IE904161A1 - Nonreplicating recombinant-made retroviral particles useful¹as anti-viral agents and as immunogens for prophylaxis and¹therapy against human retroviruses - Google Patents

Abstract

The present invention relates to the process for production of retroviral particles rendered non- replicative, characterized by comprising: (a) introduction of nucleotide sequences which code for the proteins of the retroviral envelope, protease and core, in a mammalian host cell; (b) co-expression of the proteins of the mature retroviral envelope and core in the mammalian host cell; (c) culturing of the mammalian host cell; and (d) recovery of the retroviral particles rendered recombinant and non-replicative, from the culture medium. [PT95939A]

Description

Introduction.....................................

Background of the Invention...................... 2.1. The Human Immunodeficiency Virus and AIDS.. 2.2. Pathogenesis of HIV Infection.............. 2.3. Morphology and Genomic Diversity of HIV.... 2.4. Vaccine Prospects..........................

Summary of the Invention.........................

Brief Description of the Figures.................

Detailed Description of the Invention............ .1. Generation of Nonreplicating RecombinantMade HIV Particles Useful as Vaccines Against the Human Immunodeficiency Virus... .1.1. Preparation of Recombinant DNA and Viral Vectors.............. .1.2. Infection/Transfection of Host Cells with Recombinant Vectors to Generate Recombinant-Made Retroviral Particles............... .2. Identification and Isolation of Nonreplicating Recombinant-Made Particles Containing Immunoreactlve Core and Envelope Proteins.......................... .3. Determination of the Immunogenicity of Nenrep]ieating Recombinant· Made Particles.................................. .4. Vaccine Formulations....................... .4.1. Vaccines Against the Human -11Immunodeficiency Virus............. .4.1.1. HIV-l Vaccines.......... .4.1.2. HIV-2 Vaccines and Heterologous Vaccines.... 6. Example: Generation and Isolation of Nonreplicating Recombinant-Made HIV-l Particles.. 6.1. General Procedures......................... 6.1.1. Cells and Viruses.................. 6.1.2. Detection of HIV Envelope and Core jq Antigens........................... 6.1.3. Electron Microscopy................ 6.2. Generation of Nonreplicating Recombinant-Made HIV-l Particles Containing Mature gag and env Proteins..... 6.2.1. Analysis of HIV-l Proteins Expressed in Recombinant Vaccinia Virus Infected BSC-40 Cells........ 6.2.2. Isolation of Nonreplicating Recombinant-Made HIV-l Particles... 6.2.3. Ultrastructural Analysis of Recombinant-Made HIV-l Particles by Thin Section Electron Microscopy... 6.2.4. Nucleic Acid Content of Recombinant-Made HIV-l Particles... 7. Example: Generation of Nonreplicating Recombinant-Made HIV-l Particles Using A Single Recombinant Vaccinia Virus Vector................ 7.1. General Procedures......................... 7.2. Construction of V-G2E5: A Recombinant Vaccinia Virus Containing HIV-l Env and Gag Ganc............................... 7.3. Coexpression of HIV-l Envelope and Core Antigens in BSC-40 Cells Infected with V-G2E5....................... -iii7.4. Recombinant HIV-l Particles Generated in V-G2E5 Infected BSC-40 Cells............

Example: Generation of Nonreplicating Recombinant-Made HIV-l Particles By Transfection of Plasmid DNA Into Mammalian Cells............................................ 8.1. Plasmid Constructs...................... 8.2. Generation of Recombinant-Made HIV-l Particles in Stable CHO Cell Transfectants........................... 8.2.1. Transfection and Selection of Cells........................... 8.2.2. Characterization of RecombinantMade HIV-l Particles............. 8.3. Alternative Strategies for Expression of Env and Gag Proteins and Generation of Recombinant-Made HIV-l and Particles in Mammalian Cells....................... 8.3.1. Expression of HIV Proteins in HeLa Cells Can be Obtained From Many Different Plasmid and Combinations of Plasmids......... 8.3.2. Regulation of the HIV Env Protein Expression by the Use of Regulatable Promoters............ 8.3.3. Expression of HIV Proteins in BSC-40 and Vero Cells.........

Example: Generation of Recombinant HIV-l Particles Having Modified Structural Characteristics Using Recombinant Vaccinia Virus Repressing Truncated Forms of HTV-1 Envelope Antigens................................ 9.1. Recombinant Vaccinia Virus v-ED2........... 9.2. Recombinant Vaccinia Virus v-Env5DCT....... -iv10 1214 Example: Generation of Recombinant HIV-1 Particles Having Modified Structural Characteristics Using Recombinant Vaccinia Viruses Expressing Unprocessed gpl60............ .1. Recombinant Vaccinia Virus V-160NC....... .2. Recombinant Vaccinia Virus V-11K16ONC.... Example: Recombinant Vaccinia Virus Expressing HIV-1 vpu Gene.......................

Example: Antiviral Effect of RecombinantMade HIV-1 Particles............................ 12.1. Infectivity Assay........................ 12.2. Results..................................

Example: Recombinant-Made HIV-1 Particles Inhibit HIV-1 Infection of Cultured Peripheral Blood Lymphocytes Isolated from HIV-1 Seropositive Donors.......................................... 13.1. Infectivity Assay........................ 13.2. Results..................................

Example: Immunogenicity of RecombinantMade HIV-1 Particles In Vivo.................... 14.1. Immunogenicity Assay..................... 14.2. Results.................................. 14.2.1. Antibody Titer Determined by ELISA........................ 14.2.2. Neutralization of HIV-1 Infectivity by Rabbit Antisera........................ 14.2.3. Cellular Immune Response........................ 4.2.4. Western Blot Ann 1 yp.ϊ n r,f Antibody Reactivity Example: Recombinant-Made HIV-1 Particles Bind to and are Internalized Within CD4+ Cells.......... —v— .1. Internalization Assay.................... .2. Results.................................. 16. Example: Immunogenicity of RecombinantMade HIV-l Particles in Non-Human Primates...... 16.1. Immunization Protocol.................... 16.2. Results.................................. 17. Deposit of Microorganisms.......................

The present application is a continuation-in-part of Ιθ copending application Serial No. 07/439,205 filed November , 1989, which is incorporated by reference herein in its entirety. -la1. INTRODUCTION The present invention is directed to noninfectious recombinant-made retroviral particles, to in vitro systems by which such particles can be generated, and to their use as anti-viral agents and as immunogens for prophylaxis and therapy against human retroviruses such as the human immunodeficiency virus (HIV). Recombinant-made HIV particles of the invention incorporate correctly processed Ιθ HIV core and envelope proteins and are morphologically and immunologically very similar to native HIV. Yet, since the recombinant-made HIV particles of the invention do not contain all elements of the HIV genome necessary for viral replication, they are non-infectious. 2. BACKGROUND OF THE INVENTION Two types of human retroviruses have been identified, leukemia viruses and AIDS or AIDS-related viruses. The primary targets of the human retroviruses are T lymphocytes and cells of the central nervous system. All human retroviruses are transmitted by intimate contact, blood contamination, and infection in utero or after birth by milk. It is likely that all human retroviruses orginated in Africa and that they encountered the human species via interspecies infection, possibly from African Green Monkeys or a related species. The human retroviruses first discovered, Human T Lymphotropic Virus Type 1 (HTLV-I) and Human T Lymphotropic Virus Type II (HTLV-II), have a preferential tropism for T4 cells and some T8 cells, share significant sequence homology, and are mainly associated with T cell leukemias a.rl lymphomas. Ti ; ulL.-.r g ,up ol human retroviruses, generally called Human Immunodeficiency Viruses (HIV), is discussed in greater detail below. There are two major differences between the two types of human -2retroviruses: (1) there is substantial genomic variability among various HIV isolates, whereas the genomes of HTLV-I and HTLV-II are stable; and (2) HIV entered human populations much more recently than HTLV-I or HTLV-II. 2.1. THE HUMAN IMMUNODEFICIENCY VIRUS AND AIDS The human immunodeficiency virus (HIV) is a cytopathic retrovirus and the causative agent of the acquired immunodeficiency syndrome (AIDS). Two forms of HIV have now 10 been identified. The prototype virus, HIV-l, previously termed lymphadenopathy-associated virus (LAV) and human T lymphotropic virus type III (HTLV-III), is responsible for the vast majority of reported AIDS cases worldwide. Another retrovirus, HIV-2, has been isolated primarily from West African patients with AIDS and is pathogenically related to HIV-l. On the genetic level, HIV-2 is actually more closely related to the simian immunodeficiency virus (SIV), a retrovirus infecting monkeys.

As of May 31, 1989, over 97,000 cases of AIDS had been reported in the United States alone, and over half of those people have already died. As many as three million persons in this country may be asymptomatic carriers of HIV and are capable of transmitting the virus. It has been estimated that 270,000 cases of AIDS will have occurred in the United States by 1991 (U.S. Public Health Service, 1986, Public Health Rep. 101: 341). The mortality rate from AIDS is disturbingly high, exceeding 80% within three years of diagnosis and possibly reaching 100% over a longer period.

Worldwide, the AIDS epidemic may involve some five to ten million presently infected persons. Particularly trni’hipT.nnn ^tat-isMc'· from the African continent vkov millions of individuals are believed infected with HIV, deaths range in the hundreds of thousands, and heterosexual transmission predominates. To date, there is neither a -3known cure for AIDS nor an effective vaccine against HIV infection. 2.2. PATHOGENESIS OF HIV INFECTION 5 HIV is a member of the nontransforming, cytopathic lentivirus family of retroviruses. HIV causes a typically fatal disease characterized by severe immunodeficiency or neurodegenerative disease, or both. The primary basis for HIV induced immunosuppression is the depletion of the 1θ helper/inducer subset of T lymphocytes expressing the CD4 molecule (T4 or CD4+ cells), which serves as the high affinity cell surface receptor for the virus. T4 lymphocytes are involved directly or indirectly in the induction of nearly every immunologic function in the body, and their depletion results in susceptibility to a wide range of opportunistic infections and neoplasms.

In addition to the T4 lymphocyte, other cells expressing the CD4 molecule are targets of HIV infection, especially monocyte-macrophages and certain neurons and glial cells of the brain. HIV infection also results in serious B cell abnormalities including polyclonal activation, hypergammaglobulinemia, elevated levels of circulating immune complexes, and autoantibodies. A decreased number of functional natural killer (NK) cells have also been observed in AIDS patients.

