.7
534.02 DTPYLDITYHFVMQRLPL Torp.Ac.californica.195 Torpedocalifornica 384.6 0.0 900.0 500000.0
1385.07 GELIGILNAAKVPAD TPI.23 TPI 9.0 9674.3 321.8 22.1
F167.ll ALHTYMDGTMSQVQGSA Tyrosinase.365 Tyrosinase 442.3 91.5 17.8 31.8
F167.12 ALHIYMNGTMSQVQGSA Tyrosinase.365 Tyrosinase 526.4 26631.2 3418.4 174.6
F089.22 DQSYLQDSDPDSFQD Tyrosinase.448 Tyrosinase A 923.2
F089.13 DYSFLQDSDPDSFQD Tyrosinase.448 Tyrosinase A >50000 563.6
F089.25 DYSYFQDSDPDSFQD Tyrosinase.448 Tyrosinase A 507.2
1385.10 DYSYLQDSDPDSFQD Tyrosinase.448 Tyrosinase >9128.71 39391.9 859.9 >27277.24
F089.l l DYSYLQDSVPDSFQD Tyrosinase.448 Tyrosinase A 71428.6 156.0 >62500 >45746.62
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequ Source Ag Analog DRBl DRBl DRBl DRBl DRBl 0101 *0301 *0401 *0404 *0405
F089.24 DYSYQQDSDPDSFQD Tyrosinase.448 Tyrosinase A 996.3
1385.09 FLLHHAFVDSΓFEQWLQRHRP Tyrosinase.386 Tyrosinase 10245.9 707.1 >2758.62 11258.7
F089.18 ILLSNAPLGPQFP Tyrosinase.58 Tyrosinase 869.5 32142.9
F089.20 NILLSNAPLGPQFP Tyrosinase.57 Tyrosinase 60.0 338.8
F089.06 QNFLLSNAPLGPQFP Tyrosinase.56 Tyrosinase A 5.1 61.9 3803.0 217.8
F089.28 QNTFLSNAPLGPQFP Tyrosinase.56 Tyrosinase A 321.4
F089.04 QNILLSNAPQGPQFP Tyrosinase.56 Tyrosinase A 297.4 2041.2
F089.33 QNILLSNAQLGPQFP Tyrosinase.56 Tyrosinase A 303.4
F089.34 QNILLSNAVLGPQFP Tyrosinase.56 Tyrosinase A 159.9
F089.03 QNILLSNQPLGPQFP Tyrosinase.56 Tyrosinase A 238.0 7763.2 w F089.07 QNILLSNVPLGPQFP Tyrosinase.56 Tyrosinase A 48.2 12.7 32.1 162.0
^ F089.30 QNILQSNAPLGPQFP Tyrosinase.56 Tyrosinase A 758.6
F089.32 QNILVSNAPLGPQFP Tyrosinase.56 Tyrosinase A 619.9
F089.27 QNIQLSNAPLGPQFP Tyrosinase.56 Tyrosinase A 774.6
F089.29 QNTVLSNAPLGPQFP Tyrosinase.56 Tyrosinase A 99.5
F089.19 QNVLLSNAPLGPQFP Tyrosinase.56 Tyrosinase A 58.9 996.3
F089.15 SYLQDSDPDSFQD Tyrosinase.450 Tyrosinase >50000 346.0
F089.21 SYLQDSVPDSFQD Tyrosinase.450 Tyrosinase A >50000 63.0 166666.7 3084.7
FI 67.09 WPSVFYNRTCQCSGNF Tyrosinase.80 Tyrosinase 32258.1 >17822.66 >3801.38 36791.8
F167.10 YGQMKNGSTPMFNDINTYDL Tyrosinase.156 Tyrosinase 1123.0 5706.9 1436.3 1086.3
F089.16 YLQDSDPDSFQD Tyrosinase.451 Tyrosinase >50000 567.4
F089.14 YSYLQDSDPDSFQD Tyrosinase.449 Tyrosinase >50000 247.7
604.01 (AKA)6 Unknown u 625.0 9000.0 500000.0
848.01 A(56)FAAAA(24)A(56)AA(57)- Unknown u 1.3 1.1 2.8
NH2
848.03 A(56)FAAAA(24)L(56)AA(57)- Unknown 6.4 2.5 25.0
NH2
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl 0101 *0301 *0401 *0404 *0405
848.05 23.0 12.9 50.0
848.07 A(56)FAAAATL(56)AA(57)- Unknown 2.5 11.3 38.5 NH2
F042.01 A(X)KQNTLKLAT Unknown u 5.5
848.02 AAFAAAA(24)A(56)AA(57)- Unknown u 1.1 8.2 38.5 NH2
848.04 AAFAAAA(24)L(56)AA(57)- Unknown 2.4 2.0 31.3 NH2
848.06 AAFAAAATA(56)AA(57)-NH2 Unknown u 2.5 2.7 9.6
848.08 AAFAAAATL(56)AA(57)-NH2 Unknown u 1.1 4.1 7.9
603.01 AHAAHAAHAAHAAHAAY Unknown u 20.8 9000.0 2173.9
FI 82.04 EVTPMFSALSEGA Unknown u 22.0 >51970.13 881.9 87.0 205.5
5 520.05 EVWREEAYHAADTKD Unknown u 135.1 30000.0 4090.9 16666.7
520.06 EVWREEAYHAADTKDY Unknown u 250.0 45000.0 500000.0
852.04 KYVKQNTLKLAT Unknown u 9.9 34.6 25000.0
852.05 KYVKQNTLKLAT Unknown u 14.9 30.0 500000.0
F182.09 LNKTVRMYSPTSI Unknown u 10.9 >61289.42 177.9 17.6 14.6
F182.10 NKΓVRMYSPTSIL Unknown u 11.0 >51970.13 135.0 40.8 90.8
F042.06 P(X)KQNTLKLAT Unknown u A 1.7
F042.07 P(X)KQNTLKLAT Unknown u A 14.9
F182.03 PEVIPMFSALSEG Unknown u 17.1 >51970.13 123.2 20.8 22.5
F182.01 PTVQNIQGQMVHQ Unknown u 28.0 >59528.21 227735.0 11756.6 4074.0
F042.02 PKFV(X)TLKLAT Unknown u A 6.2
F042.05 PKFVKQNTL(X)T Unknown u A 7.9
F042.03 PKFVQ(X)KLAT Unknown u A 6.9
F182.08 QEQIGWMTNNPPI Unknown u 1765.4 >51970.13 1958.1 240.6 158.5
832.01 TFGLQLELTEGMRFDKG Unknown u 50000.0 161.0 918.4 16666.7
TABLE 27a
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl
0101 *0301 *0401 *0404 *0405
173.00 TYQRTRALVTG Unknown u 2500.0 900000.0 450000.0 500000.0
F182.02 VQNIQGQMVHQAI Unknown u 138.2 >51970.13 1338.7 240.1 2952.5
835.01 YTDVWLGGLAENFLP-NH2 Unknown u 50000.0 90000.0 15000.0 50000.0
785.02 YKKSIQFHWKNSNQIKILG Unknown u 217.4 2142.9 1562.5
843.03 YKLNDRADSRRSL Naturallyprocessed u 50000.0 450000.0 500000.0
F002.02 YKPVSQLRLATPLLLRPL Unknown u 0.3 58.5 851.9 86.9
835.02 YLDPLTRGLLARPAKLQV- Unknown u 1.5 900000.0 3750.0 44.3 NH2
F002.01 YLPKPPKPVSKLRLATPLLLQ Unknown u 0.8 565.8 1227.5 435.2 ALPL
824.07 (14)AAAKTAAAFA-NH2 Artificialsequence 1.8 0.9 4.4
824.08 (15)AAAKTAAAFA-NH2 Artificialsequence 1.4 0.9 3.1 820.03 (15A)RQTTLKAAA-NH2 Artificialsequence A 4.2 1.8 4.3
820.05 (15A)RQTTLKAAA-NH2 Artificialsequence A 2500.0 15.3 1851.9
824.09 (16)AAAKTAAAFA-NH2 Artificialsequence 10.9 1.0 50.3
820.04 (16A)RQTTLKAAA-NH2 Artificialsequence A 454.6 7.1 37.0
853.01 " (39)AAAATKAA(35)-NH2 Artificialsequence A 250.0 1184.2 25000.0
853.02 (39)AAAATKAA(36)-NH2 Artificialsequence A 833.3 818.2 50000.0
853.03 (39)AAAATKAA(37)-NH2 Artificialsequence A 131.6 957.5 25000.0
824.37 (39)AAAATKAAAA Artificialsequence 156.3 616.4 12500.0
856.04 (39)AAAKTAAA(35)-NH2 Artificialsequence 76.9 2.5 294.1
824.03 (39)-AAAKTAAAFA-NH2 Artificialsequence 5.6 900000.0 1.0 13.2
824.21 (39)AAAKTAAAF-NH2 Artificialsequence 555.6 25.1 1282.1
824.26 (39)AAKTAAAFA-NH2 Artificialsequence 714.3 600.0 2083.3
824.02 (40)-AAAKTAAAFA-NH2 Artificialsequence 52.1 900000.0 11.4 22.7
717.63 (42)YARFQSQTTLKAKT-NH2 Artificialsequence 21.8 22500.0 7.7 38.5
787.34 (43)AADFFFFFFFFDA-(NH2) Artificialsequence 50000.0 483.9 500000.0
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl *0101 *0301 *0401 *0404 *0405
787.43 (43)AAFGΓDTFGFKIA-(NH2) Artificialsequence 50000.0 803.6 500000.0
824.11 (45)AAAKTAAAFA-NH2 Artificialsequence 833.3 23.2 9.1
824.28 (46)AAAATKAAAA Artificialsequence 17.9 692.3 16666.7
824.12 (46)AAAKTAAAFA-NH2 Artificialsequence 9.6 0.6 16.7
824.29 (47)AAAATKAAAA Artificialsequence 263.2 2812.5 33333.3
824.13 (47)AAAKTAAAFA-NH2 Artificialsequence 83.3 3.8 127.9
824.14 (48)AAAKTAAAFA-NH2 Artificialsequence 625.0 5.9 20.6
824.31 (49)AAAATKAAAA Artificialsequence 15.2 36.3 684.9 862.06 (49)AAAKTAA(64)A-NH2 Artificialsequence 263.2 5.2 505.1 856.03 (49)AAAKTAAA(35)-NH2 Artificialsequence 20.4 1.3 33.3
M 862.07 (49)AAAKTAAA(64)-NH2 Artificialsequence 9.2 0.9 12.8 o 862.01 (49)AAAKTAAAAA-NH2 Artificialsequence 6.2 0.5 5.8
824.15 (49)AAAKTAAAFA-NH2 Artificialsequence 2.6 0.5 2.0 824.23 (49)AAKTAAAFA-NH2 Artificialsequence 312.5 5000.0 2173.9
824.32 (50)AAAATKAAAA Artificialsequence 500.0 5000.0 520.8
824.16 (50)AAAKTAAAFA-NH2 Artificialseq :μiιence 128.2 2.5 1.2 824.45 (51)AAAATKAAAA Artificialsequence 49.5 175.1 381.7
824.43 (51)AAAKTAAAFA-NH2 Artificialsequence 13.2 1.7 6.5
824.44 (52)AAAKTAAAFA-NH2 Artificialsequence 83.3 17.5 43.5
824.51 (53)AAAATKAAAA Artificialsequence 666.7 2250.0 7142.9
824.47 (53)AAAKTAAAFA-NH2 Artificialsequence 208.3 5.5 38.5
824.52 (54)AAAATKAAAA Artificialsequence 454.6 584.4 2000.0
824.48 (54)AAAKTAAAFA-NH2 Artificialsequence 172.4 5.5 32.7 824.50 (5 .)AAAKTAAAFA-NH2 Artificialsequence 1250.0 149.0 13.3 601.42 (65)(66)PKFVKQNTLKLAT Artificialsequence 7.4 47.2 400.0 752.03 (67)AAYAAAAAAKAA-NH2 Artificialsequence 16.3 102.3 500000.0
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl *0101 *0301 *0401 *0404 *0405
752.02 (67)FAAAAAAKAA-NH2 Artific talsequence A 7.4 143.8 500000.0
858.07 (CP)-QSQTTLKAKT-NH2 Artific talsequence 166.7 900000.0 0.8 11.6
859.03 (CP)YAAFQRQTTLKAAA-NH2 Artific talsequence 7.7 900000.0 0.6 1.2
Sandoz374 (NAF)AAAKTAAAFA-NH2 Artific talsequence 20.0 4.5 49.5
934.15 (X2)KSSQYrKANSKFIGITEAA Artific talsequence A 559.0 3198.0 >50000
AFLPSDFFPSV 803.11 A(14)AAAKTAAAAA-CONH2 Artific alsequence 1.3 45000.0 1.6 9.4
838.02 A(14)AAAKTAAAA-NH2 Artific alsequence 61.0 2.7 33.3
760.73 A(14)AAAKTAAAFA-NH2 Artific alsequence A 50000.0 290.3 25000.0
838.01 A(14)AAAKTAAA-NH2 Artific alsequence 39.4 2.5 53.8
838.04 A(14)AAAKTAAA-NH2 Artific talsequence 416.7 25.7 8333.3 803.10 A(14)AAAKTAA-CONH2 Artific talsequence 50000.0 109.8 500000.0
838.03 A(14)AAAKTAA-NH2 Artific talsequence 2500.0 5.6 2500.0
736.21 AA(10)AAAAAAKAAA-NH2 Artific talsequence A 1.9 14.1 25000.0
736.23 AA(12)AAAAAAKAAA-NH2 Artific talsequence A 4.6 7.5 8333.3 839.29 AA(14)A(37)ATKAAAA Artific talsequence 625.0 2812.5 16666.7
828.03 AA(14)AAAA(24)KAAAA-NH2 Artific alsequence A 1.3 10000.0 3.2 24.4
736.25 AA(14)AAAAAAKAAA-NH2 Artific alsequence A 1.9 4.4 50.5
828.01 AA(14)AAAAPKAAAA-NH2 Artific] alsequence A 0.9 16.7 467.3
906.30 AA(14)AAAATEKAAA-NH2 Artific alsequence 6.4 6240.4 14.9 20.4
906.33 AA(14)AAAATFKAAA-NH2 Artific alsequence 1.0 2383.3 1.1 3.3 906.34 AA(14)AAAATTKAAA-NH2 Artific alsequence 0.5 1505.9 2.3 3.2 839.17 AA(14)AAAATK(36)AA Artific] alsequence 5000.0 750.0 500000.0
839.31 AA(14)AAAATK(37)AA Artific alsequence 555.6 937.5 4545.5
839.06 AA(14)AAAATKA(35)A Artific alsequence 1666.7 441.2 500000.0
839.18 AA(14)AAAATKA(36)A Artific alsequence 217.4 80.9 12500.0
839.32 AA(14)AAAATKA(37)A Artific alsequence 113.6 30.0 1612.9
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl *0101 *0301 *0401 *0404 *0405
839.20 AA(14)AAAATKAA(35)-NH2 Artificialsequence 1.8 1.7 41.7
839.24 AA(14)AAAATKAA(36)-NH2 Artificialsequence 0.8 1.9 45.5
839.35 AA(14)AAAATKAA(37)-NH2 Artificialsequence 0.7 5.6 25.0
839.25 AA(14)AAAATKAAAA Artificialsequence 1.1 3.2 29.4
828.11 AA(14)AAAATKAAAA-NH2 Artificialsequence A 1.5 45000.0 2.8 11.4
906.29 AA(14)AAAATKKAAA-NH2 Artificialsequence 3.2 >16431.68 4.7 43.1
906.35 AA( 14)AAAATLEAAA-NH2 Artificialsequence 1.7 2675.1 4.0 5.0
906.38 AA(14)AAAATLFAAA-NH2 Artificialsequence 2.8 >16431.68 3.0 6.8
760.57 AA(14)AAAATLKAAA-NH2 Artificialsequence A 1.4 1165.6 2.1 3.5
906.47 AA(14)AAAATLKAEA-NH2 Artificialsequence 3.3 7862.2 2.8 8.2
906.50 AA(14)AAAATLKAFA-NH2 Artificialsequence 0.5 117.4 1.9 3.3 906.48 AA(14)AAAATLKAQA-NH2 Artificialsequence 0.5 2433.3 2.3 5.5
906.49 AA(14)AAAATLKAVA-NH2 Artificialsequence 0.6 503.5 3.2 3.5
906.41 AA(14)AAAATLKEAA-NH2 Artificialsequence 240.6 4129.5 9.2 229.7
906.44 AA(14)AAAATLKFAA-NH2 Artificialsequence 2.2 59.6 2.9 37.1
906.45 AA(14)AAAATLKIAA-NH2 Artificialsequence 1.1 921.1 2.2 21.1
906.40 AA(14)AAAATLKKAA-NH2 Artificialsequence 79.1 386.4 11.3 29.9
906.42 AA(14)AAAATLKQAA-NH2 Artificialsequence 11.8 1214.9 5.2 7.3
906.43 AA(14)AAAATLKVAA-NH2 Artificialsequence 0.5 285.8 1.8 15.7
906.36 AA(14)AAAATLQAAA-NH2 Artificialsequence 2.6 1019.3 2.9 4.9
906.39 AA(14)AAAATLRAAA-NH2 Artificialsequence 1.1 790.2 3.9 3.1
906.31 AA(14)AAAATQKAAA-NH2 Artificialsequence 0.6 3602.9 4.3 12.4
906.32 AA(14)AAAATVKAAA-NH2 Artificialsequence 0.3 3834.1 3.5 3.4
906.24 AA(14)AAAETLKAAA-NH2 Artificialsequence 1.5 1004.8 4.0 4.5
906.27 AA(14)AAAFTLKAAA-NH2 Artificialsequence 0.5 1252.7 2.4 1.3
856.02 AA(14)AAAKTAAA(35)-NH2 Artificialsequence A 1.6 2.1 7.8
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl *0101 *0301 *0401 *0404 *0405
760.50 AA(14)AAAKTAAAAA-NH2 Artificialsequence 3.1 2345.8 2.8 7.0
906.23 AA(14)AAAKTLKAAA-NH2 Artificialsequence 0.8 672.5 2.0 4.2
906.25 AA(14)AAAQTLKAAA-NH2 Artificialsequence 1.6 581.1 2.3 4.5
906.28 AA(14)AAATTLKAAA-NH2 Artificialsequence 1.8 1058.9 4.5 7.6
906.26 AA(14)AAAVTLKAAA-NH2 Artificialsequence 1.1 680.7 3.0 2.9
906.19 AA(14)AAEATLKAAA-NH2 Artificialsequence 3.6 381.9 4.6 7.2
906.22 AA(14)AAFATLKAAA-NH2 Artificialsequence 1.7 23237.9 2.5 3.0
906.18 AA(14)AAKATLKAAA-NH2 Artificialsequence 7.0 >900 3.0 29.9
906.20 AA(14)AAQATLKAAA-NH2 Artificialsequence 1.0 17170.7 2.5 4.8
906.21 AA(14)AAVATLKAAA-NH2 Artificialsequence 0.7 4305.3 3.0 4.1
906.14 AA(14)AEAATLKAAA-NH2 Artificialsequence 6.5 3170.1 4.2 15.1 u, 906.17 AA(14)AFAATLKAAA-NH2 Artificialsequence 1.6 461.8 5.0 5.2
906.13 AA(14)AKAATLKAAA-NH2 Artificialsequence 2.6 930.8 6.1 5.0
906.15 AA(14)AQAATLKAAA-NH2 Artificialsequence 2.7 1642.4 4.1 8.5
906.16 AA(14)AVAATLKAAA-NH2 Artificialsequence 0.7 219.9 5.3 4.3
906.07 AA(14)EAAATLKAAA-NH2 Artificialsequence 3.0 1373.8 3.3 3.9
906.10 AA(14)FAAATLKAAA-NH2 Artificialsequence 1.3 783.1 5.0 2.7
906.11 AA(14)IAAATLKAAA-NH2 Artificialsequence 0.4 70.1 2.9 3.4
906.06 AA(14)KAAATLKAAA-NH2 Artificialsequence 0.8 597.6 1.7 6.4
906.12 AA(14)LAAATLKAAA-NH2 Artificialsequence 0.2 266.1 3.7 3.4
906.08 AA(14)QAAATLKAAA-NH2 Artificialsequence 1.7 653.1 6.8 4.7
906.09 AA(14)VAAATLKAAA-NH2 Artificialsequence 0.6 107.5 2.7 5.6
906.56 AA(14)WAATLKAFA Artificialsequence 0.5 27.2 1.5 4.5
828.13 AA(1 )AAAATKAAAA-NH2 Artificialsequence A 1.5 6.2 152.0
819.01 AA(15)AAKTAAAFA-NH2 Artificialsequence A 0.4 5.8 3.1
819.02 AA(15)AAKTGGGFG-NH2 Artificialsequence A 3.3 2.0 114.4
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl 0101 *0301 *0401 *0404 *0405
819.04 AA(15)GGKGGGGFG-NH2 Artificialsequence A 18.4 576.9 50000.0
819.03 AA(15)GGKTAAAFA-NH2 Artificialsequence A 0.4 1.5 50.0
819.05 AA(15)GGKTGGGFG-NH2 Artificialsequence A 94.3 16.7 5555.6
736.28 AA(17)AAAAAAKAAA-NH2 Artificialsequence A 23.8 15000.0 500000.0
736.33 AA(2)AAAAAAKAAA-CONH2 Artificialsequence A 87.7 450000.0 500000.0
773.08 AA(31)AAAAAAKAAA-NH2 Artificialsequence 6.4 37.5 500000.0
736.17 AA(6)AAAAAAKAAA-NH2 Artificialsequence A 5.0 409.1 442.5
736.18 AA(7)AAAAAAKAAA-NH2 Artificialsequence A 1.3 11.3 925.9
736.19 AA(8)AAAAAAKAAA-NH2 Artificialsequence A 2.4 18.8 649.4
736.20 AA(9)AAAAAAKAAA-NH2 Artificialsequence A 3.1 23.7 50000.0
M 736.34 AA(TIC)AAAAAAKAAA- Artificialsequence A 6.9 3214.3 10000.0
Ol J CONH2
871.14 AAAAKAATLKAAA-NH2 Artificialsequence 5000.0 288.5 463.0
760.27 AAAFAAAKTAAAFA-NH2 Artificialsequence A 1.4 398.9 1.5 17.9
730.04 AAAKAAAAAA(10)AA- Artificialsequence A 172.4 1250.0 5000.0
CONH2 730.02 AAAKAAAAAAFAA-CONH2 Artificialsequence A 714.3 937.5 500000.0
702.02 AAAKAAAAAAYAA Artificialsequence A 833.3 900000.0 1285.7 500000.0
702.06 AAAKAAAAAAYAA-COHN2 Artificialsequence A 74.6 900000.0 204.6 500000.0
789.05 AAAKAAAAAFAAA Artificialsequence 833.3 633.8 5555.6
730.07 AAAKATAAAA(23)AA- Artificialsequence A 125.0 166.7 25000.0
CONH2 787.06 AADFGIFIDFI]A-(NH2) Artificialsequence 1000.0 172.4 500000.0
736.10 AAEAAAAAAKAAA-NH2 Artificialsequence A 1000.0 22500.0 500000.0
736.07 AAFAAAAAAKAAA-NH2 Artificialsequence A 1.9 15.5 961.5
761.03 AAFAAAAAARLFA-NH2 Artificialsequence A 1.1 155.2 3846.2
828.07 AAFAAAAB(24)KAAAA-NH2 Artificialsequence A 13.6 7.6 273.2
760.71 AAFAAAATAKAAA Artificialsequence A 1.3 45000.0 2.3 11.4
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl *0101 *0301 *0401 *0404 *0405
760.41 AAFAAAATAKAAA-NH2 Artificialsequence A 1.3 90000.0 1.2 8.1
760.72 AAFAAAATLKAAA Artificialsequence A 1.9 4803.8 1.4 2.4
760.43 AAFAAAATLKAAA-NH2 Artificialsequence A 1.5 2686.9 1.4 2.9
871.12 AAFAAAATLKAKA-NH2 Artificialsequence 2.9 4.0 12.8
871.11 AAFAAAATLKKAA-NH2 Artificialsequence 500.0 22.5 135.1
760.37 AAFAAAKTAAAAA-NH2 Artificialsequence A 2.3 15000.0 1.7 9.1
803.08 AAFAAAKTAAAFA-CONH2 Artificialsequence 1.0 1.7 8.9
760.15 AAFAAAKTAAAFA-NH2 Artificialsequence A 1.3 1062.6 1.1 6.2
760.33 AAFAAAKTAAAFA-NH2 Artificialsequence A 2.2 1066.0 1.5 5.8
760.17 AAFAAAKTAAAFE-NH2 Artificialsequence A 1.2 2.1 7.3 803.13 AAFAAAKTAAAKA-NH2 Artificialsequence 2.8 6.5 8.2 760.47 AAFAAAKTLAAAA-NH2 Artificialsequence 1.9 7252.4 0.9 5.0
871.10 AAFAAAKTLKAAA-NH2 Artificialsequence 2.0 4.3 7.1
871.09 AAFAAKATLKAAA-NH2 Artificialsequence 43.1 1.1 73.1
760.70 AAFAANKNAAFAA-CONH2 Artificialsequence 108.7 62.9 25000.0
760.68 AAFAAQKQAAFAA-CONH2 Artificialsequence 500.0 6428.6 25000.0
760.69 AAFAATKTAAFAA-CONH2 Artificialsequence 185.2 29.4 8333.3
760.64 AAFAKAATAKAAA-CONH2 Artificialsequence A 2.4 45000.0 2.7 14.3
760.63 AAFAKAATLKAAA-CONH2 Artificialsequence A 3.3 8017.8 4.0 9.1
871.06 AAFAKAATLKAKA-NH2 Artificialsequence 12.8 3.2 19.2
871.05 AAFAKAATLKKAA-NH2 Artificialsequence 500.0 20.5 150.2
871.04 AAFAKAKTLKAAA-NH2 Artificialsequence 8.2 3.6 33.3
871.03 AAFAKKATLKAAA-NH2 Artificialsequence 312.5 16.7 191.6
787.05 AAFFGTFKIGKFA-(NH2) Artificialsequence 833.3 1097.6 500000.0
787.11 AAFGIKIFGFKIA-(NH2) Artificialsequence 50000.0 671.6 500000.0
871.02 AAFKKAATLKAAA-NH2 Artificialsequence 5.0 2.5 7.5
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl
*0101 *0301 *0401 *0404 *0405
770.04 AAFPPPPTLKAAA-NH2 Artificialsequence 714.3 15000.0
793.03 AAFVSQTTLKAAA Artificialsequence A 2.3 2.0 5.5
736.06 AAHAAAAAAKAAA-NH2 Artificialsequence A 17.9 45000.0 500000.0
787.03 AAIGFFFFKKGIA-(NH2) Artificialsequence 50000.0 252.8 500000.0
787.07 AAIGGIFIFKKDA-(NH2) Artificialsequence 50000.0 957.5 500000.0
736.08 AALAAAAAAKAAA-NH2 Artificialsequence A 1.9 69.2 151.5
760.09 AALKATAAAAYAA-NH2 Artificialsequence A 500.0 1406.3 500000.0
736.09 AAWAAAAAAKAAA-NH2 Artificialsequence A 1.7 23.7 8333.3
758.01 AAYA(4)A(4)AAKAAA Artificialsequence A 38.5 4500.0 500000.0
758.02 AAYAA(4)A(4)AKAAA Artificialsequence A 5.9 535.7 500000.0
_ 773.06 AAYAAAA(24)AKAAA-NH2 Artificialsequence 10.2 3.0 128.2
$ 773.02 AAYAAAA(26)AKAAA-NH2 Artificialsequence 161.3 15.0 500000.0
773.03 AAYAAAA(27)AKAAA-NH2 Artificialsequence 128.2 321.4 500000.0
773.04 AAYAAAA(28)AKAAA-NH2 Artificialsequence 5.8 11.8 12500.0
773.05 AAYAAAA(29)AKAAA-NH2 Artificialsequence 12.8 6.9 25000.0
773.07 AAYAAAA(30)AKAAA-NH2 Artificialsequence 142.9 2142.9 500000.0
702.03 AAYAAAAAAKAAA-CONH2 Artificialsequence 2.6 900000.0 6.8 500000.0
773.09 AAYAAAAPAKAAA-CONH2 Artificialsequence 1.0 33.8 25000.0
736.04 AAYAAAATAAAKA-NH2 Artificialsequence A 2.5 2.3 1724.1
736.03 AAYAAAATAKAAA-NH2 Artificialsequence A 3.9 3.1 2777.8
736.05 AAYAAAAYAAAKA-NH2 Artificialsequence A 166.7 28.1 500000.0
736.14 AAYAAJJAAKAAA-NH2 Artificialsequence A 1000.0 3214.3 500000.0
871.13 AAYAKAATLKAAA-NH2 Artificialsequence 5.5 4.0 213.7
760.58 AC-AA(14)AAAATLKAAA- Artificialsequence A 2.0 727.8 1.7 2.8 NH2
760.51 AC-AA(14)AAAKTAAAAA- Artificialsequence 7.6 4201.7 17.3 29.4 NH2
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl
*0101 *0301 *0401 *0404 *0405
730.13 AC-AAAKAAAAAA(23)AA- Artificialsequence 1000.0 548.8 1136.4 CONH2
702.08 AC-AAAKAAAAAAYAA Artificialsequence A 625.0 1956.5
702.12 AC-AAAKAAAAAAYAA- Artificialsequence A 1000.0 692.3 16666.7 CONH2
760.42 AC-AAFAAAATAKAAA-NH2 Artificialsequence A 2.5 25980.8 3.5 2.1
760.44 AC-AAFAAAATLKAAA-NH2 Artificialsequence A 3.5 2358.6 3.3 18.5
760.38 AC-AAFAAAKTAAAAA-NH2 Artificialsequence A 3.9 1.3 19.9
760.34 AC-AAFAAAKTAAAFA-NH2 Artificialsequence A 1.7 1530.9 2.5 13.5
760.48 AC-AAFAAAKTLAAAA-NH2 Artificialsequence A 17.0 16.4 111.1
760.67 AC-AAFAANKNAAFAA- Artificialsequence 500.0 44.6 25000.0 CONH2 760.65 AC-AAFAAQKQAAFAA- Artificialsequence 2500.0 5000.0 25000.0 CONH2
760.66 AC-AAFAATKTAAFAA- Artificialsequence 454.6 38.5 25000.0 CONH2
806.06 AC-YAA(10)LFLSAARKRA- Artificialsequence 5.7 300.0 500000.0 NH2
760.60 AC-YAA(14)AAAATLKAAA- Artificialsequence 3.1 2253.5 6.4 12.5 NH2
760.53 AC-YAA(14)AAAKTAAAAA- Artificialsequence A 1.2 18000.0 1.2 20.8 NH2
760.55 AC-YAAFAAAATAKAAA-NH2 Artificialsequence A 28.9 900000.0 9.6 125.0
760.46 AC-YAAFAAAATLKAAA-NH2 Artificialsequence A 4.0 12857.1 2.0 9.5
760.40 AC-YAAFAAAKTAAAAA-NH2 Artificialsequence A 14.3 900000.0 16.7 30.3
760.36 AC-YAAFAAAKTAAAFA-NH2 Artificialsequence A 6.9 10000.0 6.4 17.9
760.62 AC-YAAFAAAKTLAAAA-NH2 Artificialsequence A 7.5 18000.0 1.8 4.4
805.03 AC-YARFLALTTLRARA- Artificialsequence A 1.7 2.3 10.0 CONH2
906.02 AE(14)AAAATLKAAA-NH2 Artificialsequence 3.7 512.2 4.2 12.0
760.13 AEFAAAKTLAAFA-NH2 Artificialsequence 1.7 2.4 5.1
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl 0101 *0301 *0401 *0404 *0405
906.05 AF(14)AAAATLKAAA-NH2 Artificialsequence 0.9 554.9 1.7 1.8
851.09 AFAAAKTAA(71) Artificialsequence 1666.7 5.6 657.9
803.05 AFAAAKTAAAA-CONH2 Artificialsequence 151.5 6.5 2777.8
803.04 AFAAAKTAAA-NH2 Artificialsequence 5000.0 200.9 50000.0
760.05 AFLRAAAAAAFAAY-NH2 Artificialsequence A 625.0 1153.9 500000.0
906.01 AK(14)AAAATLKAAA-NH2 Artificialsequence 1.7 786.0 2.0 5.0
965.16 AK(14)VAAATLKAAA-NH2 Artificialsequence 4.2 558.2 7.2 71.0
965.15 AK(14)VAAHTLKAAA-NH2 Artificialsequence 2.1 514.5 3.2 17.4
965.14 AK(14)VAAKTLKAAA-NH2 Artificialsequence 5.9 296.1 8.5 58.2
965.08 AK(14)VAANTLKAAA-NH2 Artificialsequence 2.5 105.4 3.0 25.4 to 965.08 AK(14)VAANTLKAAA-NH2 Artificialsequence 0.7 484.5 1.3 4.8
Ol
365.10 AK(14)VAAWTLKAAA-NH2 Artificialsequence 2.3 55.0 3.7 14.3 58.8
965.17 AK(14)VAAWTLKAAA-NH2 Artificialsequence 2.0 678.4 3.8 34.0
965.09 AK(14)VAAYTLKAAA-NH2 Artificialsequence 1.7 69.4 2.2 12.8
965.09 AK(14)VAAYTLKAAA-NH2 Artificialsequence 0.6 1129.3 1.1 7.1
965.07 AK(14)VKAHTLKAAA-NH2 Artificialsequence 1.6 989.1 1.8 10.1
965.07 AK(14)VKAHTLKAAA-NH2 Artificialsequence 1.3 1458.0 1.4 6.7
965.01 AK(14)VKANTLKAAA-NH2 Artificialsequence 1.5 83.6 3.1 4.0
965.01 AK(14)VKANTLKAAA-NH2 Artificialsequence 1.3 9253 3.5 5.9
965.02 AK(14)VKAWTLKAAA-NH2 Artificialsequence 0.9 223.0 1.6 4.8
965.02 AK(14)VKAWTLKAAA-NH2 Artificialsequence 0.7 2574.6 0.8 1.5
965.03 AK(14)VWANTLKAAA-NH2 Artificialsequence 1.7 107.4 2.2 5.8
965.03 AK(14)VWANTLKAAA-NH2 Artificialsequence 0.4 275.6 1.0 3.5
965.04 AK(14)VWAYTLKAAA-NH2 Artificialsequence 0.5 27.8 0.6 2.8
965.04 AK(14)VWAYTLKAAA-NH2 Artificialsequence 0.3 724.1 1.1 3.6
965.05 AK(14)VYAWTLKAAA-NH2 Artificialsequence 0.5 58.8 0.3 4.4
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl *0101 *0301 *0401 *0404 *0405
965.05 AK(14)VYAWTLKAAA-NH2 Artificialsequence 0.8 3368.2 0.8 6.1
537.00 AKAAKAAKAAKAAKAA Artificialsequence 1250.0 900000.0 22500.0 500000.0
871.07 AKFAAAATLKAAA-NH2 Artificialsequence 2.9 1.3 10.9
803.14 AKFAAAKTAAAKA-NH2 Artificialsequence 4.3 4.2 33.3
Sandoz339 AKFAAALTLAAPA-NH2 Artificialsequence 19.2 7.1 6.3
Sandoz338 AKFAAALTLAQAA-NH2 Artificialsequence 238.1 32.1 35.7
1303.02 AKFIAADTLKAAA Artificialsequence A 991.8
1303.01 AKFIAAWTLKAAA Artificialsequence A 495.9 5.2
1024.03 AKFVAAWTLKAAA-NH2 Artificialsequence 1.2 599.2 1.8 8.2 11.5
1024.06 AKFVAAWTLKAAA-NH2 Artificialsequence 3.9 805.7 5.2 49.1
M 1024.04 AKFVAAYTLKAAA-NH2 Artificialsequence 0.9 860.1 4.8 7.0
∞ 1303.04 AKFVADWTLKAAA Artificialsequence A 78.6 38.5 28.8
1303.03 AKFVIAWTLKAAA Artificialsequence A 1.8 132.9 11.2
1024.01 AKFVWANTLKAAA-NH2 Artificialsequence 4.0 757.7 1.6 8.1
1024.02 AKFVYANTLKAAA-NH2 Artificialsequence 3.3 888.1 6.1 12.4
1303.08 AKIVAAWTLKAAA Artificialsequence A 7.1 409.6 20.3
1303.06 AKΓVADWTLKAAA Artificialsequence A 2506.3 80.0 146.3
1303.09 AKLVAAWTLKAAA Artificialsequence A 943.5
1303.10 AKMVAAWTLKAAA Artificialsequence A 17.8 819.1 19.1
1303.07 AKMVADWTLKAAA Artificialsequence A 3657.6 98.6 143.0
906.03 AQ(14)AAAATLKAAA-NH2 Artificialsequence 1.7 296.1 2.4 2.1
965.06 AR(14)VRANTLKAAA-NH2 Artificialsequence 0.8 1715.6 1.4 4.8
820.07 AR(15 A)RQTTLKAAA-NH2 Artificialsequence A 1.3 3.3 5.1
788.06 ARFQRQTTLKAAA Artificialsequence A 3.9 6.1 20.0
781.08 ARFQRQTTLKAAA-NH2 Artificialsequence A 2.4 2.0 7.8
640.05 ARRLKARRLKAΓY Artificialsequence 50.0 900000.0 22500.0 12500.0
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl
0101 *0301 *0401 *0404 *0405
906.04 AV(14)AAAATLKAAA-NH2 Artificialsequence 0.4 334.5 3.2 3.8 906.51 AV(14)AVAATLKAFA Artificialsequence 0.5 15.1 1.1 2.5 906.55 AV(14)VFAATLKAFA Artificialsequence 0.7 196.5 1.8 7.6 906.52 AV(14)WAATLKAAA Artificialseque aiiice 0.5 88.5 1.8 3.8 906.53 AV(14)WAATLKAFA Artificialsequence 0.4 46.4 1.1 2.2 640.01 AWRNRAKAWRNRAKAWRN Artificialseque arice 1666.7 900000.0 15000.0 500000.0
RAK
640.03 AWRNRAKAWRNRAKGTD Artificialsequence 1666.7 900000.0 15000.0 500000.0 758.03 AYAAA(4)A(4)KAAA Artificialsequence 92.6 264.7 500000.0 S5004 AYZAYAYTLKAAA Artificialsequence 18.8 25.0 32.1 S5003 BOC-AYZAYAYTLKAAA Artificialsequence 72.5 10.2 73.5 S1395 BOCXFAXAXTLKAAA Artificialsequence 20.8 12.5 62.5 631.02 DDYVKQYTKQYTKQNTLKK Artificialsequence 50000.0 900.0 500000.0 631.03 DDYVKQYTKQYTKQNTLKK Artificialsequence 238.1 >30000 11250.0 500000.0 760.08 EFAAATKAAAFAAY-NH2 Artificialsequence A 833.3 2142.9 500000.0 819.06 GG(15)GGKGGGGFG-NH2 Artificialsequence A 58.8 405.4 3571.4 736.15 JJYTJAAAAKAAA-NH2 Artificialsequence A 50000.0 22500.0 500000.0 640.06 K ^ a AK KNRAK Artificialsequence 1666.7 900000.0 15000.0 500000.0 640.07 KRLKRLKRLKRLKRL Artificialsequence 1666.7 314.2 22500.0 6250.0 965.19 KSSAK(14)VAAWTLKAAA- Artificialsequence 11.3 4.1 41.7 34.8 NH2
784.08 PKYDKQGGLKIAT Artificialsequence A 151.5 22500.0 500000.0 784.05 PKYFKQFRLKIAT Artificialsequence A 1000.0 15000.0 25000.0 784.13 PKYFKQIGLKRAT Artificialsequence A 200.0 633.8 25000.0 784.04 PKYGKQRFLKIAT Artificialsequence A 5000.0 900.0 10000.0 784.15 PKYΓKQDGLKGAT Artificialsequence A 31.3 11.8 16666.7 784.09 PKYΓKQFFLKRAT Artificialsequence A 50000.0 22500.0 746.3
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl
*0101 *0301 *0401 *0404 *0405
784.01 PKYΓKQIILKIAT Artificialsequence A 1250.0 500.0 416.7
784.10 PKYRKQFILKGAT Artificialsequence A 104.2 23.7 500000.0
736.01 PNYAAAAAAKAAA-NH2 Artificialsequence A 1.7 25.0 500000.0
736.31 PNYAAAAAAKAA-CONH2 Artificialsequence A 3.1 30.0 50000.0
781.07 RFQRQTTLKAAA-NH2 Artificialsequence A 10.9 3.5 9.1
716.02 TAIKKLTTQRQFRAY Artificialsequence A 1000.0 >45000 2500.0 25000.0
717.11 TKQKLTTQSQFRAY-NH2 Artificialsequence A 1666.7 900000.0 9000.0 500000.0
S5006 XFAXAXTLKAAA Artificialsequence 50.0 11.8 166.7