Infection of CD4+ cells is initiated by the interaction of the CD4 molecule with the major HIV envelope glycoprotein gpl20, an evept which is followed by internalization and uncoating of the virion, transcription of genomic RNA to DNA by virus-encoded reverse transcriptase, and integration of the result ing proviral DN.’. int.'. host cd 3 ebr l· Lth..

Also, unintegrated proviral DNA accumulates in large amounts within infected cells and is probably a significant factor in HIV cytopathicity (Shaw et al., 1984, Science 226: 1165). -4During replication, mRNA transcripts of integrated proviral DNA are translated into HIV proteins. These proteins are then processed and assembled along with HIV genomic RNA. Mature virions bud from the surface of infected T5 lymphocytes and bud internally in macrophages, incorporating host cell membrane lipid to form virion envelope.

Although HIV may remain dormant for some time after infection, when active replication of virus occurs, the host CD4+ cell is usually killed. The precise mechanism by which 10 HIV exerts its cytopathic effect is unknown, though several mechanisms have been proposed (e.g., accumulation of large amounts of unintegrated viral DNA in infected cells; increase in cell membrane permeability when large amounts of virus bud from the cell surface; speculations that HIV may induce terminal differentiation of infected T4 cells, leading to a shortened life span). There is growing evidence that both the CD4 molecule and the virus envelope play a role in the cytopathic effect in HIV infected cells.

A prominent feature in the cytopathology of HIV infection is 2o the formation of multinucleated syncytia which appear to be induced by the gpl20/gp41 envelope proteins. In contrast, HIV-infected macrophages may continue to produce HIV without cytopathic effects for long periods of time.

Evidence that monocytes and macrophages play a major role in the pathogenesis of HIV infection is compelling. In addition to engulfing the virus by phagocytosis, some subsets of monocyte-macrophages express the CD4 surface antigen and are therefore capable of binding to the HIV envelope. The monocyte-macrophage is the primary cell type infected in the brain and is involved in the development of the neuropsychiatric manifestations of HIV infection, iloreovei, funcoxonal defects of monocyte-macrophages are commonly observed in infected patients. These defects may contribute to the opportunistic infections characteristic in -5AIDS patients.

Of primary significance is that HIV can survive in a dormant state within the monocyte-macrophage. Infected monocytes do not exhibit the cytolytic effect that HIV has on T4 cells, perhaps due to a lower density of CD4 cell surface receptors. Monocytes can therefore serve as HIV reservoirs which may ultimately transport the virus to the brain, central nervous system, and various organs in the body. It is likely that the virus crosses the blood/brain barrier within monocytes where it affects the release of monokines, enzymes, and chemotactic factors resulting in the destruction or damage of neurons and inflammation of brain tissue (Ho et al., 1987, N. Engl. J. Med. 311: 278; Fauci, 1988, Science 239: 617). Of the various neurologic syndromes directly ascribable to HIV infection, most prevalent is subacute encephalitis or AIDS dimentia (nearly 90% of AIDS patients), the clinical features of which include dimentia, psychomotor retardation, and behavioral changes. 2.3. MORPHOLOGY AND GENOMIC DIVERSITY OF HIV The fine structure of HIV has been determined by immunological and electron microscopic analytical techniques (Gelderblom et al., 1988, Micron and Microscopia 19: 41; Gelderblom et al., 1987, Virology 156: 171). No morphological difference was detected between HIV-1 and HIV-2 strains (Gelderblom et al., 1988, Micron and Microscopia 19: 41). HIV virion is a spherical particle of about 100 to 120 nm across and contains an electron dense, tubular core comprised of the p24 gag protein, a submembrane matrix comprised of gag pl7, and a;, .•-•.•J L-c-.·. 9 the env proteins gpl20 and gp41 interspersed within the lipid bilayer membrane. HIV genomic RNA is housed within the core as part of the ribonuclear protein (RNP) complex -6which incorporates reverse transcriptase molecules (the enzyme which catalyzes transcription of RNA to proviral DNA) and core proteins. Envelope proteins gpl20 and gp41, derived by proteolytic cleavage from the precursor gpl60, exist as noncovalently associated complexes embedded in the membrane. These envelope protein complexes are visualized as knobby protrusions having a maximum width of about 14 nm, a height of 9-10 nm, and appear to be arranged in an icosahedral pattern having T=7 laevo symmetry. The 10 protrusions comprise gpl20, which is loosely connected to its transmembrane gp41 anchor. Envelope gpl20 is spontaneously shed to a high degree from the surface of the virus, a phenomenon which may influence HIV pathogenicity. Virus particle maturation takes place both during and just after the budding process. After budding from the surface of the infected cell, HIV core proteins are cleaved from precursors by an HIV-encoded protease into mature structural proteins which organize to form the core structure.

HIV genome contains three genes that encode the major structural components of the virion: env (which codes for the envelope proteins), gag (which codes for the core proteins), and pol (which codes for reverse transcriptase, protease, and endonuclease enzymes). These three genes are flanked by stretches of nucleotides called long terminal repeats (LTRs). The LTRs include sequences that have a role in controlling the expression of viral genes. However, unlike other retroviruses, the genome of HIV includes at least six additional genes, three of which have known regulatory functions. Expression of these regulatory genes is thought to have an impact on HIV pathogenesis. The tat : - fi;.: 3c;·; ; .-,,1 L.i„,:. fu,;·.1. - ··. {'.-'· etic. t i < (isactivator of HIV gene expression and, therefore, plays an important role in the amplification of virus replication.

The rev gene product regulates the splicing and transport of -7HIV mRNA. In contrast, the nef gene may down regulate virus expression. The vif gene is not absolutely required for virion formation, but is critical to the efficient generation of infectious virions and influences virus transmission in vitro. The Vpr gene encodes an immunogenic protein of unknown function. Lastly, the recently described Vpu open reading frame encodes a protein involved in the regulation of virus maturation and cytopathic effect.

Many different isolates of HIV have been obtained and 10 their nucleotide sequences determined, revealing a striking degree of genomic diversity in the env gene. Regions of the env gene characterized by significant divergence are interspersed with domains conserved among different isolates. Presumably, one such conserved region is the CD4 binding domain, as all HIV isolates bind to the CD4 cell surface receptor molecule. Related but distinct HIV-l variants, some of which are antigenically diverse, have been isolated from individual AIDS patients over the course of an infection. Isolates may differ with respect to their 2Q tropism for specific cell types. In this regard, certain isolates appear to replicate preferentially in either CD4+ T cells or in brain-derived macrophages, suggesting that HIV infection results in different clinical manifestations due to a selective pathogenicity mechanism. 2.4. VACCINE PROSPECTS Traditional approaches to viral vaccines involve the use of whole virions, either as live attenuated forms or as inactivated preparations. These approaches have been used successfully against many diseases such as smallpox, polio, m^asi.fts, mumps, rubella, etc. However, the potential usefulness of these approaches applied to HIV vaccine development has been questioned. In addition to the realistic risks associated with reversions and insufficient *E 904161 activation, such traditional approaches also pose a theoretical risk of inducing a disease such as AIDS since they involve the introduction of the entire retroviral genome into otherwise healthy individuals. Consequently, most efforts toward the development of an AIDS vaccine to date have focused on recombinant approaches, either in the form of subunit or viral vectored vaccines.

Study of HIV target antigens has been largely limited to the envelope glycoproteins and, to a lesser extent, the core 10 antigens. Little, if any, information is known about the immunogenicity of envelope glycoprotein complexes (i.e., gpl20-gp41 multimer complex, as opposed to soluble gpl20 or gpl60) or about envelope-core antigen complexes. Several lines of evidence argue that the presentation of both envelope glycoprotein complex and core antigens in a particular structure may be important. First, studies of the hepatitis B surface antigen indicate that the presentation of that antigen as part of a particle structure is more effective than the soluble antigen (Cabral et al., 1978, J. Gen. Virol. 38:339). Second, the immunogenic property of a given epitope, such as the group-specific neutralizing epitope(s) of adenovirus hexon, may be conformation-dependent. Third, the inclusion of core antigen as an immunogen may elicit broadly reactive immune responses to different HIV-l isolates since the core antigens of HIV are relatively conserved among various isolates. Therefore, it is of interest and importance to design and evaluate vaccines that combine the advantages of both traditional and recombinant approaches, i.e., recombinant-made vaccines that preserve the immunogenic propertien rTtlv·· ’'h'· V ·. l.ck th- h,1' ?· L ί , L tv other potential disadvantages of whole virus preparations.

In addition to their prophylactic use, vaccines may also be useful for post-exposure immunotherapy. For example, -9current rabies vaccines are given to individuals following potential exposure to rabies viruses. It has been proposed that immunotherapy could also be of value in preventing AIDS in HIV infected individuals, since there is a long period of latency between infection and disease progression (Salk, 1987, Nature 327:473-476). 3. SUMMARY OF THE INVENTION The present invention is directed to nonreplicating 10 recombinant-made retroviral particles, vaccine formulations comprising nonreplicating recombinant-made retroviral particles, methods for the generation of nonreplicating recombinant-made retroviral particles, and the use of nonreplicating recombinant-made retroviral particles as antiviral agents. The recombinant-made retroviral particles of the invention comprise retroviral core and envelope proteins assembled into structures having immunological and morphological characteristics that closely resemble those of native retrovirus virions. The primary structural difference between the recombinant-made retroviral particles of the invention and native retroviral particles is the absence of a complete retroviral genome in the former. Without a retroviral genome capable of directing the expression of, inter alia, the several gene products necessary for retroviral infectivity and replication, the recombinant-made retroviral particles of the invention are totally noninfectious and can not reproduce. Yet, because the recombinant-made retroviral particles are structurally organized as are infectious retroviral particles, they are highly immunogenic and are capable not only of eliciting a vv. j.'ivui· ue response against the particular retrovirus of interest, but are also effective at blocking retrovirus infectivity.

Applicants' method for generating the nonreplicating — 10— recombinant-made retroviral particles of the invention involves the coexpression of retroviral core and envelope structural proteins in mammalian host cells capable of directing their maturation and supporting their association into correctly assembled budding particles. Introduction of the nucleotide sequences encoding such retroviral core and envelope structural proteins into the mammalian host cell may be accomplished using several established techniques such as, for example, infection by live virus vectors and IQ transfection with DNA vectors. In addition, applicants believe that a nucleotide sequence encoding retroviral protease should also be introduced into the mammalian host cell in order to ensure the proper processing of the retroviral core proteins.

More particularly, the present invention is directed to nonreplicating recombinant-made HIV particles, vaccines against Human Immunodeficiency Virus, methods for generating nonreplicating recombinant-made HIV particles, and the use of nonreplicating recombinant-made HIV particles to inhibit HIV infection and to treat individuals infected with HIV.

In a particular embodiment, described by way of example herein, recombinant vaccinia viruses are used as vectors to introduce the gag, protease and envelope genes of Human Immunodeficiency Virus into mammalian host cells which direct the generation of HIV-l-like particles having immunological and morphological characteristics closely resembling those of native HIV-l. These recombinant-made HIV-l particles are able to block the infectivity of live HIV in vitro and are highly immunogenic in vivo.

. BRIEF i.’1 r BCR J FT J !’>·? C' j > · . ' .! I >. S FIG. 1. Radioimmunoprecipitation analysis of HIV-l proteins expressed in BSC-40 cells infected with recombinant vaccinia viruses. Monolayers of BSC-40 cells were grown to -11confluency in Dulbecco's Modified Eagles Medium (DMEM) supplemented with 10% fetal calf serum (FCS). Cells were infected with either v-env5 (lanes A and B) , v-env5 + v-gag2 (lanes C and D) , v-gag2 (lanes E and F) , or v-NY parental 5 virus (lanes G and H) at a MOI of 10 PFU/cell of each virus.

At 12 hours post infection, the cells were radiolabeled for . 3 5 35 hours with [ S]-methionine and [ S]-cysteine (100 uCi/ml). Culture media was collected and the cells washed with PBS, harvested, and lysed in RIP buffer (1% NP40, 0.5% 1θ deoxycholate. 0.1% SDS in PBS). The post-nuclear cell lysates (lanes A, C, E, and G) in parallel with the culture media (lanes B, D, F, and H) were assayed for HIV-l proteins by RIP with human polyclonal anti-HIV-1 sera (Section 6. 1.2., infra), followed by fractionation by SDS-PAGE in 11.5% acrylamide matrix. Radiolabeled proteins were visualized by autoradiography. Molecular weight markers are indicated in killodaltons (kD).

FIG. 2. Cell surface compartmentalization of the HIV envelope proteins synthesized by infected BSC-40 cells.

Cells were infected with v-env5, or coinfected with v-env5 and v-gag2, in parallel with parental v-NY virus at an MOI of 10 PFU/cell for each virus. At 16 hours post infection, the culture media was aspirated and the cells washed and 125 radiolabeled with 0.5 mCi [ I] by the lactoperoxidase catalyzed reaction (Haffar et al., 1987, Mol. Cell. Biol. 7: 1508). Post-nuclear cell lysates were then assayed by RIP and SDS-PAGE for HIV proteins as described in FIG. 1 and in Section 6.1.2., infra.

FIG. 3. Isolation of recombinant HIV particles containing HIV-l gag and env proteins. (1) Autoradiogram: per.-'O --τ tnbAv.i r’ ncribed in FIC. 2 were . 35 radiolabeled at 5 hours post-infection with [ S]-methionine 3 5 and [ S]-cysteine (60 MCi/ml) for 10 hours. The culture media from each infection condition (14 ml) was collected -12and clarified of cells by centrifugation at 600 X g for 10 minutes. Two milliliters of the resulting supernatants were collected for assay of the starting material (TS). The remaining 12 ml from each sample was fractionated in a SW 55Ti rotor at 120,000 X g for 3 hours into a particulate pellet and a post-particulate supernatant (S). The pellet was rinsed, resuspended in PBS and overlayed onto a 2 ml 15% sucrose cushion. The particulate material was sedimented again by ultracentrifugation in a SW 55Ti rotor at 120,000 X 1Q g for 1.5 hour. The resulting particulate pellet (P) was resuspended in RIP buffer. The P fractions (lanes Β, E, and H) were assayed for HIV proteins in parallel with 2 ml (from 12 ml total) S fractions (lanes C, F, and I) and the 2 ml TS material (lanes A, D, and G) by RIP as described in Section -,5 6.1.2., infra. (2) Graph: The particulate pellet from the first ultracentrifugation of doubly-infected BSC-40 culture supernatants was overlayed onto a continuous sucrose density gradient (15%-60%) and sedimented at 120,000 X g in a SW 55Ti rotor for 1.5 hour. The gradient fractions were 2q collected from the bottom of the gradient in 200 ul aliquots. The collected material was halved and assayed for gag p24 content by EIA as described in Section 6.1.2., infra. The peak fractions of the EIA are presented as ng of p24 detected per fraction collected (closed circles), and can be correlated to sucrose concentration (open circles). The fractions constituting the top of the gradient (not shown) did not contain any p24 as confirmed by western blot analysis.

FIG. 4. Analysis of assembled recombinant HIV-1 particles by thin section electron microscopy and immuno electron microscopy. Intact HSC-40 cells coiniected with v-env5 and v-gag2 (M01=10 PFU/cell for each virus), in parallel with particulate pellet sedimented from culture supernatants (FIG. 3), were fixed for 20 minutes in 4% -13paraformaldehyde. The samples were then washed and blocked with 0.8% bovine serum albumin, 0.1% gelatin and 5% normal goat serum in PBS. MAbs 110-4 or 41-1 (Section 6.1.2., infra) as ascites fluid (1:2000 in blocking buffer) were 5 added to the various samples as indicated. After 3.5 hours, the samples were washed with PBS and incubated with goldconjugated goat anti-mouse IgG and prepared for EM analysis following the procedures outlined in Section 6.1.3., infra.

FIG. 5. Nucleic acid content of recombinant-made HIV-l 1Q particles, determined by dot blot hybridization assay as described in Section 6.2.4., infra. Panel A: gag-specific probe. Panel B: env-specific probe. Recombinant-made HIV-l particle and inactivated HIV virion concentrations were determined as ng p24 equivalents. (Inactivated virus: lane 1, 2600 ng p24; lane 2, 260 ng p24; lane 3, 26 ng p24; lane 4, 2.6 ng p24; recombinant-made HIV particles: lane 1, 300 ng p24). Panel C: line drawing indicating the coordinates for the gag-pol gene (258-3317) and the env gene (5671-8572) used in the preparation of the recombinant 2Q vaccinia viruses v-gag2 and v-env5, respectively. The arrow indicates the position of the RNA packaging sequence (300319) located upstream of the gag-pol gene (Lever et al., 1989, J. Virol. 63:4085-4087).

FIG. 6. Schematic representation of the construction of plasmid pv-G2E5.

FIG. 7. Western Blot of Recombinant Vaccinia Virus Infected Cells. BSC-40 cells were infected at an MOI of 5 pfu/cell and harvested for PAGE at 24 hours post infection. Infected cell lysates were electrophoresed in a 7-15% acrylimide gel and electro-transferred to nitrocellulose.

T ituutij loblo Ls ι - -.bed with nlV -< funr -·η Seruta (Ttrimar) and then peroxidase conjugated goat-anti-human IgG. Blots were visualized using 2-Chloro-Napthol as substrate. Gel lanes were loaded as indicated. -14FIG. 8. Radioimmunoprecipitation analysis of recombinant-made HIV-l particles produced by V-G2E5 infected BSC-40 cells.

FIG. 9. Schematic diagrams of plasmid vector constructs 5 described in Section 8.1., infra.

FIG. 10. Immunoreactivity of recombinant-made HIV-1 particles generated in transfected CHO cells. Recombinantmade HIV Particles were collected from the culture medium of 3010-C6 cells, concentrated by high speed centrigution and IQ fractionated by banding in a 15-60% sucrose gradient. Top: Gradient fractions were analyzed for Gag protein content by Gag antigen EIA, and for sucrose density using a refractometer. Bottom: Aliquots of selected fractions (indicated on top panel by *) were analyzed by electrophoresis on a 7-15% gradient selected fractions polyacrylamide gel and electro-transfer to a nitrocellulose filter which was probed with a human AIDS patient serum and 125-1 labeled Protein A. Also loaded were an aliquot of unfractionated particles and isolated HIV virus.

FIG. 11. Analysis of HIV-specific antigens expressed in HeLa cells transfected with plasmid vectors encoding HIV-1 env, tat and rev genes. HeLa cells were contransfected with CmHiTgfbEnvS (each lane) plus the tat and rev plasmids indicated above each lane (Bs is a control plasmid comprised of the Bluescribe plus vector with no coding sequences inserted). Zinc was added to cultures, indicated by +Zn, 24 hours before samples were collected. Total cellular lysates were analysed by electrophoresis on a 10% polyacrylamide gel and electro-transfer to a nitrocellulose filter which was probed with 125-1 labeled monoclonal antibody 110-4. Also loaded was an aliquot of BSC-40 cells infected with vaccinia virus v-env5.

FIG. 12. Western Blot of Recombinant Vaccinia Virus Infected Cells. BSC-40 cells were infected at an MOI of 10 -15pfu/cell and harvested for PAGE at 23 hours post infection. Infected cell lysated were electrophoresed in a 8.5% acrylimide gel and electro-transferred to nitrocellulose. Immunoblots were reacted with HIV+ Human Serum (Trimar) and then peroxidase conjugated goat-anti-human IgG. Blots were visualized using 2-Chloro-Napthol as substrate. Gel lanes were loaded as indicated.

FIG. 13. Analysis of the infectivity of T-lymphoblastoid cells with recombinant-made HIV-l particles. T 10 lymphoblastoid cells (CEM) were incubated with either recombinant-made HIV-l particles (corresponding to 3ng p24 gag) or HIV virus (corresponding to 5pg p24 gag), as described in Section 7.1., infra. Five days post infection cell samples were collected from each well and analyzed for intracellular HIV antigens by indirect immunofluoresence, as described in Section 7.1, infra. Evans Blue dye (red stain) was used to facilitate localization of cells. Panel A: CEM cells incubated with recombinant-made HIV-l particles.

Panel B: CEM cells incubated with HIV virus, showing 2Q positive fluorescence. Panel C: Syncytium of CEM cells incubated with HIV virus.