Sandoz364 YA(AMK)FAAAKTAAAFA- Artificialsequence 96.2 6.1 200.0
NH2 Sandoz366 YA(K1)FQ(K1)QTTL(K1)AAA- Artificialsequence 40.3 7.1 35.7
OH 806.05 YAA(10)LFLSAARKRA-NH2 Artificialsequence A 8.1 36742.4 250.0 500000.0
828.04 YAA(14)AAAA(24)KAAAA- Artificialsequence A 3.7 900000.0 3.3 24.4
NH2 828.02 YAA(14)AAAAPKAAAA-NH2 Artificialsequence A 0.8 20.5 675.7
828.12 YAA(14)AAAATKAAAA-NH2 Artificialsequence A 1.1 45000.0 2.9 6.9
760.59 YAA(14)AAAATLKAAA-NH2 Artificialsequence A 1.4 353.1 2.0 3.0
760.52 YAA(14)AAAKTAAAAA-NH2 Artificialsequence A 0.4 1000.8 0.9 1.5
906.54 YAA(14)AVAATLKAAA Artificialsequence 3.2 3232.9 2.7 7.5
828.14 YAA(15)AAAATKAAAA-NH2 Artificialsequence A 1.2 3.0 71.0
Sandoz363 YAA(AMF)AAAKTAAAFA- Artificialsequence 172.4 10.7 55.0
TsJTT?
760.26 YAAAKAAAAAAFAA-NH2 Artificialsequence 555.6 5625.0 500000.0
Sandoz368 Sandoz367 YAAFAAA(K1)TAAAFA-NH2 Artificialsequence 7.0 0.9 10.2
828.08 YAAFAAAA(24)KAAAA-NH2 Artificialsequence A 12.3 6.3 144.5
760.25 YAAFAAAAAAKAAA-NH2 Artificialsequence A 4.6 15.5 1388.9
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl
*0101 *0301 *0401 *0404 *0405
761.04 YAAFAAAAAARLFA-NH2 Artificialsequence A 18.5 375.0 16666.7
761.02 YAAFAAAAAQRLFA-NH2 Artificialsequence A 1.1 52.9 5555.6
760.54 YAAFAAAATAKAAA-NH2 Artificialsequence A 1.9 15212.8 1.3 7.5
760.45 YAAFAAAATLKAAA-NH2 Artificialsequence A 0.6 2070.2 1.2 4.9
760.39 YAAFAAAKTAAAAA-NH2 Artificialsequence A 1.8 8181.8 1.3 3.9
760.39 YAAFAAAKTAAAAA-NH2 Artificialsequence A 6.5 30000.0 10.2 73.5
760.39 YAAFAAAKTAAAAA-NH2 Artificialsequence A 1.2 4285.7 1.1 6.4
760.16 YAAFAAAKTAAAFA-NH2 Artificialsequence A 0.7 0.7 5.0
760.35 YAAFAAAKTAAAFA-NH2 Artificialsequence A 13.5 2214.3 15.5 53.8
Sandoz362 YAAFAAAKTAAAFA-NH2 Artificialsequence 1.9 4.6 7.0
^ 760.18 YAAFAAAKTAAAFE-NH2 Artificialsequence A 1.0 1.3 7.7
2 760.61 YAAFAAAKTLAAAA-NH2 Artificialsequence A 1.5 4824.5 2.0 5.8
788.05 YAAFQRQTTLKAAA Artificialsequence A 2.6 1.6 17.9
788.04 YAAFQSQTTLKAAA Artificialsequence A 1.9 1.9 6.9
793.02 YAAFVRQTTLKAAA Artificialsequence A 2.6 2.4 7.6
793.01 YAAFVSQTTLKAAA Artificialsequence A 1.9 1.3 5.1
760.14 YAEFAAAKTLAAFA-NH2 Artificialsequence A 2.3 2.7 7.9
781.16 YAK(14)QRQTTLKAAA- Artificialsequence A 5.0 4.7 16.1
CONH2 Sandoz370 YAKFAAAKTAAAA(TR) Artificialsequence 6.4 6.6 19.2
717.08 YAKFKSTTKKRIKS-NH2 Artificialsequence A 50000.0 900000.0 450000.0 500000.0
1341.01 YAKFVAAWTLKAAA Artificialsequence A
717.35 YAR(10)QSQTTLKAKT-NH2 Artificialsequence A 3.9 5.8 80.7
781.20 YAR(14)QKQTTLKAAA Artificialsequence A 8.9 900000.0 4.0 10.0
788.01 YAR(14)QRQTTLKAAA Artificialsequence A 31.3 63.4 1041.7
781.15 YAR(14)QRQTTLKAAA- Artificialsequence A 3.9 2.5 15.6
CONH2
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl
*0101 *0301 *0401 *0404 *0405
782.03 YAR(15)ASQTTLKAKT-NH2 Artificialsequence 1.5 2.6 5.2
782.07 YAR(15)ASQTTLKAKT-NH2 Artificialsequence 41.7 1.7 29.4
820.02 YAR(15 A)RQTTLKAAA-NH2 Artificialsequence A 1.6 2.0 3.8
820.11 YAR(15A)RQTTLKAAA-NH2 Artificialsequence A 4.4 3.8 4.3 820.01 YAR(15A)SQTTLKAKT-NH2 Artificialsequence A 2.4 4.4 5.2
820.10 YAR(15A)SQTTLKAKT-NH2 Artificialsequence A 10.7 5.1 25.6 782.04 YAR(16)ASQTTLKAKT-NH2 Artificialsequence 192.3 900000.0 3.5 92.6
717.34 YAR(9)QSQTTLKAKT-NH2 Artificialsequence A 27.8 4.4 41.7
717.43 YAREQSQTTLKAKT-NH2 Artificialsequence A 50000.0 750.0 500000.0
782.06 YARFGGQTTLKAKT Artificialsequence 357.1 6.1 56.2 1 805.01 YARFLALTTLRARA-CONH2 Artificialsequence A 1.0 1.6 3.4
S 805.02 YARFLALTTLRARA-CONH2 Artificialsequence A 2.0 5.8 12.5
717.36 YARFQSQT(24)LKAKT-NH2 Artificialsequence A 4.6 5.8 12.8
717.18 YARFQSQTELKAKT-NH2 Artificialsequence A 714.3 264.7 16666.7
782.01 YARFQSQTTL(32)AKT-NH2 Artificialsequence 3.6 900000.0 1.7 15.2
717.24 YARFQSQTTLKEKT-NH2 Artificialsequence A 50000.0 30.0 2083.3
715.01 YAJ ICLKAΓFARRLKA Artificialsequence 38.5 11250.0
788.03 YASFQSQTTLKAAA Artificialsequence A 3.1 3.1 9.3
788.02 YASFVSQTTLKAAA Artificialsequence A 1.7 2.9 12.8
785.01 YE-KSIQFFfWKNSNQTKILGNQ Artificialsequence 5.7 11078.2 5.6 23.8
GSFLTKGPS 717.09 YPKFVKQNTLKAAT-NH2 Artificialsequence A 555.6 900000.0 5000.0 16666.7
806.01 YQFIKANSKFKGKFK-NH2 Artificialsequence A 1666.7 535.7 500000.0
768.01 YSSFSSSSSSKSSS Artificialsequence A 1000.0 7.9
768.02 YSSFSSSSSSKSSS-NH2 Artificialsequence A 714.3 900000.0 5.8 192.3
768.03 YSSFSSSSSSSSSS Artificialsequence A 50000.0 6.9
768.04 YSSFSSSSSSSSSS-NH2 Artificialsequence A 5000.0 5.8 416.7
TABLE 27a
HLA-DR binding affinity (IC50 nM)
Peptide Sequence Source Ag Analog DRBl DRBl DRBl DRBl DRBl
*0101 *0301 *0401 *0404 *0405
564.01 YVKADYVKADYVKADYVK Artificialsequence 1666.7 957.5 500000.0
718.01 YVKQNTLAFVKQNTLA Artificialsequence 172.4 239.4 50000.0
631.01 YVKQYTKQYTKQNTLK Artificialsequence 50000.0 4500.0 500000.0
S1396 ZAAFAAAATLKAAA Artificialsequence 25.0 11.5 54.4
S1399 ZAAFAAAXTAYAYA Artificialsequence 33.3 7.8 122.0
S1400 ZAAFAXAATAYAYA Artificialsequence 18.5 9.0 75.8
S5005 ZAAFAXAATLKAAA Artificialsequence 16.1 7.3 24.6
SF 1281755 vl
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQB *0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *030
PTS-04 AAWSERAGEAMVLV >25000 10000.0 91000.0 >10000 256.
582.02 DNVLDHLTGRSC >25000 10000.0 91000.0 11111.1 >250
PTS-10 NH2-DNVLAHLTGRSCQ- 91000.0 COOH
PTS-17 NH2-DNVLDHLTGRSAQ- 91000.0 COOH
PTS-18 NH2-DNVLDHLTGRSCA- 91000.0 COOH
541.19 HYTVDKSKPKVYQWRD 250000.0 1250.0 700.0 2985.4
541.15 TNTKCYKLEHPVTGCG 250000.0 1250.0 1820.0 >7692.31
541.04 NELGRFKHTDACCRTH 1550.4 266.7 28.4 >9090.91
M 541.11 NNDFYDNSADTISSYF
541.20 SKPKVYQWFDLRKY
541.13 SSYFVGKMYFNLINTK
BMP PDTRPAPGSTAPPAHGVTSAP 10206
DTR-NH2
1136.18 ALPVFTWLALYFTSAK 1181.1 20104.9 4847.9 11666.7 598.7 2790.5 1182.6
1136.20 ALYFTSAKIPQEWKPA 381.6 134.6 59.0 >8750 7690.9 >15681.4 8207.6
1136.15 FATSFLΓPLTSQFFLP 41.8 21304.4 9523.8 8750.0 48.0 592.0 42.9
1136.52 GLFCRWSYTEΓEKΓDI 555.7 30625.0 2420.8 >6405.13 >2580.87 17500.0 5698.6 791.3 1690.3
1136.53 GLFSRWSYTEIEKΓDI 298.7 11650.2 >9428.09 4341.2 >30333.33 1607.4 >47140.45
1136.48 IGGAMLSLTVFEFTKY 1946.3 >3357.42 12364.1 >7427.81 123.7 11666.7 15166.7 40312.8 >2439.21
1136.13 ΓKLPIILAFATSFLIP 112.4 16257.4 >7767.36 53.4 0.8 1676.4 63.1
1136.43 ΓMEVLFLSWLFPRFKF 104.4 >34648.23 9090.9 1144.0 538.1 >16018.68 >4 140.45
1136.67 LTNNDQVSGΓNEEDEE >33407.66 >34648.23 >6405.13 576.2 >37150.59 >42758.17 >47140.45
1136.01 MMASSILRSKIIQKPYQ >27777.78 245.3 24607.0 2112.9 >2651.58 >8750 1690.4 >10826.47 85.2
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQ *0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *030
1136.41 PSLHSGSSΓMEVLFLS 13325.0 >34648.23 >7767.36 >8750 >37150.59 6080.1 >81649.66
1136.39 SSΠFGAFPSLHSGSS 1228.7 15765.5 1598.0 1909.4 761.0 447.5 470.6
1136.10 VSILFFVFWFPASFF 1041.7 13876.0 3413.7 5834.6 >2904.73 4044.6 >9989.28 8004.0 7372.1
58.0041 IAKITPDNNGTYACF
58.0022 ΓPNITVDNSGSYTCQ
58.0012 IQNΠQDDTGFΎTLH
58.0037 LFNVTRDDARAYVCG
58.0017 LFNVTRDDTASYKCE
58.0028 LLSVTRDDVGPYECG
58.0015 LWWVNNESLPVSPRL
58.0027 LWWVNNESLPVSPRL
58.0021 QELFΓPDITVNNSGS
58.0032 QELFISDITEKNSGL
58.0009 REΠYPDASLLIQNI
58.0020 SCHAASDPPAQYSWF
58.0023 TITVYADPPKPFITS
58.0005 VLLLVHDLPQHLFGY
58.0042 YACFVSDLATGRNNS
CMP PTTTPITTTTTVTPTPTPTGTQT >25000 10000.0 91000.0 >25000 >250
YC-NH2 722.01 YIAFLKQATAK >25000 3333.3 91000.0 >50000 >250
500.02 FLRRIRPKLK 2857.1 11.1
199.02 GFLRRΓRPKLK 625.0 6.1
199.03 LRRIRPKLK 4000.0 21.7
199.01 YGGFLRPJRPKLK >25000 274.0 4.1 >16666.67 1020
510.12 DDNGPQDPDNTDDNG 25000.0 10000.0 758.3 >7692.31 >250
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQB *0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *030
F166.01 PYYTGEF1AKAIGN >16137.43 >10103.63
897.07 FPQPQLPYSQPQPFRPQQPY- 250000.0 6666.7 1000000.0 9.7
NH2
897.25 IPPYCTIAPFGiFGIN-NH2 147.1 200000.0 1000000.0 4833.3
. F168.09 ΓRNLALQTLPAMCNVY 4.9
897.04 LGQQQPFPPQQPYPQPQPFP- 250000.0 200000.0 >33333.33 252.0
NH2
897.18 LHQQQKQQQQPSSQVSFQQP- 250000.0 200000.0 1000000.0 223.1
NH2
897.15 LLQELCCQHLWQTPEQSQCQ- 25000.0 200000.0 50000.0 31.4
NH2
897.13 LQQHNIAHGRSQVLQQSTYQ- 607.0
NH2 .04 PQPFRPQQPYPQ 2.4 σ "s F168
F168.03 PQPFRPQQPYPQPQPQ 3.6
897.08 PQPFRPQQPYPQPQPQYSQP- 250000.0 2468.3 1000000.0 7.6 2500
NH2
897.09 PQPQPQYSQPQQPISQQQQQ- 250000.0 200000.0 1000000.0 573.3 1443
NH2
897.19 PSSQVSFQQPLQQYPLGQGS- 250000.0 11547.0 10000000 6.9
NH2
F168.12 QFEEIRNLALQT 84.0
F168.l l QFEEIRNLALQTLPAM 149.9
897.23 QFEEΓRNLALQTLPAMCNVY- 656 5 1230.9 1000000.0 57.7
NH2
FI 68.06 QFLGQQQPFPPQ 7.8
897.22 QGSVQPQQLPQFEEΓRNLAL- 158.5 1490.7 10000000 873.6
NH2 897.02 QNPSQQQPQEQVPLVQQQQF- 250000.0 200000.0 1000000.0 213.8
NH2
TABLE 27b
HLA-DR binding affmity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQ
*0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *03
897.05 QPYPQPQPFPSQQPYLQLQP- 250000.0 200000.0 1000000.0 23.5 NH2
897.12 QQLΓFCMDVVLQQHNIAHGR- 8333.3 20000.0 7715.5 40.1 1443
NH2 F168.08 QVPLVQQQQFLG 70.3
F168.07 QVPLVQQQQFLGQQQP 0.8
897.03 QVPLVQQQQFLGQQQPFPPQ- 21.9
NH2
897.06 SQQPYLQLQPFPQPQLPYSQ- 3149.7 228.7 1000000.0 49.0 NH2
FI 68.05 VQQQQFLGQQQPFPPQ 2.2
897.01 VRVPVPQLQPQNPSQQQPQE- 250000.0 200000.0 1000000.0 7.9
NH2 897.50 YIPPYCTIAPFGIFGΓN-NH2 0.0 >14285.71
897.44 YPSSQVSFQQPLQQYPLGQGS 250000.0 >11111.11
-NH2
897.47 YQGSVQPQQLPQFEEΓRNLAL- o.o =-11111-11
NH2 F160.26 EKVPVSEVMGTTLAEMSTPE AT
FI60.02 ΓYRRRLMKQDFSVPQLPHS
F160.07 KRCLLHLAVIGALLAVGATK
V F160.03 LCQPVLPSPACQLVLHQILKG
G F160.14 MTPAEVSΓWLSGTTAAQVTT
T F160.16 PGPVTAQWLQAAΓPLTSCGS s F160.01 VSGLSIGTGRAMLGTHTMEV
TVY
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQ
*0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *03
F167.01 VYVWKTTWGQYWQVLGGP 402.7 13011.2 >14500 VS
F167.03 WNRQLYPEWTEAQR 162.3 4229.0 21.5
F115.14 AKRKTVTAMDWYAL
F115.02 KllHRKVLPJDraQGITKPAIRR LAR
F115.15 KTVTAMDWYALKRQ
F115.10 LRDNIQGITKPAJRR
F115.ll NIQGITKPAIRRLAR
F115.03 TYTEHAKRKTVTAMDVVΎA
LKRQG
590.23 (2)KYVKQNTLKAT(SIC!) 238,1 12.0 752.01 (67)PKYVKQNTLKLAT 156.9 210.5 20.7 >50000 >250
594.09 AHAAHAAHAAHAAHAA >8838.83 200000.0 91000.0 58.
F049.01 BIOTIN-A2- 60.2 PRYVRQNTLRATC
574.00 CPKYVRSAKLRM 36.4 227.3 1300.0 >16666.67 >250
573.05 GACPKYVKQN >6250 5000.0 91000.0
573.04 GACPKYVKQNTL 735.3 5000.0 91000.0
597.04 GACPKYVKQNTLK 20.8 5000.0 479.0
573.03 GACPKYVKQNTLKL 25000.0 5000.0 3033.3
30.1200 HNTNGVTAASSH >2500 10000.0 3033.3 >16666.67 299.
573.08 KQNTLKLATGMR 806.5 5000.0 4550.0
711.03 LAKQNTLAKQNTLAKQNT >25000 2857.1 6.1 25000.0 >250
573.09 NTLKLATGMR 1315.8 5000.0 1516.7
590.22 P(2)YVKQNTLKAT(SIC!) 1538.5 94.8
864.10 PFFVKQNΓLKLAT
TABLE 27b
HLA-DR bindπiϋ ; affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQ *0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *03
864.07 PFFVKQNTLKLAT
864.06 PFΓVKQNTLKLAT
864.02 PFYVKQNTLKLAT
864.09 PΓFVKQNILKLAT
864.05 PIFVKQNTLKLAT
864.04 PΠVKQNTLKLAT
864.01 PΓYVKQNTLKLAT
590.10 PK(1)VKQNTLKAT(SIC!) 1538.5 606.7
590.21 PK(2)VKQNTLKAT(SIC!) 1538.5 650.0
772.08 PK(31)VKQNTLKLAT-NH2
611.11 PKAVKQNTLKLAT 250000.0 6666.7 505.6
601.09 PKEVKQNTLKLAT 250000.0 10000.0 91000.0
841.05 PKFQVETTKKLAT 250000.0 20000.0 650.0 1533.9
864.03 PKΓVKQNTLKLAT
713.09 PKKVKQNTLKLAT 250000.0 200000.0 2275.0
792.03 PKQVKQNTLKLAT 250000.0 20000.0 4550.0 >50000
601.10 PKSVKQNTLKLAT 250000.0 10000.0 9100.0
713.14 PKTVKQNTLKLAT 250000.0 200000.0 2275.0
590.09 PKY(1)KQNTLKAT(SIC!) 256.4 395.7
833.08 PKY(41)KQNTLKLAT
590.08 PKYV(1)QNTLKAT(SIC!) 181.8 700.0
590.19 PKYV(2)QNTLKAT(SIC!) 1000.0 758.3
833.07 PKYV(41)QNTLKLAT
590.07 PKYVK(1)NTLKAT(SIC!) 322.6 45.5
590.18 PKYVK(2)NTLKAT(SIC!) 1000.0 154.2
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQB
*0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *030
713.10 PKYVKKNTLKLAT 3571.4 107.0 52.9
590.06 PKYVKQ(1)TLKAT(SIC!) 87.0 137.9
590.17 PKYVKQ(2)TLKAT(SIC!) 219.8 758.3
833.05 PKYVKQ(41)TLKLAT
590.05 PKYVKQN(1)LKAT(SIC!) 800.0 182.0
590.16 PKYVKQN(2)LKAT(SIC!) 1538.5 535.3
772.06 PKYVKQN(24)LKLAT
772.01 PKYVKQN(25)LKLAT
772.02 PKYVKQN(26)LKLAT
772.03 PKYVKQN(27)LKLAT t~j 772.04 PKYVKQN(28)LKLAT
^ 772.07 PKYVKQN(30)LKLAT
601.24 PKYVKQNELKLAT 446.4 200000.0 3033.3
515.09 PKYVKQNHLKLAT 714.3 4000.0 1011.1
864.08 PKYVKQNILKLAT
713.12 PKYVKQNKLKLAT 301.2 31.0 1516.7
863.07 PKYVKQNNLKLAT 431.0 1481.5 1011.1
772.11 PKYVKQNPLKLAT
713.13 PKYVKQNQLKLAT 312.5 2857.1 1137.5
590.04 PKYVKQNT(1)KAT(SIC!) 1000.0 395.7
590.15 PKYVKQNT(2)KAT(SIC!) 1052.6 185.7
833.03 PKYVKQNT(41)KLAT
601.27 PKYVKQNTKKLAT 1388.9 16.7 24.4
590.03 PKYVKQNTL(1)AT(SIC!) 238.1 395.7
590.14 PKYVKQNTL(2)AT(SIC!) 294.1 116.7
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQ
*0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *03
833.02 PKYVKQNTL(41)LAT
590.02 PKYVKQNTLK(1)T(SIC!) 1538.5 260.0
590.01 PKYVKQNTLKAT(SIC!) 219.8 455.0
713.06 PKYVKQNTLKEAT 862.1 200000.0 1516.7
863.08 PKYVKQNTNKLAT 25000.0 2000.0 60.7
713.01 PKYVKQNYLKLAT 80.1 2222.2 700.0 >50000 >25
175.00 RTLYQNVGTYVSVGTSTLNK >12500 1538.5 3033.3 >πm.ιι 645
597.06 VKQNTLKLATGMR >11180.34 769.2 91000.0
841.06 YPKFQVETTKKLAT
841.04 YPKFVKLNTKKLAT
771.04 YPKFVKQRTLKLAT 254.9
IsJ
771.02 YPKFVKQRTLKLAT-NH2 94.6
771.06 YPKFVKRNTLKLAT 5000.0
771.03 YPKYVKQRTLKLAT 134.7
771.01 YPKYVKQRTLKLAT-NH2 247.5
771.07 YPKYVKRNTLKLAT 8333.3
841.02 YPSFQVQTTLLLAT
27.0278 AAPFTQCGYPALMPL 3186.5 3524.0 267.7 666.1
F039.09 AILCWGELMTLA >100000 9.5 10000.0
F076.05 ALRQAILCWGELM >285 1.43 >377.36
F039.05 ALRQAILCWGELMTLA >100000 11.6 5263.2
799.04 GYRWMCLRRFIIFLFILLLC 2272.7 4000.0 1820.0 >25000
F039.02 HHTALRQAILCWGELMTLA >66666.67 29.9 3921.6
F039.03 HTALRQAILCWGELMTLA >66666.67 27.0 7407.4
F039.10 ILCWGELMTLA >100000 127.7 5882.4
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQB
*0701 *0S02 • *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *030
F039.ll LCWGELMTLA >100000 829.3 >9523.81
F164.04 LPETTWRCRGRSPR >10640.71 >8750
F039.06 LRQAILCWGELMTLA >100000 9.9 555.6
CF-09 LSTLPETTWRRRGRS >1923.08 235.3 9100.0 12500.0 >250
F164.14 MDTDPYKEFGASVELLSFL 566.0 2455.6
F164.13 MDTDPYKEFGASVELLSFLPS 184.3 >8750 DFFP
F164.16 MDΓDPYKΈFGATVELLSFL 8394.9 4005.4
F116.01 MDIDPYKEFGATVELLSFLPS 6608.8 2429.9 DFFP
F164.15 MDIDPYKEFGATVELLSFLPS 1914.3 722.7 DFFP
FI 64.17 MDTDPYKEFGATVQLLSFLPS 777.4 2819.9 DFFP
F098. i l MGLKFRQLLWF 1174.0 255.0 11582.8 13.2 784.3 1795.8 76.1 1483.2
1297.06 PFLLAQFTSAICSWRRA 1603.9 391.2
F039.18 PHHTALRQAILCW - >28571.43 207.5 >7407.41
F039.17 PHHTALRQAILCWG >28571.43 26.5 5128.2
F039.16 PHHTALRQAILCWGE >2 000 1685.2 6451.6
F039.15 PHHTALRQAILCWGEL >25000 239.1 >6060.61
F039.14 PHHTALRQAILCWGELM 18181.8 136.8 >5714.29
F039.13 PHHTALRQAILCWGELMT 16666.7 126.1 3389.8
F039.12 PHHTALRQAILCWGELMTL >100000 18.3 5000.0
795.01 PLGFFPDHQLDPAFGANSNNP 250000.0 200000.0 91000.0 310.6 25000 DWDFNP
F039.08 QAILCWGELMTLA >100000 12.1 >10526.32
CF-03 RDLLDTASALYRREALESPEH 271.7 200000.0 364.0 >33333.33 4225.
CF-06 RDLVVSYVNTNMGLKFRQLL >1470.59 200000.0 3033.3 6250.0 >250
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQ
*0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *03
F039.07 RQAILCWGELMTLA >100000 8.9 3125.0
801.01 RVRGLYFPAGGSSSGTVN 8333.3 20000.0 535.3 >25000
799.02 SLDSWWTSLNFLGGTTVCLG 4166.7 20000.0 91000.0 >25000
F039.04 TALRQAILCWGELMTLA > 100000 14.0 >8000
F164.12 TNMGLKFRQLLWFHI 11180.7 269.7
F164.ll TNVGLKFRQLLWFHI 1012.3 5520.5
F098.08 TTWRRRGRSPRRR > 102062.07 4516.4 >60436.72 2756.5 >6708.41 35000.0 15166.7 530.7
800.04 VGAGAFGLGFTPPHGGL 250000.0 200000.0 9100.0 >25000
764.01 VSFGVWTRTPPA 4724.6 4000.0 91000.0 13609.2 >250
857.01 YPHHTALRQAILCWGELMTL 35355.3 10767.6 112.2 429.9 5455.5
A F134.07 GPGEGAVQWMNRLIAFASRG 6305.2 88.3
Pape22 GRHLTFCHSKRKCDELATKL >102062.07 >48048.45 >60436.72 17407.8 >6708.41 5000.0 827.3 2073.9
F134.06 LLFNTLGGWVAAQLAAPGAA 56433.4 7057.2
1283.40 PAΓLSPGALVVGWCA 3429.9
221.06 AFVAWRNRCK 5.2
221.08 AWAAWRNRCK 50.6
221.10 AWEAWRNRCK 60.7
221.09 AWLAWRNRCK 19.8
221.15 AWVAARNRCK 2.1
221.16 AWVAFRNRCK 5.1
221.14 AWVAQRNRCK 10.1
221.19 AWVAWANRCK 26.0
221.17 AWVAWENRCK 56.9
221.18 AWVAWKNRCK 11.1
221.22 AWVAWRARCK 7.6
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQB *0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *030
221.25 AWVAWRNACK 13.6
221.23 AWVAWRNECK 53.5
221.24 AWVAWRNKCK 36.4
221.32 AWVAWRNRCA 433 3
539.00 AWVAWRNRCK >12500 5000.0 20.2 >11111.11
221.01 AWVAWRNRCK >12500 5000.0 20.2 >11111.11 >250
221.31 AWVAWRNRCR 86.7
221.28 AWVAWRNREK 10.7
221.29 AWVAWRNRKK 3 3
221.26 AWVAWRNRQK 2.0
221.27 AWVAWRNRVK 3.4
221.20 AWVAWRQRCK 6067
221.21 AWVAWRVRCK 1625
221.12 AWVEWRNRCK 124.7
221.11 AWVSWRNRCK 36.4
221.13 AWWWRNRCK 45.5
565.01 EFVAAKAAQK >25000 1250.0 1.4 >50000 3571.
221.02 EWVAWRNRCK 19.0
AP23 LAAAMKRHGLDNYRGYSLG 5000.0 83.3 1784 >5263.16 >250
NWV AP12 RNRCKGTDVQAWΓRGCRL 3571.4 2500.0 178.4 >6250 >250
AP38 SVNCAKKΓVSDGNGMN >8333 33 666.7 4550.0 2306.3 >250
221.04 SWVAWRNRCK 21.7
221.03 VWVAWRNRCK 47.9
560.02 WRNAKWRNAKWRNAK > 12500 5000.0 505 6 > 14285.71 >250
AP37 YRGYSLGNWVCAAKFESNFN >6250 5000.0 1011.1 >5263 16 25000
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQB
*0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *030
TQ
58.0052 CWMΓDSDCRPRFREL
58.0045 CYGLGMDHLREVRAV
58.0053 FRELVSDFSRMARDP
58.0051 ΓKWMALDSILRRRFT
58.0046 LALIHHDTHLCFVHT
58.0043 LTYLPTDASLSFLQD
58.0048 QMRILKDTELRKVKV
1385.03 SPYVSRLLGICLT 886.5 4207.3 3414.1 831.4
1385.04 VPΓKWMALESILRRRF 1300.9 2815.1 1430.6 46.9
^ 58.0047 WDQLFRDPHQALLHT o! F159.13 DRVHPVHAGPIA 98.5 >9500.69 >53452.25 528.8 19198.3 >12909.94
F159.12 DRVHPVHAGPIAPG 93.2 >7836.24 >50000 342.3 724.3 11809.5
F159.ll DRVHPVHAGPIAPGQM 265.3 >6971.6 >33333.33 655.6 1102.5 1845.0
F159.10 DRVHPVHAGPIAPGQMRE 399.8 14869.0 >31622.78 591.1 706.9 6288.4
F159.09 DRVHPVHAGPIAPGQMREPR 223.2 >5591.33 >29488.39 1246.7 3572.6 >7905.69
F170.01 DTEVHNVWATQACVPTDPNP >3240.47 >5658.03 >2528.25 >3232.54 >4183.3 5055.6 >6537.23 5493.0 >533.76
F169.02 EGLΓHSQRRQDILDL >39528.47 >70725.41 >30316.95 1843.8 837.9 505.6 >77821.01 11901.1 1364.0
F170.06 EPFRDYVDRFYKTLRAEQAS 1761.7 201.7 3463.5 100.7 >7826.24 162.5 >12903.23 2902.6 690.6
F170.05 ΓΪKRWΠLGLNKΓVRMYSPV 659.0 151.5 >5056.5 >6428.24 9589.0 10111.1 >12903.23 659.7 >1054.09
F170.02 PKISFEPIPIHYCAPAGFAI 389.3 15312.5 274.0 14285.7 758.2 350.0 >6537.23 78.3 >533.76
F169.01 TAATNAACAWLEA 18351.3 >70725.41 1827.4 >37796.45 974.7 3137.9 >77821.01 59094.5 >6565.32
F170.04 TNNPPΓPVGEΓYKRWIΓLGL 912.9 200.8 1616.9 98.6 11.9 20.2 7624.9 442.7 44.7
F170.03 VWGΓKQLQARVLAVERYLKD 200.7 796.7 2451.5 541.3 134.6 16.9 5951.0 372.8 39.7
27.0374 AVQMAVFIHNFKRKG 2701.6 73.6 3.5 7.9
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQB *0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *030
27.0299 DQQLLGΓWGCSGKLI 1437.7 3090.0 606.7 2026.7
27.0287 DQSLKPCVKLTPLCV 2339.9 4025.1 5055.6 11063.2
27.0284 EDΠSLWDQSLKPCV >27277.24 >18257.42 5352.9 11985.1
190.20 ERFAVNPGLLETSEGC >12500 2500.0 1300.0 >33333.33 1976
190.15 GARASVLSGGELDKWE >12500 10000.0 1300.0 >14285.71 315.
190.16 GGELDKWEKIRLRPGG > 12500 10000.0 252.8 >33333.33 >250
RS-21 GP41584-609 >12500 645.2 9100.0 3965.3 >250
27.0320 IGGIGGFIKVRQYDQ 8059.6 1409.9 45.5 112.2
181.11 ΓLKALGPAATLEEMMT(2OO.I 1 12500.0 200000.0 91000.0 >50000 2500
)
200.10 TNEEAAEWERVHPVHA >12500 10000.0 1300.0 16666.7 >250 t. 27.0348 IQKLVGKLNWASQIY 5936.9 4573.0 6500.0 >7273.93
27.0286 ISLWDQSLKPCVKLT >14153.46 8486.2 313.8 1179.1
190.19 ΓVWASRELERFAVNPG >12500 339.0 1300.0 >33333.33 3125
200.17 IYKRWIILGLNKIVRN >12500 10000.0 364.0 >33333.33 >250
F091.13 KQIΓNMWQEVGKAMΎA 11763.0 22360.7 2527.8 61.1 5661.4
200.04 KWEEKAFSPEVD?MF 12500.0 10000.0 606.7 >33333.33 >250
190.08 LGKIWPSYKGRPGNFL >12500 277.8 1300.0 20000.0 715.
F091.08 LKQIVKKLREQFGNNK >45643.55 6900.7 206.8 601.4 492.1
27.0300 LLGΓWGCSGKLICTT 3934.7 >11785.11 1820.0 4279.4
27.0302 LSΓVNRVRQGYSPLS 16606.8 27.8 284.4 668.2
200.01 PIVQNLQGQMVHQAIS >12500 10000.0 1300.0 >33333.33 >250
F091.24 PLGVAPTKAKRRWQR 38575.8 22360.7 19.0 2371.8 57.4
190.23 PSLQTGSEELRSLYNT >12500 10000.0 758.3 >33333.33 2500
F091.16 QARILAVERYLKDQQL 26352.3 676.5 479.0 246.2 1081.5
27.0352 QGQWTYQΓYQEPFKN 9940.4 >30860.67 606.7 1363.5
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQB *0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *030
190.13 QKQEPΓDKELYPLTSL >12500 10000.0 1300.0 >33333.33 >250
27.0375 QMAVFΓHNFKRKGGI 7008.2 19.1 7.6 17.4
F091.07 RIQRGPGRAFVTIGKL >45643.55 429.0 1096.4 4207.8 2424.6
190.22 RQILGQLQPSLQTGSE > 12500 10000.0 1300.0 >33333.33 17677
F091.04 SLKPCVKLTPLCVTLN 1159.4 449.5 758.3 508.7 1707.5
F091.26 SLWDQSLKPCVKLTPL >45643.55 4255.3 413.6 2774.5 910.0
27.0359 SQHEQLΓKKEKVYL >25649.46 428.5 293.6 650.2
F091.22 SQNQQEKNEQELLELD >45643.55 >51639.78 758.3 >64845.97 1666.7
F091.ll SSGGDPEΓVMHSFNCG >45643.55 , >51639.78 22750.0 503.3 >21821.79
27.0334 STKWRKLVDFRELNK 2183.7 1753.2 21061.5 124.8 >7407.41 >3818.81 429.6 509.1 1 F091.12 TITLPCRΓKQFINMWQE 24397.5 47140.5 8272.7 730.7 18181.8
^ 27.0292 TVYYGVPVWKEATTT 1997.6 2275.4 568.8 2098.8
F091.23 VKIEPLGVAPTKAKRR >45643.55 >51639.78 6.1 5913.4 13.3
27.0301 VLSΓVNRVRQGYSPL 2756.6 3.7 5.4 11.9
27.0356 VNΓVTDSQYALGΠQ 2299.5 >25197.63 6500.0 >7273.93
F091.03 DQSLKPCVKLTPLCV 3140.7 20203.1 3137.9 4515.3 6896.6
27.0335 WRKLVDFRELNKRTQ >25649.46 69.0 5352.9 >5939.14
F160.45 STORKUSP45
106.00 APYTSTLLPPELSETP >1923.08 1818.2 4550.0 >12500 >250
F095.05 FRQLVHFVRDFAQLL 399.1 869.6
AP30 SLKMADPNRFRGKDLP >25000 1818.2 700.0 >12500 >250
605.14 ACRVNHVTLSQPKΓVK 312.5 200000.0 1011.1 7216.
530.08 GKKΓPKVEMSDMSFSK >12500 200000.0 910.0 >7142.86 >250
605.03 HPAENGKSNFLNCYVS 2500.0 200000.0 91000.0 >250
530.06 HPPHIEIQMLKNGKKI 8333.3 350.9 11.5 > 142.86 >250
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQ *0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *03
530.01 IQKTPQIQVYSRHPPE >12500 833.3 91000.0 >7142.86 >25
530.07 IQMLKNGKKΓPKVEMS 8333.3 740.7 15.4 >7142.86 >25
605.01 IQRTPKIQVYSRHPAE 12500.0 2000.0 1516.7 >25
530.02 IQVYSRHPPENGKPNI >12500 20000.0 91000.0 >7142.86 >25
530.04 KPNILNCYVTQFHPPH >12500 200000.0 4550.0 >7142.86 >25
530.10 SFSKDWSFYΓLAHTEF 1206.3 2857.1 91000.0 454.3 >25
605.10 SFSYDWSFYLLYYTEF 250000.0 200000.0 395.7 >25
605.11 SFYLLYYTEFTPTEKD 2777.8 200000.0 91000.0 176
530.14 TETDTYACRVKHDSMA 925.9 200000.0 91000.0 >7142.86 >25
530.09 VEMSDMSFSKDWSFYI 438.6 20000.0 91000.0 322.6 >25
544.02 YGSDTrTLPCRIKQFINMWQE 1000.0 909.1 91000.0 >9129.09 >25
> -o-4 JR-01 PEFLEQRRAAVDTYC 250000.0 487.8 91000.0 >12
00 F073.01 MRGSHHHHHHGSVD-π72-216 147.3 983.0 63.0 18.4 13.6
734.01 FVNQHLSGSHLVEALYLVSG- 216.5 200000.0 9100.0 20000.0
CONH2
68.0002 DLVLSIALSVGCTGA 4029.1 >141450.82 2200.2 >115470.05 4914.8 97.5 18200.0 >11629.26 459.5 >100000
68.0005 GQRVPVSHSFPHPLY 628.7 >141450.82 102.1 >57735.03 5507.3 702.5 3960.3 >11629.26 9860.5 >100000
68.0011 HDLMLLRLSEPAKIT 109.3 544.2 43.1 1146.7 84.4 0.8 115.1 488.0 11.6 211.2
68.0008 HPLYNMSLLKHQSLR 1282.0 381.7 199.2 248.2 95.2 546.3 471.5 >11629.26 8.4 219.0
68.0003 HPQWVLTAAHCLKKN 563.4 1693.2 822.4 980.8 11450.4 482.8 1219.5 8114.3 1105.8 11.0
68.0018 KPAVYTKVVHYRKWI 2401.0 53.2 3676.7 327.0 1303.0 1947.5 401.1 7186.5 4581.2 22.7
68.0140 LHLLSNDMCARAYSE 27685.5 50230.1 59904.2 26011.5 1152.5 1876.4 >2030.13 1988.8 323.8 28817.3
68.0001 MWDLVLSIALSVGCT 3031.7 23045.8 1727.3 81096.0 4574.6 107.7 11375.0 15204.5 157.5 70710.7
68.0017 NGVLQGITSWGPEPC 2285.2 52234.2 50111.5 32444.3 >3132.18 >14288.69 834.9 >10217.64 5760.9 >100000
68.0009 NMSLLKHQSLRPDED 20619.7 26496.2 96824.6 25819.9 1287.6 >20207.26 >23496.1 >11629.26 104.9 >100000
68.0015 PEEFLRPRSLQCVSL 5155.9 2207.1 5839.1 10675.2 6023.3 11666.7 3193.5 >10463.53 117.0 57537.0
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQB
*0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *030
68.0007 PHPLYNMSLLKHQSL 20690.6 3315.4 1591.6 6455.0 859.8 3307.2 3873.2 >11629.26 49.4 1901.1
68.0016 PRSLQCVSLHLLSND 2216.7 6106.8 28306.9 11128.3 3861.0 3731.0 1596.7 11649.6 544.1 46415.9
68.0004 QWVLTAAHCLKKNSQ 3402.1 98000.0 4812.5 14213.4 >10721.94 >24748.74 >30333.33 >11629.26 14395.4 382.2
68.0006 RVPVSHSFPHPLYNM 101.1 100020.8 96.8 >57735.03 10397.4 376.9 5517.7 >11629.26 9213.5 11649.7
68.0010 SHDLMLLRLSEPAKI 106.4 1326.9 111.5 5267.4 591.4 1.8 365.4 5360.8 10.2 2031.1
F090.02 ATGFKQSSKALQRPV 12.0
F090.01 IVHSATGFKQSSKALQRPVAS 16.4
DFEP F071.29 ΓKYNGEEYLILSARD 3592.1 322.1 1589.2 1443.4
F071.26 IYSKYGGTEIKYNGE >100000 3625.5 >83715.79 457.9
FI 18.06 LVΓPENAKEKPQ 535.3 1217.8 t. FI 18.02 LVTPENAKEKPQEGT 827.3 1876.3
F071.12 LVΓPENAKEKPQEGT 66666.7 56.9 >71393.06 174.1
F071.30 NGEEYLILSARDVLA 6052.3 5732.5 1691.3 590.5
F071.l l PSGLVΓPENAKEKPQ >100000 53.5 >61828.21 138.6
F071.22 RΓPVDVSEGDΓVΓYS >100000 15.3 >61828.21 >51639.78
581.02 RKHRIEDAVRNAKAAVEEGI 892.9 200000.0 91000.0 1000000.0 3726.
VAG F071.24 SEGDΓVIYSKYGGTE 3479.5 144.3 >71393.06 40824.8
572.03 TLLQAAPALDKY 1785.7 10000.0 18200.0 >15429.72 40000.0 >2500
F071.03 VAKVKΓKPLEDKILV 4789.8 180.5 5919.6 3722.9
F071.04 VKΓKPLEDKILVQAG 2309.4 471.2 483.3 28284.3
F071.17 WAVGPGRWDEDGAK >100000 650.0 >71393.06 1490.7
581.01
F160.21 EKΓWEELSVLEVFEGRED
F160.20 ETSYVKNLIIHMVKISGG
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQB *0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *030
58.0062 EEKΓWEDLSMLEVFE
58.0057 FPDLESDFQAAISRK
58.0058 LESVLRDCQDFFPVI
58.0064 MQDLVQDNYLEYRQV
58.0063 PRKLLMEDLVQENYL
58.0065 QDLVQEDYLEYRQVP
58.0059 QLVFGIDWEWPIS
58.0071 EEKΓWEDLSVLEVFE
58.0068 LGSWGDWQYFFPVI
58.0074 QHFVQEDYLEYRQVP to 58.0073 TQHFVQDNYLEYRQV
∞ o F167.06 LLKYRAREPVTKAEMLGSW 974.2 117.0 14.3
GNWQ
F167.08 MVKISGGPRISYPLLHEWALR 161.1 9.9 >11245.72 EGEE
FI 67.07 QVPGSDPACYEFLWGPRALIE >7816.32 >6092.72 27878.8
TSY
FI 60.27 VGNWQYFFPVΓFSKASDSL
520.09 YKLNFYFDLLRAKL 1470.6 1250.0 91000.0 6666.7 >250
520.07 YLDNIKDNVGKMED 1470.6 3333.3 91000.0 3363.62 >1526.32 >250
F160.15 AAGIGΓLTVTLGVL
825.10 AC- 2362.3 200000.0 91000.0
ASQKRPSQRHGSKYLATAST
765.17 AC- 299.8 200000.0 3033.3 8165.0
ASQKRPSQRSKYLATASTMD
F006.16 ANPWHFFKN TPR 1.3 315.5
825.01 ASQKRPSQRHGSKYLATAST 898.0 200000.0 91000.0
765.15 AYDAQGTLSKIFKLGGRDSR 2192.7 37.7 45.3 110.0
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQ *0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *03
F006.14 DENPWHFFKN 959.2 >6666.67
F006.13 DENPWHFFKNI 15.7 4472.1
F006.12 DENPVVFrFFKNW 6.5 2020.3
F006.11 DENP WHFFKNTVT 4.2 691.3
F006.10 DENPVVHFFKNTVTPR 10.7 1529.4
F006.09 DENPWHFFKNTVTPRT 26.8 2981.4
F006.01 DENPVVHFFKNΓVTPRTPP 3.0 54.7
F006.0202 DENPVVFIFFKNΓVTPRTPPY 12.2 26.3
F006.03 DENPVVHFFRNΓVTPRTPPY 1.4 19.5
F006.17 EAPVVHFFKNΓVTPR 2.8 691.7
F006.18 ENAWHFFKNTVTPR 4.6 423.9 t
∞ F006.19 ENPAVHFFKNTVTPR 1.6 678.1
F038.01 ENPKVHFFKNIVTPR 7.3 15.4
F006.20 ENPVAHFFKNΓVTPR 156.0 482.8
F038.02 ENPVKHFFKNIVTPR 405.4 869.6
FOO6.21 ENPWAFFKNΓVTPR 2.8 301.5
F038.03 ENPWAFFKNΓVTPR 5.2 11.1
F038.06 ENPWDFFKNΓVTPR 75.8 166.7
F038.05 ENPV FFKNTVTPR 2.1 4.4
F006.22 ENPVVHAFKNΓVTPR 2.7 910.0
F038.07 ENPVVHAFKNΓVTPR 2.1 4.7
F095.08 ENPVVHAFRNTVTPR 21.9 42.6
F038.09 ENPWHDFKNΓVTPR 451.6 909.1
F006.23 ENPVVHFAKNTVTPR 233.2 6324.6
F095.06 ENPVVΉFARNΓVTPR 975.1 2020.2
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQB *0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *030
F006.24 ENPVVHFFANTVTPR 2.9 6235.3
F038.14 ENPVVHFFANΓVTPR 3.6 7.7
Cr-8 ENPVVHFFANΓVTPRTP 126.4
F038.15 ENPWHFFDNΓVTPR 344.9 740.7
F038.16 ENPVVHFFHNΓVTPR 6.4 13.3
F006.25 ENPWHFFKAΓVTPR 4.0 209.7
Cr-9 ENPWHFFKAIVTPRTP 12.5
F038.19 ENPVVHFFKKΓVTPR 650.0 1428.6
F006.26 ENPWHFFKNAVTPR 2.6 1616.9
Cr-10 ENPWHFFKNAVTPRTP 827 188.9
„ F006.27 ENPVVHFFKNIATPR 4 1 10206
S F006.28 ENPWHFFKNΓVAPR 0.7 662
Cr-11 ENPVVHFFKNΓVAPRTP 16.0 37.0
F006.29 ENPVVHFFKNΓVTAR 1.0 495.1
F006.30 ENPVVHFFKNΓVTPA 25 3333.3
F006.36 ENPVVHFFKNΓVTPA 6.9 20000.0
F006.15 ENPVVHFFKNIVTPR 5.2 462.5
Cr-7 ENP HFFKNΓVTPRTP 43.3
F006.04 ENPVVHFFKNΓVTPRTPPY 17.4 573.1
F038.20 ENPVYHFFKNKVTPR 18.5 37.7
F038.17 ENPVVΉFFLNΓVTPR 3.4 6.3
F038.18 ENPWHFFRNΓVTPR 2.0 4.3
F038.13 EΓSTPVVHFKKNΓVTPR 339.1 714.3
F038.10 ENPVVHFΓFKNΓVTPR 7.9 16.7
F095.10 ENPVVHHFRNIVTPR 16.6 33.9
TABLE 27b
HLA-DR binding affmity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQ
*0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *03
F038.ll ENPWHLFKNΓVTPR 8.4 16.7
F095.09 ENPWHLFRNΓVTPR 5.5 11.8
F038.12 ENPVVHWFKNΓVTPR 19.7 42.6
F095.12 ENPVVFΓYFANΓVTPR 18.3 40.0
F095.ll ENPVVHYFHNΓVTPR 14.2 28.2
F038.08 ' ENPVVHYFKNΓVTPR 2.1 4.7
F095.13 ENPVVHYFLNΓVTPR 18.1 38.5
F095.07 ENPVVHYFRNΓVTPR 49.2 48.8
F038.04 ENPWKFFKNWTPR 7.0 15.4
613.02 FFKNΓVTPFFKNΓVTP 2272.7
825.07 FSWGAEGQRPGFGYGGRASD >10206.21 200000.0 91000.0 765.13 GFGYGGRASDYKSAHKGFKG > 10206.21 138.9 61.9
825.06 GKGRGLSLSRFSWGAEGQRP 4724.6 1666.7 3033.3
825.04 GSGKIDSHHPARTAHYGSLPQ > 10206.21 200000.0 91000.0
765.03 HARHGFLPRHRDTGILDSIG >10206.21 4000.0 91000.0
F006.321 HFFKNTVTPRTPPY 460.2 377.4
F006.322 HFFKNTVTPRTPPY 2144.9 571.7
765.16 IFKLGGRDSRSGSPMARR >12500 8000.0 1011.1
765.06 KRGSGKDSHTRTTHYGSLPQ >10206.21 14142.1 479.0 800.0
765.08 KSQHGRTQDENPWHFFKNI >10206.21 10000.0 9100.0
F006.31 NPWΉFFKNIVT 23.4 10000.0
F006.37 NPWHFFKNΓVTPA 4.8 13.3
F006.34 NPWHFFKNIVTPR 3.7 1889.8
F006.05 NPVVFΓFFKNΓVTPRTPPY 7.7 124.0
F006.39 PWHFFKNΓVT 348.0 714.3
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQ *0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *03
F006.38 PWHFFKNΓVTPA 15.0 20000.0
F006.35 PWHFFKNΓVTPR 18.6 8165.0
F006.06 PVVHFFKNΓVTPRTPPY 4.8 45.3
825.11 QKSHGRTQDENPWHFFKNI 10000.0 13333.3 1300.0
F121.03 RASDYKSAHKGFKGVDAQGT 449.5
F121.02 RASDYKSAHKGLKGHDAQGT 149.1
825.02 RDTGILDSIGRFFGGDRGAP >10206.21 169.5 91000.0
765.04 RDTGILDSIGRFFSGDRGAP 250000.0 265.8 3033.3 5773.5
825.03 RFFGGDRGAPKRGSGKDSHH >10206.21 200000.0 4550.0
765.05 RFFSGDRGAPKRGSGKDSHT 250000.0 200000.0 910.0 2000.0
825.05 RTAHYGSLPQKSHGRTQDEN > 10206.21 3333.3 91000.0
£ 825.09 VDAQGTLSKΓFKLGGRDSRS 1170.7 18.2 3033.3 769.2
F112.01 VDAQGTLSKΓFKLGGRDSRS 37.7
FI 12.04 VDAQGTLSKLFKLGGRDSRS 57.1
FI 12.03 VDAQGTLSRΓFKLGGRDSRS 33.9
F006.08 VHFFKNΓVTPRTPPY 63.7 49.7
765.10 VTPRTPPPSQGKGRGLSLSR >10206.21 10000.0 91000.0
F006.07 VVHFFKNΓVTPRTPPY 10.3 46.1
765.14 YKSAHKGFKGAYDAQGTLSK 250000.0 3333.3 21.7 50.3
825.08 YKSAHKGFKGVDAQGTLSKI 108.3 2000.0 606.7
9.00 ANERADLIAYLKQATK >8333.33 1333.3 171.7 >7142.86 >25
847.02 EFWEFDLPGIKA 250000.0 200000.0 91000.0 14285.7 >25
593.02 VITAFNEGLK >3125 2222.2 91000.0 >50000 >25
847.01 YEFWEFDLPGΓKA 4166.7 20000.0 91000.0
753.03 IAFNSGLEPGWAEK-NH2 250000.0 6666.7 >15166.67 >50000 200000.0 >25
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 D
*0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *0
753.02 LLPLLEKVIGAGKPL-NH2 250000.0 6666.7 313.8 >50000 18
829.01 YKTIAYDEEARR 250000.0 200000.0 >18200 >50000 200000.0 >25
831.01 TWQRDGEDQTQDTELVETRP
AG
F009.04 VDDTLFVRFDSDAASPREEPR
F009.01 VDDTLFVRFDSDATSPRKEPR
F009.06 VDDTQFVRFDSDAASPREEPR
F009.02 VDDTQFVRFDSDAASPRMAP
R
F009.05 VDDTQFVRFDSDAASPRTEPR
536.00 AHAAFiAAHAAFXAAHAA >12500 10000.0 1516.7 >7142.86 33
N-3 AVHAAHAEΓNEAGR 96 to
90 151.00 HIATNAVLFFGR >25000 2500.0 91000.0 >16666.67 >25 Ol
144.01 ISQAAHAAHAEΓNE 43
84.04 ISQADHAAHAEΓNE 64
85.04 ISQAVEAAHAEΓNE 83
92.06 ISQAVHAAHAEDNE 85
92.05 ISQAVF1AAHAEIIE 73
91.02 ISQAVHAAHAQΓNE 54
90.05 ISQAVHAALAEΓNE 89 144.08 ISQAVHAANAEΓNE 83 9o.oi ISQAVHAARAEΓNE 57
747.01 LKISQAVHAAHAEIN 3.5 705.05 MVYLGAKDSTRTQΓNKWRF >6250 5000.0 910.0 >33333.33 >25 521.00 NVMEERKIKVYLPRM >25000 2000.0 91000.0 >14285.71 >25 560.04 VHAAFlAEINVHAAHA >12500 200000.0 91000.0 >14285.71 30
TABLE 27b
HLA-DR binding affmity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQB *0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *030
594.03 YTYTVHAAHAYTYT 48.1 5000.0 700.0 14285.7
112.06 YTYTVHAAHAY'TY'T 48.1 5000.0 700.0 >14285.71 328.
58.0082 LΓRVEGDLRVEYLDD
58.0081 QHLTRVDGNLRVΈYL
58.0091 RFEMFRDLNEALELK
68.0019 AAPLLLARAASLSLG 24.8 30.3 64.4 99.8 563.8 3.2 35.0 10469.0 78.8 79.0 68.0025 AKELKFVTLVFRHGD 605.8 1952.8 2354.9 12309.2 693.3 824.0 1529.5 8563.1 51.4 23.9
68.0052 ALDVYNGLLPPYASC >28845.61 588.5 86602.5 182.4 7568.1 >24748.74 1090.8 >13968.43 >9459.77 115470.1
68.0020 APLLLARAASLSLGF 58.9 75.9 124.2 322.1 224.7 11.8 91.4 13358.3 58.9 113.9 to 68.0024 DRSVLAKELKFVTLV 2016.1 15814.7 4719.3 20965.7 300.7 4409.6 1359.0 >10217.64 53.2 2217.2
Ox 68.0030 DRTLMSAMTNLAALF 382.6 2361.5 221.6 2366.9 704.3 114.2 870.9 3927.1 57.4 26137.9 68.0051 DTTVSGLQMALDVYN 14705.9 >110162.86 2875.6 >19640.02 712.5 3500.0 1042.3 10843.6 960.7 >200000 68.0056 FAELVGPVΓPQDWST 24056.3 >110162.86 39471.8 >19640.02 12503.5 >17500 >45500 >13968.43 983.2 >200000
68.0028 FGQLTQLGMEQFΓYEL >51031.04 109567.3 >167705.1 27216.6 652.8 >35000 >18200 5-10217.64 543.3 100000.0
68.0047 GGVLVNEILNHMKRA 29462.8 3238.7 54410.7 254.6 6694.4 48.7 575.6 8124.1 5.8 8.7
68.0156 GPVΓPQDWSTECMTT >8184.79 20296.3 961.1
68.0034 GVSΓWNPILLWQPIP 4992.0 11008.0 3984.9 10286.9 3902.2 207.3 5.0 4427.9 492.0 522.6
68.0038 ILLWQPΓPVHTVPLS 18.8 13091.1 131.0 2343.5 7288.6 1111.3 65.5 >8824.57 712.3 28768.5
68.0048 ΓPSYKKLΓMYSAHDT 1946.3 60.5 350.5 52.8 669.1 2122.2 17.3 9982.0 12.0 191.1
68.0046 KSRLQGGVLV EILN 2837.6 >49000 5516.2 >29814.24 9605.1 318.3 >26269.44 >13968.43 713.0 >100000
68.0053 LDVYNGLLPPYASCH >28845.61 404.3 31277.2 194.3 9752.9 >24748.74 3035.0 >13968.43 >10496.41 25819.9
68.0050 LΓMYSAHDTTVSGLQ 730.9 24812.1 813.4 >29814.24 >12214.98 1752.2 183.7 6827.8 4381.2 >100000
68.0023 LLFFWLDRSVLAKEL 135.0 163.2 518.4 154.2 178.6 23.9 33.7 85.8 7.5 134.5
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQB *0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *030
68.0042 LPSWATEDTMTKLRE >33407.66 >49000 >108253.18 >28114.42 >8417.51 >24748.74 >31547.94 59727 >10717.79 343.5
68 0043 LRELSELSLLSLYGI 4009.8 9367.8 1614.0 6958.4 1169 0 3217.7 234.8 >13968.43 544.0 5184.8
68.0044 LSELSLLSLYGΓHKQ 20906 1 1186.3 1450 2 1657.2 262 1 1253.2 45.0 >10746.91 794 7.3
68.0040 LSGLHGQDLFGTWSK >33407.66 >49000 >108253 18 30151 1 7890 6 >24748 74 32173 4 >8824 57 134 8 81649 7
68.0045 LSLLSLYGTHKQKEK >33407.66 1636.9 4959.5 742 1 646.5 >24748.74 58 4 >13968.43 771.9 3.4
68.0153 LTELYFEKGEYFVEM 13061 7 18840 8 26949.3 > 18736.1 12690.0 3157.4 4042 7 184.4 600.5 6655.5
68.0031 MSAMTNLAALFPPEG 36084.4 73870 3 >144439.26 >200000 3873.3 249.5 12383.5 7157 7 1072.0 63245.6
68 0032 MTNLAALFPPEGVSI >68790.15 39231 4 22821.8 141421 4 4530.8 1309.8 10370.4 >882457 4605 8 141421.4
68 0036 NPΓLLWQPIPVHTVP 41.4 12998 7 575.3 599.1 6124 250.0 4.6 >8824 57 67 1 25000.0
68.0033 PEGVSIWNPILLWQP 15030 0 285774 103095 8 30860 7 7975 9 444 3 7 2 4623 6 107 3 222222
68.0037 PILLWQPIPVHTVPL 45 6 212442 168 3 4040 6 2370 0 567 3 6 9 >8824 57 106 2 41491 3 g 68.0021 PLLLARAASLSLGFL 162 1 36 6 57 9 1254 6 1511 2 124 117 7 >8602 89 52 0 150 7
"^ 68.0026 RSPΓDTFPTDPΓKES >51031.04 >109567.33 6123 7 >200000 >3132 18 >24748 74 2373 5 >10217 64 468 9 28571 4
68.0022 SLSLGFLFLLFFWLD 22727.3 >58095 92 24620.0 1000000 1220.9 639.5 11375.0 3710 2 >9602 54 66666.7
68.0147 TVPLSEDQLLYLPFR 11312.7 42162 0 37369.2 26455.0 14387.2 5300.1 >2030.13 43229 872.5 27220.8
68.0035 WNPILLWQPΓPVΉTV 520.5 115494.1 607.1 19640.0 5694.0 2259.2 14.0 >8824.57 80 6 100000.0
68 0039 WQPΓPVHTVPLSEDQ 1594 >49000 17517.8 >28114.42 >8417.51 2692.3 >31547.94 >882457 1228 2 >100000
68 0041 YDPLYCESVHNFTLP 838.4 30867 1 643.1 30151.1 >8417.51 >35000 2136.1 >8824.57 6900.7 28768.5
68 0049 YKKLIMYSAHDTTVS 291 8 308 8 107 5 207 7 927 6 374 14 5 13224 0 5 8 5482 3
68.0054 YNGLLPPYASCHLTE >54554.47 14026 8 8022 4 5300.4 >12214 98 11666.7 252.1 >13968.43 >10496.41 100000.0
1188.24 AGGIAGGLALLACAG >72168.78 138871.0 >63245.55 >10864.32 7000 0 >74877.68 >13074.41
1188.14 ATSVLAGLLGNVSTV >72168.78 952274 25000.0 10819.9 18200.0 16307.3 >29814.24
1188.28 AVPLAMKLIQQLNLN 327.7 1305.2 100000 0 306 2 15166.7 1659 9 >33333.33
F143.02 EWSPCSVTCGNGIQVRΓK 1355.0 44208 9 >50000 >225000 1374.0 >64346.72 >66666.67
27.0396 FLALFFIΓFNKESLA 1794.4 23400 9 >20044.59 1004.1 >2412.22 1840.7 4333.3 >6655.58
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQB *0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *030
F143.09 IEQYLKKΓKNSISTEWSPCS 250.4 426.5 1961.0 20044.5 211.1 376.0 2483.4
1188.04 IFHINGKIΓKNSEKD 1685.5 1267.6 9377.5 539.2 3381.2 300.5 420.3 > 1147.08 48502.0 349.9
27.0401 KHILYISFYFILVNL 1533.6 25198.9 9578.0 >2412.22 4333.3 >8908.71
1188.20 LK)VHDLISDMIKKE 2602.2 5290.8 1734.6 6085.8 >10864.32 9668.5 1491.8 646.8 2679.0
F150.02 NAPΛIIRLHSDASKNKEKAL >47245.56 24424.4 2064.7 >17500 797.9 2653.1
27.0414 NHAVPLAMKLIQQLN 4536.7 305.2 5991.9 1174.1 220.8 2010.7 3640.0 8074.6
F107.12 TVLLGGVGLVLYNTE 35816.8 >173241.16 >81649.66 >5590.06 18200.0 >40000
1188.47 VDLYLLMDCSGSΓRR 5597.2 73283.2 >50000 >10864.32 947.9 >52946.51 2522.9
27.0410 VKNVSQTNFKSLLRN 3469.0 361.1 >20044.59 186.5 >2412.22 1013.5 3198.6 1612.4
1188.48 WILTDGΓPDSIQDS >72168.78 >141450.82 >50000 >10864.32 15166.7 5138.6 >33333.33
F150.03 YADSAWENVKNVTGPFMKAV 611.0 4751.3 21344.7 >17500 ' 520.8 633.8 to
00 191.16 ADLIAY'LKQATAK 133.3 3033.3 so
12.04 DLIAYLKQATAK 95.2 1300.0
12.05 ERADLIAYLKQATAK 100.0 185.7
12.03 IAYLKQATAK 1333.3 827.3
191.10 KAERADLIAY'LKQATA 714.3 165.5
199.17 LIAY'LKQATAK 181.8 1820.0
F025.08 AATYNFAVLKLMGRGTKF 16.7 239.0 70028.0 1217.9 17.9
K-09 FLYGALLLAEGFYTTGAVRQ 44.6 256.4
F050.02 FLYGALLLAEGFYTTGAVRQ 25197.6 91324.2 1000.6
K-28 FNTWTTCQSIAFPS >9100 99.2
K-20 LCADARMYGVLPWNAFPGK 44.7 5773.5
V
K-05 LTGTEKLIETYFSKNYQDYE 195.8 20000.0
F025.05 QKGRGYRGQHQAHSLERVCH 30151.1 >9100 >250000 17950.6 9759.0
K-18 SAVPVYΓYFNTWTTCQSIAF 92.0 20000.0
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQ
*0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 0101 *030
F050.05 SAWVΎΓYFNTWTTCQSIAF 33333 3 157604 72500 0
K-16 TAEFQMTFHLFIAAFVGAAA 548 8 >20000
F025.03 WTTCQSIAFPSKTSASIGSL 40000 0 276 9 37453 2 504 8 400 5
68 0066 AHCΓRNKSVILLGRH 2573 4 104 0 715 1 93 2 159 5 75 1 88 4 47524 8 7 3630 5
68 0078 CAQVHPQKVTKFMLC 32274 9 8730 5 34893 2 18490 0 2697 7 2191 8 808 9 >5543 24 604 1 1229 0
68 0079 GGPLVCNGVLQGΓTS >29880 72 9333 8 16308 2 1827 9 3744 7 35 9 30333 3 >3547 48 815 0 13417 3
68.0080 GPLVCNGVLQGITSW 4893 0 4187 0 32639 6 914 6 1875 7 49 3 6309 7 116144 6460 65372
68.0069 GQVFQVSHSFPHPLY 27 0 548 4 33 2 102 9 5574 145 7 2172 2 1070 7 415 9 127 6
68.0062 GRAVCGGVLVHPQWV 3581 7 >110162 86 8068 7 >19640 02 16411 4 54559 12888 3 >10756 16 62 1 100000 0
68 0063 GVLVHPQWVLTAAHC 153 3 1931 0 3645 2625 7487 5 2426 8 65 7 >10133 77 6 2 1061 9
68.0073 HDLMLLRLSEPAELT 152 1 3913 9 22 3 2141 0 520 0 2 3 661 8 5305 0 44 9 10540 9
68 0064 HPQWVLTAAHCIRNK 282 5 1305 2 106 7 784 7 5790 0 1169 8 6500 0 13240 55184 40 1
68 0158 HSLFHPEDTGQVFQV >8184 79 552 6 11502 9
68 0077 LHVISNDVCAQVHPQ 17451 2 > 122500 32670 5 >44721 36 >7118 239 0 22750 0 18867 10867 >200000
68 0081 GVLQGITSWGSEPC 4854 5874 3 819 3 97243 27164 775 0 257 6 80379 4487 5 11619 1
68 0071 PHPLYDMSLLKNRFL 10699 0 298127 12835 5 >44721 36 486 7 116667 711 8 >5543 24 7486 1 3103 9
68 0065 QWVLTAAHCΓRNKSV 213 8 2598 0 966 8 21694 4170 5 2062 4 13565 5 7341 6 3801 6 34 7
68 0082 PSLYTKWHYRKWI 6525 38 7 5483 8 3504 4160 1 4183 3 717 0 2981 8 4896 6 13 4
68.0072 SHDLMLLRLSEPAEL 58 1 3537 8 644 4470 8 736 7 5 8 1098 5 13577 7 11 6 100000 0
68 0061 SQPWQVLVASRGRAV 384 7 385 9 621 3 135 2 8775 4 32 1 11258 9 >10756 16 7561 8 83 5
68.0067 SVΓLLGRHSLFHPED 26088 3 500 1 5216 5 96 1 91 2 96 3 105 7 13044 6 4410 6 16116 5
68.0059 SVTWIGAAPLILSRI 82 9 139 4 304 2195 8 511 9 419 8 1475 13676 2 41 104 1
68.0074 TDAVKVMDLPTQEPA >28306 93 20874 7 >75000 >44721 36 >7118 >35000 >37150 59 >5543 24 7472 >141421 36
68.0058 TLSVTWIGAAPLILS 157 839 7 5 4 6859 9 553 6422 973 6030 6 35065 31 2
68 0070 VFQVSHSFPHPLYDM 50 6 8751 4 17 5 881 2 24774 83 2 2395 6 234302 >8574 92 8972
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQB *0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *030
68.0068 VILLGRHSLFHPEDT 30624.8 737.2 18519.9 343.6 56.4 543.4 426.4 >10756.16 10695.9 100000.0
68.0060 VTWIGAAPLILSRΓV 195.4 730.7 82.1 1779.4 818.5 2338.5 551.6 >10133.77 88.3 147.1
68.0125 ADKIYSISMKHPQEM 4098.4 1135.6 3512.2 169.5 9245.9 4957.0 8272.7 >15552.1 3550.1 26726.1
68.0101 AEAVGLPSΓPVHPIG 2015.2 >282901.63 23101.5 >43643.58 699.6 5455.9 55.9 >11642.8 12393.6 69336.1
68.0102 AVGLPSΓPVHPIGYY 1079.9 4431.7 15376.7 33333.3 384.3 1190.7 518.4 >11642.8 5386.6 38517.1
68.0113 CTPLMΎSLVHNLTKE 139.7 223.4 249.3 589.5 1727.7 259.8 426.1 18348.6 58.2 35.9
68.0114 DFEVFFQRLGIASGR 21926.5 122.3 2005.2 128.4 2005.3 10069.0 10248.9 30740.9 4.2 3559.1
68.0118 DPMFKYHLTVAQVRG 167.6 42.8 257.7 68.6 470.2 699.4 230.0 7297.1 466.8 11.5
68.0181 DQLMFLERAFΓDPLG 146.3 17114.5 6.6
68.0111 DSSIEGNYTLRVDCT 14457.9 >163333.33 > 100222.97 >40548.01 8939.2 7.6 1202.3 575.7 1261.8 16823.9
68.0167 EDFFKLERDMKΓ CS 8549.9 1439.3 >52337.75 10433.3 >10789.89 3188.2 >2432.11 4036.4 7886.1 3494.5 to 68.0109 ERGVAYΓNADSSIEG 34020.7 >163333.33 25515.5 >40548.01 >7055.5 3689.3 30333.3 6846.0 87.4 200000.0
©
68.0115 EVFFQRLGIASGRAR 5310.6 6.3 2976.2 30.9 2940.6 17500.0 4555.7 >13118.19 51.2 7.9
68.0100 EYAYRRGIAEAVGLP 70.5 596.5 66.6 2589.8 12278.3 5217.5 >45500 8773.5 6324.6 1204.4
68.0168 FFKLERDMKΓNCSGK >11622.71 8109.0 >52337.75 9687.3 6935.8 381.7 >2432.11 4917.9 98.4 3795.7
68.0173 GAAVVFIEΓVRSFGTL 517.3 788.3 88.7
68.0096 GKVFRGNKVKNAQLA 2349.8 4120.7 31277.2 894.1 >10595.71 45.8 3372.7 7591.3 7884.3 1385.1
68.0123 GMVFELANSΓVLPFD 29.6 4994.8 81.4 >25819.89 97.5 11.9 82.8 234.0 4154.0 902.6
68.0090 GNEΓFNTSLFEPPPP >29880.72 >126517.46 10414.7 >20380.71 >10595.71 2804.4 >91000 >12809.02 835.0 >115470.05
68.0097 GNKVKNAQLAGAKGV >72168.78 28904.2 7881.7 >26726.12 >10595.71 >20207.26 >45500 >12103.61 1064.9 1217.9
68.0110 GVAYLNADSSIEGNY 6244.5 23359.8 3047.6 >36514.84 5493.2 496.8 7609.8 1420.1 476.5 66666.7
68.0170 GVΓLYSDPADYFAPG 7848.0 106290.7 2472.8 >18736.1 1078.3 39.4 964.9 14.2 64.1 14167.9
68.0103 IGYYDAQKLLEKMGG >72168.78 8235.6 47245.6 >26726.12 >7751.94 5729.1 1978.3 17304.0 13587.6 506.4
68.0086 ΓKKFLYNFTQΓPHLA 28.8 512.5 159.9 136.8 551.7 27.3 305.2 477.4 96.4 658.5
68.0166 ISIΓNEDGNEIFNTS >11622.71 >81666.67 >52337.75 >18736.1 10650.6 343.1 3005.9 73.6 5853.6 >34616.84
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQB
*0701 *0802 *0901 *U01 *1201 *1302 *1501 *0101 *0101 *0101 *030
68.0126 IYSISMKHPQEMKTY 11573.2 1356.9 12292.8 212.9 11435 8 >35000 5024.7 >15552.1 5356 2 2588.2
68.0087 KFLYNFTQΓPHLAGT 29 7 415.0 54.5 90.8 1244 5 220.7 227.1 10211.4 256.3 1600.2
68.0120 KYHLTVAQVRGGMVF 228 4 1519.1 5860 1 858.6 6376.7 192.9 1221.5 >15552 1 3445 6 86 1
68.0089 LAHYDVLLSYPNKTH 3617.2 414.9 1009.0 380.1 7286.3 268.2 82.3 1405 7 588 5 172.4
68.0085 LDELKAENΓKKFLYN 7470.2 1248.2 12778.1 3243 368 1 597.0 413.8 547.8 787.9 149.5
68.0084 LGFLFGWFΓKSSNEA 2261.4 1420.6 1700.6 7303.0 474 6 10103.6 354 8 680 8 9285 1 460.9
68.0131 LRMMNDQLMFLERAF 17506 9 2492 0 4600 6 1832 9 279 9 1314.0 1411.2 1569 6 49 8 757.8
68.0119 MFKYHLTVAQVRGGM 722 70 4 265 8 147.1 481 6 1615.2 1197.8 3647 9 1061 8 5.8
68.0176 NSRLLQERGVAYΓNA 7996.7 3224.4 2616.1 12812 3 619 9 327.5 1229.3 33664 698.5 3472.8
68.0112 NYTLRVDCTPLMYSL 24596.7 6322.7 48412.3 7115.7 593.9 9 0 5055.6 254 404.1 66666.7
68 0127 PQEMKTYSVSFDSLF 1192.4 >82825.12 1980.9 >44721.36 5347 0 24748.7 919.2 14564 5 579.3 100000.0
68 0083 PRWLCAGALVLAGGF 766 0 26530 7 1438.6 >20380 71 4596.1 20207.3 15166.7 13149.2 883.1 40824.8
68.0135 QTYVAAFTVQAAAET 323.7 101 7 64.5 33.8 933 7 343 6 251 8 1323 8 50 5 216 1
68 0122 RGGMVFELANSΓVLP 41 5 86824 33 1 >25819 89 208 0 4 4 942 131 7 411 4 413 4
68 0133 RHVIYAPSSHNKYAG 31250 0 11666 7 481 2 13363 1 7082 2 8750 0 1290 8 >12475 05 5293 4 87.6
68 0134 QIYVAAFTVQAAAE 291 9 36 1 909 346 6090 524.4 1663 68074 472 142.6
68 0105 TGNFSTQKVKMHTHS 9407 4 10281 7 1450 5 11856 3 11636 9 6187.2 3744 6 >11642 8 508.5 1926.9
68 0116 TNKFSGYPLYHSVYE 30853.4 613 6 740.7 33333.3 4482.1 >24748.74 489.3 >15552 1 12465.6 2942.5
68.0107 TRIYNVIGTLRGAVE 4806.0 70.4 2900.4 45.4 502.4 1459.6 1605.3 17550.0 447.4 31.6
68.0128 TYSVSFDSLFSAVKN 345.5 2256 0 526.2 5981.5 5276.7 5888.4 3223.4 8546 3 10461.3 61.1
68.0136 VAAFTVQAAAETLSE 792.9 1420 0 127.5 21262 4460.8 445 9 18200 0 21160 464 1 3777
68 0121 VAQVRGGMVFELANS 4448 6 >98000 499 1 >44721 36 7605 2 2802 2 116 5 >15552 1 99 9 64366 0
68 0177 VAYΓNADSSIEGNYT 9744 9 105831 5 54673 >18736 1 8247 2 2147.4 >2432.11 471 3 841.5 >34616.84
68 0124 VFELANSΓVLPFDCR 39 0 36122 8 49.9 11764.7 525.2 23.7 477.2 128.0 1215.0 10814.8
68.0130 VLRMMNDQLMFLERA 17334.4 1699.9 10683.8 2353 0 98.5 129.8 126 8 97 9 88.1 85.0
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQB
*0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *030
68.0088 WKEFGLDSVELAHYD 3511.0 19970.9 7051.7 4935.0 >10595.71 8413.1 22750.0 829.1 5925.1 89442.7
68.0117 YDPMFKYHLTVAQVR 158.2 171.9 178.7 252.5 239.7 1014.3 1348.5 8137.4 552.7 62.4
68.0165 YISIΓNEDGNEIFNT 23719.2 >81666.67 83056.5 >18736.1 >10438.01 345.8 2713.2 52.9 3705.3 72992.7
68.0132 YPJEΓVΓYAPSSHNKYA 8792.9 750.0 528.4 1461.8 742.7 6390.1 896.8 61349.7 1117.4 54.1
FI 12.02 VDAQGTLSRLFKLGGRDSRS 25.3
938.01 KVNNQWSLKPEIΓVDQEY 2041.2 >10000
F160.32 STORKUSP32
FI 60.34 STORKUSP34
¥16036 STORKUSP36
F160.37 STORKUSP37
F160.39 STORKUSP39 F047.09 DKLKQQRDTLSTQKET >12578.87 611.4 F047.16 EQKSKQNIGALKQEL >12996.88 110.7
938.06 SGGTNYAQKFQGRVTMTRDT 8838.8 1571.4
-NH2
938.08 ELSRLSDDTAVYYCARAPG- 4166.7 40.8
NH2
938.09 ELSRLTSDDTAVYYCAIAPG- 2311.3 3162.3
NH2
938.10 TISCSGSSSNIGSNTVN-NH2 17677.7 >6666.67
FO 15.05 APYHFDLSGHA 208.
791.08 APYHFDLSGHAF 603.
791.07 APYHFDLSGHAFGS 714.
791.06 APYHFDLSGHAFGSMA 54.
791.05 APYHFDLSGHAFGSMAKK 101.
620.11 APYHFDLSGHAFGSMAKKGE >12500 1000.0 >5051.81 9592.2 172.4 20000.0 90.
620.05 CGYKDVDKAPFNGMTGCGN >12500 200000.0 91000.0 >20000 >250
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQ *0701 *0802 *0901 *1101 *1201 *1302 1501 *0101 *0101 *0101 *03
T
807.03 DLSGHAFGS 928
595.02 EDVΓPEGWKADTSYSAK >8333.33
620.14 ELQFRRVKCKYPDDTKPTFH 8333.3 200000.0 202.2 >25000 >25
620.13 EQNVRSAGELELQFRRVKCK 5000.0 2000.0 479.0 >25000 >25
620.20 ESWGAVWRΓDTPDKLTGPFT > 12500 444.4 2268.7 1011.1 18.9 186
791.02 FDLSGHAFGSMAKKGE 143
620.18 GDWAWDΓKEKGKDKWIEL >12500 200000.0 4550.0 >25000 >25
K
MA-05 GEKRAYAASDPGRYC 6250.0 2222.2 910.0 408.2 1767
620.19 KGKDKWIELKESWGAVWRΓD 5000.0 3333.3 3033.3 55.6 295 791.03 LSGHAFGSMAKKGE 443 620.23 SEVEDVΓPEGWKADTSYSAK 4166.7 6666.7 91000.0 1041.7 >25
MA-06 VAYESSEIASKKAG >8333.33 200000.0 15.4 >16666.67 2500
620.16 VEKGSNPNYLAILVKYVDGD 61.0 2000.0 3033.3 >25000 156
791.09 YHFDLSGHAFGS • 944
791.01 YHFDLSGHAFGSMAKKGE 171
620.15 PDDTKPTFHVEKGSNPNYL >12500 200000.0 3033.3 >25000 117
F165.05 KSDNQΓKAVPASQALVA 59.0 40.7
F165.01 PKSDNQΓKAVPAS 5989.5 >8750
F165.03 PKSDNQTKAVPASQA 1107.8 30.0
F165.02 VRPKSDNQKAVPAS 1582.1 1197.7
213.16 FRKDIAAKYKELGY 83.3 3033.3 169.5
213.15 LFRKDIAAKYKELGY 66.7 1820.0 256.4
542.00 NKALELFRKDIAA 909.1 91000.0 16666.7
213.12 NKALELFRKDIAAK 142.9 91000.0 8333.3
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQ *0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *03
213.11 KALELFRKDIAAKY 105.3 91000.0 0.0
13.00 NKALELFRKDIAAKYKELGY 80.0 650.0 178.6
QG
213.17 RKDIAAKYKELGY 142.9 91000.0 >20000
NASE061- FTKKMVENAKKIEVEFDKGQ 8333.3 6666.7 455.0 >25000 >25
80
F015.01 GLAKVAYVYKP 962
NASE121- HEQHLRKSEAQAKKEKLNTW 6250.0 200000.0 4.8 >5555.56 >25 140
191.26 LVRQGLAKVAY 200000.0 4550.0 533
NASE011- PATLIKAIDGDTVKLMYKGQ 8333.3 6666.7 1516.7 2381.0 >250
30
NASE031- PMTFRLLLVDTPETKHPKKG >12500 6666.7 1820.0 >5555.56 >250 O 50 - 191.29 QGLAKVAYVYK 1333.3 4550.0 75.
191.28 RQGLAKVAYVΎ 200000.0 4550.0 988
NASE041- TPETKHPKKGVEKYGPEASA 12500.0 6666.7 1820.0 >11785.5 >250
60
NASE051- VEKYGPEASAFTKKMVENAK 12500.0 20000.0 15.6 16666.7 263
70
191.27 VRQGLAKVAYV 200000.0 4550.0 637
NASE091- YTYADGKMVNEALVRQGLAK 1562.5 6666.7 1820.0 >5555.56 1250
110
546.00 FTKKMVENAKKIEVEFDKGQ 250000.0 3333.3 116.7 >250
866.05 HEQTiLRKSEAQAKKEKLNrW 25000.0 200000.0 7.6 16.7
598.00 PATLIKAIDGDTVKLMYKGQ 250000.0 2222.2 568.8 >25
866.06 QAKKEKLNΓWSEDNADSGQ 250000.0 200000.0 91000.0
866.02 VEKYGPEASAFTKKMVENAK 250000.0 200000.0 85.9
866.04 YIΎADGKMVNEALVRQGLAK 8333.3 20000.0 3033.3 2500
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQ *0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *03
835.03 YGAVDSILGGVATYGAA-NH2 250000.0 200000.0 91000.0 26.
F178.08 AGTIAALNNSIGVLG 4848.3 4873.6 4351.8 6001.8 2069.8 14.9 204.3 3870.9 175.9 99711.3 609
F178.10 GSISYPARYANAMAV 688.0 3679.5 1575.8 22091.7 >7434.33 2701.3 832.5 >4156.45 6815.0 100930.8 612
F178.06 GTVAALDNSAGVLGV 5286.3 36537.9 3850.5 5734.7 1466.7 122.6 983.0 699.9 404.9 19777.6 220
F178.05 GTVAALDNSIGVLGV 376.6 22837.4 328.5 9283.1 651.2 26.1 60.4 45.6 48.5 27201.0 146
F178.03 GTVAALNNSAGVLGV 1178.0 12106.6 54.9 3925.6 577.4 3.5 140.2 1788.8 53.5 24476.1 105
F178.01 GTVAALNNSIGVLGV 213.8 2519.7 56.8 3330.3 74.0 1.7 21.0 1468.0 41.7 13528.6 491.
F178.09 IAALNNSIGVLGVAP 851.3 2926.4 131.1 3058.5 194.5 3.0 273.9 1654.6 6.9 14400.4 4843
F178.04 GIEWAIANNMDVAN 148.6 3188.2 74.7 1742.4 503.0 17.8 214.3 95.9 603.7 1044.3 330
F178.02 NGIEWALANNMDVIN 109.5 2209.2 45.9 3910.6 932.5 14.0 561.7 116.0 719.2 983.1 251
F178.ll SYPARYANAMAVGAT 129.6 2415.5 196.2 5392.5 >7476.32 465.1 113.4 10999.9 10139.5 2044.3 71.
IO
SO F178.07 TGSGVKVAVLDTGIS >18494.24 177601.5 >30905.75 >19820.12 >6676.56 2755.6 >4297.05 1217.5 11.3 >30573.62 2653 Ol
573.13 ANSKFIGITELKK 250000.0 10000.0 568.8 >11111.11
573.12 ΓKANSKFIGITELKK 2500.0 33.9 178.4 7142.9
597.10 ΓLMQYΓKANS 12500.0 200000.0 91000.0
L-05 QAΓKANSKFIGITE 6666.7 65.0 >3703.7
650.05 QEΓKANSKFIGITE 12500.0 57.1 267.7 >50000 >250
650.06 QSrKANSKFIGITE 5000.0 40.0 131.9
650.21 QYΓKANQKFIGITE 1315.8 26.3 20.2 14285.7 >250
650.29 QYΓKANSKFKGITE 5000.0 35.1 2.3 >50000 >250
650.14 QYΓKKNSKFIGITE 531.9 46.5 2600.0 >50000 >250
650.16 QYIKSNSKFIGITΈ 20.8 57.1 32.5
650.13 QYIRANSKFIGITE 8.9 9.5 18896.5 >250
573.14 SKFIGITELKK 781.3 645.2 2275.0 >14285.71
548.02 YNGQIGNDPNRDIL 0.0
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQ *0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *03
534.02 DTPYLDITYHFVMQRLPL 390.6 200000.0 91000.0 800.0 >250
1385.07 GELIGILNAAKVPAD 516.9 13.0 >2599.36 931.9
F167.l l ALHΓYMDGTMSQVQGSA >10879.85 !933.4 >16680.72
F167.12 ALHIYMNGTMSQVQGSA >9731.24 65.5 >56873.68
F089.22 DQSYLQDSDPDSFQD
F089.13 DYSFLQDSDPDSFQD >66666.67
F089.25 DYSYFQDSDPDSFQD