FIG. 14. Relative antibody titers in serum samples collected from New Zealand White rabbits immunized with (A) recombinant-made HIV-l particles, and (B) psoralen25 inactivated HIV-l, as determined by ELISA. The details of the assay are set forth in Section 14.1., infra.

FIG. 15. Humoral immune response in immunized animals. New Zealand white rabbits were immunized with recombinantmade HIV-l particles (R#238 and R#241) and inactivated HIV-l virions (R#239 and R#243). At different intervals following t*.llP p ΤΠrt VV i 1Π *1 lonr ft F Ί Tr> θΓ -’C 7' 1 1 C* t·· 1 assayed for HIV-l specific antibodies by ELISA on disrupted whole virus (panels A and B) or on purified gpl20 (panels C and D). The data presented (ordinate) are the end point -1610 titers of HIV-l specific antibodies calculated at 2 fold the preimmune serum titers. The abscissa values represent the schedule in weeks post-primary immunizations when serum samples were collected. The arrows indicate the times of the secondary (wk4 R#241 and 243, wk5 R#238 and 239) and tertiary (wkl8 R#241, wk33 #R238) immunizations.

FIG. 16. Neutralization of HIV-l infectivity of CEM cells with the rabbit sera. Selected serum samples from the immunized rabbits (panel A R#238 and R#241, panel B R#239 and R#243) were assayed for HIV-l specific neutralizing activity. The homologous virus (BRU isolate) was preincubated with the appropriate sera for 45 minutes at 37 °C prior to addition to the cells. After 1 hour at 37° the virus and sera were removed from the cells and replaced with appropriate dilution of sera in culture medium. Neutralization was determined by measuring, using a EIA, the reduction in p24^a<^ protein released from the cells. The reported neutralizing titers (ordinate) were for 75% reduction in p24 levels in the culture medium. The abscissa values are as described in the description of FIG. 15.

FIG. 17. Antibody reactivity with individual viral proteins as determined by Western blot analysis. Details of the experimental procedure used and discussion of the results are presented in Section 14.2.4., infra.

FIG. 18. Confocal Laser Scanning Micrographs of HeLa cells transfected with CD4 gene incubated with recombinantmade HIV-l particles then with HIV specific antibodies. Details of the procedure are set forth in Section 15.1., infra.

· DETAILED DESCRIPTION OF THE INVENTION 'rbe ;·ΐ •«-••w·;!; i 11 v 6? γ» fc jl < jt* - eJ ates to nonreplicating recombinant-made retroviral particles which closely resemble live retrovirus virions in their immunological, structural, and morphological features. The method of the invention is -17applicable to the construction of recombinant-made particles resembling any of the human retroviruses (e.g., HTLV-I, HTLV-II, HIV-1, HIV-2).

A particular aspect of the invention relates to 5 recombinant-made HIV particles. Recombinant-made HIV particles, like native HIV, are comprised of correctly processed and assembled HIV core and envelope proteins which retain immunoreactivity to anti-HIV sera. The recombinantmade HIV particles do not, however, contain HIV genome and ,q are therefore nonreplicating. The method of the invention is illustrated by examples in which a novel in vitro system is used to generate recombinant-made HIV-1 particles displaying gpl20/gp41 envelope protein complexes on their surfaces. One skilled in the art will understand that the present invention encompasses numerous embodiments, and any falling within the scope of the appended claims not specifically described or illustrated herein are within the scope of the invention.

Several features of the present invention distinguish it as a novel approach to an AIDS vaccine. First, the recombinant-made HIV particles closely resemble authentic HIV virions, both in morphology and in antigenic properties. When used as an immunogen, these particles will present antigens in a manner similar to presentation of antigen during HIV infection, thereby eliciting immune responses that are highly relevant and potentially protective against natural infection. This feature of the invention can not be achieved by any recombinant subunit vaccine described to date. Second, the approach of the invention, being based on recombinant DNA techniques, provides flexibility for incorporat ϊ ng antigens from civersc isolates of HTv-] HIV-2, thereby generating cross-reactive immune responses considered essential for an effective vaccine against AIDS. Recombinant DNA techniques may also be used to delete or -18modify potentially harmful epitopes that contribute to any enhanced infectivity or pathogenicity of the virus. Third, the recombinant-made HIV particles described herein are not infectious and do not contain complete HIV genome.

Therefore, immunization with these particles does not introduce the risk of infection potentially associated with inactivated or attenuated whole virus vaccines. These and other features of the present invention are further explained in the sections and subsections that follow.

The recombinant-made HIV particles of the invention may also be useful as specific immunological enhancers to prevent the progression of AIDS in individuals already infected with HIV by boosting the immune reaction against the virus. This embodiment of the invention is directed 15 towards potentiating or maintaining the immunoprotective factors already induced in the seropositive individual. A similar approach is being evaluated by Dr. Jonas Salk using killed, envelope-depleted HIV preparations.

Other contemplated uses of the recombinant-made HIV particles of the invention include their use as an antiviral agents which interfere with HIV infection, their use in raising monoclonal antibodies to HIV core and envelope protein antigens, their use in the development of antiidiotypic antibodies, and their use in elucidating the process of HIV encapsidation. The recombinant-made HIV-l particles of the invention demonstrate antiviral effect (Sections 12 and 13, infra) and elicit HIV-specific humoral and cellular immune responses in both rabbits and macaque monkeys immunized with the particles (Sections 14 and 16, respectively). .1. GENERATION OF NONREPLICATING RECOMBINANTMADE HIV PARTICLES USEFUL AS VACCINES AGAINST THE HUMAN IMMUNODEFICIENCY VIRUS Applicants' method for generating recombinant-made HIV -19particles involves the coexpression of the HIV env-encoded and gag-encoded structural proteins in mammalian cells. The cultured host cells of choice must be capable of synthesizing and correctly processing HIV proteins.

Introduction of the env and gag genes into host cells may be accomplished using a variety of established techniques known in the art including infection by live virus vectors, such as vaccinia virus and retroviral vectors, and transfection using DNA vectors. Following successful expression of the 10 HIV proteins in host cells, the recombinant-made HIV particles may be isolated from the culture media using techniques standard in the art.

In a specific embodiment described in further detail below and by way of example in Section 6., infra, recombinant-made HIV particles are produced in African green monkey kidney (BSC-40) cells coinfected with two recombinant vaccinia viruses, one carrying the complete gag gene and the other carrying the complete env gene of HIV-1. This double infection results in the budding of assembled, recombinant20 made HIV-1 particles from the surface of the BSC-40 cells. Biochemical analysis revealed that these particles incorporated mature, immunoreactive gag and env proteins.

The morphology of the recombinant-made particles, as visualized by electron microscopy, is virtually the same as live HIV.

In a related embodiment, an alternative system for generating the recombinant retroviral particles of the invention using viral vectors is demonstrated by way of examples in which a single recombinant vaccinia virus containing both the env and gag genes of HIV-1 is used to transfect mammalian cells which then generate recombinantmade HIV-l particles (Section 7, et seq., infra).

In another embodiment, recombinant-made retroviral particles may be generated using a system involving -20mammalian cells transfected with DNA encoding the retroviral structural proteins. As one example of this embodiment, described in further detail in Section 8, et seq., infra, two plasmid vectors encoding, respectively, the HIV-l gag and HIV-l env genes, are used to transfect CHO cells, which then direct the synthesis of HIV-l gag and env antigens assembled into recombinant-made HIV-l particles. Other strategies in connection with this embodiment include, but are not limited to, transfection with complex plasmid 10 vectors containing multiple HIV genes, the use of constitutive and regulatable enhancer/promoter elements to drive the expression of HIV genes, the expression of HIV regulatory proteins in conjunction with and to control, HIV structural gene expression, the use of different cell lines, and the use of plasmid vectors encoding modified HIV proteins.

Other strategies for the expression of HIV structural proteins and the generation of recombinant-made HIV particles are disclosed in, for example, Sections 8.3., 9., et seq., and 10, et seq., infra.

A number of options are available using the systems of the present invention that allow control over the nature of the resulting particles. These options may be exercised at both the virus construction and infection stages. .1.1. PREPARATION OF RECOMBINANT DNA AND VIRAL VECTORS Recombinant DNA vectors and viral vectors such as vaccinia viruses may be constructed according to the methods outlined in copending United States Patent Applications Serial No. 779,909 filed September 25, 1985; Serial No. 942,984 fil'd y.-rb 27, and S--?ria.l No. 905,2^7 filed September 9, 1986, each of which is incorporated by reference herein in its entirety.

In a particular embodiment of the invention, recombinant -21vaccinia viruses carrying HIV env and gag sequences are constructed and used as vectors. Briefly, plasmid vectors containing HIV core and envelope protein coding sequences under the transcriptional control of the vaccinia promoter are constructed and used to affect the integration of the HIV gene sequences into the vaccinia virus genome by in vivo recombination. Recombinant vaccinia viruses are identified, purified, and evaluated for their ability to direct the synthesis of HIV proteins in infected cells, as described in the above-referenced copending patent applications.

In another embodiment, recombinant plasmid vectors encoding various combinations of HIV structural and/or regulatory genes are constructed and used as vectors for transfecting cells capable of generating recombinant-made HIV particles. The constructions of a representative range of such vectors are described in Section 8., et seq., infra.