1385.10 DYSYLQDSDPDSFQD >11037.77 >10552.9 6582.4 31455.1
F089.ll DYSYLQDSVPDSFQD >102062.07 >48048.45 >79950.27 >66666.67 >6708.41 17500.0 >37150.59 >36514.84
F089.24 DYSYQQDSDPDSFQD
1385.09 FLLHHAFVDSΓFEQWLQRHRP 578.6 >6390.1 >2196.1 21.6
F089.18 ILLSNAPLGPQFP 66666.67
F089.20 NILLSNAPLGPQFP 49508.7
F089.06 QNFLLSNAPLGPQFP 78.1 169.1 92.0 1677.1 >6708.41 1.6 1184.7 1291.0
F089.28 QNIFLSNAPLGPQFP
F089.04 QNILLSNAPQGPQFP 33256.7
F089.33 QNILLSNAQLGPQFP
F089.34 QNΓLLSNAVLGPQFP
F089.03 QNILLSNQPLGPQFP 6234.6
F089.07 QNILLSNVPLGPQFP 869.1 5853.2 1143.8 26263.3 4694.4 3.9 250.2 >36514.84
F089.30 QNTLQSNAPLGPQFP
F089.32 QNILVSNAPLGPQFP
F089.27 QNIQLSNAPLGPQFP
F089.29 QNΓVLSNAPLGPQFP
F089.19 QNVLLSNAPLGPQFP 24784.1
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQ *0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *03
F089.15 SYLQDSDPDSFQD >66666.67
F089.21 SYLQDSVPDSFQD >102062.07 >48048.45 >60436.72 >66666.67 >6708.41 >17500 >45500 >36514.84
F167.09 PSVFYNRTCQCSGNF 14367.8 391.8 >17950.55
F167.10 YGQMKNGSTPMFNDΓNΓYDL 1186.5 172.2 6592.5
F089.16 YLQDSDPDSFQD >66666.67
F089.14 YSYLQDSDPDSFQD >66666.67
604.01 (AKA)6 > 12500
848.01 A(56)FAAAA(24)A(56)AA(57)- 286.9 2.0 1.4 NTT2
848.03 A(56)FAAAA(24)L(56)AA(57)- 174.1 26.6 4.6 NH2
848.05 A(56)FAAAATA(56)AA(57)- 537.8 79.7 5.1 NH2 848.07 A(56)FAAAATL(56)AA(57)- 235.3 16.7 5.4 NH2
F042.01 A(X)KQNTLKLAT
848.02 AAFAAAA(24)A(56)AA(57)- 145.7 36.0 2.5 NH2
848.04 AAFAAAA(24)L(56)AA(57)- 137.5 14.3 1.6 NH2
848.06 AAFAAAATA(56)AA(57)-NH2 596.8 18.2 13.3
848.08 AAFAAAATL(56)AA(57)-NH2 133.4 2.0 4.1
603.01 AHAAHAAFLA\HAAHAAY >12500
F182.04 EVΓPMFSALSEGA 15001.0 5769.3 10733.4 52426.9
520.05 EVWREEAYHAADΓKD 25000.0 10000.0 3033.3 >12599.22 >250
520.06 EVWREEAYHAADΓKDY
852.04 KYVKQNTLKLAT
852.05 KYVKQNTLKLAT
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQ *0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *03
F182.09 LNKTVRMYSPTSI 1030.8 7820.2 138.9 971.4
F182.10 NKΓVRMYSPTSIL 274.9 250.7 306.1 1140.9
F042.06 P(X)KQNTLKLAT
F042.07 P(X)KQNTLKLAT
F182.03 PEVΓPMFSALSEG 23900.6 132744.2 3185.4 11281.7
F182.01 PΓVQNIQGQMVHQ 15599.3 665242.5 >74649.21 70687.3
F042.02 PKFV(X)TLKLAT
F042.05 PKFVKQNTL(X)T
F042.03 PKFVQ(X)KLAT
F182.08 QEQIGWMTNNPPI 4044.9 313909.2 >74649.21 158188.1
832.01 TFGLQLELTEGMRFDKG 289.2 20000.0 4550.0
173.00 TYQRTRALVTG 51.6 4000.0 91000.0 >16666.67 >250
F182.02 VQNIQGQMVHQAI 22807.6 446065.2 >74649.21 280386.1
835.01 YIDVWLGGLAENFLP-NH2 250000.0 200000.0 91000.0 269.
785.02 YKKSIQFHWKNSNQIKILG
843.03 YKLNDRADSRRSL 250000.0 227.3 91000.0
F002.02 YKPVSQLRLATPLLLRPL 14.8 434.8 0.9 51.0 21.1
835.02 YLDPLΓRGLLARPAKLQV- 250000.0 101.0 216.7 1000000.0 1020
NH2
F002.01 YLPKPPKPVSKLRLATPLLLQ 22.8 1451.0 48.2 99.4 93.3 ALPL
824.07 (14)AAAKTAAAFA-NH2 2551.6 3.2 5.9
824.08 ( 15)AAAKTAAAFA-NH2 4419.4 1.3 1.6
820.03 (15A)RQTTLKAAA-NH2 250000.0 1.8 4.3
820.05 (15A)RQTTLKAAA-NH2 - 4550.0
824.09 (16)AAAKTAAAFA-NH2 25000.0 64.5 325.0
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQ *0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *03
820.04 (16A)RQTTLKAAA-NH2 250000.0 76.9 1820.0
853.01 (39)AAAATKAA(35)-NH2
853.02 (39)AAAATKAA(36)-NH2
853.03 (39)AAAATKAA(37)-NH2
824.37 (39)AAAATKAAAA
856.04 (39)AAAKTAAA(35)-NH2
824.03 (39)-AAAKTAAAFA-NH2 250000.0 65.8 1516.7 1000000.0
824.21 (39)AAAKTAAAF-NH2
824.26 (39)AAKTAAAFA-NH2
824.02 (40)-AAAKTAAAFA-NH2 250000.0 769.2 4550.0 1000000.0
717.63 (42)YARFQSQTTLKAKT-NH2 7905.7 50.9 137.9 >4347.83 >250
787.34 (43)AADFFFFFFFFDA-(NH2)
787.43 (43)AAFGTDIFGFKIA-(NH2)
824.11 (45)AAAKTAAAFA-NH2
824.28 (46)AAAATKAAAA
824.12 (46)AAAKTAAAFA-NH2 25000.0 129.0 827.3
824.29 (47)AAAATKAAAA
824.13 (47)AAAKTAAAFA-NH2 25000.0 1176.5 3033.3
824.14 (48)AAAKTAAAFA-NH2
824.31 (49)AAAATKAAAA 8333.3 500.0 1516.7
862.06 (49)AAAKTAA(64)A-NH2
856.03 (49)AAAKTAAA(35)-NH2
862.07 (49)AAAKTAAA(64)-NH2
862.01 (49)AAAKTAAAAA-NH2
824.15 (49)AAAKTAAAFA-NH2 8333.3 12.5 30.6 27.
TABLE 27b
HLA-DR binding affmity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQB
*0701 *0802 *0901 +1101 *1201 *1302 *1501 *0101 *0101 *0101 *030
824.23 (49)AAKTAAAFA-NH2
824.32 (50)AAAATKAAAA
824.16 (50)AAAKTAAAFA-NH2 >17677.67 1428.6 2275.0
824.45 (51)AAAATKAAAA 12500.0 869.6 1011.1
824.43 (51)AAAKTAAAFA-NH2 25000.0 370.4 154.2
824.44 (52)AAAKTAAAFA-NH2 12500.0 285.7 910.0
824.51 (53)AAAATKAAAA
824.47 (53)AAAKTAAAFA-NH2 25000.0 769.2 3033.3
824.52 (54)AAAATKAAAA
824.48 (54)AAAKTAAAFA-NH2 25000.0 2000.0 2275.0
824.50 (55)AAAKTAAAFA-NH2
601.42 (65)(66)PKFVKQNTLKLAT 129.5 588.2 11.7
752.03 (67)AAYAAAAAAKAA-NH2 >12500 666.7 43.3 33333.3 357.
752.02 (67)FAAAAAAKAA-NH2 >25000 5000.0 126.4 50000.0 143.
858.07 (CP)-QSQTTLKAKT-NH2 250000.0 117.7 1011.1
859.03 (CP)YAAFQRQTTLKAAA-NH2 250000.0 2.9 123.0 297.7
Sandoz374 (NAF)AAAKTAAAFA-NH2 4000.0
934.15 (X2)KSSQYTKANSKFIGITEAA 1666.7 2390.5 568.8 23678.4 1296.4 AFLPSDFFPSV
803.11 A(14)AAAKTAAAAA-CONH2 892.9 10.5 22.6 >5000 67.
838.02 A(14)AAAKTAAAA-NH2 454.6 108.7 46.0
760.73 A(14)AAAKTAAAFA-NH2
838.01 A(14)AAAKTAAA-NH2 96.2 42.7 54.5
838.04 A(14)AAAKTAAA-NH2
803.10 A(14)AAAKTAA-CONH2 >8333
838.03 A(14)AAAKTAA-NH2
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQB *0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *030
736.21 AA ;iO)AAAAAAKAAA-NH2 190.8 153.9 13.4 50000.0 82.2
736.23 AA ;i2)AAAAAAKAAA-NH2
839.29 AA ;i4)A(37)ATKAAAA
828.03 AA ;i4)AAAA(24)KAAAA-NH2 92.3 6.6 2.6 >4545.45 193.
736.25 AA 14) AAAAAAKAAA-NH2 297.6 22.2 13.4
828.01 AA i4)AAAAPKAAAA-NH2 102.0 8.9 3.2 47.
906.30 AA i4)AAAATEKAAA-NH2 773.7 55.4 11.8 756.5 26.2 252.
906.33 AA i4)AAAATFKAAA-NH2 44.8 3.3 0.8 4767.4 1.9 31.
906.34 AA :I4)AAAATΓKAAA-NH2 80.9 3.2 1.1 896.2 2.3 69.
839.17 AA ;i4)AAAATK(36)AA
839.31 AA( ;i4)AAAATK(37)AA
O oJ 839.06 AA ;i4)AAAATKA(35)A
" 839.18 AA< ;i4)AAAATKA(36)A
839.32 AA ;i4)AAAATKA(37)A
839.20 AA ^14)AAAATKAA(35)-NH2 58.1 16.7 3.5
839.24 AA 14)AAAATKAA(36)-NH2 2083.3 6.7 1.4
839.35 AA :i4)AAAATKAA(37)-NH2
839.25 AA T4)AAAATKAAAA 201.6 9.1 1.9
828.11 AA( T4)AAAATKAAAA-NH2 192.3 7.4 7.6 >4545.45 70.
906.29 AA( 14)AAAATKKAAA-NH2 317.8 7.8 1.3 >19611.69 2.9 471.
906.35 AA( 14)AAAATLEAAA-NH2 169.6 11.3 7.0 1494.0 17.3 67.
906.38 AA( ,14)AAAATLFAAA-NH2 62.4 19.3 1.8 2719.6 4.1 27.
760.57 AA( M)AAAATLKAAA-NH2 171.1 6.9 492.1 2827.2 80.9 4.3 99.
906.47 AA< ;i4)AAAATLKAEA-NH2 147.8 26.8 2.4 1792.9 5.7 103.
906.50 AA( ;i4)AAAATLKAFA-NH2 79.3 10.1 21.2 459.8 30.1 3.7 35.
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQB *0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *030
906.48 AA(14)AAAATLKAQA-NH2 102.9 20.1 1.0 443.5 2.2 32.
906.49 AA(14)AAAATLKAVA-NH2 29.3 4.6 1.0 604.6 2.2 29.
906.41 AA(14)AAAATLKEAA-NH2 252.6 295.2 13.0 =>19611.69 31.0 449.
906.44 AA(14)AAAATLKFAA-NH2 26.2 117.7 3217.3 21.6 845.7 2.3 277.
906.45 AA( 14)AAAATLKIAA-NH2 28.5 30.6 1.2 54.4 2.6 93.
906.40 AA(14)AAAATLKKAA-NH2 625.0 39.3 5253.9 >1754.39 8202.4 0.6 61.
906.42 AA(14)AAAATLKQAA-NH2 275.5 29.4 2.7 5661.2 13.4 806.
906.43 AA(14)AAAATLKVAA-NH2 49.5 11.9 54.2 85.5 2092.9 2.0 43.
906.36 AA(14)AAAATLQAAA-NH2 120.6 17.1 1.6 5423.3 3.8 46.
906.39 AA(14)AAAATLRAAA-NH2 97.0 6.9 0.5 5263.2 1.2 48.
906.31 AA(14)AAAATQKAAA-NH2 114.9 9.0 0.9 1465.7 1.9 89. J 906.32 AA(14)AAAATVKAAA-NH2 58.3 4.2 1.3 2917.9 3.0 55.
^ 906.24 AA(14)AAAETLKAAA-NH2 423.1 11.4 2.8 343.4 6.3 82.
906.27 AA(14)AAAFTLKAAA-NH2 67.6 2.6 1.6 3823.7 3.5 73.
856.02 AA(14)AAAKTAAA(35)-NH2
760.50 AA(14)AAAKTAAAAA-NH2 753.1 6.1 743.0 2416.8 95.3 1250.0 56.
906.23 AA(14)AAAKTLKAAA-NH2 29.9 2.2 0.7 4445.6 2.8 52.
906.25 AA(14)AAAQTLKAAA-NH2 154.1 3.3 0.8 4545.5 1.8 71.
906.28 AA(14)AAATTLKAAA-NH2 75.2 5.3 0.6 2461.8 1.4 50.
906.26 AA(14)AAAVTLKAAA-NH2 69.7 4.1 0.7 104.2 1.5 46.
906.19 AA(14)AAEATLKAAA-NH2 >1388.89 6.8 6434.7 315.7 92.4 10.0 1136
906.22 AA(14)AAFATLKAAA-NH2 70.8 4.1 1.5 2858.3 3.7 3125
. 906.18 AA(14)AAKATLKAAA-NH2 25000.0 1.6 1.6 >1961 1.69 3.8 581.
906.20 AA(14)AAQATLKAAA-NH2 2727.7 4.2 1.5 >19611.69 3.4 1087
906.21 AA(14)AAVATLKAAA-NH2 45.4 2.5 0.7 3261.7 1.6 714.
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQB
*0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *030
906.14 AA(14)AEAATLKAAA-NH2 331.1 14.6 15.2 11180.7 24.4 3571
906.17 AA(14)AFAATLKAAA-NH2 33.8 3.3 20.5 1145.9 22.8 1.2 137.
906.13 AA( 14)AKAATLKAAA-NH2 97.6 3.3 628.0 22361.4 605.4 3.4 >1336
906.15 AA(14)AQAATLKAAA-NH2 104.2 5.7 0.8 21838.8 1.9 581.
906.16 AA(14)AVAATLKAAA-NH2 240.2 7.4 75.8 1744.5 13.5 1.3 3571
906.07 AA(14)EAAATLKAAA-NH2 221.8 4.4 7.6 3760.8 18.0 114.
906.10 AA(14)FAAATLKAAA-NH2 32.8 4.8 1.8 501.4 4.1 159.
906.11 AA(14)IAAATLKAAA-NH2 30.6 4.2 20.5 173.1 42.4 1.4 188.
906.06 AA(14)KAAATLKAAA-NH2 53.5 2.8 1.8 318.7 4.3 57.
906.12 AA(14)LAAATLKAAA-NH2 47.5 4.8 44.6 305.6 41.7 1.6 97.
906.08 AA(14)QAAATLKAAA-NH2 171.9 5.5 1.4 443.0 3.2 123.
906.09 AA(14)VAAATLKAAA-NH2 77.2 2.6 14.3 100.0 39.0 1.9 86.
906.56 AA(14)WAATLKAFA 64.6 3.8 6.2 844.8 12.3 8.9
828.13 AA(15)AAAATKAAAA-NH2 47.5 8.3 0.5
819.01 AA(15)AAKTAAAFA-NH2 7.8 1.2 0.9
819.02 AA(15)AAKTGGGFG-NH2 136.1 2.5 1.9
819.04 AA(15)GGKGGGGFG-NH2
819.03 AA(15)GGKTAAAFA-NH2 2273.3 2.0 9.1
819.05 AA(15)GGKTGGGFG-NH2
736.28 AA(17)AAAAAAKAAA-NH2
736.33 AA(2)AAAAAAKAAA-CONH2
773.08 AA(31)AAAAAAKAAA-NH2
736.17 AA(6)AAAAAAKAAA-NH2
736.18 AA(7)AAAAAAKAAA-NH2
736.19 AA(8)AAAAAAKAAA-NH2
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQ
*0701 *0802 *0901 *1101 1201 *1302 *1501 *0101 *0101 *0101 *03
736.20 AA(9)AAAAAAKAAA-NH2 2083.3 181.8 53.5 50000.0 224
736.34 AA(TIC)AAAAAAKAAA- CONH2
871.14 AAAAKAATLKAAA-NH2 493
760.27 AAAFAAAKTAAAFA-NH2 29.4 16.7 6.5 1000000.0 36.
730.04 AAAKAAAAAA(10)AA- CONH2
730.02 AAAKAAAAAAFAA-CONH2 1785.7 20000.0 1516.7 >50000 >25
702.02 AAAKAAAAAAYAA 12500.0 200000.0 1300.0 6250.0 423
702.06 AAAKAAAAAAYAA-COHN2 3125.0 2222.2 364.0 16666.7 2500
789.05 AAAKAAAAAFAAA
730.07 AAAKATAAAA(23)AA- >6250 1818.2 395.7 >50000 108 J
© CONH2
^ 787.06 AADFGrFrDFIIA-(NH2)
736.10 AAEAAAAAAKAAA-NH2
736.07 AAFAAAAAAKAAA-NH2
761.03 AAFAAAAAARLFA-NH2
828.07 AAFAAAAB(24)KAAAA-NH2 1041.7 129.0 5.4 162
760.71 AAFAAAATAKAAA 752.4 22.8 26.0 >4545.45 91.
760.41 AAFAAAATAKAAA-NH2 147.1 12.5 13.4 >4545.45 36.
760.72 AAFAAAATLKAAA 321.5 13.3 10.7 >4545.45 18.
760.43 AAFAAAATLKAAA-NH2 64.1 9.5 8.3 >4545.45 37.
871.12 AAFAAAATLKAKA-NH2 44.
871.11 AAFAAAATLKKAA-NH2 771.
760.37 AAFAAAKTAAAAA-NH2 280.3 5.6 23.2 >4545.45 39.
803.08 AAFAAAKTAAAFA-C0NH2 35.
760.15 AAFAAAKTAAAFA-NH2 67.5 4.6 11.2 20000.0 49.
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQ *0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *03
760.33 AAFAAAKTAAAFA-NH2 98.9 7.7 10.5 >4545.45 47.
760.17 AAFAAAKTAAAFE-NH2
803.13 AAFAAAKTAAAKA-NH2
760.47 AAFAAAKTLAAAA-NH2 180.7 5.1 14.9 >4545.45 22.
871.10 AAFAAAKTLKAAA-NH2 47.
871.09 AAFAAKATLKAAA-NH2 176
760.70 AAFAANKNAAFAA-CONH2 862.1 714.3 182.0
760.68 AAFAAQKQAAFAA-CONH2 250000.0 1176.5 57.2
760.69 AAFAATKTAAFAA-CONH2 8.3 222.2 11.5
760.64 AAFAKAATAKAAA-CONH2 641.0 5.9 36.4 >4545.45 83.
760.63 AAFAKAATLKAAA-CONH2 115.2 4.2 10.2 > 5 5.45 122
871.06 AAFAKAATLKAKA-NH2 2551
871.05 AAFAKAATLKKAA-NH2 106
871.04 AAFAKAKTLKAAA-NH2 1511
871.03 AAFAKKATLKAAA-NH2 >125
787.05 AAFFGΓFKIGKFA-(NH2)
787.11 AAFGΓKΓFGFKIA-(NH2)
871.02 AAFKKAATLKAAA-NH2 2500
770.04 AAFPPPPTLKAAA-NΗ2 2500
793.03 AAFVSQTTLKAAA
736.06 AAHAAAAAAKAAA-NH2
787.03 AAIGFFFFKKGIA-(NH2)
787.07 AAIGGIFIFKKDA-(NH2)
736.08 AALAAAAAAKAAA-NH2 1315.8 2222.2 30.3
760.09 AALKATAAAAYAA-NH2
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQ *0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *03
736.09 AAWAAAAAAKAAA-NH2
758.01 AAYA(4)A(4)AAKAAA
758.02 AAYAA(4)A(4)AKAAA
773.06 AAYAAAA(24)AKAAA-NH2
773.02 AAYAAAA(26)AKAAA-NH2
773.03 AAYAAAA(27)AKAAA-NH2
773.04 AAYAAAA(28)AKAAA-NH2
773.05 AAYAAAA(29)AKAAA-NH2
773.07 AAYAAAA(30)AKAAA-NH2
702.03 AAYAAAAAAKAAA-CONH2 129.9 9.1 7.0 3030.3 47.
773.09 AAYAAAAPAKAAA-CONH2
736.04 AAYAAAATAAAKA-NH2
736.03 AAYAAAATAKAAA-NH2
736.05 AAYAAAAYAAAKA-NH2
736.14 AAYAAJJAAKAAA-NH2
871.13 AAYAKAATLKAAA-NH2 481.
760.58 AC-AA(14)AAAATLKAAA- 289.0 7.4 3.5 >4545.45 70.
NH2 760.51 AC-AA(14)AAAKTAAAAA- 315.5 56.2 91.0 >4545.45 396.
NH2 730.13 AC-AAAKAAAAAA(23)AA-
CONH2 702.08 AC-AAAKAAAAAAYAA
702.12 AC-AAAKAAAAAAYAA- 2777.8 5000.0 4550.0 CONH2 760.42 AC-AAFAAAATAKAAA-NH2 533.9 26.2 27.2 >4545.45 50.
760.44 AC-AAFAAAATLKAAA-NH2 1075.8 13.3 16.2 >4545.45 68.
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQ
*0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *03
760.38 AC-AAFAAAKTAAAAA-NH2 >4347.83
760.34 AC-AAFAAAKTAAAFA-NH2 203.7 20.0 67.4 >4545.45 472.
760.48 AC-AAFAAAKTLAAAA-NH2 5000.0 25.2 202.2
760.67 AC-AAFAANKNAAFAA- 1190.5 909.1 246.0 CONH2
760.65 AC-AAFAAQKQAAFAA- 250000.0 1176.5 455.0 CONH2
760.66 AC-AAFAATKTAAFAA- 50.0 555.6 97.9 CONH2
806.06 AC-YAA(10)LFLSAARKRA- 1679.2 12.5 0.5 NH2
760.60 AC-YAA(14)AAAATLKAAA- 705.7 14.3 7.6 >4347.83 85. NH2
760.53 AC-YAA(14)AAAKTAAAAA- 1010.6 11.8 56.5 >4347.83 81. NH2
760.55 AC-YAAFAAAATAKAAA-NH2 25000.0 384.6 84.3 >4347.83 131.
760.46 AC-YAAFAAAATLKAAA-NH2 1000.8 20.0 11.6 >4347.83 48.
760.40 AC-YAAFAAAKTAAAAA-NH2 1250.0 38.6 93.8 >4347.83 33.
760.36 AC-YAAFAAAKTAAAFA-NH2 1828.2 64.9 66.4 >4347.83 63.
760.62 AC-YAAFAAAKTLAAAA-NH2 249.6 5.4 17.1 >4347.83 97.
805.03 AC-YARFLALTTLRARA- 1250 CONH2
906.02 AE(14)AAAATLKAAA-NH2 181.8 5.8 2.1 2942.5 4.6 50.
760.13 AEFAAAKTLAAFA-NH2
906.05 AF(14)AAAATLKAAA-NH2 35.7 3.4 0.8 1335.1 1.9 39.
851.09 AFAAAKTAA(71)
803.05 AFAAAKTAAAA-CONH2 74.
803.04 AFAAAKTAAA-NH2 757.
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQ
*0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *03
760.05 AFLRAAAAAAFAAY-NH2
906.01 AK(14)AAAATLKAAA-NH2 88.9 4.6 1.2 1346.0 2.9 42.
965.16 AK(14)VAAATLKAAA-NH2 234.2 23.2 2.8 88.5 10.9
965.15 AK(14)VAAHTLKAAA-NH2 168.6 30.1 2.5 50.5 4.0
965.14 AK(14)VAAKTLKAAA-NH2 232.9 34.5 3.6 63.2 8.6
965.08 AK(14)VAANTLKAAA-NH2 198.9 8.9 1.7 100.1 3.6
965.08 AK(14)VAANTLKAAA-NH2 146.8 13.7 3.3 5.5
965.10 AK(14)VAAWTLKAAA-NH2 157.7 97.1 127.6 16.1 >2852.25 220.0 45.1 268.6 104.9 16.9 42.
965.17 AK(14)VAAWTLKAAA-NH2 151.3 15.4 2.7 201.1 7.9
965.09 AK(14)VAAYTLKAAA-NH2 247.5 8.2 3.4 53.3 8.5
965.09 AK(14)VAAYTLKAAA-NH2 57.8 4.9 2.9 6.7 965.07 AK(14)VKAHTLKAAA-NH2 174.0 10.5 2.3 5.4
965.07 AK(14)VKAHTLKAAA-NH2 581.6 5.3 3.0 6.7
965.01 AK(14)VKANTLKAAA-NH2 492.2 13.2 5.7 13.4
965.01 AK(14)VKANTLKAAA-NH2 875.4 2.4 4.8 11.3
965.02 AK(14)VKAWTLKAAA-NH2 93.1 7.3 2.6 5.7
965.02 AK(14)VKAWTLKAAA-NH2 357.1 1.1 4.1 9.4
965.03 AK(14)VWANTLKAAA-NH2 206.9 8.8 2.5 26 L2 5.8
965.03 AK(14)VWANTLKAAA-NH2 291.5 3.3 239.8 4134.5 11.0 322
965.04 AK(14)VWAYTLKAAA-NH2 157.4 3.5 1.2 2.6
965.04 AK(14)VWAYTLKAAA-NH2 673.0 4.4 4.3 10.1
965.05 AK(14)VYAWTLKAAA-NH2 885.0 5.7 >20454.55 3.3 7.3
965.05 AK(14)VYAWTLKAAA-NH2 252.5 7.0 4.1 9.1
537.00 AKAAKAAKAAKAAKAA 12500.0 363.6 16.6 >7142.86 1250
871.07 AKFAAAATLKAAA-NH2 62.
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQ
*0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *03
803.14 AKFAAAKTAAAKA-NH2
Sandoz339 AKFAAALTLAAPA-NH2 >4545.45 84.
Sandoz338 AKFAAALTLAQAA-NH2 >4545.45 721
1303.02 AKFIAADTLKAAA
1303.01 AKFIAAWTLKAAA 3164.2
1024.03 AKFVAAWTLKAAA-NH2 270.4 12.0 178.4 19.8 5487.8 290.6 29.0 213.9 798.2 16.2 44.
1024.06 AKFVAAWTLKAAA-NH2 100.9 9.5 69.9 7.3 572.0 50.4 5362.1 30.4
1024.04 AKFVAAYTLKAAA-NH2 362.4 15.3 59.0 300.6 1421.8 13.6 30.
1303.04 AKFVADWTLKAAA 15212.8 281.4 263.9 >28355.39 248.8 8974.4 >72500 1854.8
1303.03 AKFVIAWTLKAAA 178.2 20.4 27.8 30000.0 234.1 7.7 10105.7 13.1
1024.01 AKFVWANTLKAAA-NH2 264.9 15.3 1174.8 415.2 5919.6 47.6 1250
1024.02 AKFVYANTLKAAA-NH2 322.4 33.6 1985.8 6250.0 1764.9 21.7 1250
1303.08 AKTVAAWTLKAAA 302.8 99.2 176.4 1380.3 134.5 76.1 5515.1 190.2
1303.06 AKΓVADWTLKAAA >47245.56 6381.7 5379.4 >28355.39 145.3 653.3 >72500 >66666.67
1303.09 AKLVAAWTLKAAA
1303.10 AKMVAAWTLKAAA 396.8 100.0 265.1 90000.0 277.5 160.7 7934.4 178.7
1303.07 AKMVADWTLKAAA >45950.91 4289.6 5310.6 >28355.39 173.8 4338.5 >72500 61728.4
906.03 AQ(14)AAAATLKAAA-NH2 53.2 3.7 0.8 1136.4 34.1 92.2
965.06 AR(14)VRANTLKAAA-NH2 84.0 4.4 2.9 6.6
820.07 AR(15A)RQTTLKAAA-NH2 1250.0 1.6 0.5
788.06 ARFQRQTTLKAAA
781.08 ARFQRQTTLKAAA-NH2
640.05 ARRLKARRLKATY >12500 10000.0 650.0 >16666.67 >250
906.04 AV(14)AAAATLKAAA-NH2 122.9 3.1 123.8 5564.2 10.8 2.2 69.
906.51 AV(14)AVAATLKAFA 77.8 3.6 38.9 411.3 1.3 8.6
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl* DRB] DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQB
*0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0I0I *030
906.55 AV(14)VFAATLKAFA 91.4 7.0 18.1 3603.7 25.5 16.5
906.52 AV(14)WAATLKAAA 135.0 5.4 62.2 221.7 46.6 11.2
906.53 AV(14)WAATLKAFA 86.2 6.3 26.6 133.2 7.8 14.0
640.01 AWRNRAKAWRNRAKAWRN >8333.33 714.3 182.0 >10000 1785
RAK 640.03 AWTUv^AKAWRNRAKGTD >12500 5000.0 104.6 >12500 2512
758.03 AYAAA(4)A(4)KAAA S5004 AYZAYAYTLKAAA
S5003 BOC-AYZAYAYTLKAAA
S1395 BOCXFAXAXTLKAAA 3030.3
631.02 DDYVKQYTKQYTKQNTLKK 12500.0 1111.1 16.0 >11111-11 >250
OJ 631.03 DDYVKQYTKQYTKQNTLKK >25000 645.2 175.0 >11111.11
® 760.08 EFAAATKAAAFAAY-NH2
819.06 GG(15)GGKGGGGFG-NH2
736.15 JJYJJAAAAKAAA-NH2 >12500 200000.0 91000.0 >50000 90.
640.06 KNRAKNRAKNRAKNRAK >12500 200000.0 197.8 >12500 >250
640.07 KRLKRLKRLKRLKRL >12500 87.0 168.5 5882.4 >250
965.19 KSSAK(14)VAAWTLKAAA- 514.6 29.3 6.8 10.7 24.8
NH2 784.08 PKYDKQGGLKIAT
784.05 PKYFKQFRLKIAT
784.13 PKYFKQIGLKRAT
784.04 PKYGKQRFLKIAT
784.15 PKYTKQDGLKGAT
784.09 PKYTKQFFLKRAT
784.01 PKYΓKQΠLKIAT
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQB *0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *030
784.10 PKYRKQFILKGAT
736.01 PNYAAAAAAKAAA-NH2 >4166.67
736.31 PNYAAAAAAKAA-CONH2
781.07 RFQRQTTLKAAA-NH2
716.02 TAIKKLTTQRQFRAY >14433.76 200000.0 4550.0 1449.3
717.11 TKQKLTTQSQFRAY-NH2 >14433.76 200000.0 91000.0 >33333.33
S5006 XFAXAXTLKAAA
Sandoz364 YA(AMK)FAAAKTAAAFA- 4545.5 NH2
Sandoz366 YA(K1)FQ(K1)QTTL(K1)AAA- 4347.8 OH
806.05 YAA(10)LFLSAARKRA-NH2 2777.8 5.6 2.6 1923
828.04 YAA(14)AAAA(24)KAAAA- 121.4 31.8 3.7 >4347.83 79. NH2
828.02 YAA(14)AAAAPKAAAA-NH2 192.3 10.3 4.7 36.
828.12 YAA(14)AAAATKAAAA-NH2 115.7 7.7 5.2 >4347.83 37.1
760.59 YAA(14)AAAATLKAAA-NH2 256.2 7.1 4.8 >4347.83 30.
760.52 YAA(14)AAAKTAAAAA-NH2 406.5 6.9 14.5 2439.0 64.1 20.
906.54 YAA(14)AVAATLKAAA 716.3 9.5 10.6 20000.0 48.7 23.5
828.14 YAA(15)AAAATKAAAA-NH2 75.8 8.3 0.3
Sandoz363 YAA(AMF)AAAKTAAAFA- 4545.5 NH2
760.26 YAAAKAAAAAAFAA-NH2
Sandoz368 YAAFAAA(DHPS)TAAAFA- 45.
NH2
Sandoz367 YAAFAAA(K1)TAAAFA-NH2 4000.0 82.
828.08 YAAFAAAA(24)KAAAA-NH2 1190.5 129.9 3.3 72.1
760.25 YAAFAAAAAAKAAA-NH2 266.0 487.8 75.8 1000000.0 409.
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRB1 DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQ *0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *03
761.04 YAAFAAAAAARLFA-NH2
761.02 YAAFAAAAAQRLFA-NH2
760.54 YAAFAAAATAKAAA-NH2 575.1 15.4 14.4 >4347.83 11.
760.45 YAAFAAAATLKAAA-NH2 279.7 9.5 4.3 >4347.83 28.
760.39 YAAFAAAKTAAAAA-NH2 563.8 12.5 29.2 >4347.83 79.
760.39 YAAFAAAKTAAAAA-NH2 1562.5 18.2 91.0
760.39 YAAFAAAKTAAAAA-NH2 46.3
760.16 YAAFAAAKTAAAFA-NH2 33.7 2.6 4.3 33333.3 30.0 35.
760.35 YAAFAAAKTAAAFA-NH2 1275.8 13.3 46.7 >4347.83 168.1 255
Sandoz362 YAAFAAAKTAAAFA-NH2 >4347.83 38.
760.18 YAAFAAAKTAAAFE-NH2
760.61 YAAFAAAKTLAAAA-NH2 134.7 5.0 20.0 >4347.83 37.
788.05 YAAFQRQTTLKAAA
788.04 YAAFQSQTTLKAAA
793.02 YAAFVRQTTLKAAA
793.01 YAAFVSQTTLKAAA
760.14 YAEFAAAKTLAAFA-NH2
781.16 YAK(14)QRQTTLKAAA- >25000 3.6 31.4 >50000 >250
C0NH2 Sandoz370 YAKFAAAKTAAAA(TR) >4545.45 38.
717.08 YAKFKSTTKKRIKS-NH2 785.7 87.0 70.0 >33333.33
1341.01 YAKFVAAWTLKAAA 2502.4 395.8
717.35 YAR(10)QSQTTLKAKT-NH2 25000.0 8.0 32.5
781.20 YAR(14)QKQTTLKAAA >12500 7.1 61.5
788.01 YAR(14)QRQTTLKAAA
781.15 YAR(14)QRQTTLKAAA- >25000 2.6 75.8 >50000 >25
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQ *0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *03
CONH2
782.03 YAR(15)ASQTTLKAKT-NH2 1195.9 3.9 1.7 >25
782.07 YAR(15)ASQTTLKAKT-NH2
820.02 YAR(15A)RQTTLKAAA-NH2 8333.3 1.2 0.4
820.11 YAR(15A)RQTTLKAAA-NH2 250000.0 1.2 5.4
820.01 YAR(15A)SQTTLKAKT-NH2 1785.7 2.5 0.7
820.10 YAR(15A)SQTTLKAKT-NH2 250000.0 4.2 22.8
782.04 YAR(16)ASQTTLKAKT-NH2 25000.0 800.0 76.5
717.34 YAR(9)QSQTTLKAKT-NH2 2988.1 47.6 118.2
717.43 YAREQSQTTLKAKT-NH2 >25000 200000.0 4550.0
782.06 YARFGGQTTLKAKT
805.01 YARFLALTTLRARA-CONH2 >25
805.02 YARFLALTTLRARA-CONH2 >25
717.36 YARFQSQT(24)LKAKT-NH2 >25000 14.3 12.5
717.18 YARFQSQTELKAKT-NH2 3608.4 4000.0 379.2
782.01 YARFQSQTTL(32)AKT-NH2 25000.0 57.1 151.7 >4347.83 >25
717.24 YARFQSQTTLKEKT-NH2 4166.7 6666.7 193.6
715.01 YARRLKAΓFARRLKA 0.0
788.03 YASFQSQTTLKAAA
788.02 YASFVSQTTLKAAA
785.01 YKKSIQFFΓWKNSNQΓKILGNQ 93.7 170.9 48.4
GSFLTKGPS 717.09 YPKFVKQNTLKAAT-NH2 >7216.88 1666.7 606.7 >33333.33
806.01 YQFIKANSKFKGKFK-NH2 5000.0 8.7 2.4
768.01 YSSFSSSSSSKSSS 208
768.02 YSSFSSSSSSKSSS-NH2 347.2 20000.0 700.0 1538.5 342
TABLE 27b
HLA-DR binding affinity (IC50 nM)
Peptide Sequence DRBl DRBl DRBl DRBl DRBl DRBl DRBl DRB3 DRB4 DRB5 DQ *0701 *0802 *0901 *1101 *1201 *1302 *1501 *0101 *0101 *0101 *03
768.03 YSSFSSSSSSSSSS 277
768.04 YSSFSSSSSSSSSS-NH2
564.01 YVKADYVKADYVKADYVK >25000 200000.0 1137.5
718.01 YVKQNTLAFVKQNTLA 12500.0 200000.0 650.0
631.01 YVKQYTKQYTKQNTLK 2083.3 689.7 364.0 >14285.71 >25
S1396 ZAAFAAAATLKAAA
S1399 ZAAFAAAXTAYAYA
S1400 ZAAFAXAATAYAYA
S5005 ZAAFAXAATLKAAA
SF 1281754 vl
Table 28a
Peptide AA Sequence Source
008.00 16 SALLSSDITASVNCAK HEL 81-96
200.06 16 SALSEGATPQDLNTML HIN gp25 41-56
213.10 16 NKALELFRKDIAAKYK Sp. W. myo. 132
506.01 20 NKALELFRKDIAAKYKELGY SW Myo 132-151
506.03 18 ALELFRKDIAAKYKELGY Sp. W myo. 134
506.05 16 ELFR DIAAKYKELGY Sp. W myo. 136
570.01 16 MAKTIAYDEEARRGLE Heat Shock Prot
705.06 20 KVYLPRMKMEEKYNLTSVLM Ova 279-298
717.04 14 YASFVKTTTLRKFT-NH2 DR2 combinatorial
857.02 20 PHHTALRQAILCWGELMTLA HBN.core.50
865.01 15 YKMKN[VHAAHAKMKM OVA KM core ext.
F050.03 20 GFYTTGANRQLFGDYKTTIC PLP 91-110
F089.01 15 QΝILLSΝAPLGPQFP Tyrosinase 56
F098.03 20 AAYAAQGYKNLNLNPSNAAT HCV.ΝS3.1242
F098.04 20 GYKVLNLΝPSNAATLGFGAY HCV NS3 1248
F098.05 14 GYKVLNLΝPSNAAT HCV NS3 1248
F098.06 19 SYNΝTΝMGLKFRQLLWFHI HBV Core 87
F098.10 12 GLKFRQLLWFHI HBV Core 94
F134.04 20 TLHGPTPLLYRLGANQΝEIT HCV NS4 1-20
F134.05 20 ΝFISGIQYLAGLSTLPGΝPA HCV.NS4.151
F134.08 21 GEGAVQWMΝRLLAFASRGΝIΪN HCV.NS4.293
IA-p5 17 KPNSQMRMATPLLMRPM Mouse.Ii.85
Tr-28 pi 24 LPKPPKPVSKMRMATPLLMQALPM Human.Ii.80
27.0279 15 EYLNSFGVWIRTPPA HBV.nuc.117
27.0280 15 GNWLRTPPAYRPPΝA HBV.nuc.123
27.0281 15 RHYLHTLWKAGILYK HBV.pol.145
27.0283 15 NPΝLQSLTΝLLSSΝL HBV POL 409
27.0288 15 WTNYYGVPVWKEAT HIVl.env.47
27.0293 15 YYGNPNWKEATTTLF HIV1 ENV 51
27.0294 15 VPVWKEATTTLFCAS HIVl.env.54 Peptide AA Sequence Source
27.0295 15 LSGINQQQNNLLRAI HIVl.env.711
27.0296 15 QQHLLQLTVWGLKQL HIVl ENV 728
27.0297 15 QHLLQLTVWGEKQLQ HIVl.env.729
27.0298 15 LLQLTNWGIKQLQAR HIVl ENV 731
27.0304 15 QGQMNHQAISPRTLΝ HIVl.gag.171
27.0307 15 SPENLPMFSALSEGA HIVl GAG 197
27.0310 15 QEQIG MTΝΝPPLPV HTVl GAG 276
27.0311 15 GEIYKRWIILGLΝKI HIVl.gag.294
27.0312 15 YKRWΠLGLΝKΓVRM HTVl GAG 297
27.0313 15 KRWΠLGLΝKΓVRMY HIVl.gag.298
27.0314 15 WIILGLΝKTVRMYSP HIVl.gag.300
27.0315 15 VKNWMTETLLVQNAN HIVl GAG 348
27.0322 15 GTVLVGPTPVNIIGR HTVl POL 153
27.0324 15 PVNIIGRNLLTQIGC HIVl POL 161
27.0326 15 GRNLLTQIGCTLNFP HlNl.pol.166
27.0328 15 TLNFPISPIETVPVK HIVl POL 176
27.0329 15 NFPISPLETVPVKLK HiNl.pol.178
27.0341 15 FRKYTAFTIPSL NE HIVl.pol.303
27.0344 15 SPALFQSSMTKILEP HTVl.pol.335
27.0345 15 PAIFQSSMTKILEPF HIVl POL 336
27.0349 15 QKLVGKLNWASQIYA HIVl POL 437
27.0350 15 VGKLNWASQΓYAGLK HIVl.pol.440
27.0351 15 NRELLKEPVHGVYYD HTVl.pol.485
27.0353 15 LPEWEFVNTPPLVKL HIVl POL 593
27.0354 15 WEFVNTPPLVKLWYQ HTVl.pol.596
27.0360 15 EQLΓKKEKVYLAWVP HIVl POL 705
27.0361 15 EKVYLAWVPAHKGIG HTVl.pol.711
27.0364 15 HSNWRAMASDFNLPP HTVl.pol.758
27.0370 15 ASGYLEAEVLPAETG HIVl POL 822
27.0372 15 AEHLKTAVQMAVFΓH HTVl.pol.911
27.0373 15 KTAVQMAVFΓHNFKR HTVl.pol.915 Peptide AA Sequence Source
27.0377 15 QKQITKIQNFRVYYR HTVl.pol.956
27.0379 15 KLLWKGEGAVVIQDN HINl.pol.982
27.0381 15 ENRWQVMΓVWQVDRM HlNl.vif.2
27.0382 15 VEAIΓRILQQLLFΓH HIVl NPR 57
27.0384 15 FNWNSSIGLΓMVLS PfCSP 413
27.0387 15 MNYYGKQENWYSLKK Pf CSP 53
27.0388 15 MRKLAILSVSSFLFV Pf.CSP.2
27.0390 15 NSSIGLΓMVLSFLFL Pf CSP 417
27.0392 15 SSNFNVVNSSIGLLM Pf.CSP.410
27.0393 15 MKILSVFFLALFFII Pf EXP1 1
27.0398 15 FILVNLLΓFHΓNGKI PfLSAl 11
27.0400 15 HILYISFYFILVNLL Pf LSA1 3
27.0402 15 LLLFHΓNGKIIKNSE PfLSAl 16
27.0403 15 LNNLLLFHLNGKIIK PfLSAl 13
27.0406 15 NLLΓFHΓNGKIIKNS PfLSAl 15
27.0408 15 QTNFKSLLRNLGVSE PfLSAl 94
27.0412 15 AYKFVVPGAATPYAG Pf SSP2 514
27.0415 15 NVKYLVΓVFLΓFFDL Pf SSP2 6
27.0417 15 VKNVIGPFMKAVCVE Pf.SSP2.223
27.0418 15 WENVKNVIGPFMKAV Pf SSP2 220
1186.04 15 CSWRRAFPHCLAFS HBN.pol.534
1186.06 15 FVQWFVGLSPTVWLS HBN EΝN 342
1186.10 15 LAQFTSAICSVVRRA HBN.pol.526
1186.15 15 LVPFVQWFVGLSPTV HBN.env.339
1186.18 15 NLSWLSLDVSAAFYH HBV POL 422
1186.25 15 SFGVWΓRTPPAYRPP HBN.nuc.121
1186.26 15 SPFLLAQFTSAICSV HBN.pol.522
1186.27 15 SSNLSWLSLDVSAAF HBN POL 420
1188.01 15 DKELTMSNVKNVSQT PfLSAl 81
1188.13 15 AGLLGNVSTVLLGGV Pf.EXP1.82
1188.16 15 KSKYKLATSVLAGLL Pf.EXP1.71 Peptide AA Sequence Source
1188.32 15 GLAYKFVVPGAATPY Pf.SSP2.512
1188.34 15 HNWNNHANPLAMKLI Pf.SSP2.62