The precise nature of the individual protein components of the recombinant-made particles of the invention may be modified by recombinant DNA techniques, during construction of the recombinant DNA vectors, recombinant vaccinia virus vectors, etc. In this way, the existence and structural composition of retroviral epitopes presented on the particles may be defined. For example, variable epitopes of HIV gpl20 from the different HIV isolates may be included to generate a cross-reactive immune response. Similarly, different HIV gag gene sequences may be incorporated within recombinant vectors to vary the immunogenicity of recombinant-made HIV particles. Vectors encoding mutated HIV gene sequences may also be useful in generating recombinant-made HIV particles, which may result improved in immunogenicity, anti-viral effect, etc. Applicants intend tnat recombinant-made retroviral particles incorporating such modified core and/or envelope proteins be within the scope of the present invention and the appended claims. -225.1.2. INFECTION/TRANSFECTION OF HOST CELLS WITH RECOMBINANT VECTORS TO GENERATE RECOMBINANT-MADE RETROVIRAL PARTICLES___ The nature of the recombinant-made retroviral particles is controlled to a large extent not only by the composition of the recombinant vectors used but also by the combination of vectors used in the infection or transfection process, this choice being a primary variable in the overall method of the invention. As a simple illustration, applicants have discovered that infecting BSC-40 host cells with a single recombinant vaccinia strain carrying the HIV-l gag gene (vgag2) resulted in the formation of HIV-l core proteins assembled into particles. However, when these same cells were coinfected with v-gag2 as well as a recombinant vaccinia carrying the HIV-l env gene (v-env5), the resulting 15 assembled particles incorporated and displayed HIV-l envelope proteins on their surfaces (Section 6., infra). Thus, while a particle comprised only of core proteins is formed after infection with v-gag2, adding v-env5 to the infection system results in particles of greater structural 2θ complexity which incorporate the envelope proteins. Taking the above illustration one step further, coinfection of host cells with v-gag2, v-env5, and a third recombinant vaccinia carrying the env gene from HIV-2 would be expected to result in the formation of heterologous particles incorporating HIV-l core as well as both HIV-l and HIV-2 envelope proteins. Alternatively, single recombinant vaccinia viruses encoding multiple HIV genes may be used as infection vectors. As demonstrated by example in Section 7, et seq., infra, host cells infected with one such vaccinia virus vector also generate immunoreactive recombinant-made HIV-l particles .

The same principles apply to generating recombinant-made particles using other vector systems, such as the use of plasmid vectors to transfect host cells. For example, host -23cells may be transfected with a single plasmid vector encoding both HIV env and gag, or a vector encoding HIV env, gag and other HIV genes, etc. Cells may also be transfected with a plurality of plasmid vectors, each encoding a 5 different HIV gene or combinations of HIV genes.

Furthermore, transfected cell lines may be transfected again with vectors designed to add the expression of other HIV genes to the particle generation system. Vectors encoding regulatable promoters may be used to modulate the expression 10 of HIV proteins in transfected host cells (see, for example, Section 8.3.2., infra). Vectors encoding other HIV genes may be used to affect their expression in conjunction with the expression of HIV structural genes in transfected cells. The expression of such HIV regulatory and/or accessory proteins in the system may be used as a means of altering particle characteristics and/or their production levels.

It is important to note that particles will not form in the absence of gag proteins, thus the inclusion of essential HIV core protein gene sequences in the recombinant vector is necessary. Although HIV protease is not required for the assembly of core particles, its role in the formation of infectious virion is indicated (Peng et al., 1989, Virology 63: 2550). As such, it may be advantageous to include HIV protease function in the production of recombinant-made HIV particles such that they may closely resemble native virions. In addition, gag genes from HIV-l, HIV-2, or different isolates thereof may be used to construct recombinant vectors. As will be clear to one skilled in the art, the multi-infection approach illustrated above, and similar approaches using other recombinant vectors, may be used to qoripr-?t.c recombinant HTV particles having a broad range of surface and core antigen characteristics. The number of different combinations are essentially unlimited.

The particular host cell selected will also influence -24the nature of the particles produced by the method of the invention. Cells should be chosen for their ability to express and correctly process mature HIV proteins. Since the HIV envelope proteins gpl20 and gp41 are glycosylated and are derived by proteolytic cleavage from a larger gpl60 precursor, a cell capable of directing these posttranslational processing modifications is desirable. Of course, where recombinant viral vectors are employed, the host cell must be susceptible to infection with recombinant virus. In preferred embodiments of the invention, host cells of human, simian, or rodent origin are used.

Host cells may be infected by recombinant vaccinia virus according to the conditions described in Section 6., infra, or transfected by recombinant plasmid vectors as described in Section 8., et seq., infra. When utilizing a recombinant vaccinia vector system, such as that described in Section 6., et seq., infra, cells may be infected at a multiplicity of infection (MOI) of about 10 PFU per cell of each recombinant vaccinia virus. However, one skilled in the art will understand that increasing or decreasing the MOI for one or more recombinant vaccinia may be used to influence the nature of the resulting particles. This would be an important factor in designing polytropic or heterologous particles. For example, a desired ratio of HIV-l to HIV-2 envelope antigens on the surface of a heterologous particle may be achieved by infecting with a proportionally corresponding MOI ratio.

In a specific embodiment of the invention, described in detail in Section 6., infra, recombinant vaccinia viruses v-env5 and v-gag2 were used to coinfect cultured African green monkey kidney (BSC-40) cells. The infected BSC-40 cells synthesized HIV-l envelope proteins yp^zu, yp41, and the gpl60 precursor, as well as HIV-l gag proteins p24, pl7, pl5, p55, p45, and p39. Furthermore, at least p24, pl7, -25gpl20 and gp41 assemble particles that are immunoreactive to polyclonal anti-HIV-1 sera and monoclonal antibodies specific for pl7, p24, gpl20 and gp41. Ultrastructural analysis of the recombinant-made HIV-l particles by thin section electron microscopy and immunogold labeling revealed substantial morphologically identity with native HIV. In this regard, recombinant-made HIV-l particles were visualized as spherical objects having a diameter of between 100 and 120 nm, and contained an electron dense inner core 10 which was either rod-shaped or spherical, depending on the section angle. Capture enzyme immunoassay and immuno electron microscopic analysis using monoclonal antibodies against p24 and pl7, respectively, confirm the identity of the core structures of HIV. Immuno electron microscopy analysis using monoclonal antibodies specific for HIV-l gpl20 and gp41 demonstrated that the gpl20/gp41 complex is displayed on the surface of the recombinant-made HIV-l particles. Various forms of immature particles were also visualized, consistent with the course of HIV-l virion morphogenesis. These features virtually parallel those observed from similar analyses of the HIV-l virion (Compare the electron micrographs shown in FIG. 4 with those presented in Gelderblom et al., 1988, Micron and Microscopia 19: 41, and in Gelderblom et al., 1987, J. Virol. 156: 171).

Applicants' results suggest that the ultrastructure of these recombinant-made HIV-l particles differs from the ultratructure of live HIV-l only in that they do not contain the viral genome or the reverse transcriptase enzyme.

The recombinant-made HIV particles of the invention may also be generated by cells transfected with recombinant nlasmid vfintnrR encod i nn HTV go,. env anr* other HTV genes. Various specific embodiments of this aspect of the invention are described in Section 8.2. infra. In a particular embodiment, Chinese Hamster Ovary (CHO) cells are -26transfected with plasmid vectors encoding HIV-l gag, env, tat, and rev genes. Stable CHO cell lines expressing and secreting processed env and gag proteins as recombinant-made HIV-l particles are obtained. Similar results may be obtained using HeLa, BSC-40 and Vero cells transfected with various plasmids or combinations thereof (See, for example, Sections 8.3.1., 8.3.2., and 8.3.3., infra). .2. IDENTIFICATION AND ISOLATION OF NONREPLICATING RECOMBINANT-MADE PARTICLES CONTAINING IMMUNO1θ REACTIVE CORE AND ENVELOPE PROTEINS_ Recombinant-made particles may be identified by a variety of immunochemical means and/or by electron microscopy (EM) visualization. Immunochemical detection methods such as radioimmunoprecipitation (RIP), capture 15 enzyme immunoassay (EIA), western blot analysis and the like may be used. Specific examples of how these techniques may be used to identify recombinant-made HIV particles are described by way of example in Section 6., infra. Various EM techniques may be used to identify and characterize 2θ recombinant-made HIV particles, such as the thin section EM and immuno electron microscopy techniques described in Section 6.1.3., infra. Additional EM techniques which may be used include scanning electron microscopy (SEM), surface replica electron microscopy, and immunocryoultramicrotomy, 25 all of which have proven useful in the elucidation of HIV fine structure (Gelderblom et al., 1988, Micron and Microscopia 19: 41).

Recombinant-made particles may be isolated from the culture media of host cells using standard techniques well known in the art. It is important, however, to use isolation methods which minimize the degree of gpl2O shedding in order to maximize the immunogenicity of recombinant-made HIV particles. -275.3. DETERMINATION OF THE IMMUNOGENICITY OF NONREPLICATING RECOMBINANT-MADE PARTICLES The immunogenicity of the recombinant-made particles can be determined by monitoring the the immune response of test animals following immunization. Test animals may include mice, rabbits, chimpanzees, and eventually humans. Several routes of immunization may be considered, including oral, intradermal, intramuscular, intraperitoneal, intravenous, subcutaneous, intranasal, etc. The immune response induced by recombinant-made HIV particle immunogens can be analyzed by three approaches: (a) the reactivity of the resultant immune sera to authentic HIV antigens using known techniques such as enzyme linked immunosorbent assay (ELISA), immunoblot, radioimmunoprecipitation, etc., (b) the ability of the immune sera to neutralize HIV infectivity in vitro (Robert-Guroff, 1985, Nature 316: 72), and (c) protection from HIV infection and/or attenuation of infectious symptoms in immunized animals (Francis, 1984, Lancet 2: 1276; Gujdusek, 1985, Lancet 1: 55).

In a specific embodiment, isolated recombinant-made HIV-l particles (Section 6., infra) were assayed for immunogenicity in rabbits (Section 14., et seq., infra).

The results of these analyses indicate that the recombinant-made HIV-l particles are highly immunogenic since the particles elicited significant humoral and cellular immune responses specific for both HIV envelope and core structural proteins. Moreover, rabbits immunized with recombinant-made HIV-l particles generated neutralizing antibodies to HIV-l.

In a related embodiment, the immunogenicity of the recombinant-made HIV-l particles is evaluated in non-human primates (Section 16., et seq., intra). More particularly, macaque monkeys are immunized with recombinant-made HIV-l particles in conjunction with other HIV-l antigens. Immune responses in immunized subjects may be determined by various -28assays, including whole virion ELISA, gpl20 ELISA, focal immunoassay and lymphoproliferative response assay. As described by way of the examples in Section 16., et seq., infra, when used as the sole immunogen for primary and secondary immunizations, recombinant-made HIV-l particles elicit HIV-specific humoral and cellular immune responses. The recombinant-made HIV-l particles were particularly effective when used to immunize animals previously primed with a recombinant vaccinia virus encoding HIV-l env and gag ,0 antigens. .4. VACCINE FORMULATIONS A specific embodiment of the invention is the formulation of vaccines capable of invoking immune responses 15 that contribute to the prevention of retrovirus infection or the development of retrovirus-associated diseases such as AIDS. The vaccine formulations use the recombinant-made retroviral particles of the invention as immunogens which, by combining major retroviral core and envelope proteins, are multivalent in nature. In related embodiments, the recombinant-made retroviral particles may be used as specific immunologic enhancers that may be used to ameliorate the progression of retrovirus-associated diseases in persons already infected with retrovirus. .4.1. VACCINES AGAINST THE HUMAN IMMUNODEFICIENCY VIRUS A further particular embodiment of the invention involves vaccine formulations capable of invoking immune responses that contribute to the prevention of HIV infection or the development of AIDS. Such vaccine formulations utijize recombinant-made HIV particles as immunogens.

Traditionally, viral vaccines have been prepared from attenuated or inactivated whole virions. Neither approach has been favored for the design of a vaccine against HIV-l -29primarily because of the hazards associated with large scale preparation of the virus, potentially incomplete activation, and the introduction of the HIV genome into healthy recipients (Minor, 1989, J. Antimicrobial Chemotherapy 23, Supp. A: 55). HIV vaccine development has therefore focused on subunit vaccine candidates. Although initial attention was directed to a subunit formulation comprising recombinant gpl20 envelope protein, it is now clear that both gpl20 and gp 41 are target antigens for the development of IQ neutralizing antibodies (Chahn et al., 1986, EMBO J. 5: 3065; Ho et al, 1987, J. Virol. 61: 2024; Skinner et al., 1988, J. virol. 62: 4195), for mediating antibody cellular cytotoxicity (Tyler et al., 1989, Fifth International Conference on AIDS, Abstract T.C.O. 33: 521), and for conferring susceptibility of cytotoxic T lymphocyte killing (Zarling et al., 1987, J. Immunol. 139: 988). These results argued for the inclusion of both gpl20 and gp41 in the design of an HIV-l vaccine.

The association of gp41 with cell membranes, in conjunction with its weak noncovalent interaction with gpl20, render impractical the purification of intact soluble gpl20/gp41 complexes. More importantly, like other viral antigens presented as components of membrane structures, such as Hepatitis B surface antigen (Cabral et al., 1978, J.

Gen. Virol. 38: 339) and Herpes Simplex Virus glycoprotein (Ho et al., 1989, J. Virol. 63: 2951), membrane bound gpl20/gp41 complexes are likely to be more immunogenic than the soluble counterparts.

As discussed in the Background of the Invention section herein, development of an effective HIV vaccine is complicated by several characV.ec.i sties of HIV. The pres;T.t invention may circumvent many, if not most of the problems.

In addition to presenting gag and env proteins in their native conformations, the recombinant-made HIV particles of -30the invention may be designed so that desirable epitopes are retained, while undesirable epitopes are deleted or modified. Furthermore, the invention provides a means by which several different variable epitopes of the same HIV protein may be incorporated into the particles used in the vaccine formulation. The invention also provides a way to create heterologous recombinant-made HIV particles that may be used to formulate a vaccine capable of preventing infection by both HIV-l and HIV-2. jq One of the novel aspects of a vaccination approach utilizing the present invention is that a full battery of these and other such epitopes may be consolidated into one immunogenic particle. Moreover, these epitopes are presented to the immune system as they are on native HIV, thereby inducing immune responses that are effective against infection by native virions. .4.1.1. HIV-l VACCINES Protective immunity against HIV has not been fully elucidated. It is commonly believed that both neutralizing antibodies and cell-mediated immunity may be required, since HIV can be transmitted in cell-free or cell-associated form. Neutralizing antibodies recognizing a number of different HIV epitopes have been identified in HIV-l infected individuals, including those which recognize epitopes on highly conserved as well as variable regions of the envelope protein gpl20. Similarly, neutralizing antibodies directed against epitopes of gp41 and pl7 (Papsidero et al., 1989, J. Virol. 63:267-272) have been identified. Other antibodies detected in HIV infected individuals include those specific -Cc·.:.' ii\. ι X . : S ι ί j p 1 Z U V. ! .L C: .UjCiCl t.O C D-t Cell SUL’filCCI receptor. Still other antibodies, which bind to a hypervariable region of gpl20, are capable of inhibiting fusion of HIV infected cells into syncytia (Rusche et al., -311988, Proc. Natl. Acad. Sci. U.S.A. 85: 3198). Cellular immune responses are also seen in HIV infected persons and, specifically, cytotoxic T-lymphocytes directed against env, gag and pol gene products have been identified (Walker et al., 1987, Nature 328:345; Nixon et al., 1988, Nature 336:484; Riviere et al., 1989, J. Virol. 63:2270-2277).

One embodiment of the invention is a vaccine against the HIV-l virus, presently the most prevalent form of HIV, using recombinant-made HIV-l particles such as the recombinant10 made HIV-l particles described in Section 6., et seq., infra, which comprise mature core and envelope proteins of the type 1 virus, assembled within a structure that mimics the morphologic and antigenic properties of live HIV. This embodiment encompasses vaccine formulations using a variety of recombinant-made HIV-l particles. For example, particles silmultaneously presenting the gpl20/gp41 complexes of two or more HIV isolates may be useful for inducing the development of protective antibodies against a number of variable region epitopes. The generation of such particles could be achieved by coinfecting host cells with several different recombinant vaccinia viruses carrying, respectively, the env genes from the different HIV-l isolates. Individuals immunized with such particles would be able to mount immune responses against a number of different HIV-l strains.

Similarly, the construction of polytropic particles may also increase the efficacy of the vaccine formulation. In this embodiment, particles are designed to incorporate epitopes from HIV-l strains having different tropisms. For example, recombinant-made HIV-l particles displaying dete'.-iitinanfs unique to a monocyte-associated HIV-l strain in combination with determinants common to T4 cell-associated virus strains may be generated using a multi-infection approach. Specifically, such particles may be generated by -32coinfecting host cells with three recombinant vaccinia, one carrying the gag gene from one strain, one carrying the env gene from the same strain, and the other carrying the env gene from a tropogenically different strain.

The most effective vaccine against HIV-l may involve using the recombinant-made HIV-l particles of the invention in combination with other immunogens. In this regard, recombinant-made HIV-l particles appear most effective at eliciting humoral and cellular immune responses when used as a secondary immmunogen following initial immunization with recombinant gpl60 in non-human primate subjects. .4.1.2. HIV-2 VACCINES AND HETEROLOGOUS VACCINES Other embodiments of the present invention relate to vaccines against HIV-2 as well as heterologous vaccines which may include, for example, a single vaccine for both HIV-l and HIV-2. The recombinant-made particles used in such heterologous vaccines may comprise, for example, the core proteins of HIV-l and the envelope proteins of HIV-l and HIV-2. Alternatively, it may be desirable to formulate a vaccine comprised of two or more different recombinantmade HIV particles. This may be especially true when designing a vaccine that would protect against the many different isolates of both HIV-l and HIV-2.

Vaccines comprising a single recombinant-made HIV particle type or different types in combination may be formulated with a suitable adjuvant in order to enhance the immunological response to their antigens. Suitable adjuvants include, but are not limited to, mineral gels, surface active substances such as lysolecithin, plurionic pq ] voi s, po] v? η ί o*'.- ’ypt W .- oil pt 1 ρ ΐ one, nnd potentially useful human adjuvants such as BCG (bacille Calmette-Guerin) and corynebacterium parvum.

A number of methods well known in the art may be used to -33introduce the vaccine formulations described above, including intradermal scarification, intravenous injection, subcutaneous injection, intramuscular injection, intranasal administration, oral administration, etc. 6. EXAMPLE: GENERATION AND ISOLATION OF NONNONREPLICATING RECOMBINANT-MADE HIV-l PARTICLES Described here is an in vitro system for generating recombinant-made HIV-l particles which contain assembled core and envelope proteins and which display the env gpl20 and gp41 antigens on their surfaces. Briefly, BSC-40 cells are coinfected with recombinant vaccinia viruses carrying either the complete envelope gene of HIV-l (v-env5) or the complete HIV-l gag and protease genes (v-gag2). HIV-l proteins are expressed in the BSC-40 cells and assemble into 15 HIV-l particles which bud from the cell membrane. The resulting particles are nonreplicating, react with monoclonal antibodies specific for HIV-l envelope and core proteins, and are morphologically similar to HIV-l virions. 6.1. GENERAL PROCEDURES 6.1.1. CELLS AND VIRUSES African green monkey kidney cells (strain BSC-40, a 2g continuous line of African Green Monkey Cells derived from BSC-1 cells, ATCC No. CCL26) were propagated in Dulbecco's modified Eagle's medium (DMEM, Gibco, Grand Island, NY) supplemented with 10% fetal bovine serum and 100 units per ml each of penicillin and streptomycin. 3θ Recombinant vaccinia viruses carrying HIV-l env and gag crane sequences were prepared and evaluated as described 5n copending United States Patent Application Serial No. 905,217 filed September 9, 1986. Recombinant vaccinia virus v-env5 carries the entire env gene of HIV-l. Recombinant vaccinia virus v-gag2 carries the entire HIV-l gag and prt -34genes as well as part of the pol gene.

The New York City Board of Health strain of vaccinia virus was purified from a commercial preparation of smallpox vaccine (Dryvax Lot 321501G) marketed by Wyeth Laboratories (Marietta, PA). Smallpox vaccine was diluted with PBSAM (see below) and plaque-purified three times successively on BSC-40 cells. A stock (hereafter designated as v-NY) was prepared on BSC-40 cells from such a plaque-purified isolate and was used to construct recombinant viruses. 6.1.2. DETECTION OF HIV ENVELOPE AND CORE ANTIGENS Four techniques were used for the detection of HIV-l env and gag proteins: radioimmunoprecipitation (RIP), capture enzyme immunoassay (EIA), western blot analysis, and immuno 15 electron microscopy.