1188.35 15 IGPFMKANCNENEKT Pf SSP2 227
1188.38 15 KYKIAGGIAGGLALL Pf.SSP2.494
1188.45 15 RHΝWVΝHAVPLAMKL PfSSP2 61
F091.15 16 IKQFΓΝMWQEVGKAMY HTVl.env.566
F107.03 15 LQSLTΝLLSSΝLSWL HBV.pol.412
F107.04 15 PFLLAQFTSAICSNN HBV.pol.523
F107.09 15 KYKLATSNLAGLLGΝ Pf EXP1 73
F107.10 15 LAGLLGNVSTVLLGG Pf EXP1 81
F107.l l 15 RHPFKIGSSDPADNA PfEXPl 107
F107.14 15 ANQLVVILTDGLPDS Pf SSP2 153
F107.17 15 KFVVPGAATPYAGEP Pf SSP2 516
F107.23 15 VFNVVNSSIGLΓMVL PfCSP 412
35.0093 15 VGPLTVNEKRRLKLI HBV.pol.96
35.0096 15 ESRLVVDFSQFSRGN HBV.pol.387
35.0100 15 LCQVFADATPTGWGL HBV.pol.683
35.0106 15 VWVATDALMTGYTG HCV.1437
35.0107 15 TVDFSLDPTFTLETT HCV.1466
35.0125 15 AETFYVDGAANRETK HTV.pol.619
35.0127 15 EVNΓVTDSQYALGΠ HIV.pol.674
35.0131 15 WAGIKQEFGIPYNPQ HIV.pol.874
35.0133 15 GANVIQDNSDIKNVP HIV.pol.989
35.0135 15 YRKILRQRKΓDRLΓD HIV.vpu.31
35.0171 15 PDSIQDSLKESRKLΝ Pf.SSP2.165
35.0172 15 KCΝLYADSAWΈΝVKΝ Pf.SSP2.211
1280.02 15 IGTVLVGPTPVΝIIG HTV.pol.152
1280.03 15 KVYLAWVPAHKGIGG HIV.pol.712
1280.04 15 TKELQKQITKIQΝFR HIV.pol.952
1280.06 15 AGFFLLTRILTΓPQS HBV.env.180
1280.08 15 GFFLLTRILTΓPQSL HBV EΝV 181 Peptide AA Sequence Source
1280.09 15 GTSFNYVPSALNPAD HBV.pol.774
1280.12 15 ΠFLFILLLCLLFLL HBV ENV 244
1280.13 15 KFAVPNLQSLTNLLS HBV POL 406
1280.15 15 LHLYSHPIILGFRKI HBV.pol.501
1280.16 15 LLCLΓELLVLLDYQG HBV ENV 251
1280.21 15 VGLLGFAAPFTQCGY HBV POL 637
1280.22 15 FYFILNNLLLFHLNG PfLSAl 9
1280.23 15 KSLLRNLGNSENLFL PfLSAl.98
1280.25 15 RGYYΓPHQSSLPQDN PfLSAl.1669
1283.02 15 VYLLPRRGPRLGVRA HCV Core 34
1283.10 15 GHRMAWDMMMNWSPT HCV El 315
1283.11 15 CGPVYCFTPSPWVG HCV.NS1/E2.506
1283.12 15 VYCFTPSPVVVGTTD HCV NS1/E2 509
1283.13 15 GNWFGCTWMNSTGFT HCV.NS1/E2.550
1283.14 15 FTTLPALSTGLLHLH HCV NS1/E2 684
1283.16 15 SKGWRLLAPITAYAQ HCV.NS3.1025
1283.17 15 DLYLVTRHADVIPVR HCV NS3 1134
1283.20 15 AQGYKVLVLNPSVAA HCV.NS3.1251
1283.21 15 GYKVLVLNPSVAATL HCV.NS3.1253
1283.22 15 VLVLNPSVAATLGFG HCV.NS3.1256
1283.24 15 GARLVVLATATPPGS HCV NS3 1345
1283.26 15 DVVVVATDALMTGYT HCV.NS3.1436
1283.30 15 FTGLTHLDAHFLSQT HCV.NS3.1567
1283.31 15 YLVAYQATVCARAQA HCV.NS3.1591
1283.33 15 LEVVTSTWVLVGGVL HCV NS4 1658
1283.34 15 TWVLVGGVLAALAAY HCV NS4 1664
1283.36 15 AKHMWNFISGIQYLA HCV.NS4.1767
1283.37 15 IQYLAGLSTLPGNPA HCV NS4 1777
1283.44 15 MNRLIAFASRGNHVS HCV.NS4.1921
1283.50 15 SYTWTGALITPCAAE HCV.NS5.2456
1283.55 15 GSSYGFQYSPGQRVE HCV.NS5.2641 Peptide AA Sequence Source
1283.57 15 LELITSCSSNVSVAH HCV.NS5.2813
1283.61 15 ASCLRKLGVPPLRVW HCV.NS5.2939
1298.02 15 VGNFTGLYSSTVPVF HBV.pol.53
1298.03 15 TNFLLSLGLHLNPNK HBV.pol.568
1298.04 15 KQCFRKLPVNRPIDW HBV.pol.615
1298.06 15 KQAFTFSPTYKAFLC HBV.pol.661
1298.07 15 AANWILRGTSFVYVP HBV.pol.764
1298.08 15 PDRVHFASPLHVAWR HBV.pol.824
1298.10 15 LRPWSTQLLLNGSL HTVl.env.333
1298.11 15 RSELYKYKVVKIEPL HTVl.env.637
1298.13 15 DRFYKTLRAEQASQE HIVl GAG 333
1298.16 15 KVILVAVHVASGYLE HIVl.pol.813
F125.02 17 LNNLLIFHLNGKIIKNS PfLSAl.13
F125.04 16 RTTNWVNHAVPLAMKLI Pf.SSP2.61
indicates binding affinity >15,000nM.
Table 28b
ICso nM
Sequence DR1 DR2 DR2w DR3 DR4 DR4 DR5 DR5 DR6 DR7 Z>R8 DR52a DR9 DR Cross w251 2B2 w4 wl5 wl l wl2 wl9 w2 w53 reactiv
SALLSSDITASVNCAK >1667 >5000 244 84 >1000 >8333 9592 0
SALSEGATPQDLNTML 417 833 587 - 323 4
NKALELFRKDIAAKYK 1667 233 529 182 261 4
NKALELFRKDIAAKYKELGY >1250 1429 240 306 42 — 392 4
ALELFRKDIAAKYKELGY 1818 150 237 364 336 4
ELFRKDIAAKYKELGY 1667 297 300 125 470 4
MAKTIAYDEEARRGLE - >5000 283 1
KVYLPRMKMEEKYNLTSVLM 1000 3333 335 >11250 1053 714 — 3
YASFVKTTTLRKFT-NH2 500 3.6 178 12 22 31 6
PHHTALRQAILCWGELMTLA 70 8.3 211 85 263 - - 676 196 2701 7
YKMKMVHAAIiAKMKM 3.6 8.7 208 92 45 62 6
GFYTTGAVRQTFGDYKTTIC 91 346 7833 48 3
QNTLLSNAPLGPQFP 225 1
AAYAAQGYKVLVLNPSVAAT 2.9 48 488 1765 17 1226 105 3239 11 96 61 6528 242 77 10
GYKVLVLNPSVAATLGFGAY 3.6 41 8000 10 1520 241 9613 4.1 23 80 20
GYKVLVLNPSVAAT 1.4 38 3704 141 74 4585 3.5 125 21 268
SYVNTNMGLKFRQLLWFHI 417 123 2899 6618 6441 41 1987 13 833 377 9259
GLKFRQLLWFHI 179 34 1053 4091 1027 32 5960 1591 641 123 4688
IC50 nM
Sequence DR1 DR2 DR2w DR3 DR4 DR4 DR5 DR5 DR6 DR7 DR8 DR52a DR9 DR Cross 251 252 w4 wl5 wl l wl2 wl9 w2 w53 reactiv
TLHGPTPLLYRLGAVQNEIT 17 1286 690 2273 2
NFISGIQYLAGLSTLPGNPA 10 606 85 74 - 70 5
GEGAVQWMNRLIAFASRGNHV 3.3 29 182 - 375 14 - 26 227 158 8
KPVSQMRMATPLLMRPM 1.2 15 52 49 88 111 25 169 13 9
LPKPPKPVSKMRMATPLLMQA 0.90 14 31 79 141 200 444 392 0.70 40 258 54 8 13
LPM
EYLVSFGVWIRTPPA 8.8 15 435 - 4091 792 1818 - 2333 58 6901 87 6
GVWΓRTPPAYRPPNA 14 217 2.8 - 13 67 42 - >875 114 93 1667 13488 8
0
RHYLHTLWKAGILYK 17 5.4 35 — 2250 1462 42 149 745 61 27 11191 174 784 10
VPNLQSLTNLLSSNL 83 3033 - - 237 1250 10643 5000 - 4083 - 2
WVTVΎYGVPVWKEAT 63 2 286 - 2500 4.6 - - >875 807 10000 163 6
0
YYGVPVWKEATTTLF 455 - 7407 - 1452 13333 - >875 109 13243 197 3
0
VPVWKEATTTLFCAS 192 — 385 — 409 422 9524 — 8750 397 5698 160 6
LSGΓVQQQNNLLRAI 54 57 61 10345 300 2000 - - 46 - - - 5
QQHLLQLTVWGΓKQL 4.5 12 345 - 1364 141 5556 608 194 64 2333 147 8
QHLLQLTVWGΓKQLQ 6.1 21 690 - 1184 346 2128 1064 350 44 907 375 414 9
LLQLTVWGΓKQLQAR 60 2083 2368 267 1389 2
QGQMVHQAISPRTLN 73 65 13 - 54 400 — — 412 455 7313 117 135 9
ICso nM
Sequence DR1 DR2 DR2w DR3 DR4 DR4 DR5 DR5 DR6 DR7 DR8 DR52a DR9 DR Cross w2Bl 2S2 w4 wl5 ll wl2 wl9 w2 w53 reactiv
SPEVIPMFSALSEGA 109 325 5882 - 281 2667 - 5000 - 3769 5769 3
QEQIGWMTNNPPΓPV 714 4550 8333 13044 38 - - 1.0 1923 - - 3
GEΓYKRWΠLGLNKI 82 138 225 - 1500 380 213 1656 98 192 63 1205 536 161 10
YKRWIILGLNKΓVRM 4.2 5.7 26 273 608 158 65 199 0.90 208 91 121 12
KJIWΠLGLNKΓVRMY 4.2 5.1 24 188 570 404 54 347 0.40 379 49 1808 58 187 13
WΠLGLNKΓVRMYSP 125 28 182 273 1452 1310 54 1242 1.9 2841 175 -- 7
VKNWMTETLLVQNAN 1515 700 2597 - 938 - - 1094 893 - - (i 3
GTVLVGPTPVNIIGR 758 1492 >14285 - - 4651 - 121 305 - 4167 3
PVNIIGRNLLTQIGC 848 >14285 10465 202 - - 2
GRNLLTQIGCTLNFP 25 182 >14285 - 500 >8261 3030 - 27 4167 - - 4
TLNFPISPIETVPVK 263 - >14285 - 1286 - 8054 233 391 - - 3
NFPISPIETVPVKLK 104 7000 9091 - 556 4000 - 6478 184 167 - - 4
FRKYTAFTIPSΓNNE 185 70 4167 - 265 136 1818 - >875 30 803 - 40 - 7 0
SPAΓFQSSMTKΓLEP 357 217 667 — 3214 109 741 — 13 68 3267 887 33 14500 9
PAIFQSSMTKILEPF 156 284 1000 - 7759 59 303 - 32 34 3500 82 8
QKLVGKLNWASQIYA 128 989 3636 8108 10227 >8261 5714 2709 2.3 510 223 375 6
VGKLNWASQIYAGIK 357 178 13 - 7258 >8261 4348 1064 2.2 481 5104 68 6
NREILKEPVHGVYYD 17 61 >14285 2500 237 1267 - 12957 292 7576 - 3571 4
IPEWEFVNTPPLVKL 4.5 1023 11 3261 68 24 241 5519 152 18 189 29 9
WEFVNTPPLVKLWYQ 7.2 222 2.1 13636 25 20 318 1355 90 15 350 8546 40 527 11
Sequence DRl DR2 DR2w DR3 DR4 DR4 DR5 DR5 DR6 DR7 DR8 DR52a DR9 DR Cross 2Sl 2B2 w4 l5 wll wl2 wl9 2 53 reactiv
EQLIKKEKVYLAWVP 7.8 114 3390 13636 11 3448 - >116
67
EKVYLAWVPAHKGIG 3.6 21 4.9 3226 8.3 27 37 6478 3500 18 31 144 14 10
HSNWRAMASDFNLPP 33 - 125 9.6 15 95 4375 472 1960 872 951 8
ASGYTEAEVΓPAETG 217 -- >9523 196 10000 5833 2083 5052 1563 2
AEHLKTAVQMAVFIH 200 4333 6452 3462 224 - 7268 66 403 9608 142 5
KTAVQMAWTF1NFKR 161 650 690 818 452 182 125 1786 1441 14688 2586 1000 8
QKQITKIQNFRVYYR 2.9 3.4 80 321 49 53 124 25 25 75 577 611 12
KLLWKGEGAVVIQDN 11 8273 3448 600 1900 3333 78 104 1089 357 5
ENRWQVMΓVWQVDRM 2 1542 5556 652 20 6250 1944 208 327 259 6
VEAIΓRILQQLLFΓH 147 2667 1216 556 1136 2
FNWNSSIGLΓMVLS 66 350 >9523 14063 >1407 — 65 281 469 5 4
MNYYGKQENWYSLKK 6.4 9100 435 21 292 351 - 3182 3788 539 6
MRKLAILSVSSFLFV 50 18 1539 5769 1407 541 2483 38 500 682 6
NSSIGLΓMVLSFLFL 1250 364 8333 3750 10857 - 8765 3889 362 2
SSVFNVVNSSIGLΓM 42 314 2500 450 1652 1177 - 10 33 891 63 7
MKILSVFFLALFFII 2941 535 >9523 1216 >8261 >2000 - 1842 694 12500 2 0
FILVNLLIFHΓNGKI 1389 700 13333 1406 >8085 2632 — 1029 521 11667 6818 2 HΓLYISFYFILVNLL 3125 827 — 1667 >1266 18182 2500 357 2
ICso nM
Sequence DR1 DR2 DR2w DR3 DR4 DR4 DR5 DR5 DR6 DR7 DR8 DR52a DR9 DR Cross w2Bl 2B2 w4 wl5 wl l wl2 wl9 2 w53 reactivi
7
LLIFHΓNGKΠKNSE 8.8 31 80 682 7500 >1266 56 12957 106 192 350 500 9
7
LVNLLΓFHΓNGKIΓK 78 13 2857 - 4091 >1266 74 7268 66 208 1690 417 6
7
NLLΓFHΓNGKIΓKNS 3.6 6.1 71 1200 5769 2375 83 6082 19 49 153 278 8
QTNFKSLLRNLGVSE 91 8273 5405 - 2500 1900 51 - 47 7813 69 - 4
AYKFWPGAATPYAG 14 >1011 323 18750 281 10556 31 2483 21 139 53 577 8
1 uι
NVKYLVΓVFLΓFFDL 2000 650 >6897 - 750 >1266 6667 - 2188 714 9074 - 3
7
VKNVIGPFMKAVCVE 56 212 250 - - >1266 476 3239 32 424 2130 - 862 5859 7
7
WΈNVKNVIGPFMKAV 79 54 290 — ~ 8636 __ — 4375 1563 9375 3
CSWRRAFPHCLAFS 50 89 260 - - >1266 - - 65 424 1960 63 1261 6
7
FVQWFVGLSPTVWLS 11 2600 1250 — 3462 2778 — 184 362 2722 1829 — 3
LAQFTSAICSWRRA 417 1400 133 - 3000 1357 2632 - 3500 893 3267 852 3053 4
LVPFVQWFVGLSPTV 385 13 1429 - 300 27 53 452 1944 2717 74 1679 30 20 9
NLSWLSLDVSAAF H 36 - - 395 155 6061 14900 106 6098 3267 63 1210 7.4 6
SFGVWTRTPPAYRPP 532 827 47 - 577 603 769 - - 1042 196 - 938 - 8
ICso nM
Sequence DR1 DR2 DR2w DR3 DR4 DR4 DR5 DR5 DR6 DR7 DR8 DR52a DR9 DR Cross w251 252 w4 wl5 wll wl2 wl9 w2 w53 reactiv
SPFLLAQFTSAICSV 42 455 2353 - 608 2000 -- - 65 758 - 1974 290 6
SSNLSWLSLDVSAAF 36 3033 - 200 167 4348 8514 35 6410 1065 22 6818 3.2 6
DKELTMSNVKNVSQT 2778 - - - - 5135 6667 - 81 610 4455 1056 - 2
AGLLGNVSTVLLGGV 116 379 - ~ 6923 1056 - - 0.80 58 - 142 - 5
KSKYKLATSVLAGLL 3.6 1247 24 - 7.1 47 30 - 427 13 45 1567 28 4143 9
GLAYKFWPGAATPY 3.1 - 29 - 45 1407 11 851 7.1 167 20 47000 125 3053 9
HNWVNHAVPLAMKLI 14 364 143 1304 12 950 2703 497 3.7 66 68 - 19 3053 10
IGPFMKAVCVEVEKT 694 - 465 - - 4419 ~ - 11667 13158 - 915 829 4
KYKIAGGIAGGLALL 132 - 417 12000 3750 - 87 828 15 3968 31 289 - 7
RIL WVNHAVPLAMKL 26 260 125 750- 9.0 1056 2532 12417 3.9 57 27 16 1349 9
ΓKQFΓNMWQEVGKAMY 128 217 206 - 375 271 4878 - 1000 - 350 - 5769 112 8
LQSLTNLLSSNLSWL 2.0 21 1000 - 9.4 47 294 397 135 167 557 - 682 1813 11
PFLLAQFTSAICSW 28 337 4762 - 563 317 1667 - 44 325 845 - 1271 1349 7
KYKLATSVLAGLLGN 4.2 5056 286 - 14 317 952 - 467 39 377 29 9
LAGLLGNVSTVLLGG 119 827 - 38462 2813 1652 - - 5.5 66 - 136 5
RHPFKIGSSDPADNA 1136 - - - 96 13103 3571 - 11667 - 1290 790 2
ANQLWΓLTDGΓPDS 1316 11375 - - 978 6129 - - 500 4630 - 1786 2
KFWPGAATPYAGEP 217 - - 4839 375 5672 20000 3465 76 14706 7656 300 4
VFNWNSSIGLΓMVL 161 4333 - - 5696 6786 - - 14 139 - 150 4
VGPLTVNEKRRLKLI 8333 4136 4255 136 >8182 6667 - 3889 - 5326 >3615 8169 1
ESRLWDFSQFSRGN 7143 1230 - 115 188 - - 875 - - 2474 8657 3
ICso nM
Sequence DR1 DR2 DR2w DR3 DR4 DR4 DR5 DR5 DR6 DR7 DR8 DR52a DR9 DR Cross 251 252 w4 wl5 wl l wl2 wl9 w2 w53 reactiv
LCQVFADATPTGWGL 7143 - - 67 489 - - 1944 - - 1808 1036 2
WWATDALMTGYTG 1042 1936 14286 273 >8182 - - 1207 625 - >3615 817 3
TVDFSLDPTFTIETT 5556 - >10000 150 1957 - - 169 8333 >30625 24 3625 3
AETFYVDGAANRETK 2381 - 4348 769 >8182 - - - -- 14000 1068 - 1
EVNIVTDSQYALGΠ - 2677 - 732 7627 - - 324 - - 118 - 3
WAGΓKQEFGΓPYNPQ 2778 5056 125 300 >10000 - 805 285 - - >3615 951 5
GAWIQDNSDIKWP 1515 325 14286 1000 - - - 78 - - >3615 725 4
YRKILRQRKΓDRLID 2083 123 488 23 >10000 133 4257 2188 - 1815 >3615 36 5
PDSIQDSLKESRKLN - 2275 >11111 357 >10000 - - - - - >3615 - 1
KCNLYADSAWENVKN - - -- 857 >10000 - - 11667 - - - - 1
IGTVLVGPTPVNIIG 417 535 - 56250 12667 - 88 352 - 2344 4
KVYLAWVPAHKGIGG 8.3 25 24 - 141 165 71 12417 2500 179 196 - 250 290 10
TKELQKQITKIQNFR 704 433 571 833 1900 377 700 4546 1960 - 6
AGFFLLTRILTIPQS 1.1 217 1053 - 8.5 253 6 4257 10 8 189 4273 58 699 10
GFFLLTRΓLTΓPQSL 12 607 1818 15 84 9 45 7 31 136 9
GTSFVYVPSALNPAD 14 650 400 - 118 93 426 - 35000 93 803 - 221 - 9
ITFLFILLLCL LL 0
KFAVPNLQSLTNLLS 278 - - 346 4651 398 - - 3
LHLYSHPIILGFRKI 227 268 500 - 66 238 488 9613 17500 41667 803 - 1531 102 8
LLCLIFLLVLLDYQG 0
VGLLGFAAPFTQCGY 106 29 - - — - 17857 132 3
ICso nM
Sequence DR1 DR2 DR2w DR3 DR4 DR4 DR5 DR5 DR6 DR7 DR8 DR52a DR9 DR Cross w251 252 w4 wl5 l l wl2 wl9 w2 w53 reactiv
FYFILVNLLΓFFΠNG 0
KSLLRNLGVSENΓFL 333 1034 - 2143 469 6061 6.1 325 - 47 5
RGYYΓPHQSSLPQDN 17 - 6897 11 136 3125 8750 147 3267 500 5
VYLLPRRGPRLGVRA 357 23 556 - 1667 - - - 3
GHRMAWDMMMNWSPT 179 6067 4546 281 2532 438 14706 3261 3
CGPVYCFTPSPVWG 19 3640 - 173 95 ~ - 93 - 174 5
VYCFTPSPVWGTTD 278 - - 489 667 3571 - 338 14000 417 5
GNWFGCTWMNSTGFT 139 284 - 107 1520 952 - 1000 14000 2778 5
FTTLPALSTGLΓHLH 1.2 2528 12500 6338 1539 - 625 2419 2
SKGWRLLAPITAYAQ 0.40 125 23 - 21 152 5 10276 - 962 54 1191 527 9
DLYLVTRHADVTPVR 617 414 18182 - 2632 7000 309 1210 3
AQGYKVLVLNPSVAA 6.0 650 - 10000 7.1 224 74 2980 5.9 833 175 375 276 10
GYKVLVLNPSVAATL 4.5 350 - 3061 4.7 567 143 5731 5.1 89 288 54 1933 9
VLVLNPSVAATLGFG 2.8 758 - 21 10857 1429 11 17 — 23 6
GARLWLATATPPGS 167 10111 - 51 2128 8750 568 11194 3
DWWATDALMTGYT 455 827 - 2500 5278 - 250 275 - - 4
FTGLTHΓDAHFLSQT 6.6 15 154 - 12667 2410 - 179 980 13393 5
YLVAYQATVCARAQA 6.8 379 571 80 1357 1418 1207 2778 7903 278 5
LEWTSTWVLVGGVL 417 1167 - 1607 - 761 156 6250 3
TWVLVGGVLAALAAY 6.5 8273 - - - - 439 12931 2
AKHMWNFISGIQYLA 3.3 607 351 11250 633 2632 8750 109 3063 278 6
ICso nM
Sequence DR1 DR2 DR2w DR3 DR4 DR4 DR5 DR5 DR6 DR7 DR8 DR52a DR9 DR Cross w251 252 w4 wl5 wl l wl2 wl9 w2 w53 reactiv
IQYLAGLSTLPGNPA 1.4 212 2128 12 12 - 11905 1364 4
MNRLIAFASRGNHVS 66 5 1539 51724 5696 585 46 14191 7.3 227 102 - 313 6374 8
SYTWTGALITPCAAE 192 13000 13333 662 1727 6452 - 51 3769 1000 4
GSSYGFQYSPGQRVE 11 - 667 - 375 745 - - 19 156 - 6620 68 - 7
LELITSCSSNVSVAH 204 455 -- 517 1086 - 69 714 - 2273 5
ASCLRKLGVPPLRVW 5.0 16 217 - 5625 78 ' 645 157 2500 862 671 - 8621 5273 8
VGNFTGLYSSTVPVF 2.9 910 12500 3214 224 5714 60 45 11136 242 6
TNFLLSLGIHLNPNK 1.4 222 167 2046 1056 3774 219 114 - 197 6
KQCFRKLPVNRPIDW 3.3 4136 952 - 38 45 1539 - 814 63 845 - 3000 3053 7
KQAFTFSPTYKAFLC 9.4 38 143 - 41 173 83 - 175 76 408 4845 139 322 11
AANWILRGTSFVYVP 54 379 3279 - 882 1520 1429 805 140 43 196 - 278 6517 8
PDRVHFASPLHVAWR 98 314 - - 7037 - 184 309 14000 313 5
TRPWSTQLLLNGSL 568 233 - 1875 4750 - 71 74 - 5769 4
RSELYKYKWKΓEPL 758 284 14286 - 2000 4762 350 139 446 441 6
DRFYKTLRAEQASQE 94 5688 400 300 465 - 8929 - 4
KVILVAVHVASGYIE 7.7 4333 - 455 2923 2174 714 156 2130 1667 4
LVNLLΓFHLNGKIΓKNS 7.6 17 182 20000 1810 357 11462 200 446 6
RHNWVI>πLAVPLAMKLI 3.6 260 23 8824 317 1333 438 36 70 7
Table 29a
No. % % amino Sequence Motif Source Conserv Conserv acids (Total) (Core)
20 FPQPQLPYSQPQPFRPQQPY DRsup Gliadin 61-80
16 ΓPPYCTIAPFGIFGTN DRsup Gliadin 261-276
20 LGQQQPFPPQQPYPQPQPFP DRsup Gliadin 31-50
20 LHQQQKQQQQPSSQVSFQQP DRsup Gliadin 181-200
20 LLQELCCQHL QIPEQSQCQ DRsup Gliadin 151-170
20 LQQHNIAHGRSQVLQQSTYQ DRsup Gliadin 131-150
20 PQPFRPQQPYPQPQPQYSQP DRsup Gliadin 71-90
20 PQPQPQYSQPQQPISQQQQQ DRsup Gliadin 81-100
20 PSSQVSFQQPLQQYPLGQGS DRsup Gliadin 191-210
20 QFEEIRNLALQTLPAMCNVY D sup Gliadin 231-250
20 QGSVQPQQLPQFEETRNLAL DRsup Gliadin 221-240
20 QNPSQQQPQEQVPLVQQQQF D sup Gliadin 11-30
20 QPYPQPQPFPSQQPYLQLQP DRsup Gliadin 41-60
20 QQLIFCMDVVLQQHNIAHGR DRsup Gliadin 121-140
20 QVPLVQQQQFLGQQQPFPPQ DRsup Gliadin 21-40
20 SQQPYLQLQPFPQPQLPYSQ DRsup Gliadin 51-70
20 VRVPVPQLQPQNPSQQQPQE DRsup Gliadin 1-20
20 IRNLALQTLPAMCNVY DRsup gliadin 235
12 PQPFRPQQPYPQ DRsup gliadin 71
16 PQPFRPQQPYPQPQPQ DRsup gliadin 71
12 QFEEIRNLALQT DRsup gliadin 231
16 QFEEΓRNLALQTLPAM DRsup gliadin 231
20 QFLGQQQPFPPQ DRsup gliadin 29
12 QVPLVQQQQFLG DRsup gliadin 21
16 QVPLVQQQQFLGQQQP DRsup gliadin 21
20 VQQQQFLGQQQPFPPQ DRsup gliadin 25
16 aHAAHAAHAAHAAHAa DRsup d protected AHA reiterative
12 CPKYVRSAKLRM DRsup HA 302-313 (PR8)
12 GACPKYVKQNTL DRsup HA 304-315
13 GACPKYVKQNTLK DRsup HA 304-316
12 KQNTLKLATGMR DRsup HA 311-322
18 LAKQNTLAKQNTLAKQNT DRsup HA 307-319 reiterative
13 PKAVKQNTLKLAT DRsup HA 307-319 analog
13 PKSVKQNTLKLAT DRsup HA 307-319 analog
13 PKYDKQGGLKIAT DRsup HA multivariate
13 PKYFKQFRLKIAT DRsup HA multivariate
13 PKYGKQRFLKIAT DRsup HA multivariate
13 PKYIKQΠLKIAT DRsup HA multivariate
13 PKYVKKNTLKLAT DRsup HA 307-319 analog
13 PKYVKQNKLKLAT DRsup HA 307-319 analog
13 PKYVKQNT KLAT DRsup HA 307-319 analog
13 PKYVKQNTLKEAT DRsup HA 307-319 analog
13 P YVKQNTLKLAT DRsup HA 307-319
13 PKYVKQNTLK1AT DRsup HA 307-319 analog
13 P YVKQNTLK1AT DRsup HA 307-319 analog No. % % amino Sequence Motif Source Conserv Conserv acids (Total) (Core)
13 PKYVKQNT1KLAT DRsup HA 307-319 analog
13 PKYVKQnTLKLAT DRsup HA 307-319 analog
13 pKYVKQNTLKLAT DRsup HA 307-319 analog
13 PKYVKQNTLKNAT DRsup HA 307-319 analog; Asn scan
13 PKYVKQNTNKLAT DRsup HA 307-319 analog; Asn scan
20 RTLYQNVGTYVSVGTSTLNK DRsup HA 187-206
13 VKQNTLKLATGMR DRsup HA 310-322
14 YPKYVKRNTLKLAT DRsup HA 307-319 dbl. substitutions
15 AAPFTQCGYPALMPL DRsup HBV POL 643 95
15 AFSYMDDVVLGAKSV DRsup HBV POL 546 90
12 AΓLCWGELMTLA DRsup HBV core 58-69
16 ALRQAΓLCWGELMTLA DRsup HBV core 54-69
20 ASARFSWLSLLVPFVQWFVG DRsup HBs(ayw) 166-185
15 DWKVCQRΓVGLLGFA DRsup HBV POL 629 85
15 GAHLSLRGLPVCAFS DRsup HBV X 50 90
20 GYRWMCLRRFLTFLFILLLC DRsup HBs (ayw) 71-90
19 HHTALRQAΓLCWGELMTLA DRsup HBV core 51-69
HLSLRGLPVCAFSSA DRsup HBV.X.52 90
18 HTALRQAΓLCWGELMTLA DRsup HBV core 52-69
11 ILCWGELMTLA DRsup HBV core 59-69
15 ΓVGLLGFAAPFTQCG DRsup HBV POL 636 90
LCQVFADATPTGWGL DRsup HBV.POL.694 95
10 LCWGELMTLA DRsup HBV core 60-69
15 LRQAΓLCWGELMTLA DRsup HBV core 55-69
20 LSPTVWLSVΓWMMWYWGPSL DRsup HBs (ayw) 186-205
16 LSTLPETTWRRRGRS DRsup Hep. B core 140-
154
19 MDΓDPYKEFGASVELLSFL DRsup HBV core 1
25 MDΓDPYKEFGASVELLSFLPSDFFP DRsup HBV core 1
19 MDIDPYKEFGATVELLSFL DRsup HBV core 1
20 MDΓDPYKEFGATVELLSFLP DRsup Hep. B core 1-20
25 MDIDPYKEFGATVELLSFLPSDFFP DRsup HBV core 1-25
25 MDIDPYKEFGATVELLSFLPSDFFP DRsup HBV core 1
25 MDIDPYKEFGATVQLLSFLPSDFFP DRsup HBV core 1
15 NAPILSTLPETTWR DRsup HBVNLJC136 95
18 PFLLAQFTSAICSVVRRA DRsup HBV pol 523 95
13 PHΉTALRQAΓLCW DRsup HBV core 50-62
14 PHHTALRQAILCWG DRsup HBV core 50-63
16 PHHTALRQAILCWGEL DRsup HBV core 50-65
17 PHHTALRQAILCWGELM DRsup HBV core 50-66
18 PHHTALRQATLCWGELMT D sup HBV core 50-67
19 PHHTALRQAΓLCWGELMTL DRsup HBV core 50-68
20 PHHTALRQAΓLCWGELMTLA D sup HBV core 50-69
PLPΓHTAELLAACFA DRsup HBV.POL.722 80
15 PPAYRPPNAPΓLSTL DRsup HBV UC129 95 No. % % amino Sequence Motif Source Conserv Conserv acids (Total) (Core)
PQAMQWNSTTFHQTL DRsup HBV.ENV.114 40 80
13 QAΓLCWGELMTLA DRsup HBV core 57-69
15 QCGYPALMPLYACIQ DRsup HBV POL 648 95
RDLLDTASALYREAL DRsup HBV.NUC.28 80
20 RDLLDTASALYRREALESPEH DRsup Hep. B core 28-47
20 RDLVVSYVNTNMGLKFRQLL DRsup Hep. B core 82-
101
15 RFSWLSLLVPFVQWF DRsup HBV ENV 332 100
14 RQATLCWGELMTLA DRsup HBV core 56-69
20 SLDSWWTSLNFLGGTTVCLG DRsup HBs (ayw) 31-50
SVRFSWLSLLVPFVQ DRsup HBV.ENV.330 80
17 TALRQAΓLCWGELMTLA DRsup HBV core 53-69
15 TNLLSSNLSWLSLDV DRsup HBV POL 416 90
25 TNMGLKFRQLLWFHI DRsup HBV core 91
25 TNVGLKFRQLLWFHI DRsup HBV core 91
14 TTWRRRGRSPRRR DRsup HBV Core 146-159
15 VCAFSSAGPCALRFT DRsup HBV X 60 90
20 VSFGVWΓRTPPAYRPPNAPI DRsup HBVnucl20 90
YPALMPLYACIQSKQ DRsup HBV.POL.648 55 95
AEQFKQKALGLLQTA DRsup HCV.NS4.1730 86
ANLLWRQEMGGNITR DRsup HCV.NS5.2238 86
ARLΓVFPDLGVRVCE DRsup HCV.NS5.2610 79
ASQLSAPSLKATCTT DRsup HCV.NS5.2208 50 79
AVQWMNRLIAFASRG DRsup HCV.NS4.1917 100 100
DADLIEANLLWRQEM DRsup HCV.NS5.2232 50 85
EDLVNLLPAXLSPGA DRsup HCV.NS4.1882 19 85
GALVVGWCAAILRR DRsup HCV.NS4.1895 19
GCSFSΓFLLALLSCL DRsup HCV.Core.171 86
20 GPGEGAVQWMNRLIAFASRG DRsup HCV NS4291-310
KPTLHGPTPLLYRLG DRsup HCV.NS4.1620 79
LAGYGAGVAGALVAF DRsup HCV.NS4.1857 79
LHGLSAFSLHSYSPG DRsup HCV.NS5.2919 79 79
20 LLFNILGGWVAAQLAAPGAA DRsup HCV NS4191-210
LTSMLTDPSHITAET DRsup HCV.NS5.2176 57 100
20 NFISGIQYLAGLSTLPGNPA DRsup HCV NS41772
PAΓLSPGALVVGWCA DRsup HCV.NS4.1889 79
PQTFQVAHLHAPTGS DRsup HCV.NS3.1225 43 85
PTLWARMILMTHFFS DRsup HCV.NS5.2870 79 85
RAAVCTRGVAKAVDF DRsup HCV.NS3.1186 19
TVDFSLDPTFTIETT DRsup HCV.NS3.1466 79
WLLFLLLADARVCS DRsup HCV.NS1/E2.724 29 100
WES TGLTfflDAHF DRsup HCV.NS3.1563 43 92
10 AFVAWRNRCK DRsup HEL 107-116 analogs
10 AWAAWRNRCK DRsup HEL 107-116 analogs
10 AWEAWRNRCK DRsup HEL 107-116 analogs No. % % amino Sequence Motif Source Conserv Conserv acids (Total) (Core)
10 AWLAWRNRCK DRsup HEL 107-1 16 analogs
10 AWVAARNRCK DRsup HEL 107-1 16 analogs
10 AWVAFRNRCK DRsup HEL 107-1 16 analogs
10 AWVAQRNRCK DRsup HEL 107-1 16 analogs
10 AWVAWANRCK DRsup HEL 107-1 16 analogs
10 AWVAWENRCK DRsup HEL 107-1 16 analogs
10 AWVAWKNRCK DRsup HEL 107-1 16 analogs
10 AWVAWRARCK DRsup HEL 107-1 16 analogs
10 AWVAWRNACK DRsup HEL 107-1 16 analogs
10 AWVAWRNECK DRsup HEL 107-1 16 analogs
10 AWVAWRNKCK DRsup HEL 107-1 16 analogs
10 AWVAWRNRCA DRsup HEL 107-1 16 analogs
0 AWVAWRNRCK DRsup HEL 107-1 16
10 AWVAWRNRCK DRsup HEL 107-116
10 AWVAWRNRCR DRsup HEL 107-116 analogs
10 AWVAWRNREK DRsup HEL 107-1 16 analogs
10 AWVAWRNRKK DRsup HEL 107-1 16 analogs
10 AWVAWRNRQK DRsup HEL 107-1 16 analogs
10 AWVAWRNRVK DRsup HEL 107-1 16 analogs
10 AWVAWRVRCK DRsup HEL 107-1 16 analogs
10 AWVEWRNRCK DRsup HEL 107-1 16 analogs
10 AWVSWRNRCK DRsup HEL 107-1 16 analogs
10 AWWWRNRCK DRsup HEL 107-1 16 analogs
10 EFVAAKAAQK DRsup Super HEL 107-116 10 EWVAWRNRCK DRsup HEL 107-116 analogs
22 LAAAMKRHGLD DRsup HEL 8-29 16 NTDGSTDYGILQ DRsup HEL 46-61 No. % % amino Sequence Motif Source Conserv Conserv acids (Total) (Core)
18 Rj RCKGTDVQAWIRGCRL DRsup HEL 112-129
16 SVNCAKKIVSDGNGMN DRsup HEL91-106
10 SWVAWRNRCK DRsup HEL 107-116 analogs
10 VWVAWRNRCK DRsup HEL 107-116 analogs
15 WRNAKWRNAKWRNAK DRsup HEL 112-116 reit.
22 YRGYSLGNWVCAAKFESNFNTQ DRsup HEL 20-41
13 SPYVSRLLGICLT DRsup Her2/neu.777
15 ASDFNLPPVVAKEΓV DRsup HIVl POL 765 80
15 AVQMAVFfflNFKRKG DRsup HIVl POL 917 100
15 DFNLPPVVAKEIVAS DRsup HTVl POL 767 87
15 DQQLLGIWGCSGKLI DRsup HIVl ENV 755 83
15 DQSLKPCVKLTPLCV DRsup HIVl ENV 126 90
12 DRVHPVHAGPIA DRsup HTV gag 245
14 DRVHPVHAGPIAPG DRsup HIV gag 245
16 DRVHPVHAGPIAPGQM DRsup HTV gag 245
18 DRVHPVHAGPIAPGQMRE DRsup HTVgag245
20 DRVHPVHAGPIAPGQMREPR DRsup HTV gag 245
22 DRVHPVHAGPIAPGQMREPRGS DRsup HTV gag 245
20 DTEVHNVWATQACVPTDPNP DRsup fflVen δ
15 EAΠRILQQLLFULF DRsup HIVl VPR 58 82
15 EDΠSLWDQSLKPCV DRsup HIVl ENV 119 87
15 EKAFSPEVIPMFSAL DRsup HIVl GAG 193 96
15 EKVYLAWVPAHKGIG DRsup HIVl.pol.711 74 93
16 ERFAVNPGLLETSEGC DRsup HIV gpl741-56
16 ERYLKDQQLLGIWGCS DRsup HIVl ENV 589
15 ESELVSQΠEQLIKK DRsup HIVl POL 696 80
ETAYFLLKLAGRWPV DRsup HIV.POL.838 65
15 EVQLGIPHPAGLKKK DRsup HIVl POL 268 80
15 FWEVQLGIPHPAGLK DRsup HTVl POL 266 100
16 GARASVLSGGELDKWE DRsup HTV gpl71-16
15 GCTLNFPISPIETVP DRsup HIVl POL 174 100
15 GEIYKRWΠLGLNKI DRsup HIVl.gag.294 45 85
16 GGELDKWEKΓRLRPGG DRsup HTV gp 179-24
15 HKAIGTVLVGPTPVN DRsup HIVl POL 149 93
15 IGGIGGFIKVRQYDQ DRsup HTVl POL 127 93
ΠRILQQLLFΓHFRI DRsup HIV1.VPR.60 76 82
15 IISLWDQSLKPCVKL DRsup HTVl ENV 121 85
15 ΓKVVPRRKAKΠRDY DRsup HIVl POL 999 80
16 ILKALGPAATLEEMMT(200.11) DRsup HIV
16 INEEAAEWERVHPVHA DRsup HIV gp2573-88
15 IQKLVGKLNWASQIY DRsup HIVl POL 436 100
15 ISLWDQSLKPCVKLT DRsup HTVl ENV 122 83
16 ΓVWASRELERFAVNPG DRsup HTV gpl733-48
20 ΓYKRWIILGLNKΓVRMYSPV DRsup HIV gag 27
16 ΓYKRWIILGLNKIVRN DRsup HIV gp25129-144
KARVLAEAMSQVTNS DRsup HIV1.GAG.394 46 No. % % amino Sequence Motif Source . Conserv Conserv acids (Total) (Core)
15 KDSWTVNDIQKLVGK DRsup HIVl POL 428 100
16 KQIINMWQEVGKAMYA DRsup HIVl ENV 428 is KRWΠLGLNKΓVRMY DRsu HIVl.gag.298 77
15 KTTLKALGPAATLEE DRsup HIVl GAG 366 92
16 LGKIWPSYKGRPGNFL DRsup HIV gpl357-72 16 LICTTAVPWNASWSNK DRsup HIVl ENV 607 16 LKQIVKKLREQFGNNK DRsup HIVl ENV 342 15 LLGIWGCSGKLICTT DRsup HIVl ENV 758 81 15 LSIVNRVRQGYSPLS DR sup HIVl ENV 877 81 15 NEQVDKLVSAGIRKV DRsup HIVl POL 727 80
NNLLRAIEAQQHLLQ DR sup fflVl.ENV.719 61 82
15 PAGLKKKKSVTVLDV DRsup HIVl POL 276 80
15 PGNFLQSRPEPTAPP DRsup HIVl GAG 490 80
16 PrVQNLQGQMVHQAIS DRsup HIV gp251-16 16 PLGVAPTKAKRRWQR DRsup HIV1ENV671 16 QARILAVERYLKDQQL DRsup HTVl ENV 582
15 QGQMVHQAISPRTLN DRsup HIVl.gag.171 44 85
16 QKQEPIDKELYPLTSL DRsup fflVgpl397-112
15 QMAVFΓHNFKRKGGI DRsup HIVl POL 919 100
16 RIQRGPGRAFVTIGKL DRsup HIVl ENV 315 16 RQ1LGQLQPSLQTGSE DRsup HIV gpl757-72 16 SLKPCVKLTPLCVTLN DRsup HLV1ENV115 16 SLWDQSLKPCVKLTPL DR sup HIVl ENV 825 15 SPAIFQSSMTKTLEP DRsup HIVl.pol.335 70 80 15 SPGIWQLDCTHLEGK DR sup HIVl POL 799 100
15 SQIIEQLrKKEKVYL DRsup HTVl POL 701 80
16 SSGGDPETVMHSFNCG DRsup HIVl ENV 369 13 TAATNAACAWLEA DR sup HTV nef 48
17 TITLPCRTKQFINMWQE DRsup HIVl ENV 413 15 VDKLVSAGIRKVLFL DRsup HTVl POL 730 80
15 VrPMFSALSEGATPQ DRsup HIVl GAG 200
16 VKIEPLGVAPTKAKRR DRsup HTVl ENV 667 15 VLSrVNRVRQGYSPL DRsup HTVl ENV 876 81 15 VNπGRNLLTQIGCT DR sup HIVl POL 162 87
15 VNΓVTDSQYALGΠQ DRsup HTVl POL 675 93
15 VTVYYGVPVWKEATT DR sup HT l ENV 48 83 20 VWGIKQLQARVLAVERYLKD DR sup HTVenv54
16 WDQSLKPCVKLTPLCV DRsup HIVl ENV 112
16 WGCSGKLICTTAVPWN DRsup HTVl ENV 601
15 WRKLVDFRELNKRTQ DRsup HTVl POL 250 80 20 VYVWKTTWGQYWQVLGGPVS DR sup gpl00.150
17 ALHIYMNGTMSQVQGSA DRsup Tyrosinase.365
16 WPSVFYNRTCQCSGNF DR sup Tyrosinase.80 20 YGQMKNGSTPMFNDINΓYDL DR sup Tyrosinase.156
15 DΓVIYSKYGGTEΓKY DRSUP M. Leprae 67-81
15 Π YNGEEYLΓLSARD DR sup M. Leprae 79-93
15 ΓYSKYGGTEIKYNGE DRsup M. Leprae 70-84
15 LVrPENAKEKPQEGT DRsup M. Leprae 28-42 No. % % amino Sequence Motif Source Conserv Conserv acids (Total) (Core)
15 NGEEYLΓJ SARDVLA DRsup M. Leprae 82-96
15 PSGLVΓPENAKEKPQ DRsup M. Leprae 25-39
15 RΓJPVDVSEGDΓVIYS DRsup M. Leprae 58-72
15 SEGDΓVTYSKYGGTE DRsup M. Leprae 64-78
15 VAKVKΓKPLEDKΓLV DRsup M. Leprae 1-15
15 VKΓKPLEDKΓLVQAG DRsup M. Leprae 4-18
15 LQLVFGΓEVVEWPI DRsup MAGE2.158
15 PRKLLMQDLVQENYL DRsup MAGE2.242
15 QDFFPVΓESKASEYL DRsup MAGE2.144
15 QLVFGΓEVVEWPIS DRsup MAGE2.159
15 RALΓETSYVKVLHHT DRsup MAGE2.276
15 RKLLMQDLVQENYLE DRsup MAGE2.243
15 SHLYΓLVTCLGLSYD DRsup MAGE2.173
15 YEFLWGPRALIETSY DRsup MAGE2.269
15 GEALGLVGAQAPATE DRsup MAGE2/3.20
15 FFPVΓFSKASSSLQL DRsup MAGE3.146
15 FPVΓFSKASSSLQLV DRsup MAGE3.147
15 GΓELMEVDPIGHLYI DRsup MAGE3.163
15 QAALSRKVAELVHFL DRsup MAGE3.106
15 QYFFPVΓFSKASSSL DRsup MAGE3.144
15 RALVETSYVKVLHHM DRsup MAGE3.276
15 VDPIGHLYΓFATCLG DRsup MAGE3.169
15 VFGΓELMEVDPIGHL DRsup MAGE3.161
15 VGNWQYFFPVΓFSKA DRsup MAGE3.140
15 YEFLWGPRALVETSY DRsup MAGE3.269
15 VGNWQYFFPVIFSKA DRsup Mage3/6.140
25 MVKISGGPRISYPLLHEWALREGEE DRsup Mage6.290
24 QVPGSDPACYEFLWGPRALIETSY DRsup Mage6.260
15 ANPVVHFFKNIVTPR DRsup Human MBP 85- 99(85A)
20 ASQKRPSQRHGSKYLATAST DRsup Human MBP 1-20
20 AYDAQGTLSKΓFKLGGRDSR DRsup Mouse MBP 141-
160
11 DENPVVHFFKN DRsup Human MBP 84-94
12 DENPVVHFFKNI DRsup Human MBP 84-95
13 DENPVVHFFKNTV DRsup Human MBP 84-96
14 DENPVVHFFKNΓVT DRsup Human MBP 84-97
16 DENPVVHFFKNΓVTPR DRsup Human MBP 84-99
17 DENPVVHFFKNΓVTPRT DRsup Human MBP 84-
100
19 DENPVVHFFKNΓVTPRTPP DRsup Human MBP 84-
102
20 DENPVVHFFKNΓVTPRTPPY DRsup Human MBP 84-
102Y
20 DENPWHFFRN TPRTPPY DRsup Human MBP 84- 102Y(99R)
15 EAPVVHFFKNΓVTPR DRsup Human MBP 85- 99(86A)
15 ENAWHFFKNIVTPR DRsup Human MBP 85- No. % % amino Sequence Motif Source Conserv Conserv acids (Total) (Core)
99(87A)
15 ENPAVHFFKNIVTPR DRsup Human MBP 85- 99(88A)
15 ENPKVHFFKNΓVTPR DRsup Human MBP 85-99 SAAS (88K)
15 ENPVAHFFKNΓVTPR DRsup Human MBP 85- 99(89A)
15 ENPVKHFFKNΓVTPR DRsup Human MBP 85-99 SAAS (89K)
15 ENPVVAFFKN TPR DRsup Human MBP 85- 99(90A)
15 ENPVVAFFKNΓVTPR DRsup Human MBP 85-99 SAAS (90A)
15 ENPVVDFFKNΓVTPR DRsup Human MBP 85-99 SAAS (90D)
15 ENPV FFKNΓVTPR DRsup Human MBP 85-99 SAAS (90F)
15 ENPWHAFKNTVTPR DRsup Human MBP 85- 99(91A)
15 ENPVVHAFKNΓVTPR DRsup Human MBP 85-99 SAAS (91 A)
15 ENPWHAFR ΓVTPR DRsup MBP85-99 (91A,93R)
15 ENPVVHDFKNIVTPR DRsup Human MBP 85-99 SAAS (9 ID)
15 ENPVVHFAKNΓVTPR DRsup Human MBP 85- 99(92A)
15 ENPVVHFAR VTPR DRsup MBP85-99 (92A,93R)
15 ENPVVHFFANΓVTPR DRsup Human MBP 85- 99(93A)
15 ENPVVHFFANIVTPR DRsup Human MBP 85-99 SAAS (93A)
17 ENPVVHFFANΓVTPRTP DRsup MBP 91K>A analog
15 ENPVVHFFDNΓVTPR DRsup Human MBP 85-99 SAAS (93D)
15 ENPVVHFFHNΓVTPR DRsup Human MBP 85-99 SAAS (93H)
15 ENPVVHFFKAΓVTPR DRsup Human MBP 85- 99(94A)
17 ENPVVHFFKAΓVTPRTP DRsup MBP 92N>A analog
15 ENPVVHFFKKΓVTPR DRsup Human MBP 85-99 SAAS (94K)
15 ENPVVHFFKNAVTPR DRsup Human MBP 85- 99(95A)
17 ENPVVHFFKNAVTPRTP DRsup MBP 93I>A analog
15 ENPVVHFFKNIATPR DRsup Human MBP 85- 99(96A) No. % % amino Sequence Motif Source Conserv Conserv acids (Total) (Core)
15 ENPVVHFFKNTVAPR DR sup Human MBP 85- 99(97A)
17 ENPVVHFFKMVAPRTP DR sup MBP 95T>A analog
15 ENPVVHFFKNTVTAR DR sup Human MBP 85- 99(98A)
15 ENPVVHFFKNΓVTPA DR sup Human MBP 85- 99(99A)
15 ENPVVHFFKNΓVTPA DR sup Human MBP 85- 98A
15 ENPVVHFFKNTVTPR DR sup Human MBP 85-99
17 ENPVVHFFKNTVTPRTP DR sup MBP 83
19 ENPVVHFFKNΓVTPRTPPY DR sup Human MBP 85- 102Y
15 ENPVVHFFKNKVTPR DR sup Human MBP 85-99 SAAS (95K)
15 ENPVVHFFLNTVTPR DR sup Human MBP 85-99 SAAS (93L)
15 ENPVVHFFRNΓVTPR DR sup Human MBP 85-99 SAAS (93R)
15 ENPVVHFKKNΓVTPR DR sup Human MBP 85-99 SAAS (92K)
15 ENPVVHHFKNΓVTPR DR sup Human MBP 85-99 SAAS (91H)
15 ENPVVHHFRNΓVTPR DR sup MBP85-99 (91H,93R)
15 ENPVVHLFKNΓVTPR DR sup Human MBP 85-99 SAAS (91L)
15 ENPWHLFRNΓVTPR DR sup MBP85-99 (91L.93R)
15 ENPVVHWFKNΓVTPR DR sup Human MBP 85-99 SAAS (91W)
15 ENPVVHYFANΓVTPR DR sup MBP85-99 (91Y.93A)
15 ENPVVHYFHNTVTPR DR sup MBP85-99 (91Y.93H)
15 ENPVVHYFKNTVTPR DR sup Human MBP 85-99 SAAS (91Y)
15 ENPWHYFLNΓVTPR DR sup MBP85-99 (91Y.93L)
15 ENPVVHYFRNΓVTPR DR sup MBP85-99 (91Y.93R)
15 ENPVVKFFKNΓVTPR DR sup Human MBP 85-99 SAAS (90K)
16 FFKNΓVTPFFKNΓVTP DR sup MBP reiterative
20 GFGYGGRASDYKSAHKGFKG DR sup Mouse MBP 121- 140/Human 124- 143
14 HFFKNTVTPRTPPY DR sup Human MBP 90- No. % % amino Sequence Motif Source Conserv Conserv acids (Total) (Core)
102Y
14 HFFKNTVTPRTPPY DR sup Human MBP 90-
102Y
20 IFKLGGRDSRSGSPMARR DR sup Mouse MBP 151-
168/Human 154-
171
12 NPVVHFFKNIVT DR sup Human MBP 86-97
14 NPVVHFFKNTVTPA DR sup Human MBP 86-
98A
14 NPVVHFFKNTVTPR DR sup Human MBP 86-99
18 NPVVHFFK TVTPRTPPY DR sup Human MBP 86-
102Y
11 PWHFFKNTVT DR sup Human MBP 87-97
13 PWHFFKNTVTPA DR sup Human MBP 87-
98A
13 PWHFFKNΓVTPR DR sup Human MBP 87-99
17 PWHFFKNTVTPRTPPY DR sup Human MBP 87-
102Y
20 QKSHGRTQDENPWHFFKNI DR sup Human MBP 74-93
20 RASDYKSAHKGFKGVDAQGT DR sup MBP 131-152
20 RASDYKSAHKGLKGHDAQGT DR sup MBP 131-152 F>L analog
20 RFFSGDRGAPKRGSGKDSHT DR sup Mouse MBP 41 -60
20 VDAQGTLSKJFKLGGRDSRS DR sup Hu MBP 144-163
20 VDAQGTLSKLFKLGGRDSRS DR sup MBP 144-163 var ./analog
20 VDAQGTLSRXFKLGGRDSRS DR sup MBP 144-163 var./analog
20 VDAQGTLSRLFKLGGRDSRS DR sup Rabbit MBP 144-
163
15 VHFFKNTVTPRTPPY DR sup Human MBP 89-
102Y
16 WHFFKNTVTPRTPPY DR sup Human MBP 88-
102Y
20 YKSAHKGFKGAYDAQGTLSK DR sup Mouse MBP 131-
150
15 AKSVTCTYSPALNKM DR sup ρ53.119
15 APPVAPAPAAPTPAA DR sup ρ53.70
15 APSWPLSSSVPSQKT DR sup p53.88
15 FCQLAKTCPVQLWVD DR sup ρ53.134
15 FSDLWKLLPENNVLS DR sup p53.19
15 GTRVRAMATYKQSQH DR sup p53.154
15 HYNYMCNSSCMGGMN DR sup p53.233
15 LGFLHSGTAKSVTCT DR sup ρ53.111
15 LSPLPSQAMDDLMLS DR sup p53.32
15 NNVLSPLPSQAMDDL DR sup p53.29
15 RLGFLHSGTAKSVTC DR sup p53.110
15 RNTFRHSWVPYEPP DR sup p53.209
15 SWPLSSSVPSQKTYQ DR sup p53.90 No. % % amino . Sequence Motif Source Conserv Conserv acids (Total) (Core)
15 SYGFRLGFLHSGTAK DRsup P53.106
15 WKLLPENNVLSPLPS DRsup p53.23
15 YNYMCNSSCMGGMNR DRsup p53.234
14 AKFVAAWTLKAAA DRsup PADRE analog
14 YAKFVAAWTLKAAA DRsup PADRE analog
15 AGGIAGGLALLACAG DRsup PfSSP2498 100
15 ATSVLAGLLGNVSTV DRsup Pf EXP177 100
15 AVPLAMKLIQQLNLN DRsup PfSSP268 100
15 FLALFFΠFNKESLA DRsup Pf EXP18 100
15 GRDVQNNΓYDEΓKYR DRsup PfSSP225 90
15 IFHINGKΠKNSEKD DRsup PfLSAl 18 100
15 KHΓLYISFYFΓLVNL DRsup PfLSAl 2 100
15 KYLVΓVFLTJFFDLFL DRsup PfSSP28 100
15 LGNVSTVLLGGVGLV DRsup Pf EXP185 100
15 LΓDVHDLISDMΓKKE DRsup Pf EXP147 100
15 LΓFFDLFLVNGRDVQ DRsup Pf.TRAP.15 100
15 LSVFFLALFFIΓFNK DRsup Pf EXP14 100
20 NAREΠRLHSDASKNKEKAL DRsup Pf.SSP2
15 NDRTNRENANQLVVI DRsup Pf SSP2145 100
15 NHAVPLAMKLIQQLN DRsup PfSSP266 80
15 SFYFΓLVNLLΓFHIN DRsup PfLSAl 8 100
15 TVLLGGVGLVLYNTE DRsup Pf EXP190 100
15 VFFLALFFΠFNKES DRsup Pf EXP16 100
15 VSTVLLGGVGLVLYN DRsup Pf EXP188 100
15 WΓJTDGΓPDSIQDS DRsup Pf SSP2157 100
20 YADSAWENVKNVIGPFMKAV DRsup Pf.SSP2
15 YKFWPGAATPYAGE DRsup PfSSP2515 80
15 DQSYLQDSDPDSFQD DRsup Tyrosinase 448-462 (Q449)
15 DYSFLQDSDPDSFQD DRsup Tyrosinase 448-462 (F451)
15 DYSYFQDSDPDSFQD DRsup Tyrosinase 448-462 (F452)
15 DYSYLQDSDPDSFQD DRsup Tyrosinase.448
15 DYSYLQDSDPDSFQD DRsup Tyrosinase 448-462
15 DYSYLQDSVPDSFQD DRsup Tyrosinase 448-462 (V456)
15 DYSYQQDSDPDSFQD DRsup Tyrosinase 448-462 (Q452)
14 NΓLLSNAPLGPQFP DRsup Tyrosinase 57-70
15 QNFLLSNAPLGPQFP DRsup Tyrosinase 56-70 (F58)
15 QNΓFLSNAPLGPQFP DRsup Tyrosinase 56-70 (F59)
15 QNΓLLSNAPLGPQFP DRsup Tyrosinase.56
15 QNΓLLSNAQLGPQFP DRsup Tyrosinase 56-70 (Q64)
15 QNΓLLSNAVLGPQFP DRsup Tyrosinase 56-70 (V64) No. % % amino Sequence Motif Source Conserv Conserv acids (Total) (Core)
15 QNΓLLSNVPLGPQFP DR sup Tyrosinase 56-70
(V63)
15 QNΓLQSNAPLGPQFP DR sup Tyrosinase 56-70
(Q60)
15 QNΓLVSNAPLGPQFP DR sup Tyrosinase 56-70
(V60)
15 QNIQLSNAPLGPQFP DR sup Tyrosinase 56-70
(Q59)
15 QNTVLSNAPLGPQFP DR sup Tyrosinase 56-70
(V59)
15 QNVLLSNAPLGPQFP DR sup Tyrosinase 56-70
(V58)
13 SYLQDSDPDSFQD DR sup Tyrosinase 450-462 13 SYLQDSVPDSFQD DR sup Tyrosinase 450-462
(V456)
12 YLQDSDPDSFQD DR sup Tyrosinase 451-462 14 YSYLQDSDPDSFQD DR sup Tyrosinase 449-462
Table 29b
DR147 Cross- Cro
DR2 DR2 DR4 DR4 DR4 DR5 DR5 DR6 DR8 DR Cross- react. re
Sequence DR1 w2§l w2§2 w4 wl4 wl5 wll wl2 wl9 DR7 2 DR52a DR9 w53 react. (4/7) (7/
FPQPQLPYSQP 0.001 0.0001 0.0001 4.6 0
QPFRPQQPY
ΓPPYCTIAPFGΓF 0.0001 0.17 0.0001 0.012 1
GTN
LGQQQPFPPQQ 0.0001 0.0001 0.0001 0.246 0 PYPQPQPFP LHQQQKQQQQ 0.0001 0.0001 0.0001 0.192 0
PSSQVSFQQP
LLQELCCQHL 0.0001 0.001 0.001 1.3 0
WQΓPEQSQCQ
LQQHNIAHGRS 0.111 0
QVLQQSTYQ
PQPFRPQQPYP 0.01 0.0001 0.0001 12.9 0
Ul 4- QPQPQYSQP
PQPQPQYSQPQ 0.0001 0.0001 0.0001 0.074 0
QPISQQQQQ
PSSQVSFQQPL 0.002 0.0001 0.0001 8.5 0
QQYPLGQGS
QFEETRNLALQ 0.017 0.042 0.0001 1.2 1
TLPAMCNVY
QGSVQPQQLPQ 0.015 0.16 0.0001 0.087 1
FEEΓRNLAL
QNPSQQQPQEQ 0.0001 0.0001 0.0001 0.297 0
VPLVQQQQF
QPYPQPQPFPS 0.0001 0.0001 0.0001 1.9 0
QQPYLQLQP
QQLTFCMDWL 0.001 0.002 0.015 1.5 0
QQHNIAHGR
QVPLVQQQQFL 5.5 0
GQQQPFPPQ
SQQPYLQLQPF 0.102 0.006 0.0001 0.898 0
PQPQLPYSQ
DR147 Cross- Cros
DR2 DR2 DR4 DR4 DR4 DR5 DR5 DR6 DR8 DR Cross- react. reac
Sequence DR1 2§l w2§2 w4 w!4 wl5 wl l wl2 wl9 DR7 w2 DR52a DR9 w53 react. (4/7) (7/1
VRVPVPQLQPQ 0.0001 0.0001 0.0001 7.4 0
NPSQQQPQE
TRNLALQTLPA 13 0
MCNVY
PQPFRPQQPYP 25 0
Q PQPFRPQQPYP 16 0
QPQPQ
QFEEΓRNLALQ 0.75 0
T
QFEEΓRNLALQ 0.39 0
TLPAM QFLGQQQPFPP 8 0
Q
QVPLVQQQQFL 0.86 0 - i G
QVPLVQQQQFL 86 0
GQQQP
VQQQQFLGQQ 27 0
QPFPPQ alLAAJHAAHAA 0.019 0.0001 0.0001 0.0001 0.0001 0.0001
IiAAHAa
CPKYVRSAKLR 0.003 0.007 0.0001 0.0001 0.088 0.686 -0.006
M
GACPKYVKQN 0.0001 0.0001 0.039 -0.004 0.034
TL
GACPKYVKQN 0.0001 -0.019 0.012 -0.004 1.2
TLK
KQNTLKLATG 0.0001 0.002 -0.003 -0.004 0.031
MR
LAKQNTLAKQ 0.0001 1.5 0.3 0.58 -0.007 0.0001 0.004
NTLAKQNT
PKAVKQNTLK 0.005 -0.018 -0.003 0.002 -0.003 0.0001
LAT
DR147 Cross- Cros
DR2 DR2 DR4 DR4 DR4 DR5 DR5 DR6 DR8 DR Cross- react. reac
Sequence DR1 w2§l w2§2 w4 wl4 w!5 wll wl2 wl9 DR7 w2 DR52a DR9 w53 react. (4/7) (7/1
PKSVKQNTLKL 0.0001 0.001 0.78 0.0001 -0.002 0.0001
AT
PKYDKQGGLKI 0.033 -0.002 0.0001
AT
PKYFKQFRLKI 0.005 0.003 -0.002
AT
PKYGKQRFLKI 0.001 0.05 0.005
AT
PKYTKQIILKIA 0.004 0.09 0.12
T
PKYVKKNTLK 0.056 0.172 0.015 0.0001 0.187 0.007
LAT
PKYVKQNKLK -0.002 0.006 -0.005 0.0001 0.646 0.083
LAT
PKYVKQNTKK 0.36 0.373 0.021 0.0001 1.2 0.018
LAT
PKYVKQNTLK -0.002 0.006 -0.041 0.0001 0.0001 0.029
EAT
PKYVKQNTLK 0.45
LAT
PKYVKQNTLK1 0.013 0.0001 0.021 0.0001
AT
PKYVKQNTLK1 0.14 0.014
AT
PKYVKQNT1KL 0.052 0.005 0.028 0.0001 0.003 -0.004 0.0001
AT
PKYVKQnTLKL 0.015 0.04
AT pKYVKQNTLKL 0.013 -0.004
AT
PKYVKQNTLK 0.0001 0.027 0.031 0.0001 0.01 0.016
NAT
PKYVKQNTNK 0.071 0.15 0.041 0.0001 0.01 0.001 1
LAT
DR147 Cross- Cr
DR2 DR2 DR4 DR4 DR4 DR5 DR5 DR6 DR8 DR Cross- react. re
Sequence DR1 w2§l w2§2 w4 w!4 w!5 wll w!2 w!9 DR7 w2 DR52a DR9 w53 react. (4/7) (7
RTLYQNVGTY 0.26 -0.003 0.0001 -0.002 -0.013 0.0001 -0.009 1
VSVGTSTLNK
VKQNTLKLAT 0.0001 0.0001 -0.006 0.026 0.0001 0
GMR
YPKYVKRNTL 0.21 0.023 0.004 0.003 1
KLAT
AAPFTQCGYPA 0.034 0.034 - 0.0064 0.008 1 2
LMPL 0.0016
AFSYMDDWL 0.0027 - 2.9 0.002 0.0006 _ 1 1
GAKSV 0.0005 0.0003 0.0005
AILCWGELMTL 0.0008 1 0.0001 0
A
ALRQAILCWGE 0.013 0.86 0.0019 1
LMTLA
ASARFSWLSLL 0.011 0.001 0.029 0.002 0.0001 0.012 0.009 1
Uι VPFVQWFVG
4- Ul DWKVCQRTVG 0.012 0.003 0.011 0.25 0.0018 0.013 1 1 LLGFA 0.0026
GAHLSLRGLPV 0.78 0.0042 0.0011 0.026 0.0025 0.0077 0.015 1 1
CAFS
GYRWMCLRRF 0.002 0.005 0.106 0.004 0.005 0.011 -0.004 1
ITFLFILLLC
HHTALRQAILC 0.008 0.31 0.0002 1
WGELMTLA
HLSLRGLPVCA 1.3 0.0028 0.013 1 1
FSSA
HTALRQAILCW 0.014 0.38 0.0014 1
GELMTLA
ILCWGELMTLA 0.0001 0.081 0.0001 0 rVGLLGFAAPF 0.02 - - 0.0046 - 0.0009 0.0067 1 1
TQCG 0.0005 0.0007 0.0002
LCQVFADATPT 0.002 0.96 0.011 0.0013 0.33 0.078 1 1
GWGL
LCWGELMTLA 0.0001 0.029 0.0001 0
DR147 Cross- Cr
DR2 DR2 DR4 DR4 DR4 DR5 DR5 DR6 DR8 DR Cross- react. re
Sequence DR1 w22§§ll ww22§§22 44 !l44 ww!l55 wwllll ww!l22 ww!l99 DR7 w2 DR52a DR9 w53 react. (4/7) (7/
LRQAILCWGEL 0.0089 1 0.0002 1
MTLA
LSPTVWLSVTW 0.004 0.003 0.076 0.005 0.004 0.005 -0.004 1
MMWYWGPSL
LSTLPETTWR 0.0001 0.001 -0.005 0.002 0.085 -0.013 0.008 0
RRGRS
MDTDPYKEFGA 0.044 0.058 1.9 0.0015 0.044 3
SVELLSFL
MDTDPYKEFGA 0.15 0.018 0.46 - 0.15 2
SVELLSFLPSDF 0.0002
FP
MDTDPYKEFGA 0.0037 0.17 0.46 0.0009 0.003 1
TVELLSFL
MDTDPYKEFGA 0.0001 0.0001 0.065 0.275 0.002 -0.017 0.003 1
TVELLSFLP M MDDTTDDPPYYKKEEFFGGAA 0 0..00003322 0 0..004477 0 0..00001188 0 0..000044 1
TVELLSFLPSDF
FP
MDΓDPYKEFGA 0.045 0.31 3 0.0049 0.013
TVELLSFLPSDF
FP
MDTDPYKEFGA 0.013 1.4 4.9 0.0013 0.035
TVQLLSFLPSDF FP
NAPILSTLPETT 0.0009 0.0009 - 0.0054 - 0.0005 0.16 0
WR 0.0007 0.0002
PFLLAQFTSAIC 0.069 0.15 0 S RRA
PFTHTALRQAIL 0.0003 0.045 0.0094 0 CW
PFTHTALRQAIL 0.0024 0.37 0.0001 0 CWG
PHHTALRQAIL 0.0021 0.045 0.0003 0 CWGEL
DR147 Cross- Cros
DR2 DR2 DR4 DR4 DR4 DR5 DR5 DR6 DR8 DR Cross- react. rea
Sequence DR1 w2§l w2§2 w4 wl4 wl5 wll wl2 wl9 DR7 w2 DR52a DR9 w53 react. (4/7) (7/1
PHHTALRQAIL 0.03 0.067 0.0082 1
CWGELM
PHHTALRQAIL 0.0031 0.075 0.0055 0
CWGELMT
PHHTALRQAIL 0.039 0.54 0.006 1
CWGELMTL
PHHTALRQAIL 0.0053 1.2 0.001 1
CWGELMTLA
PLPTHTAELLAA 0.0046 0.049 1 1
CFA 0.0003
PPAYRPPNAPIL 0.0056 - 0.0038 - 0.0022 0.0024 0.0015 1 1
STL 0.0005 0.0005
PQAMQWNSTT 0.0012 0.03 0.12 1 1
FHQTL
Uι QAILCWGELM 0.0039 0.76 0.0026 0
4- ~4 TLA
QCGYPALMPL 0.0062 0.0018 0.0068 0.0023 0.0006 1 1
YACIQ
RDLLDTASALY 0.0001 0.0092 0.077 1 1
REAL
RDLLDTASALY 0.0001 0.025 -0.006 0.003 0.0001 0.092 -0.003 1
RREALESPEH
RDLWSYVNT 0.005 0.003 0.02 0.017 0.0001 -0.017 0.016 1
NMGLKFRQLL
RFSWLSLLVPF 0.043 0.0009 - 0.0034 0.0002 0.0005 0.0031 1 1
VQWF 0.0007
RQAILCWGEL 0.0016 1.3 0.0002 0
MTLA
SLDSWWTSLNF 0.136 0.0001 0.023 0.002 0.001 0.006 -0.004 1
LGGTTVCLG
SVRFSWLSLLV 0.9 0.0099 0.0037 1 1
PFVQ
TALRQAILCWG 0.0055 0.71 0.0011 1
ELMTLA
DR147 Cross- Cr
DR2 DR2 DR4 DR4 DR4 DR5 DR5 DR6 DR8 DR Cross- react. re
Sequence DR1 w2§l w2§2 w4 wl4 wl5 wll wl2 wl9 DR7 w2 DR52a DR9 w53 react. (4/7) (7/
TNLLSSNLSWL 0.0016 0.13 0.023 0.0006 0.0019 0.041 1
SLDV 0.0005
TNMGLKFRQL - _ 0.0081 0.013 0.0022 0
LWFHI 0.0005 0.0043
TNVGLKFRQLL 0.0034 0.055 0.33 0.0006 0.025 2
WFHI
TTWRRRGRSP 0.0001 0.0001 _ 0.0075 -0.005 0.0001 0.0001 0.018 0
RRR 0.0004 0.0003 0.0007
VCAFSSAGPCA 0.21 0.0023 0.0048 0.0003 0.02 0.015 1
LRFT
VSFGVWIRTPP -0.012 0.15 0
AYRPPNAPI
YPALMPLYACI 0.24 0.0014 0.0011
QSKQ
AEQFKQKALG 0.049 0.0006 0.0058
OJ LLQTA 4-
00 ANLLWRQEMG 0.7 0.0018 0.0022
GNITR
ARLΓVFPDLGV 0.0053 0.0017 0.0004
RVCE
ASQLSAPSLKA 0.015 0.0056 0.0006
TCTT
AVQWMNRLIA 2.2 0.0035 0.0205
Γ TjA A PUC; DADLIEANLLW 0.0088 -0.001 0.0025
RQEM
EDLVNLLPAILS 0.37 0.011 0.0015 X>ΠA
GALWGWCA 0.017 0.0067 0.0043
AILRR
GCSFSTFLLALL 0.006 0.0015 0.003
SCL
GPGEGAVQWM 0.57 0.0084 0.23 0.004
NRLIAFASRG
DR147 Cross- Cr
DR2 DR2 DR4 DR4 DR4 DR5 DR5 DR6 DR8 DR Cross- react. re
Sequence DR1 w2§l w2§2 w4 wl4 wl5 wl l wl2 wl9 DR7 w2 DR52a DR9 w53 react. (4/7) (7/
KPTLHGPTPLL 0.038 0.001 0.0055 1 1
YRLG
LAGYGAGVAG 0.041 - 0.0008 1 1
ALVAF 0.0003
LHGLSAFSLHS 1.6 0.0095 0.007 1 1
YSPG
LLFNILGGWVA 0.19 - 0.0028 0.0004 1
AQLAAPGAA 0.0035
LTSMLTDPSHIT 0.0004 0.074 1 1
AET 0.0003
NFISGIQYLAGL 0.18 -0.012 1.6 0
STLPGNPA
PAILSPGALVV 0.11 0.0007 0.0076 1 1
GWCA
PQTFQVAHLHA 0.24 0.0053 1 1
OJ PTGS 0.0003
PTLWARMILM 0.0064 0.02 0.019 1 1 THFFS
RAAVCTRGVA 0.01 0.0077 0.0024 1 1
KAVDF
TVDFSLDPTFTI 0.0001 0.16 0.0005 1 1
ETT
WLLFLLLADA 0.024 0.012 0.0033 1 1
RVCS
WESVFTGLTHI 0.031 0.0068 0.0005 1 1
DAHF
AFVAWRNRCK 1.75 0
AWAAWRNRC 0.18 0
K
AWEAWRNRCK 0.15 0
AWLAWRNRCK 0.46 0
AWVAARNRCK 4.4 0
AWVAFRNRCK 1.8 0
DR147 Cross- Cr
DR2 DR2 DR4 DR4 DR4 DR5 DR5 DR6 DR8 DR Cross- react. re
Sequence DRl w2§l w2§2 w4 wl4 wl5 wl l wl2 wl9 DR7 w2 DR52a DR9 w53 react. (4/7) (7
AWVAQRNRCK 0.9 0
AWVAWANRC 0.35 0
K
AWVAWENRC 0.16 0
K
AWVAWKNRC 0.82 0
K
AWVAWRARC 1.2 0
K
AWVAWRNAC 0.67 0
K
AWVAWRNEC 0.17 0
K
AWVAWRNKC 0.25 0
K
OJ AWVAWRNRC 0.021 0
© A
AWVAWRNRC 0.0001 0.45 0.012 0.0001 -0.004 0.0001 -0.009 0
K
AWVAWRNRC 0.0001 0.45 0.012 0.0001 -0.004 0.0001 -0.009 0
K
AWVAWRNRC 0.105 0
R
AWVAWRNRE 0.85 0
K
AWVAWRNRK 2.8 0
K
AWVAWRNRQ 4.6 0
K
AWVAWRNRV 2.7 0
K
AWVAWRVRC 0.056 0
K
AWVEWRNRCK 0.073 0
DR147 Cross- Cr
DR2 DR2 DR4 DR4 DR4 DR5 DR5 DR6 DR8 DR Cross- react, re
Sequence DRl w2§l w2§2 w4 wl4 w!5 wll wl2 wl9 DR7 w2 DR52a DR9 w53 react. (4/7) (7
AWVSWRNRCK 0.25 0
AWWWRNRC 0.2 0
K
EFVAAKAAQK 0.008 6.7 0.004 0.0001 -0.016 0.0001 -0.002 1
EWVAWRNRCK 0.48 0
LAAAMKRHGL -0.004 0.051 -0.002 0.0001 0.24 0.005 -0.019 0
DNYRGYSLGN
WV
NTDGSTDYGIL 0.007 -0.003 0.01 0.013 -0.007 -0.003 -0.014 1
QTNSR
RNRCKGTDVQ 0.01 0.051 -0.002 0.046 -0.008 0.007 -0.016 1
AWTRGCRL
SVNCAKKTVSD 0.0001 -0.002 0.04 0.006 0.03 -0.003 0.044 0
GNGMN
SWVAWRNRCK 0.42 0
VWVAWRNRC 0.19 0
K
WRNAKWRNA 0.005 0.018 -0.002 0.0001 0 0..000044 0.0001 -0.007 1
KWRNAK
YRGYSLGNWV 0.009 0.009 -0.002 0.0001 0 0..000044 -0.004 -0.019 1
CAAKFESNFNT Q
SPYVSRLLGICL 0.41 _ 0.32 0 0..00000088 0 0..002222 0 0..001144 0.098 1
T 0.0035
ASDFNLPPWA 0.0026 - - - _ 0.084 1 1
KETV 0.0021 0.0028 0 0..00000066
AVQMA IHNF 0.0032 2.6 0.032 0 0..33 0.0096 0 1
KRKG
DFNLPPWAKE 0.0042 - - 0 0..00003366 0.053 1 1
TVAS 0.0021 0.0024
DQQLLGIWGCS 0.029 0.015 - 0 0..00007733 0.018 1 1
GKLI 0.0016
DR147 Cross- Cr
DR2 DR2 DR4 DR4 DR4 DR5 DR5 DR6 DR8 DR Cross- react. re
Sequence DRl w2§l w2§2 w4 wl4 wl5 wll wl2 wl9 DR7 w2 DR52a DR9 w53 react. (4/7) (7/
DQSLKPCVKLT 0.0076 0.0018 - 0.005 0.011 1 1
PLCV 0.0016
DRVHPVHAGPI 0.0006 0.0005 - - - - 0.0066 0.27 - 1
A 0.0005 0.0027 0.0009 0.0001 0.0014
DRVHPVHAGPI 0.023 0.013 0.0019 - - - 0.01 0.28 - 2
APG 0.0031 0.0011 0.0001 0.0017
DRVHPVHAGPI 0.0066 0.0083 0.011 - - - 0.0055 0.14 - 2
APGQM 0.0036 0.0012 0.0002 0.0019
DRVHPVHAGPI 0.012 0.013 0.0051 -0.004 - - 0.0059 0.064 0.0034 2
APGQMRE 0.0014 0.0002
DRVHPVHAGPI 0.0045 0.0026 - - - - 0.0029 0.12 - 1
APGQMREPR 0.0008 0.0045 0.0016 0.0002 0.0024
DRVHPVHAGPI 0.021 0.0053 0.0014 - - - 0.0055 0.24 - 2
APGQMREPRGS 0.0049 0.0017 0.0002 0.0027
DTEVHNVWAT 0.0073 - 0.0027 0.016 - 0.0006 0.0065 0.0007 - 0.011
OJ Ul QACVPTDPNP 0.0018 0.0006 0.0027 0.0005
EAΠRILQQLLFI 0.047 - 0.033 0.016 0.023 1
HF 0.0021
EDIISLWDQSL 0.052 0.0017 - -0.001 - 1
KPCV 0.0016 0.0007
EKAFSPEVTPMF 0.0086 0.0015 0.034 -0.001 0.0023 1
SAL
EKVYLAWVPA 0.0052 3.5 0
HKGIG
ERFAVNPGLLE 0.02 -0.007 0.0001 0.007 0.008 0.0001 -0.003
TSEGC
ERYLKDQQLL 0.0018 - 0.089 - 0.004 - 0.18 1
GIWGCS 0.0004 0.0005 0.0005
ESELVSQIIEQLI 0.0059 0.021 0.0095 0.0009 0.004 1
KK
ETAYFLLKLAG 0.061 0.021 0.0041 1
RWPV
EVQLGΓPFΓPAG 0.002 0.13 - - - 0 1
LKKK 0.0026 0.0007 0.0005
DR147 Cross- Cro
DR2 DR2 DR4 DR4 DR4 DR5 DR5 DR6 DR8 DR Cross- react. rea
Sequence DRl w2§l w2§2 w4 wl4 wl5 wll wl2 wl9 DR7 w2 DR52a DR9 w53 react. (4/7) (7/1
FWEVQLGΓPHP 0.024 - 0.0033 - 0.0024 1 1
AGLK 0.0014 0.0006
GARASVLSGGE 0.006 -0.007 0.0001 0.0001 -0.002 0.0001 -0.007 1
LDKWE
GCTLNFPISPIE 0.0014 - - - 0.038 1 1
TVP 0.0014 0.0026 0.0006
GEΓYKRWΠLGL 0.066 0.16 0
NKI
GGELDKWEKTR -0.002 0.036 0.0001 0.0001 -0.002 0.0001 -0.003 0
LRPGG
HKAIGTVLVGP 0.0072 - - -0.001 0.0016 1 1
TPVN 0.0013 0.0022
IGGIGGFTKVRQ 0.0002 0.2 - 0.015 0.0031 0 1
YDQ 0.0023
OJ ITRILQQLLFIHF 0.0054 0.02 0.0084 1 1 Ul
OJ RI
IISLWDQSLKPC 0.0057 0.0061 0.0096 0.0059 0.0012 1 1
VKL
TKWPRRKAKΠ 0.0003 0.07 - 2.5 0.003 0 1
RDY 0.0024
TLKALGPAATL 0.226 0.0001 0.002 0.032 0.0001 0.001 0.0001 1
EEMMT(200.11)
TNEEAAEWERV 0.008 -0.007 0.0001 0.005 0.002 0.0001 0.006 1
FTPVHA
IQKLVGKLNW 0.026 - - 0.0044 0.0043 1 1
ASQIY 0.0014 0.0026
ISLWDQSLKPC 0.004 0.029 - 0.0024 0.0012 0 1
VKLT 0.0016
ΓVWASRELERF 0.002 -0.007 0.0001 0.013 0.059 0.0001 -0.003 0
AVNPG
ΓYKRWΠLGLN 0.0044 - 0.0067 0.01 0.0022 0.0004 0.041 0.32 0.0073 0.05 0.185 1
KΓVRMYSPV 0.0009
ΓYKRWIILGLN -0.002 0.025 0.0001 0.0001 -0.002 0.0001 -0.003 0
KΓVRN -
DR147 Cross- Cro
DR2 DR2 DR4 DR4 DR4 DR5 DR5 DR6 DR8 DR Cross- react. re
Sequence DRl w2§l w2§2 w4 w!4 w!5 wl l wl2 wl9 DR7 w2 DR52a DR9 w53 react. (4/7) (7/
KARVLAEAMS 0.008 0.012 0.0025 1 1
QVTNS
KDSWTVNDIQ 0.0027 - - 0.12 0 0
KLVGK 0.0014 0.0026 0.0005
KQIΓNMWQEV 0.003 0.0036 0.021 0.51 0.0009 0.0027 0.96 0 0
GKAMYA
KRWIILGLNKI 0.18 0.4 0
VRMY
KTILKALGPAA 0.076 0.01 - -0.001 0.0006 1 1
TLEE 0.0023
LGKTWPSYKGR -0.002 -0.007 0.005 0.33 0.072 0.0001 0.005 0
PGNFL
LICTTAVPWNA 0.0036 0.0004 0.0012 0.0011 - 0.052 0.0013 1
SWSNK 0.0003
OJ LKQΓVKKLREQ 0.0003 0.044 - 0.0008 0.0051 0.11 0
Ul
4- FGNNK 0.0006 0.0005
LLGTWGCSGKL 0.028 0.005 - 0.0014 0.0064 1
ICTT 0.0016
LSΓVNRVRQGY 0.0045 0.032 0.018 0.72 0.0015 0
SPLS
NEQVDKLVSA 0.0024 0.59 - - 0.0028 0
GTRKV 0.0026 0.0006
NNLLRAIEAQQ 0.028 0.015 0.015 1
HLLQ
PAGLKKKKSVT 0.006 - - - 0.014 1
VLDV 0.0014 0.0026 0.0006
PGNFLQSRPEP 0.097 0.017 0.019 0.0015 0.013 1
TAPP
PΓVQNLQGQM 0.008 -0.007 0.0001 0.0001 -0.002 0.0001 -0.003 1
VHQAIS
PLGVAPTKAKR 0.0001 0.48 - 0.004 0.0017 0.0007 0.025 0
RWQR 0.0006
QARILAVERYL 0.0056 0.019 - 0.0058 0.033 0.001 0.26 1
KDQQL 0.0006
DR147 Cross- Cros
DRl DR2 DR4 DR4 DR4 DR5 DR5 DR6 DR8 DR Cross- react. reac
Sequence DRl w2§l w2§2 w4 wl4 wl5 wll wl2 wl9 DR7 w2 DR52a DR9 w53 react. (4/7) (7/1
QGQMVHQAISP - 1.2 0
RTLN 0.0047
QKQEPIDKELY 0.04 -0.007 0.0001 0.2 -0.002 0.0001 -0.003 1
PLTSL
QMA THNFKR 0.0005 1.2 0.0031 1.1 0.0037 0 1
KGGI
RIQRGPGRAFV 0.0004 0.0083 - - 0.085 - 0.015 0 0
TIGKL 0.0006 0.0005 0.0005
RQILGQLQPSL 0.022 -0.007 0.006 0.05 -0.002 0.0001 -0.003 1
QTGSE
SLKPCVKLTPL 0.018 0.012 0.003 0.013 0.047 0.023 0.12 1 1
CVTLN
SLWDQSLKPCV 0.0011 0.022 - - 0.0047 - 0.016 0 0
KLTPL 0.0006 0.0005 0.0005 J SPATFQSSMTKI 1 0.0025 0 Ul Ul LEP
SPGΓWQLDCTH 0.0013 - 0.099 - - 1 1
LEGK 0.0021 0.0006 0.0009
SQUΈQLΓKKEK 0.0006 0.031 - 0.052 - 0 1
VYL 0.0026 0.0005
SSGGDPEΓVMH 0.0001 - - - - - 0.12 0 0
SFNCG 0.0004 0.0006 0.0005 0.0003 0.0005
TAATNAACAW 0.0005 - -0.015 0.0006 - 0.0036 0.0015 - 0.046 0.0012 0
LEA 0.0029 0.0004 0.0006 0.0011
TITLPCRΓKQFI 0.0002 0.0011 0.03 0.061 0.0005 0.0011 0.08 0 0
NMWQE
VDKLVSAGIRK 0.0039 0.15 - 0.0045 0.012 0 1
VLFL 0.0026
VTPMFSALSEG 0.0085 - 0.0058 -0.001 - 1 1
ATPQ 0.0014 0.0007
VKIEPLGVAPT 0.0028 1.5 0.001 0.074 - - 0.01 0 1
KAKRR 0.0003 0.0005
VLSrVNRVRQG 0.0031 1.7 0.026 5.9 0.0092 0 1
YSPL
DR147 Cross- Cro
DR2 DR2 DR4 DR4 DR4 DR5 DR5 DR6 DR8 DR Cross- react rea
Sequence DRl w2§l w2§2 w4 wl4 wl5 wll wl2 wl9 DR7 w2 DR52a DR9 w53 react (4/7) (7/1
VNHGRNLLTQI 0.0027 - 0.062 0.0067 0.0012 1 1
GCT 0.0014
VNTVTDSQYAL 0.062 - 0.0091 0.018 1 1
GIIQ 0.0014 0.0007
VTVYYGVPVW 0.0087 0.027 0.0071 0.0021 0.016 1 2
KEATT
VWGΓ QLQAR 2.2 0.54 0.013 0.047 0.041 0.026 0.13 0.064 0.018 0.034 0.239 2
VLAVERYLKD
WDQSLKPCVK 0.0083 0.0029 - - 0.0011 0.0081 0.013 1 1
LTPLCV 0.0006 0.0005
WGCSGKLICTT 0.0001 - 0.0033 - 0.031 -0.001 1 1
AVPWN 0.0004 0.0005 0.0003
WRKLVDFREL 0.0011 0.0017 - 0.29 _ 0 0
NKRTQ 0.0026 0.0005
VYVWKTTWG 0.044 - 0.0018 0.0003 0.0623 2
OJ QYWQVLGGPV 0.0063 0.0016 Ul σs S
ALHIYMNGTM 0.014 0.026 0.29 0.056 -0.001 1
SQVQGSA 0.0008
WPSVFYNRTC 0.0002 - 0.0014 0.009 0.0017 0
QCSGNF 0.0048 0.0012
YGQMKNGSTP 0.005 0.032 0.052 0.021 0.021 0.0092 1
MFNDTNIYDL
DΓVΓYSKYGGT 0.01 0.0031 - 0
EΓKY 0.0006 0.0002 0.0006
ΓKYNGEEYLILS 0.031 0.014 0.0016 0.0056 0.037 0
ARD
ΓYSKYGGTETK 0.0026 0.045 0.0036 0
YNGE 0.0002 0.0008
LVTPENAKEKP 0.0001 0.16 - 0.0003 0
QEGT 0.0006 0.0006
NGEEYLILSAR 0.0017 0.034 0.049 0.0037 0.039 1
DVLA
DR147 Cross- Cros
DR2 DR2 DR4 DR4 DR4 DR5 DR5 DR6 DR8 DR Cross- react. rea
Sequence DRl w2§l w2§2 w4 wl4 wl5 wl l wl2 wl9 DR7 w2 DR52a DR9 w53 react (4/7) (7/1
PSGLVTPENAK 0.0001 0.17 - 0
EKPQ 0.0006 0.0002 0.0008
RTPVDVSEGDΓV 0.64 0.001 0
IYS 0.0003 0.0002 0.0008
SEGDΓVTYSKY 0.064 0.0006 - 0.0058 0
GGTE 0.0006 0.0006
VAKVKΓKPLED 0.055 0.0057 0.0008 0.006 0.011 0
KΓLV
VKTKPLEDKILV 0.023 0.0008 0.0025 0.0088 0.14 0
QAG
LQLVFGIEWE 0.1 0.033 0.27 2
WPI
PRKLLMQDLV 0.0009 0.16 1 QENYL 0.0019
OJ QDFFPVTFSKAS 0.011 0.27 2 Ul ~4 EYL 0.0019
QLVFGIEWEV 0.017 0.018 0.283 2 VPIS
RALIETSYVKV 0.022 0.075 0.13 3
LHHT
RKLLMQDLVQ 0.14 1
ENYLE 0.0003 0.0019
SHLYILVTCLG 0.015 0.022 0.0036 1
LSYD
YEFLWGPRALI 1.8 0.0059 0.011 1
ETSY
GEALGLVGAQ 0.082 1 APATE 0.0019 0.0019
FFPVTFSKASSS 0.048 0.12 0.63 3
LQL
FPVTFSKASSSL 0.026 0.049 0.21 3
QLV GIELMEVDPIG 0.0094 0.028 0.0049 1
HLYI
DR147 Cross- Cr
DR2 DR2 DR4 DR4 DR4 DR5 DR5 DR6 DR8 DR Cross- react. re
Sequence DRl w2§l w2§2 w4 w!4 w!5 wl l wl2 w!9 DR7 w2 DR52a DR9 w53 react. (4/7) (7
QAALSRKVAEL 0.03 - 0.0046 1
RALVETSYVKV 0.021 0.38 0.23 3
LHHM
VDPIGHLYΓFAT 0.0093 0.0043 0.0073 1
CLG
VFGIELMEVDPI 0.0039 0.057 1
GHL 0.0019
VGNWQYFFPVI 0.14 2.1 0.26 3
FSKA
YEFLWGPRAL 3.7 0.0051 0.0061 1
VETSY
VGNWQYFFPVI 0.014 0.034 0.028 0.0002 0.0076 1
OJ FSKA 0.0012 Ul oe MVKISGGPRIS 0.018 - 0.0034 0.35 0.29 2
YPLLHEWALRE 0.0075 0.0019
GEE
QVPGSDPACYE 0.15 - - 0.0021
FLWGPRALIET 0.0075 0.0005 0.0003 0.0011
SY
ANPWHFFKNI 7.2 0.07
VTPR
ASQKRPSQRHG 0.0001 0.0001 0.019 0.001 0.0001 0.028
SKYLATAST
AYDAQGTLSKI 0.172 0.201 0.017 0.212 0.535 0.012
FKLGGRDSR
DENPWHFFKN 0.012 0
DENPWHFFKN 0.55 0.005
I
DENPWHFFKN 1.4 0.011
DR147 Cross- Cr
DR2 DR2 DR4 DR4 DR4 DR5 DR5 DR6 DR8 DR Cross- react. re
Sequence DRl w2§l w2§2 w4 wl4 w!5 wl l w!2 w!9 DR7 w2 DR52a DR9 w53 react (4/7) (7/
DENPWHFFKN 2.5 0.029 0
ΓVT
DENPWHFFKN 0.86 0.014 0 rVTPR
DENPWHFFKN 0.69 0.007 0
ΓVTPRT
DENPWHFFKN 2.8 0.42 0 rVTPRTPP
DENPWHFFKN 0.76 0
ΓVTPRTPPY
DENPWHFFRN 6.6 1.1 0
ΓVTPRTPPY
EAPWΉFFKNI 3.3 0.032 0
VTPR
ENAWHFFKNI 2 0.048 0
OJ Ul VTPR vo ENPAVHFFKNI 5.7 0.053 0
VTPR
ENPKVHFFKNI 1.3 0
VTPR
ENPVAHFFKNI 0.065 0.042 0
VTPR
ENPVKFTFFKNI 0.023 0
VTPR