Radioimmunoprecipitations were performed essentially as described (Haffar et al., 1988, J. Cell. Biol. 107:1677) using human polyclonal anti-HIV-1 sera (Trimar, Inc.). Briefly, BSC-40 cells were infected with recombinant or 2Q parental vaccinia virus at a multiplicity of infection (MOI) of 10 PFU per cell per virus used. At 12 hours postinfection, the cells were radiolabeled for 4 hours with . . 35 [ S]-methionine and [ S]-cysteine (100 uCi/ml). Media was then collected and the cells washed with PBS, harvested, and lysed in RIP buffer (1% NP40, 0.5% deoxycholate, 0.1% SDS in PBS). Post-nuclear cell lysates or culture media were then reacted with the polyclonal antisera for 30 minutes at room temperature. Antibody-antigen complexes were incubated with 10% glutaraldehyde-fixed Staphylococcus aureus (Staph A) for minutes at room temperature. Staph A-antibody-antigen complexes were sedimented ! y ecntr liugati·. π ruu wtv.· 3 e with RIP wash buffer (1% NP-40, 0.1% SDS in PBS). The resulting pellets were solubilized with SDS-PAGE sample buffer (Laemmli, 1970, Nature 227: 680), fractionated in -3511.5% polyacrylamide gels, and the immunoprecipitated proteins visualized by autoradiography.

Capture enzyme immunoassay and western blots were used to specifically detect HIV-l p24 as described (Hu et al., 1987, Nature 328: 721) with a monoclonal antibodies against p24. The monoclonal antibodies used for both capture enzyme immunoassays and Western blots were generated to p24 sequences by immunization of mice with recombinant fusion peptides that define overlapping sequences in the p24 10 protein. Monoclonal antibodies 25-2 and 25-3 were generated at Genetic Systems (Seattle, WA) and are described in United States Patent Application Serial Nos. 054,026, filed April 30, 1987, and 105,761, filed October 7, 1987.

Immuno electron microcopy was used to detect gpl20 and gp41 envelope proteins on the surface of recombinant-made HIV-l particles using MAb 110-4 specific for gpl20 (Thomas et al., 1988, AIDS Res. Hum. Retroviruses 2: 25; Linsley et al., 1988, J. Virol. 62: 3695) and MAb 41-1 specific for gp41 (Gosting et al., 1987, J. Clin. Microbiol. 25: 845), as well as to elucidate the morphology of mature recombinantmade HIV particles, following the electron microscopy techniques described in Section 6.1.3., infra 6.1.3 ELECTRON MICROSCOPY Recombinant-made HIV-l particles were isolated and prepared for EM visualization as follows: Culture media from 15 hr infected cell cultures were collected and pooled. The media was clarified from contaminating cells by centrifugation in a refrigerated table top centrifuge at 600 xg. The particulate fraction was then isolated from the ,,1 4- --. r entri' 120,000 xg.

The resulting supernatant was collected as the postparticulate material (S). The particulate pellet was resuspended in phosphate buffered saline (PBS) pH 7.4 and -36resedimented by ultracentrifugation at 120,000 xg through a 15% sucrose solution layer. The twice sedimented material was refered to as the particulate fraction (P).

The sedimented particulate pellet (P) was washed several 5 times by gently overlaying the pellet with PBS and then aspirating it off. The pellet was then fixed with 4% paraformaldehyde for 20 minutes and washed again with PBS.

In a similar procedure, small monolayers of BSC 40 cells 4 5 (10 -10 cells) were infected with the appropriate 10 recombinant viruses. After 15 hr the growth media was discarded, and the cell monolayers were washed several times with PBS and then fixed with 4% paraformaldehyde for 20 minutes at 22*C.

The fixed cells and fixed particulate pellets were then washed 5 times with PBS and then blocked with a solution containing 0.8% bovine serum albumin (BSA), 0.1% gelatin and 5% normal goat serum in PBS (blocking buffer) for 30 minutes. Blocking solution was decanted and monoclonal antibodies added to the cells as ascites fluid (diluted 1:2000 in blocking buffer) and allowed to incubate for 2 to hours. Cells were washed with PBS and then incubated with gold-conjugated goat anti-mouse secondary antibody (IgG conjugated to 15 nm colloidal gold; Janssen, Piscataway, NJ) at a dilution of 1:5 for an additional 2 hours, washed with PBS, and fixed in 2% glutaraldehyde. Samples were incubated with 1% osmium tetraoxide (OsO4) in 0.1 M Cacadylate buffer for 30 minutes at 22 °C. Samples were then rinsed well with PBS, and dehydrated by 3 minutes sequential incubations in 35%, 50%, and 75% ethanol, prior to staining with 3% uranyl acetate in 70% ethanol for 30 minutes at 22 °C. Samples were th»n further dehydrated with sequential incuba4· inns. :s described above, in 80%, 90%, 95%, and finally 100% ethanol (3 times), at 22’C.

Samples were then embedded in methacrylate resin -3710 (plastic) as follows: 1 hour treatment with absolute ethanol/plastic at a ratio of 2:1 respectively, overnight treatment with 100% plastic. The resin was then polymerized for 2 days at 60 degrees C. The plastic with the embedded samples was mechanically removed from the dish and thin sections (100 nm) were cut and collected on formvar coated grids. The grids were subsequently stained with saturated uranyl acetate/lead citrate (Millonig's) for 10 minutes each and washed extensively. The grids were evaluated after drying at 100,000 X magnification with a JEOL 100B transmission electron microscope at 60 kV. 6.2. GENERATION OF NONREPLICATING RECOMBINANTMADE HIV-l PARTICLES CONTAINING MATURE gag and env PROTEINS 6.2.1. ANALYSIS OF HIV-l PROTEINS EXPRESSED IN RECOMBINANT VACCINIA VIRUS INFECTED BSC-40 CELLS Cell lysates and growth media from metabolically radiolabeled BSC-40 cells infected with either v-env5, vgag2, both recombinants together, or parental vaccinia virus v-NY were analyzed for HIV-l proteins by RIP with human polyclonal anti-HIV-1 sera as described in Section 6.2.1., supra. As shown in FIG. 1, the gpl60 env precursor protein, as well as its proteolytic processing products gpl20 and gp41, were detected in the cell lysates of v-env5 infected cells (lane A). Additionally, gpl20 was secreted by the venv5 infected cells (lane B). The p55 gag precursor synthesized in v-gag2 infected cells is also processed to yield the mature gag proteins p24, pl7, pl5, as well as two intermediate precursor species p45 and p39 (lane E) (Gowda proLei were also detected in the culture supernatant (lane F).

BSC-40 cells coinfected with v-env5 and v-gag2 yielded processed env and gag proteins identical to those expressed -38in cells infected individually (lane C, compare with lanes A and E). The mature env and gag proteins generated by these doubly infected cells were similarly localized to the culture supernatants (lane D, compare with lanes B and F) with identical kinetics. Additionally, lactoperoxidase catalyzed iodination of plasma membrane-associated proteins revealed that the transport of gpl60, gpl20 and gp41 to the cell surface is the same in v-env5 infected cells as it is in doubly infected cells (Fig. 2, lanes A and B, respectively). 6.2.2. ISOLATION OF NONREPLICATING RECOMBINANT-MADE HIV-l PARTICLES To determine whether extracellular gpl20 and gp41 expressed by infected BSC40 cells are released as soluble 15 proteins or as constituents of budding particles, culture supernatants were separated by into particulate (P) and post-particulate (S) fractions (Section 6.1.3., supra) and the HIV protein content of each fraction analyzed by RIP in parallel with unfractionated culture supernatants (TS). As shown in FIG. 3(1) (lanes A, B and C), the extracellular gpl20 derived from v-env5 infected cells was detected primarily in the S fraction, suggesting that the protein is not a constituent of budding particles. However, gpl20 derived from cells coinfected with v-env5 and v-gag2 was detected in the P fraction as well as the S fraction (FIG. 3(1), lanes E and F respectively), though the particulateassociated gpl20 contributed little to the overall level of detectable extracellular gpl20.

In contrast to gpl20, gp41 was detected only in the P fraction of supernatants from doubly infected cells (FIG.3(1), lanes E vs D and F), indicating that gp41 is associated only with budding particles. Of interest is that the gpl60 env precursor was detected in the P fraction of supernatants from doubly infected cells, albeit at low -39levels (FIG. 3(1), lanes E vs D and F).

HIV-l core proteins expressed by infected BSC4O cells were analyzed similarly. All detectable core proteins— p24, p55, p45, p39, and pl7 — were observed in the P fractions from v-gag2 infected (FIG. 3(1), compare lanes H and I) as well as doubly infected (FIG. 3(1), compare lanes E and F) cell culture supernatants. P fractions obtained from doubly infected cells were also subfractionated by sedimentation through a continuous sucrose density gradient 1Q of 15%-60% and the presence of p24 antigen evaluated by EIA as described in Section 6.1.2., supra. The results depicted in FIG. 3(2) show that p24 partitions as a single prominent peak together with the 36%-40% sucrose fractions. These results suggest that the gag proteins expressed by infected BSC40 cells are released as constituents of particles of relatively uniform size. Moreover, the presence of gpl20 and gp41 in the P fractions of doubly infected cells suggests that the particles released from coinfected cells incorporate gpl20/gp41 complexes. This conclusion is further supported by the results obtained from immuno electron microscopy analysis (Section 6.2.3., infra). 6.2.3. ULTRASTRUCTURAL ANALYSIS OF RECOMBINANT-MADE HIV-l PARTICLES BY THIN SECTION ELECTRON MICROSCOPY To directly analyze the morphology of the recombinantmade HIV-l particles, P fractions isolated from the culture supernatants of BSC40 cells coinfected with v-env5 and vgag2 were reacted with monoclonal antibodies (MAbs) specific for either gpl20 (MAb 110-4) or gp41 (MAb 41-1). Primary 3q antigen-antibody complexes were further reacted with a secondary antibody-colloidal gold conjugate, embedded in plastic, and viewed by thin section electron microscopy (EM) as described in Section 6.1.3., supra. These analyses revealed particles of about 100-120 nm in diameter containing an electron dense rod-shaped (FIG. 4, *a* and -40c) or spherical (FIG. 4, b) core morphologically similar to EM images of isolated HIV-l virion particles (Gelderblom et al., 1988, Micron and Microscopia 19:41; Gelderblom et al., 1987, Virology 156: 171). Moreover, the particles were labeled with the colloidal gold conjugates indicating that they display gpl20 (FIG. 4, a* and *b*) and gp41 (FIG. 4, c) on their surfaces.