ENPWAFFKNI 3.3 0.068 0
VTPR
ENPWAFFKNI 1.8 0
VTPR
ENPWDFFKNI 0.12 0
VTPR
ENPWFFFKNI 4.5 0
VTPR
DR147 Cross- Cr
DR2 DR2 DR4 DR4 DR4 DR5 DR5 DR6 DR8 DR Cross- react. re
Sequence DRl w2§l w2§2 w4 wl4 wl5 wll wl2 wl9 DR7 w2 DR52a DR9 w53 react (4/7) (7
ENPWHAFKNI 4.3 0
VTPR
ENPVYHAFRNI 0.47 0
VTPR
ENPWHDFKNI 0.022 0
VTPR
ENPWHFAKNI 0.056 0.002 0
VTPR
ENPWHFARNI 0.0099 0
VTPR
ENPWHFFANI 3.6 0.005 0
VTPR
ENPWHFFANI 2.6 0
VTPR
ENPWHFFANI 0.072 5.8 0
OJ VTPRTP σs © ENPWHFFDNI 0.027 0
VTPR
ENPWHFFHNI 1.5 0
VTPR
ENPWHFFKAI 2.6 0.1 0
VTPR
ENPWHFFKAI 0.73 4.4 0
VTPRTP
ENPWHFFKKI 0.014 0
VTPR
ENPWHFFKNA 3.8 0.013 0
VTPR
ENPWHFFKNA 0.11 4.8 0
VTPRTP
ENPWHFFKNI 2.3 0.022 0
ATPR
ENPWHFFKNT 13 0.31 0
VAPR
DR147 Cross- Cro
DR2 DR2 DR4 DR4 DR4 DR5 DR5 DR6 DR8 DR Cross- react rea
Sequence DRl w2§l w2§2 w4 wl4 w!5 wll wl2 wl9 DR7 w2 DR52a DR9 w53 react. (4/7) (7/
ENPWHFFKNI 0.57 3.9 0
VAPRTP
ENPWHFFKNI 9.5 0.046 0
VTAR
ENPWHFFKNI 4.3 0.007 0
VTPA
ENPWHFFKNI 1.4 0.001 0
VTPA
ENPWHFFKNI 2.2 0.045 0
VTPR
ENPWHFFKNI 0.21 0
VTPRTP
ENPWHFFKNI 1.1 0.036 0
VTPRTPPY
ENPWHFFKNK 0.53 0
VTPR
ENPWHFFLNI 3.2 0
VTPR
ENPVVHFFRNT 4.7 0
VTPR
ENPWHFKKNI 0.028 0
VTPR
ENPWHHFKNI 1.2 0
VTPR
ENPVVHHFRNI 0.59 0
VTPR
ENPWHLFKNI 1.2 0
VTPR
ENPWHLFRNI 1.7 0
VTPR
ENPWHWFKNI 0.47 0
VTPR
ENPWHYFANI 0.5 0
VTPR
DR147 Cross- Cr
DR2 DR2 DR4 DR4 DR4 DR5 DR5 DR6 DR8 DR Cross- react. re
Sequence DRl w2§l w2§2 w4 wl4 wl5 wl l wl2 wl9 DR7 w2 DR52a DR9 w53 react (4/7) (7/
ENPWHYFHNT 0.71 0 Λ V IJPriv
ENPWHYFKNI 4.3 0
VTPR
ENPVVFΓYFLNI 0.52 0
VTPR
ENPWHYFRNI 0.41 0
VTPR
ENPWKFFKNI 1.3 0
VTPR
FFKNΓVTPFFKN 0.006 0.009 0.008 0.011 1
ΓVTP
GFGYGGRASD 0.0001 0.147 0.003 0.0001 0.144 0.0001 0
YKSAHKGFKG J HFFKNΓVTPRTP 0.02 0.056 0 s PY
HFFKNΓVTPRTP 0.005 0.038 0
PY
ΓFKLGGRDSRS 0.171 0.009 0.002 0.0001 0.0025 0.0001 1
GSPMARR
NPWHFFKNΓV 0.39 0.002 0
T
NPWHFFKNIV 1.5 0.0001 0
TPA
NPWHFFKNIV 2.6 0.011 0
TPR
NPWHFFKNTV 1.3 0.17 0
TPRTPPY
PWHFFKNIVT 0.028 0.0001 0
PWHFFKNΓVT 0.91 0.001 0
PA
PWHFFKNTVT 0.54 0.003
PR
DR147 Cross- Cro
DR2 DR2 DR4 DR4 DR4 DR5 DR5 DR6 DR8 DR Cross- react. rea
Sequence DRl w2§l w2§2 w4 wl4 wl5 wl l wl2 wl9 DR7 w2 DR52a DR9 w53 react. (4/7) (7/1
PWHFFKNTVT 3.8 0.48 0
PRTPPY
QKSHGRTQDE 0.004 0.007 0.05 0.032 0.0015 0.003 1
NPWHFFKNI
RASDYKSAHK 0.053 0
GFKGVDAQGT
RASDYKSAHK 0.099 0
GLKGHDAQGT
RFFSGDRGAPK 0.0001 0.01 0.158 0.0001 0.0001 0.0001 1
RGSGKDSHT
VDAQGTLSKIF 0.53 0
KLGGRDSRS
VDAQGTLSKLF 0.35 0
KLGGRDSRS
VDAQGTLSRTF 0.59 0 KLGGRDSRS
VDAQGTLSRLF 0.79 0
KLGGRDSRS
VHFFKNΓVTPR 0.27 0.46 0
TPPY
WHFFKNΓVTP 1.4 0.47 0
RTPPY
YKSAHKGFKG 0.002 0.419 0.532 0.002 0.007 0.0001 1
AYDAQGTLSK
AKSVTCTYSPA 0.002 0.013 0.17 1
LNKM APPVAPAPAAP 0.014 1
TPAA 0.0019 0.0019 APSWPLSSSVP 0.001 0.046 0.017 1
FSDLWKLLPEN 1.8 0.22 0.0051 2
DR147 Cross- Cro
DR2 DR2 DR4 DR4 DR4 DR5 DR5 DR6 DR8 DR Cross- react rea
Sequence DRl w2§l w2§2 w4 w!4 wl5 wll wl2 wl9 DR7 w2 DR52a DR9 w53 react. (4/7) (7/1
GTRVRAMAIY 0.15 0.49 0.87 3
KQSQH
HYNYMCNSSC 0.066 0.041 0.0099 1
MGGMN
LGFLHSGTAKS 0.46 0.57 0.19 3
VTCT
LSPLPSQAMDD 0.011 0.0079 1
LMLS 0.0019
NNVLSPLPSQA 0.037 0.002 0.016 1
MDDL
RLGFLHSGTAK 0.028 0.057 0.01 2
SVTC
RNTFRHSVWP 0.031 0.072 0.27 3
YEPP
OJ SWPLSSSVPSQ 0.0015 0.049 0.013 1 σs
4- KTYQ
SYGFRLGFLHS 0.14 0.24 0.079 3
GTAK
WKLLPENNVLS 0.071 0.41 2
PLPS 0.0019
YNYMCNSSCM 0.041 1
GGMNR 0.0019 0.0018
AKFVAAWTLK 0.27 0.21 0
AAA
YAKFVAAWTL 0.044 0.15 0
KAAA
AGGIAGGLALL 0.016 0.0013 0.0014 0.008 - - 0.0007 _ 0.0004 1 1
ACAG 0.0014 0.0002 0.0003 0.0005
ATSVLAGLLGN 0.26 0.0021 0.054 - 0.0008 0.0043 - - 0 0..00000055 00..00003399 11 11
FLALFFΠFNKE 0.0081 0.043 0.0082 0.022 0.0002 0.0021 0.014 0.0021 -0.001 1 1
SLA 0.0021
DR147 Cross- Cr
DR2 DR2 DR4 DR4 DR4 DR5 DR5 DR6 DR8 DR Cross- react. re
Sequence DRl w2§l w2§2 w4 w!4 w!5 wll w!2 w!9 DR7 w2 DR52a DR9 w53 react (4/7) (7/
GRDVQNNIVDE 0.0001 0.0001 - - - - - 0.0001 0.081 - - - 0.085 0 1
TKYR 0.0006 0.0006 0.0005 0.0014 0.0004 0.0003 0.0003 0.0005
ΓFFTTNGKITKNSE 0.032 0.022 O.O66 - - 0.0038 0.038 0.019 0.012 0.016 0.04 -0.04 0.0093 0.002 1 4
KD 0.0007 0.0005
KHILYISFYFIL 0.0016 - 0.051 -0.003 0.0023 0.0009 0.016 0.0019 1 1
VNL 0.0021
KYLVTVFLIFFD 0.0012 0.0057 -0.002 0.068 -0.003 - 0.0021 0.0034 0.013 0.0065 - 1 1
LFL 0.0009 0.0018
LGNVSTVLLGG 0.014 0.0001 - 0.0016 - - - 0.0005 0.0006 - - - - 1 1
VGLV 0.0005 0.0005 0.0014 0.0002 0.0003 0.0003 0.0005 0.0005
LTDVHDLISDMI 0.013 0.0061 0.031 0.0011 0.0076 0.0037 0.0001 0.0004 0.01 0.0096 0.043 0.094 1 1 KKE
LΓFFDLFLVNGR 0.0042 0.0036 0.047 1 1
DVQ
LSVFFLALFFΠF 0.0015 0.016 - 0.0095 - 0.0015 0.0006 0.0006 0.009 0.0028 - 0 1 NK 0.0021 0.0047 0.0018
NAREIΓRLHSDA 0.051 0.013 0.0078 0.024 0.01 - - 0.002 1
SKNKEKAL 0.0001 0.0004
NDRTNRENANQ 0.077 0.0015 0.0011 0.002 0.001 - 0.0001 - - 0.0096 1 1
LWI 0.0004 0.0003 0.0003
NHAVPLAMKLI 0.02 0.0025 0.0091 -0.003 0.019 0.24 0.0019 0.0056 0.17 0.013 1 1
QQLN
SFYFILVNLLIF 0.0009 0.01 -0.002 0.025 0.0038 - 0.0009 0.0004 0.0084 - - 0 1
HIN 0.0005 0.0007 0.0018
TVLLGGVGLVL 0.49 - 0.0032 - - 0.0004 0.0007 - 1 1
YNTE 0.0005 0.0009 0.0002 0.0002
VFFLALFFΠFN 0.0006 0.018 - 0.0047 0.01 - 0.0002 - 0.0056 - - 0 1
KES 0.0021 0.0005 0.0002 0.0007 0.0018
VSTVLLGGVGL 0.88 0.008 0.0005 0.0067 - 0.0003 0.0011 0.0002 0.002 - 0.012 1 1
VLYN 0.0009 0.0002
WILTDGΓPDSI O.OOOI - 0.12 0.0045 - - 0.0001 - - 0.0114 1 1
QDS 0.0006 0.0014 0.0004 0.0003 0.0003
YADSAWENVK 0.055 0.018 0.036 - 0.0009 - 0.031 0.01 2
NVIGPFMKAV 0.0045 0.0001
DR147 Cross- Cro
DR2 DR2 DR4 DR4 DR4 DR5 DR5 DR6 DR8 DR Cross- react rea
Sequence DRl w2§l w2§2 w4 wl4 wl5 wll wl2 wl9 DR7 w2 DR52a DR9 w53 react (4/7) (7/1
YKFWPGAATP 0.11 0.0008 0.0053 0.0057 0.0036 0.0001 0.0017 0.016 0.0026 0.02
YAGE 0.0014
DQSYLQDSDPD 0.049
SFQD
DYSFLQDSDPD 0.08
SFQD
DYSYFQDSDPD 0.089
SFQD
DYSYLQDSDPD - 0.053 0.029 0.0016
SFQD 0.0001 0.0004 0.0001 0.0009
DYSYLQDSDPD 0.046
SFQD
DYSYLQDSVPD 0.29
SFQD
DYSYQQDSDP 0.046
DSFQD
NILLSNAPLGP 0.14
QFP
QNFLLSNAPLG 0.82
PQFP
QNTFLSNAPLGP 0.14
QFP
QNILLSNAPLG 0.22 0.04 0.37 0.66 0.085 0.13
PQFP 0.0024
QNTLLSNAQLG 0.16
PQFP
QNTLLSNAVLG 0.29
PQFP
QNILLSNVPLG 3.7
PQFP
QNILQSNAPLG 0.06 1
PQFP
QNILVSNAPLG 0.074 1
PQFP
DR147 Cross- Cr
DR2 DR2 DR4 DR4 DR4 DR5 DR5 DR6 DR8 DR Cross- react. re
Sequence DRl w2§l w2§2 w4 wl4 wl5 wl l wl2 wl9 DR7 w2 DR52a DR9 w53 react. (4/7) (7/
QNIQLSNAPLG 0.06 1
PQFP
QNTVLSNAPLG 0.48
PQFP
QNVLLSNAPLG 0.047
PQFP
SYLQDSDPDSF 0.14
QD
SYLQDSVPDSF 0.72
QD
YLQDSDPDSFQ 0.08
D
YSYLQDSDPDS 0.19
FQD
OJ σs
~4
Table 30
Core
Total Conser-
Protein/ 1st Conser- vancy DRBl DRBl DRB5 DRBl DRBl DRBl DRBl DRBl DRBl Deg
Peptide Sequence Organism Segment Position vancy % % Motif *0101 *1501 *0101 *0401 *1101 *1302 *0701 *0802 *0901 era
68 0001 MWDLVLSIALSVGCT Human Kallιkrem2 1 DR super 0 025 00008 00022 00055 00003 0 033 00083 00038 0 036
680002 DLVLSIALSVGCTGA Human Kallιkrem2 3 DR super 00046 00005 00002 00007 00004 0 043 00082 00003 0 030 1
68 0003 HPQWVXTAAHCLKKN Human Kallιkrem2 56 DR super 044 00077 1 9 0011 0 017 00073 0 093 0058 0 10
680004 QWVLTAAHCLKKNSQ Human Kal krem2 58 DR super 00093 <00002 0052 00005 00016 <0 0001 00098 00005 0 016 2
680005 GQRVPVSHSFPHPLY Human Kalhkrem2 87 DR super 00027 00019 <0 0001 00006 <0 0001 00054 0 090 00002 084 3
680006 RVPVSHSFPHPLYNM Human Kalhkrem2 89 DR super 0075 00019 00024 00002 <0 0001 0 011 026 00005 0 97
680008 HPLYNMSLLKHQSLR Human Kallιkrem2 98 DR super 0 046 0022 0 095 0017 0085 00075 0026 0 13 034 8
680010 SHDLMLLRLSEPAKI Human Kallιkrem2 118 DR super 0 074 0033 00098 0 0038 00048 20 0 18 0 041 089
680011 HDLMLLRLSEPAKIT Human Kallιkrem2 119 DR super 037 0 16 0072 00040 0013 43 0 13 0 10 1 9 w 68 0017 NGVLQGITSWGPEPC Human Kal krem2 220 DR super 00024 0011 00002 0 0012 00019 <0 0001 0 012 00022 00012
∞ 68 0018 KPAVYTKWHYRKWI Human Kallιkrem2 239 DR super 00008 0023 069 0 0063 0063 00037 0 027 1 1 0 024
680019 AAPLLLARAASLSLG Human PAP 3 DR super 074 0 28 021 0063 0 21 1 2 0 17 1 3 1 6
680020 APLLLARAASLSLGF Human PAP 4 DR super 052 0 12 0 14 0034 0048 0 87 022 0 85 055
68 0021 PLLLARAASLSLGFL Human PAP 5 DR super 046 0084 0 14 0020 0034 029 0 17 1 1 1 4
68 0022 SLSLGFLFLLFFWLD Human PAP 13 DR super 00005 0 0007 00005 0 0020 00021 00069 00011 <00004 00055 1
68 002 LLFFWLDRSV AKEL Human PAP 21 DR super/ 1 9 0 27 022 3 6 0 15 0 15 020 0 ^ 0 17 DR3
680024 DRSVLAKELKFVTLV Human PAP 27 DR super 00087 0016 0 017 0013 00036 00008 0 014 00063 0014
68 0025 AKELKFVTLVFRHGD Human PAP 32 DR super 00049 0 0051 066 0 0083 00048 00033 0 046 0 024 0024
680030 DRTLMSAMTNLAALF Human PAP 110 DR super 0046 0014 00009 0 87 00062 0041 0 047 0 022 0 26
680031 MSAMTNLAALFPPEG Human PAP 114 DR super 00028 0 0007 00003 0 0139 O 0001 0016 00003 00007 <0 0004 1
680032 MTNLAALFPPEGVSI Human PAP 117 DR super 0 17 0 0009 00002 <00002 0 0001 00028 <00002 00019 00045 1
680033 PEGVSIWNPILLWQP Human PAP 126 DR super 0048 1 8 00016 00003 00005 00082 00026 00038 00007
680034 GVSIWNPILLWQPIP Human PAP 128 DR super 0 10 2 4 0 029 0 0019 0 0014 0019 00052 00049 0019
68 0035 NPILLWQPIPVHTV Human PAP 132 DRsuper 0029 0 57 00002 0012 0 0015 00017 0070 00005 0 10
Core Total Conser-
Protein/ 1st Conser- vancy DRBl DRBl DRB5 DRBl DRBl DRBl DRBl DRBl DRBl De
Peptide. Sequence Organism Segment Position vancy % % Motif *0101 *1501 *0101 *0401 *1101 *1302 *0701 *0802 *0901 er
68 0036 NPILLWQPIPVHTVP Human PAP 133 DR super 0.16 2.6 0.0007 0.039 0.026 0.014 0.61 0 0078 0 17
68.0037 PILLWQPIPVHTVPL Human PAP 134 DR super 0.1361 1.1257 0.0311 00064
68.0038 ILLWQPIPVHTVPLS Human PAP 135 DR super 0.1175 0 1756 00518 0.0033
68.0039 WQPIPVHTVPLSEDQ Human PAP 138 DR super 0 0009 <0 0002 <0.0003 0.0013
68.0040 LSGLHGQDLFGIWSK Human PAP 194 DR super 00253 00003 <0.0003 0.0002
68.0041 YDPLYCESVHNFTLP Human PAP 10 DR super/ 0 0042 00044 00009 <0.0001 DR3
68.0042 LPSWATEDTMTKLRE Human PAP 223 DR super 0.0003 <0.0002 00084 00002
68.0043 LRELSELSLLSLYGI Human PAP 235 DR super 0.0077 00456 00393 0.0011
68.0044 LSELSLLSLYGIHKQ Human PAP 238 DR super 0.0172 0.1806 0.0053 0.0023
68.0045 LSLLSLYGIHKQKEK Human PAP 241 DR super 0.0083 0.1789 0.0018 0.0001
68.0046 KSRLQGGVLVNEILN Human PAP 255 DR super 0.0156 0.0002 <0.0003 0.0094
680047 GGVLV EILNHMKRA Human PAP 260 DR super/ 0.0042 0.0217 0.0237 0.1210 DR3
68.0048 ffSYKKLIMYSAHDT Human PAP 277 DR super 0.6438 0.4477 0.0181 0.0042
680049 YKKLΓMYSAHDTTVS Human PAP 280 DR super 0.2156 0.9144 0.0443 0 1011
68.0050 LIMYSAHDTTVSGLQ Human PAP 283 DR super 0.0014 0.0507 0.3934 00025
68 0051 DTTVSGLQMALDVYN Human PAP 290 DR super 00623 0.0072 00003 00009
68.0052 ALDVYNGLLPPYASC Human PAP 299 DR super 03874 0.0070 0 0166 00003
68 0053 LDVYNGLLPPYASCH Human PAP 300 DR super 06779 0 0026 0.0236 00002
680054 YNGLLPPYASCHLTE Human PAP 303 DR super 0 1217 00319 0.0031 0.0003
68.0055 PYPLMLPGCSPSCPL Human PAP 339 DR super 00007 0.0012 0.0005 0.0003
680056 FAELVGPVIPQDWST Human PAP 356 DR super 0.5207 <00002 0.0003 <0.0001
68 0057 PQDWSTECMTTNSHQ Human PAP 365 DR super O.0001 <00002 0.0049 0.0002
68 0058 TLSVTWIGAAPLILS Human PSA 5 DR super 2.9004 0.1003 0.0012 0.0083
68.0059 SVTWIGAAPLILSRI Human PSA 7 DR super 1.4446 0.0783 0 0044 00083
68.0060 VTWIGAAPLILSRIV Human PSA 8 DR super 08231 0 0198 0.0009 0.0025
Core
Total Conser-
Protein/ 1st Conser- vancy DRBl DRBl DRB5 DRBl DRBl DRBl DRBl DRBl DRBl De
Peptide. Sequence Organism Segment Position vancy % % Motif *0101 *1501 *0101 *0401 *1101 *1302 *0701 *0802 *0901 e
68.0061 SQPWQVLVASRGRAV Human PSA 31 DR super 0.0870 0.0008 0.0023 0 1456
68 0062 GRAVCGGVLVHPQWV Human PSA 42 DR super 0.0130 0.0008 <00003 0.0007
68.0063 GVLVHPQWVLTAAHC Human PSA 48 DR super 00719 0 1391 0.1412 0.0019
68.0064 HPQWVLTAAHCIRNK Human PSA 52 DR super 02853 0.0015 0.0114 0.0034
68.0065 QWVLTAAHCIRNKSV Human PSA 54 DR super 0.1376 0.0007 0.0009 0.0013
68.0066 AHCIRNKSVILLGRH Human PSA 60 DR super 0.0087 0.2285 0.0555 0.0377
68.0067 SVILLGRHSLFHPED Human PSA 67 DR super 0.0147 0.1046 0.0006 0.0276
68.0068 VILLGRHSLFHPEDT Human PSA 68 DR super 0.0298 0.0223 0.0012 0.0054
68.0069 GQVFQVSHSFPHPLY Human PSA 83 DR super 0.0238 0.0051 1.1475 0.0322
68 0070 VFQVSHSFPHPLYDM Human PSA 85 DR super 0.3534 0.0033 03255 0.0473
68.0071 PHPLYDMSLLKNRFL Human PSA 93 DR super 0.0048 00132 00007 0.0005
68.0072 SHDLMLLRLSEPAEL Human PSA 114 DR super 0 0181 00232 00014 0.6572 o
68.0073 HDLMLLRLSEPAELT Human PSA 115 DR super 0.0807 00294 00014 2.0129
68.0074 TDAVKVMDLPTQEPA Human PSA 129 DR super 0.0002 <0.0002 O.0001 0.0001
68.0075 AVKVMDLPTQEPALG Human PSA 131 DR super 0.0002 <0.0002 O.0001 <0.0001
68.0076 VMDLPTQEPALGTTC Human PSA 134 DR super <0.0001 0.0002 <0.0001 <0 0001
68.0077 LHVISNDVCAQVHPQ Human PSA 172 DR super/ 0.0076 0.0004 0.0175 00194 DR3
68 0078 CAQVHPQKVTKFMLC Human PSA 180 DR super 0.0011 0.0121 0.0009 0.0024
68 0079 GGPLVCNGVLQGITS Human PSA 210 DR super 0.0023 0.0003 0.1185 0.0785
68.0080 GPLVCNGVLQGITSW Human PSA 211 DR super 00050 0.0012 0.2750 00826
680081 NGVLQGITSWGSEPC Human PSA 216 DR super 00055 0.0356 0 0376 00055
680082 RPSLYTKWHYRKWI Human PSA 235 DR super 00012 0 0128 0.0353 00008
680083 PRWLCAGALVLAGGF Human PSM 18 DR super 0 1374 0 0006 <0.0004 0.0002
68.0084 LGFLFGWFKSSNEA Human PSM 35 DR super 0.6071 0.0220 0.0047 0.0005
68.0085 LDELKAENKKFLYN Human PSM 62 DR super/ 0.0066 0.0222 0.0049 0.0064 DR3
Core Total Conser-
Protein/ 1st Conser- vancy DRBl DRBl DRB5 DRBl DRBl DRBl DRBl DRBl DRBl Deg
Peptide Sequence Organism Segment Position vancy % % Motif *0101 *1501 *0101 *0401 *1101 *1302 *0701 *0802 *0901 era
68 0086 K FLYNFTQIPHLA Human PSM 70 DR super 0 0177 0 0396 0 2948 0 1991 4
68 0087 KFLYNFTQIPHLAGT Human PSM 72 DR super 0 0257 0 0437 0 0456 0 0171 4
68 0088 WKEFGLDSVELAHYD Human PSM 100 DR super/ 0 0054 0 0004 0 0842 00004 2 DR3 68 0089 LAHYDVLLSYPNKTH Human PSM 110 DR super 0 1256 0 1161 0 0077 0 0181 3
68 0090 GNEEFNTSLFEPPPP Human PSM 135 DR super 00004 <0 0001 <0 0004 0 0013 0
68 0091 NTSLFEPPPPGYENV Human PSM 140 DR super <0 0001 <0 0001 0 0008 <0 0001 0
68 0092 YENVSDΓVPPFSAFS Human PSM 151 DR super 0 0002 <0 0001 <0 0004 <0 0001 0
68 0093 VSDIVPPFSAFSPQG Human PSM 154 DR super <0 0001 0 0031 <0 0003 <0 0001 0
68 0094 VPPFSAFSPQGMPEG Human PSM 158 DR super 0 0011 <0 0002 0 0008 <0 0001 0
680095 FSAFSPQGMPEGDLV Human PSM 161 DR super 00005 <00002 0 0008 <0 0001 0
68 0096 GKVFRGNKVKNAQLA Human PSM 206 DR super 0 0083 0 0022 0 0076 00567 2 68 0097 GNKVKNAQLAGAKGV Human PSM 211 DR super 0 0034 0 0003 0 0006 0 0001 0
68 0098 PADYFAPGVKSYPDG Human PSM 231 DR super 0 0011 0 0065 0 0013 <0 0001 0
68 0099 GWNLPGGGVQRGNIL Human PSM 245 DR super 0 0008 <0 0002 <0 0003 0 0002 0
68 0100 EYAYRRGIAEAVGLP Human PSM 276 DR super 0 9961 <0 0002 0 0381 0 0022 1
68 0101 AEAVGLPSIPVHPIG Human PSM 284 DR super 0 8834 0 1429 0 0009 0 0007 2
68 0102 AVGLPSIPVHPIGYY Human PSM 286 DR super 1 0857 0 0176 0 0021 0 0030 2
68 0103 IGYYDAQKLLEKMGG Human PSM 297 DR super 0 0029 0 0055 0 0007 00009 0
68 0104 GPGFTGNFSTQKVKM Human PSM 330 DRsuper 0 0007 <0 0002 0 0010 00003 0
68 0105 TGNFSTQKYKMHIHS Human PSM 334 DR super 0 0004 0 0024 0 0096 0 0009 0
68 0106 KVKMHIHSTNEVTR1 Human PSM 341 DR super <0 0001 <00002 <0 0003 0 0001 0
68 0107 TRIYNVIGTLRGAVE Human PSM 353 DR super 0 3949 0 0057 1 4548 0 0026 2
68 0108 AEEFGLLGSTEWAEE Human PSM 423 DR super 0 0043 O 0001 0 0026 <0 0001 0
68 0109 ERGVAYINADSSIEG Human PSM 444 DR super 0 0015 0 0003 0 0016 0 0010 0
68 0110 GVAYINADSSIEGNY Human PSM 446 DR super 0 0101 0 0014 0 0547 0 0076 3
Core Total Conser-
Protein/ 1st Conser- vancy DRBl DRBl DRB5 DRBl DRBl DRBl DRBl DRBl DRBl De
Peptide Sequence Organism Segment Position vancy % % Motif *0101 *1501 *0101 *0401 *1101 *1302 *0701 *0802 *0901 era
68 0111 DSSIEGNYTLRVDCT Human PSM 453 DR super 00005 00077 00024 04910 1
68 0112 NYTLRVDCTPLMYSL Human PSM 459 DR super/ 00024 00020 0 8167 03464 DR3
680113 CTPLMYSLVHNLTKE Human PSM 466 DR super 00450 00217 00326 00151
68 0114 DFEVFFQRLGIASGR Human PSM 520 DR super 00465 00010 00372 00004 1
680115 EVFFQRLGIASGRAR Human PSM 522 DR super 02315 00029 03827 00002
680116 TNKFSGYPLYHSVYE Human PSM 5 3 DR super 00026 00186 00015 00001 1
680117 YDPMFKYHLTVAQVR Human PSM 566 DR super 1 0795 o oosi 04387 00044
680118 DPMFKYHLTVAQVRG Human PSM 567 DR super 09479 00424 0 9194 00080
680119 MFKYHLTVAQVRGGM Human PSM 569 DR super 06395 00062 04702 00025
680120 YHLTVAQVRGGMVF Human PSM 571 DR super 00646 00081 00100 00188
680121 VAQVRGGMVFELANS Human PSM 576 DR super 00478 00804 00130 00009 68 0122 RGGMVFELANSrVLP Human PSM 580 DR super/ 06223 00981 00350 1 6407 DR3
680123 GMVFELANSΓVLPFD Human PSM 582 DR super 07165 00976 00347 02378
680124 VFELANSIV PFDCR Human PSM 584 DR super 03050 00197 00081 0 1282
68 0125 ADKIYSISMKHPQEM Human PSM 608 DR super 00003 00009 00015 00008
680126 IYSISMKHPQEMKTY Human PSM 611 DR super 00014 00018 00005 <00001
680127 PQEM TYSVSFDSLF Human PSM 619 DR super 00004 00101 00048 00002 1
68 0128 TYSVSFDSLFSAVKN Human PSM 62 DR super/ 00354 00031 0 1139 00006 2 DR3
680129 VKNFTEIASKFSERL Human PSM 636 DR super 00036 00014 00050 <0 0001
68 0130 VLRMMNDQLMFLERA Human PSM 660 DR super/ 00878 00677 02804 00239 DR3
68 0131 LRMMNDQLMFLERAF Human PSM 661 DR super 00037 00057 00208 00027
680132 YRHVIYAPSSHNKYA Human PSM 687 DR super 00404 00110 00287 00007
68 0133 RHVIYAPSSHNKYAG Human PSM 688 DR super 00051 00069 00195 00004 1
68 0134 RQIYVAAFTVQAAAE Human PSM 730 DR super 26553 00471 56034 00151
68 0135 QIYVAAFTVQAAAET Human PSM 731 DR super 4 8432 00387 8 9131 00080
Core
Total Conser¬
Protein/ 1st Conservancy DRBl DRBl DRB5 DRBl DRBl DRBl DRBl DRBl DRBl Deg
Peptide. Sequence Organism Segment Position vancy % % Motif *0101 *1501 *0101 *0401 *1101 *1302 *0701 *0802 *0901 era
68.0136 VAAFTVQAAAETLSE Human PSM 734 DR super 0.4271 0.0005 0.1482 0.0092 3
GGKWSKSSΓVGWPAI HΓV NEF 2 8 31 DRsuper
SRDLEKHGAITSSNT HΓV NEF 50 20 20 DRsuper
HGAΓΓSSNTAATNAD HIV NEF 61 16 20 DRsuper
GFPVRPQVPLRPMTY HΓV NEF 93 56 75 DRsuper
RPQVPLRPMTYKGAF HΓV NEF 98 11 73 DRsuper
RQDILDLWVYHTQGY HIV NEF 182 14 53 DRsuper
RQEILDLWVYHTQGF HIV NEF 182 16 53 DRsuper
RQEILDLWVYHTQGY HΓV EF 182 19 53 DRsuper
RQDILDLWVYNTQGY HΓV NEF 182 8 30 DRsuper
ILDLWVYHTQGYFPD HΓV NEF 186 33 33 DRsuper
ILDLWVYHTQGFFPD HΓV NEF 186 20 20 DRsuper
FPDWQNYTPGPGIRY HIV NEF 200 23 83 DRsuper
FPDWQNYTPGPGTRF HΓV NEF 200 20 83 DRsuper
GPGIRYPLTFGWCF HΓV NEF 210 9 20 DRsuper
RFPLTFGWCFKLVPV HΓV NEF 216 19 61 DRsuper
RYPLTFGWCFKLVPV HΓV NEF 216 24 61 DRsuper
TFGWCFKLVPVDPRE HΓV NEF 222 11 41 DRsuper
NNCLLHPMSQHGMDD HΓV NEF 254 9 27 DRsuper
NNSLLHPICQHGMED HIV NEF 254 6 25 DRsuper
LKAVRIIKILYQSNP HΓV REV 13 9 25 DRsuper
KFLYQSNPPPSPEG HΓV REV 21 6 28 DRsuper
AEPVPLQLPPLERLT HΓV REV 72 16 56 DRsuper
PVPLQLPPLERLTLD HΓV REV 74 20 56 DRsuper
LEPWNHPGSQPKTAC HΓV TAT 11 17 23 DRsuper
Core
Total Conser
Protein/ 1st Conser vancy DRBl DRBl DRB5 DRBl DRBl DRBl DRBl DRBl DRBl Deg
Peptide Sequence Organism Segment Position vancy % % Motif *0101 1501 *0101 *0401 *1101 *1302 *0701 *0802 *0901 era
LEPWKHPGSQPKTAC HΓV TAT 11 17 20 DRsuper
LEPWNHPGSQPTTAC HΓV TAT 11 π 16 DRsuper
LEPWNHPGSQPRTPC HIV TAT 11 5 13 DRsuper
NNCYCKKCCFHCQVC HIV TAT 26 6 17 DRsuper
TNCYCKKCCYHCQVC HΓV TAT 26 3 17 DRsuper
QVCFLNKGLGISYGR HΓV TAT 38 6 22 DRsuper
QVCFITKGLGISYGR HΓV TAT 38 11 14 DRsuper
QLCFLKKGLGISYGR HΓV TAT 38 5 11 DRsuper
68 0023 LFFWLDRSVLAKEL Human PAP 21 DR3a 1 9 027 022 3 6 0 15 0 15 020 044 0 17 9
DR super
680027 IDTFPTDPIKESSWP Human PAP 50 DR3a
DR super
OJ 680041 YDPLYCESVHNFTLP Human PAP 210 DR3a/ 00042 0 0044 0 0009 <00001 0
DR super
*" 680047 GGVLVNEILNHMKRA Human PAP 260 DR3a/ 00042 0 0217 0 0237 0 1210 2
DR super
680077 LHVISNDVCAQVHPQ Human PSA 172 DR3a/ 00076 00004 00175 00194 2
DR super
68 0085 LDELKAENKKFLYN Human PSM 62 DR3a/ 00066 00222 0 0049 00064 3
DR super
68 0088 WKEFGLDSVELAHYD Human PSM 100 DR3a 00054 0 0004 0 0842 00004 2
DR super
680112 NYTLRVDCTPLMYSL Human PSM 459 DR3a 00024 0 0020 0 8167 03464 2
DR super
68 0122 RGGMVFELANSΓVLP Human PSM 580 DR3a 06223 0 0981 0 0350 1 6407 3
DR super
68012 TYSVSFDSLFSAVKN Human PSM 624 DR3a/ 00354 0 0031 0 1139 00006 2
DR super
68 0130 VLRMMNDQLMFLERA Human PSM 660 DR3a/ 00878 0 0677 02804 00239 4
DR super
680137 HNLFEPEDTGQRVPV Human Kallιkrem2 78 DR3a
680138 HQSLRPDEDSSHDLM Human Kallιkrem2 108 DR3a
680139 WGSIEPEEFLRPRSL Human Kallιkreιn2 157 DR3a
680140 LHLLSNDMCARAYSE Human Kallιkrem2 176 DR3a
Core
Total Conser¬
Protein/ 1st Conservancy DRBl DRBl DRB5 DRBl DRBl DRBl DRBl DRBl DRBl De
Peptide. Sequence Organism Segment Position vancy % % Motif *0101 *1501 *0101 *0401 *1101 *1302 *0701 *0802 *0901 era
68.0141 RSVLAKELKFVTLVF Human PAP 28 DR3b
68.0142 LTQLGMEQHYELGEY Human PAP 70 DR3b
68.0143 YRKFLNESYKHEQVY Human PAP 89 DR3a
68.0144 RKFLNESYKHEQVYI Human PAP 90 DR3b
68.0145 NESYKHEQVYIRSTD Human PAP 94 DR3a
68.0146 AALFPPEGVSIWNPI Human PAP 121 DR3a
68.0147 TVPLSEDQLLYLPFR Human PAP 145 DR3a
68.0148 FQELESETLKSEEFQ Human PAP 164 DR3a
68.0149 SETLKSEEFQKRLHP Human PAP 169 DR3a
68.0150 DPLYCESVHNFTLPS Human PAP 211 DR3b
68.0151 KKLIMYSAHDTTVSG Human PAP 281 DR3b
68.0152 GLQMALDVYNGLLPP Human PAP 295 DR3a
68.0153 LTELYFEKGEYFVEM Human PAP 315 DR3a
68.0154 KGEYFVEMYYRNETQ Human PAP 322 DR3a
68.0155 EMYYRNETQHEPYPL Human PAP 328 DR3a
68.0156 GPVIPQDWSTECMTT Human PAP 361 DR3a
68.0157 TECMTTNSHQGTEDS Human PAP 370 DR3b
68.0158 HSLFHPEDTGQVFQV Human PSA 74 DR3a
68.0159 WGSIEPEEFLTPKKL Human PSA 153 DR3a
68.0160 SNDVCAQVHPQKVTK Human PSA 176 DR3b
68.0161 MWNLLHETDSAVATA Human PSM' 1 DR3a
68.0162 TDSAVATARRPRWLC Human PSM 8 DR3b
68.0163 MKAFLDELKAEN1KK Human PSM 58 DR3b
68.0164 AKQIQSQWKEFGLDS Human PSM 93 DR3b
68.0165 YISIINEDGNEIFNT Human PSM 127 DR3a
Core
Total Conser¬
Protein/ 1st Conservancy DRBl DRBl DRB5 DRBl DRBl DRBl DRBl DRBl DRBl De
Peptide Sequence Organism Segment Position vancy % % Motif *0101 *1501 *0101 *0401 *1101 *1302 *0701 *0802 *0901 er
68 0166 ISIINEDGNEIFNTS Human PSM 128 DR3a
68 0167 EDFFKLERDMKINCS Human PSM 183 DR3a
68 0168 FFKLERDMKINCSGK Human PSM 185 DR3b
680169 DMKINCSGKΓVIARY Human PSM 191 DR3b
68 0170 GVILYSDPADYFAPG Human PSM 224 DR3a
680171 IYNVIGTLRGAVEPD Human PSM 355 DR3b
68 0172 RGAVEPDRYVILGGH Human PSM 363 DR3a
68 0173 GAAWHEΓVRSFGTL Human PSM 391 DR3a
680174 FGTLKKEGWRPRRTI Human PSM 402 DR3a
68.0175 TEWAEENSRLLQERG Human PSM 432 DR3b
68.0176 NSRLLQERGVAYΓNA Human PSM 438 DR3a
680177 VAYINADSSIEGNYT Human PSM 447 DR3a
68 0178 VHNLTKELKSPDEGF Human PSM 474 DR3b
680179 SΓVLPFDCRDYAWL Human PSM 590 DR3b
68 0180 DKIYSISMKHPQEMK Human PSM 609 DR3b
68.0181 DQLMFLERAFIDPLG Human PSM 666 DR3a
68.0182 HVIYAPSSHNKYAGE Human PSM 689 DR3b
680183 HNKYAGESFPGIYDA Human PSM 697 DR3a
680184 DALFDIESKVDPSKA Human PSM 710 DR3b
68 0185 PSKAWGEVKRQIYVA Human PSM 721 DR3b
QDAVSQDLDKCGAAA HIV NEF 51 2 100 DR3a
LSHFLKEKGGLEGLI HΓV NEF 114 23 47 DR3a
LSFFLKEKGGLDGLI HΓV NEF 114 22 41 DR3a
TQGYFPDWQNYTPGP HΓV NEF 195 52 56 DR3a
TQGFFPDWQNYTPGP HTV NEF 195 27 27 DR3a
Table 31
Class II motif bearing peptides for HIV regulatory proteins core core
HLA protein % cons. # aa position sequence position 9 sequence conservation
DR3a NEF 2 15 51 QDAvsqdldkcgAAA 54 VSQDLDKCG 100
DRsuper NEF 23 15 200 FPDwqnytpgpglRY 204 WQNYTPGPG 83
DRsuper NEF 20 15 200 FPDwqnytpgpgTRF 204 WQNYTPGPG 83
DRsuper NEF 56 15 93 GFPv qvplrpMTY 97 VRPQVPLRP 75
DRsuper NEF 11 15 98 RPQvplrpmtykGAF 101 VPLRPMTYK 73
DRsuper NEF 19 15 216 RFPltfgwcfklVPV 221 LTFGWCFKL 61
DRsuper NEF 24 15 216 RYPltfgwcfklVPV 221 LTFGWCFKL 61
DR3a NEF 52 15 195 TQGyfpdwqnytPGP 199 YFPDWQNYT 56
DRsuper NEF 14 15 182 RQDildlwvyhtQGY 186 ILDLWVYHT 53
DRsuper NEF 16 15 182 RQEildlwvyhtQGF 186 ILDLWVYHT 53
DRsuper NEF 19 15 182 RQEildlwvyhtQGY 186 ILDLWVYHT 53
DR3a NEF 23 15 114 LSHflkekggleGLI 117 FLKEKGGLE 47
DR3a NEF 22 15 114 LSFflkekggldGLI 117 FLKEKGGLD 41
DRsuper NEF 11 15 222 TFGwcfklvpvdPRE 225 WCFKLVPVD 41
DRsuper NEF 33 15 186 ILDlwvyhtqgyFPD 190 LWVYHTQGY 33
DRsuper NEF 8 15 2 GGKwskssivgwPAI 5 WSKSSIVGW 31
DRsuper NEF 8 15 182 RQDildlwvyntQGY 186 ILDLWVYNT 30
DR3b NEF 17 15 171 LDGliyskkrqeILD 174 LIYSKKRQE 28
DR3a NEF 27 15 195 TQGffpdwqnytPGP 199 FFPDWQNYT 27
DRsuper NEF 9 15 254 NNCllhpmsqhgMDD 257 LLHPMSQHG 27
DRsuper NEF 6 15 254 NNSllhpicqhgMED 257 LLHPICQHG 25
DRsuper NEF 9 15 210 GPGirvpltfgwCFK 214 IRYPLTFGW 20
DRsuper NEF 16 15 61 HGAitssntaatNAD 64 ITSSNTAAT 20
DRsuper NEF 20 15 50 SRDlekhgaitsSNT 58 LEKHGAITS 20
DRsuper NEF 20 15 186 ILDlwvyhtqgfFPD 190 LWVYHTQGF 20
DR3b REV 28 15 38 TRQarrnrrrrwRAR 41 ARRNRRRRW 61
DR3b REV 19 15 38 TRQarrnrrrrwRER 41 ARRNRRRRW 61
DRsuper REV 20 15 74 PVPlqlpplerlTLD 77 LQLPPLERL 56
DRsuper REV 16 15 72 AEPvplqlppleRLT 75 VPLQLPPLE 56
DR3b REV 20 15 38 TRQarknrrrrwRAR 41 ARKNRRRRW 28
DRsuper REV 6 15 21 IKFlyqsnpppsPEG 24 LYQSNPPPS 28
DRsuper REV 9 15 13 LKAvriikilyqSNP 18 VRIIKILYQ 25
DRsuper TAT 17 15 11 LEPwnhpgsqpkTAC 14 WNHPGSQPK 23
DRsuper TAT 6 15 38 QVCflnkglgisYGR 41 FLNKGLGIS 22
DRsuper TAT 17 15 11 LEPwkhpgsqpkTAC 14 WKHPGSQPK 20
DR3a TAT 2 15 95 KEKveretetdpAVQ 98 VERETETDP 17 DRsuper TAT 6 15 26 NNCyckkccfhcQVC 29 YCKKCCFHC 17
DRsuper TAT 3 15 26 TNCyckkccyhcQVC 29 YCKKCCYHC 17
DRsuper TAT 11 15 11 LEPwnhpgsqptTAC 14 WNHPGSQPT 16
DRsuper TAT 11 15 38 QVCfitkglgisYGR 41 FITKGLGIS 14
DRsuper TAT 5 15 11 LEPwnhpgsqprTPC 14 WNHPGSQPR 13
DRsuper TAT 5 15 38 QLCflkkglgisYGR 41 FL KGLGIS 11

Claims

WHAT IS CLAIMED IS:
1. A composition comprising at least one peptide, the peptide comprising an isolated, prepared epitope consisting of a sequence selected from the group consisting of the sequences listed in Tables 2-31.
2. A composition of claim 1, wherein the epitope is joined to an amino acid linker.
3. A composition of claim 1, wherein the epitope is admixed or joined to a CTL epitope.
4. A composition of claim 1, wherein the epitope is admixed or joined to an HTL epitope.
5. A composition of claim 4, wherein the HTL epitope is a pan-DR binding molecule.
6. A composition of claim 1, further comprising a liposome,* wherein the epitope is on or within the liposome.
7. A composition of claim 1, wherein the epitope is joined to a lipid.
8. A composition of claim 1 , wherein the epitope is a heteropolymer.
9. A composition of claim 1, wherein the epitope is a homoplymer.
10. A composition of claim 1 , wherein the epitope is bound to an HLA heavy chain, β2-microglobulin, and strepavidin complex, whereby a tetramer is formed.
11. A composition of claim 1, further comprising an antigen presenting cell, wherein the epitope is on or within the antigen presenting cell.
12. A composition of claim 11, wherein the epitope is bound to an HLA molecule on the antigen presenting cell, whereby when an A2-restricted cytotoxic lymphocyte (CTL) is present, a receptor of the CTL binds to a complex of the HLA molecule and the epitope.
13. A composition of claim 11, wherein the antigen presenting cell is a dendritic cell.
14. A method of inducing a cytotoxic T cell response against a preselected antigen in a patient expressing a specific MHC class I allele, the method comprising contacting cytotoxic T cells from the patient with a composition comprising an immunogenic peptide selected from the group consisting of the peptides listed in Tables 2-31.
15. An isolated nucleic acid comprising a nucleic acid sequence encoding a polyepitopic construct comprising at least one peptide selected from the peptides listed in Tables 2-31.
EP01274676A 2000-10-19 2001-10-18 Hla class i and ii binding peptides and their uses Withdrawn EP1455816A4 (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
EP07023116A EP1911461B1 (en) 2000-10-19 2001-10-18 HLA class I and II binding peptides and their uses

Applications Claiming Priority (5)

Application Number Priority Date Filing Date Title
US24235000P 2000-10-19 2000-10-19
US242350P 2000-10-19
US28562401P 2001-04-20 2001-04-20
US285624P 2001-04-20
PCT/US2001/051650 WO2003040165A2 (en) 2000-10-19 2001-10-18 Hla class i and ii binding peptides and their uses

Related Child Applications (1)

Application Number Title Priority Date Filing Date
EP07023116A Division EP1911461B1 (en) 2000-10-19 2001-10-18 HLA class I and II binding peptides and their uses

Publications (2)

Publication Number Publication Date
EP1455816A2 true EP1455816A2 (en) 2004-09-15
EP1455816A4 EP1455816A4 (en) 2007-03-28

Family

ID=26935024

Family Applications (2)

Application Number Title Priority Date Filing Date
EP01274676A Withdrawn EP1455816A4 (en) 2000-10-19 2001-10-18 Hla class i and ii binding peptides and their uses
EP07023116A Expired - Lifetime EP1911461B1 (en) 2000-10-19 2001-10-18 HLA class I and II binding peptides and their uses

Family Applications After (1)

Application Number Title Priority Date Filing Date
EP07023116A Expired - Lifetime EP1911461B1 (en) 2000-10-19 2001-10-18 HLA class I and II binding peptides and their uses

Country Status (5)

Country Link
EP (2) EP1455816A4 (en)
AT (1) ATE536187T1 (en)
AU (1) AU2001298049A1 (en)
CA (1) CA2425648A1 (en)
WO (1) WO2003040165A2 (en)

Families Citing this family (67)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
AU2002227406A1 (en) * 2000-12-13 2002-06-24 Argonex Pharmaceuticals Mhc class i associated peptides for prevention and treatment of tuberculosis
WO2003008537A2 (en) * 2001-04-06 2003-01-30 Mannkind Corporation Epitope sequences
US20060222656A1 (en) 2005-04-01 2006-10-05 University Of Maryland, Baltimore MAGE-A3/HPV 16 peptide vaccines for head and neck cancer
US7049413B2 (en) * 2001-05-18 2006-05-23 Ludwig Institute For Cancer Research MAGE-A3 peptides presented by HLA class II molecules
WO2002094994A2 (en) 2001-05-18 2002-11-28 Mayo Foundation For Medical Education And Research Chimeric antigen-specific t cell-activating polypeptides
ES2606537T3 (en) 2001-10-23 2017-03-24 Psma Development Company L.L.C. Antibodies against PSMA
US20050215472A1 (en) 2001-10-23 2005-09-29 Psma Development Company, Llc PSMA formulations and uses thereof
EP1670509A4 (en) * 2003-09-03 2007-10-31 Dendritherapeutics Inc Multiplex vaccines
IL157772A (en) * 2003-09-04 2016-06-30 Bmr Solutions Ltd Compositions comprising an oligopeptide derived from tortoise spleen for use in stimulating mammalian hemopoiesis
WO2005037855A2 (en) * 2003-10-17 2005-04-28 Pecos Labs, Inc. T cell epitopes useful in a yersinia pestis vaccine and as diagnostic tools and methods for identifying same
CA2552508A1 (en) * 2003-12-31 2005-09-29 Pharmexa Inc. Inducing cellular immune responses to human papillomavirus using peptide and nucleic acid compositions
GB0406054D0 (en) * 2004-03-17 2004-04-21 Univ Nottingham Trent Prostatic acid phosphatase antigens
GB0408164D0 (en) 2004-04-13 2004-05-19 Immune Targeting Systems Ltd Antigen delivery vectors and constructs
GB0716992D0 (en) 2007-08-31 2007-10-10 Immune Targeting Systems Its L Influenza antigen delivery vectors and constructs
WO2005105993A1 (en) * 2004-04-30 2005-11-10 Nec Corporation Hla-binding peptide, precursor thereof, dna fragment encoding the same and recombinant vector
JP4731867B2 (en) 2004-10-01 2011-07-27 国立大学法人三重大学 Method for inducing CD8 positive cytotoxic T lymphocytes
DE102004049223A1 (en) 2004-10-08 2006-04-20 Johannes-Gutenberg-Universität Mainz Preparation for vaccination, vaccination and use of a vaccine preparation
EP1709971A1 (en) * 2005-04-06 2006-10-11 Ganymed Pharmaceuticals AG Peptide antigens useful for the prophylaxis, treatment and diagnosis of poxvirus infections
CA2612494A1 (en) * 2005-06-17 2006-12-28 Mannkind Corporation Epitope analogues
BRPI0504117A (en) 2005-09-05 2007-05-22 Fundacao De Amparo A Pesquisa epitopes, combination of epitopes, uses of epitopes or their combination, composition, uses of composition, anti-HIV-1 prophylactic vaccines, therapeutic vaccines, method for identifying epitopes and methods for treatment or prevention.
ATE461216T1 (en) * 2006-01-25 2010-04-15 Viro Pharmaceuticals Gmbh & Co HUMAN VIRAL INFECTION AMPLIFIER (SEVI) AND ITS APPLICATION
WO2007097561A1 (en) 2006-02-20 2007-08-30 Ewha University - Industry Collaboration Foundation Peptide having cell membrane penetrating activity
EP1840133A1 (en) * 2006-03-29 2007-10-03 Global Biotech Development Corp. Ltd. New immunomodulating oligopeptides
US20080107668A1 (en) * 2006-08-30 2008-05-08 Immunotope, Inc. Cytotoxic t-lymphocyte-inducing immunogens for prevention, treatment, and diagnosis of cancer
EP2091965B9 (en) * 2006-10-17 2013-09-25 Oncotherapy Science, Inc. Peptide vaccines for cancers expressing mphosph1 or depdc1 polypeptides
US20090117140A1 (en) * 2007-09-26 2009-05-07 Mayumi Nakagawa Human papilloma virus dominant CD4 T cell epitopes and uses thereof
WO2009067584A1 (en) * 2007-11-20 2009-05-28 Duke University Methods and compositions for modulating drug-polymer architecture, pharmacokinetics and biodistribution
EP2227486B1 (en) * 2007-11-20 2017-03-08 Vianex S.A. Peptide analogues and conjugates thereof
AU2008338063B2 (en) * 2007-12-19 2013-03-14 Rhovac Aps RhoC-based immunotherapy
US20100166782A1 (en) * 2008-07-25 2010-07-01 Martha Karen Newell Clip inhibitors and methods of modulating immune function
US8975086B2 (en) 2008-08-28 2015-03-10 Oncotherapy Science, Inc. Method for treating or preventing bladder cancer using the DEPDC1 polypeptide
EP2334318B1 (en) 2008-10-06 2016-02-10 Yissum Research Development Company of The Hebrew University of Jerusalem Ltd. Hiv-1 integrase derived stimulatory peptides interfering with integrase - rev protein binding
EP2391635B1 (en) 2009-01-28 2017-04-26 Epimmune Inc. Pan-dr binding polypeptides and uses thereof
JP5317336B2 (en) * 2009-02-23 2013-10-16 国立大学法人東北大学 Peptide for evaluation, artificial standard protein, and protein quantification method for protein quantification using mass spectrometer
BRPI0924827A2 (en) * 2009-04-02 2019-01-08 Vaxon Biotech identification, optimization and use of hla-a24 cryptic epitopes for immunotherapy
US8431530B2 (en) * 2009-06-12 2013-04-30 Morehouse School Of Medicine Compositions and methods for treating aids or cancer by inhibiting the secretion of microparticles
US9023802B2 (en) * 2009-12-14 2015-05-05 Immatics Biotechnologies Gmbh HLA-binding peptides derived from prostate-associated antigenic molecules and methods of use thereof
JP5564730B2 (en) 2011-08-12 2014-08-06 オンコセラピー・サイエンス株式会社 MPHOSPH1 peptide and vaccine containing the same
GB201300683D0 (en) * 2013-01-15 2013-02-27 Apitope Int Nv Peptide
US10364451B2 (en) 2013-05-30 2019-07-30 Duke University Polymer conjugates having reduced antigenicity and methods of using the same
US10392611B2 (en) 2013-05-30 2019-08-27 Duke University Polymer conjugates having reduced antigenicity and methods of using the same
US10272144B2 (en) 2013-07-31 2019-04-30 Bioventures, Llc Compositions for and methods of treating and preventing targeting tumor associated carbohydrate antigens
DK3140317T3 (en) 2014-05-09 2020-07-20 Univ Southampton PEPTIDE-INDUCED NK CELL ACTIVATION
WO2016154530A1 (en) 2015-03-26 2016-09-29 Duke University Targeted therapeutic agents comprising multivalent protein-biopolymer fusions
IL254129B2 (en) 2015-03-27 2023-10-01 Immatics Biotechnologies Gmbh Novel peptides and combination of peptides for use in immunotherapy against various tumors
GB201505305D0 (en) 2015-03-27 2015-05-13 Immatics Biotechnologies Gmbh Novel Peptides and combination of peptides for use in immunotherapy against various tumors
US11155585B2 (en) * 2015-07-09 2021-10-26 Intervacc Ab Vaccine against S. suis infection
US11458205B2 (en) 2015-08-04 2022-10-04 Duke University Genetically encoded intrinsically disordered stealth polymers for delivery and methods of using same
GB201513921D0 (en) * 2015-08-05 2015-09-23 Immatics Biotechnologies Gmbh Novel peptides and combination of peptides for use in immunotherapy against prostate cancer and other cancers
WO2017026503A1 (en) 2015-08-12 2017-02-16 オンコセラピー・サイエンス株式会社 Depdc1-derived peptide and vaccine containing same
CN108699111B (en) 2015-10-08 2022-11-01 肿瘤疗法科学股份有限公司 MPHOSPH 1-derived peptides and vaccines containing the same
GB201520570D0 (en) * 2015-11-23 2016-01-06 Immunocore Ltd & Adaptimmune Ltd Peptides
US11752213B2 (en) 2015-12-21 2023-09-12 Duke University Surfaces having reduced non-specific binding and antigenicity
WO2017210476A1 (en) 2016-06-01 2017-12-07 Duke University Nonfouling biosensors
WO2018053201A1 (en) 2016-09-14 2018-03-22 Duke University Triblock polypeptide-based nanoparticles for the delivery of hydrophilic drugs
KR20190064600A (en) 2016-09-23 2019-06-10 듀크 유니버시티 Unstructured non-repetitive polypeptides with LCST behavior
CA3042703A1 (en) * 2016-11-07 2018-05-11 The United States Of America, As Represented By The Secretary, Department Of Health And Human Services Development of agonist epitopes of the human papillomavirus
WO2018132732A1 (en) 2017-01-12 2018-07-19 Duke University Genetically encoded lipid-polypeptide hybrid biomaterials that exhibit temperature triggered hierarchical self-assembly
WO2018187356A2 (en) * 2017-04-03 2018-10-11 Neon Therapeutics, Inc. Protein antigens and uses thereof
US11554097B2 (en) 2017-05-15 2023-01-17 Duke University Recombinant production of hybrid lipid-biopolymer materials that self-assemble and encapsulate agents
US11680083B2 (en) 2017-06-30 2023-06-20 Duke University Order and disorder as a design principle for stimuli-responsive biopolymer networks
TW202019955A (en) 2018-07-31 2020-06-01 德商英麥提克生物技術股份有限公司 Immunotherapy with b*07 restricted peptides and combination of peptides against cancers and related methods
WO2020028806A1 (en) 2018-08-02 2020-02-06 Duke University Dual agonist fusion proteins
US11512314B2 (en) 2019-07-12 2022-11-29 Duke University Amphiphilic polynucleotides
AU2020315981A1 (en) * 2019-07-24 2022-02-17 Agenus Inc. Antigenic polypeptides and methods of use thereof
NL2030990B1 (en) * 2022-02-17 2023-09-01 Academisch Ziekenhuis Leiden T cell receptors directed against jchain and uses thereof
CN117285597B (en) * 2023-11-27 2024-01-26 中国科学院烟台海岸带研究所 Pentapeptide KK5 with uric acid reducing function and application thereof

Citations (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO1999027954A2 (en) * 1997-12-03 1999-06-10 Institut National De La Sante Et De La Recherche Medicale (Inserm) Mixed lipopeptide micelles for inducing an immune response

Family Cites Families (21)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US4235871A (en) 1978-02-24 1980-11-25 Papahadjopoulos Demetrios P Method of encapsulating biologically active materials in lipid vesicles
US4722848A (en) 1982-12-08 1988-02-02 Health Research, Incorporated Method for immunizing animals with synthetically modified vaccinia virus
US4501728A (en) 1983-01-06 1985-02-26 Technology Unlimited, Inc. Masking of liposomes from RES recognition
US5019369A (en) 1984-10-22 1991-05-28 Vestar, Inc. Method of targeting tumors in humans
US4690915A (en) 1985-08-08 1987-09-01 The United States Of America As Represented By The Department Of Health And Human Services Adoptive immunotherapy as a treatment modality in humans
US4844893A (en) 1986-10-07 1989-07-04 Scripps Clinic And Research Foundation EX vivo effector cell activation for target cell killing
US4837028A (en) 1986-12-24 1989-06-06 Liposome Technology, Inc. Liposomes with enhanced circulation time
US5703055A (en) 1989-03-21 1997-12-30 Wisconsin Alumni Research Foundation Generation of antibodies through lipid mediated DNA delivery
ATE342730T1 (en) 1992-08-07 2006-11-15 Pharmexa Inc HLA BINDING PEPTIDES AND THEIR USES
BR9406652A (en) 1993-03-05 1996-09-10 Cytel Corp Composition
US5804566A (en) 1993-08-26 1998-09-08 The Regents Of The University Of California Methods and devices for immunizing a host through administration of naked polynucleotides with encode allergenic peptides
US5679647A (en) 1993-08-26 1997-10-21 The Regents Of The University Of California Methods and devices for immunizing a host against tumor-associated antigens through administration of naked polynucleotides which encode tumor-associated antigenic peptides
AU698962B2 (en) 1993-09-14 1998-11-12 Epimmune, Inc. Alteration of immune response using pan DR-binding peptides
US5739118A (en) 1994-04-01 1998-04-14 Apollon, Inc. Compositions and methods for delivery of genetic material
US5736524A (en) 1994-11-14 1998-04-07 Merck & Co.,. Inc. Polynucleotide tuberculosis vaccine
US5922687A (en) 1995-05-04 1999-07-13 Board Of Trustees Of The Leland Stanford Junior University Intracellular delivery of nucleic acids using pressure
US6019974A (en) 1996-01-26 2000-02-01 Emory University SPE-4 peptides
CA2262006A1 (en) 1996-07-26 1998-02-05 Sloan-Kettering Institute For Cancer Research Method and reagents for genetic immunization
US6128946A (en) 1997-06-26 2000-10-10 Crane Nuclear, Inc. Method and apparatus for on-line detection of leaky emergency shut down or other valves
AU6226100A (en) 1999-07-19 2001-04-24 Epimmune, Inc. Inducing cellular immune responses to hepatitis c virus using peptide and nucleic acid compositions
US7026443B1 (en) 1999-12-10 2006-04-11 Epimmune Inc. Inducing cellular immune responses to human Papillomavirus using peptide and nucleic acid compositions

Patent Citations (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO1999027954A2 (en) * 1997-12-03 1999-06-10 Institut National De La Sante Et De La Recherche Medicale (Inserm) Mixed lipopeptide micelles for inducing an immune response

Non-Patent Citations (2)

* Cited by examiner, † Cited by third party
Title
HADIDA F ET AL: "CARBOXYL-TERMINAL AND CENTRAL REGIONS OF HUMAN IMMUNODEFICIENCY VIRUS-1 NEF RECOGNIZED BY CYTOTOXIC T LYMPHOCYTES FROM LYMPHOID ORGANS AN IN-VITRO LIMITING DILUTION ANALYSIS" JOURNAL OF CLINICAL INVESTIGATION, vol. 89, no. 1, 1992, pages 53-60, XP002406423 ISSN: 0021-9738 *
See also references of WO03040165A2 *

Also Published As

Publication number Publication date
WO2003040165A3 (en) 2004-06-24
CA2425648A1 (en) 2002-04-19
AU2001298049A8 (en) 2005-11-03
ATE536187T1 (en) 2011-12-15
EP1911461B1 (en) 2011-12-07
WO2003040165A2 (en) 2003-05-15
EP1455816A4 (en) 2007-03-28
EP1911461A2 (en) 2008-04-16
EP1911461A3 (en) 2008-07-16
AU2001298049A1 (en) 2003-05-19

Similar Documents

Publication Publication Date Title
EP1911461B1 (en) HLA class I and II binding peptides and their uses
EP1917970B1 (en) Hla binding peptides and their uses
JP3908271B2 (en) HLA-A2.1 binding peptides and their use
US9340577B2 (en) HLA binding motifs and peptides and their uses
US7252829B1 (en) HLA binding peptides and their uses
AU725550B2 (en) HLA binding peptides and their uses
US6689363B1 (en) Inducing cellular immune responses to hepatitis B virus using peptide and nucleic acid compositions
US20060079453A1 (en) Hla binding peptides and their uses
CA2248667C (en) Hla-a2.1 binding peptides and their uses
CA2422506A1 (en) Inducing cellular immune responses to hepatitis b virus using peptide and nucleic acid compositions
US20100068228A1 (en) Inducing Cellular Immune Responses to Hepatitis B Virus Using Peptide and Nucleic Acid Compositions
US20020098197A1 (en) Hla binding peptides and their uses
US20030152580A1 (en) Hla binding peptides and their uses
EP1263775A1 (en) Hla binding peptides and their uses
US20020177694A1 (en) Hla binding peptides and their uses
US20040096445A1 (en) Subunit vaccines with A2 supermotifs
WO1999065522A1 (en) Hla binding peptides and their uses
EP1320377A1 (en) Hla binding peptides and their uses
AU4754899A (en) HLA Binding peptides and their uses

Legal Events

Date Code Title Description
PUAI Public reference made under article 153(3) epc to a published international application that has entered the european phase

Free format text: ORIGINAL CODE: 0009012

17P Request for examination filed

Effective date: 20030519

AK Designated contracting states

Kind code of ref document: A2

Designated state(s): AT BE CH CY DE DK ES FI FR GB GR IE IT LI LU MC NL PT SE TR

AX Request for extension of the european patent

Extension state: AL LT LV MK RO SI

A4 Supplementary search report drawn up and despatched

Effective date: 20070226

17Q First examination report despatched

Effective date: 20070529

RAP1 Party data changed (applicant data changed or rights of an application transferred)

Owner name: PHARMEXA INC.

STAA Information on the status of an ep patent application or granted ep patent

Free format text: STATUS: THE APPLICATION IS DEEMED TO BE WITHDRAWN

18D Application deemed to be withdrawn

Effective date: 20071211