Intact BSC-40 cells coinfected with the two recombinant vaccinia viruses were similarly analyzed using the anti,0 gpl20 MAb. Numerous 100-120 nm particles positive for the gpl20 antigen were visualized. The majority of these cell associated particles assumed either of two distinct morphologies, one characterized by a diffuse vesicle form (FIG. 4, e, open arrow) and the other distinguished by an eccentrically-localized, thickened double-membrane region (FIG. 4, d, double arrow). Applicants speculate that these different structures represent various forms of immature particles which may parallel those occurring during HIV-l virion morphogenesis. Occasionally, particles containing a fully-formed rod-shaped capsid structure could be seen near the cell surface, as captured in the electron micrograph presented in FIG. 4, e (open arrow). Vaccinia particles budding from the cell membrane did not incorporate gpl20 (FIG. 4, d, double arrow). 6.2.4. NUCLEIC ACID CONTENT OF RECOMBINANTMADE HIV-l PARTICLES The nucleic acid content of the recombinant-made HIV-l . . . . . . 32 particles was determined by dot blot hybridization with P 2Q RNA probes reactive with either the gag or env sequences.

The probes were synthesized by in vitro transcription of DNZi. temple tes, carrying the gag or env sequences, in the presence of radiolabeled nucleotides using the Promega Riboprobe in vitro transcription kit according to manufacturers directions. Briefly, recombinant particles, -41equivalent to 300ng p24, were solubilized in RNA preparation lysis buffer (2M guandin isothiocyanate, 12 5mM sodium citrate pH 7.0, 0.125% sarkocinate, 50% dimethyl sulfoxide) and blotted onto nitrocellulose filters, in parallel with various concentrations of similarly solubilized Psoralininactivated HIV (equivalent to 2600ng, 260ng, 26ng, and 2.6ng p24). Separate filters were prepared for reaction with the gag specific or env specific probes. The nitrocellulose filters were incubated for 2 hour at 42 °C in 10 hybridization buffer (3x SSC, 50% Formamide, 5x Denhardt's solution, and 150ug nonspecific RNA), prior to addition of the respective probes. The filters were incubated with the probes overnight at 42 °C, then washed extensively with O.lx SSC/0.1% SDS solution, air dryed, and analyzed by autoradiography.

Autoradiograms of the dot bot hybridizations are shown in FIG. 5. Only the gag probe reacted with nucleic acids in the recombinant particle sample (panel A vs panel B). In contrast, both probes reacted with the Psoralin inactivated virus controls. This data suggests that the recombinantmade HIV-l particles packaged gag but not env RNA. This conclusion is consistent with the fact that the gag gene used for generating the v-gag2 vaccinia recombinant virus included the 5' untranslated sequences recently identified as the packaging signal for HIV viral RNA (FIG. 5, panel C, arrow).

These results indicate that the recombinant-made HIV-l particles do not have the capacity to replicate. This conclusion is supported by the experiments described in Section 12., infra, which demonstrate the absence of intracellular HIV nntigens in CD4+ ctils incuba' -.-1 recombinant-made HIV-l particles for an extended period. -427. EXAMPLE: GENERATION OF NONREPLICATING RECOMBINANT-MADE HIV-l PARTICLES USING A SINGLE RECOMBINANT VACCINIA VIRUS VECTOR As an alternative to the system for generating recombinant-made HIV-l particles using two recombinant vaccinia virus vectors as described in Section 6., supra, a single viral vector approach involving the construction of a recombinant vaccinia virus containing both the env and gag genes of HIV-l may be used. In the following example, a recombinant vaccinia virus containing HIV-l env and gag 10 genes is used to infect BSC-40 cells. The infected cells express envelope and core antigens of HIV-l, which assemble in the infected cells to generate the recombinant HIV-l particles. Recombinant HIV-l particles purified from the infected cell media are immunogenic in vivo. 7.1. GENERAL PROCEDURES 7.2. CONSTRUCTION OF V-G2E5: A RECOMBINANT VACCINIA VIRUS CONTAINING HIV-l ENV AND GAG GENES 2o A 3.2 Kbp fragment which contains the entire env-coding sequence of HIV-l (nucleotide no. 5707-8608) under the control of vaccinia virus 7.5K promoter was excised from plasmid pv-env5 (copending United States Patent Application Serial No. 07/593,401, filed October 5, 1990) by restriction endonuclease EcoRI. This fragment was inserted into the EcoRI site on plasmid pv-gag2N (identical to pv-gag2 described in copending United States Patent Application 07/593,401, filed October 5, 1990, with the exception that a synthetic linker containing translational termination signals was inserted at the Smal site downstream of the gag-coding sequence). Plasmid pv-gag2N contains the HIV-l yay ceiic cila j under the control of vaccinia virus 7.5K promoter. The construction of the resulting plasmid, pvG2E5, is schematically represented in FIG. 6. The HIV-l gag and env genes were introduced into the thymidine kinase gene of vaccinia virus by in vivo recombination as described in -43copending United States Patent Application Serial No. 07/593,401, filed October 5, 15141990, thereby generating recombinant vaccinia virus V-G2E5, containing both gag and env genes of HIV-l. 7.3. COEXPRESSION OF HIV-l ENVELOPE AND CORE ANTIGENS IN BSC-40 CELLS INFECTED WITH V-G2E5 African green monkey kidney cells (BSC-40) were infected with recombinant V-G2E5 at a multiplicity of infection of 5 pfu/cell. At 24 hr after infection, cells were washed and cell lysates were resolved by SDS-PAGE on a 7-15% gel. Proteins in cell lysates were transfered onto nitrocellulose filters and reacted with HIV-positive human sera, followed by goat anti-human immunogloblin antibodies conjugated to horseradish peroxidase. Immunoreactlve proteins were detected by reaction with peroxidase substrates. The results shown in FIG. 7 indicate that both envelope and core antigens of HIV-l were expressed and processed in cells infected with V-G2E5. The level of both antigens was comparable to that obtained in cells infected with either the env-containing or gag-containing recombinant vaccinia viruses alone. 7.4. RECOMBINANT HIV-l PARTICLES GENERATED IN V-G2E5 INFECTED BSC-40 CELLS_ Recombinant V-G2E5 was used to produce HIV-l-like particles from BSC-40 cells. BSC-40 cells were seeded onto Cytodex 3 beads (Pharmacia LKB Biotechnology) and were grown in spinner culture bottles in Dulbecco modified Eagle's medium with 5% fetal calf serum according to the manufacturer's recommendations. When cells attained confluency, they were infected with recombinant vaccinia virus V-G2E5 at a MOI of 5 pfu/cell. Following a 1 hr adsorption, the cells were washed twice with fresh medium to remove any excess inoculum. After 24 hr incubation at 37.5’C, culture medium was collected and cell debris removed -44by low speed centrifugation. Pre-cleared culture medium was then centrifuged for 3 hr at 19,000 rpm in a type 19 rotor (Sorvall). Pellets from this high-speed centrifugation were resuspended in PBS, pooled and resedimented by 5 centrifugation for 1 hr at 32,000 rpm using a SW55Ti rotor (Beckman). The final pellet was resuspended in cold PBS and stored at -70.5°C until use. The p24 and gpl20 antigen contents of the particle preparations were quantitated by p24 antigen capture and immunoblot assays, respectively, ,q essentially as described in Section 6.1.2., supra.

A radioimmunoprecipitation analysis of the particles produced by V-G2E5 infected cells is represented in FIG. 8. These results demonstrate the presence of both gpl20 and p24 antigens in the pellet fraction of infected cell medium after high-speed centrifugation, indicating the selective assembly of these mature virion proteins into particle forms. The relative abundance of p24 and gpl20 in these particles were similar to that of HIV-l virion preparations, underlying the structural and biochemical similarities between recombinant-made and authentic HIV-l virions. 8. EXAMPLE: GENERATION OF NONREPLICATING RECOMBINANT-MADE HIV-l PARTICLES BY TRANSFECTION OF PLASMID DNA INTO MAMMALIAN CELLS In addition to the systems for generating recombinant OC HIV-l particles using recombinant vaccinia virus vectors, described in Sections 6 and 7, supra, a system involving mammalian cells transfected with DNA encoding HIV-l env and gag genes may be used. This system allows for the generation of recombinant HIV-l particles in a stable mammalian cell line.

Generatija of recombinant-made L1V particles using the system described herein may be accomplished using a variety of strategies, including but not limited to (1) the transfection of complex plasmid vectors containing multiple HIV structural or regulatory genes, (2) the co-transfection -45of multiple plasmid vectors containing different HIV genes, (3) the use of both constituitive and regulatable enhancer/promoter elements to drive the expression of HIV proteins, (4) the use of HIV regulatory proteins including 5 tat and/or rev to indirectly control the expression of HIV gag and env structural proteins, (5) the use of different cell lines for expression of HIV proteins and recombinantmade HIV particles, and (6) the use of plasmid vectors encoding modified HIV proteins. These variations allow for Ιθ the optimization of the system in different cell types and the manipulation of different protein species or structures in the recombinant HIV particles. 8.1. PLASMID CONSTRUCTS Many of the plasmid vectors used in this system contain a hybrid CMV:HIV Enhancer:Promotor (designated CmHi) derived from the expression vector pH3MPy, which contains the enhancer from cytomegalovirus immediate early gene fused to the promoter and tar region of HIV (nucleotides -69 to + 78). Some of these plasmid vectors contain alternative enhancer: promoter elements derived from the cytomegalovirus immediate early gene (designated CMV) or the mouse metallothionein-I gene (Mt). These regulatory elements are linked to gene sequences encoding HIV proteins which are followed by a Hpal to Hhal (nucleotides 1569 to 1680) fragment of Adenovirus2 containing the Ela gene polyA addition site, followed by the BamHI to SphI fragment of pBR322, cloned into the plasmid Bluescribe plus (Strategene). The individual HIV proteins encoded by each of these plasmid vectors are indicated in Table I, and «.•cbomat ir. diagrams of these plasmids are in FIG. 9. -46TABLE I HIV GENES ENCODED BY PLASMID VECTORS Vector HIV Genes Gag+Pro Tat Rev Env Other CmHiEnvS (1104-(bl) + CmHiTgfbEnv5 (1113-al) CmHiGag2Rre (1158-al) + + CmVGag2Rre (1159-al) CmHiRev (1132-cl) + + 10 CmvRev (1152-al) CmHiTat (1132-bl) + + BsMtRev (1202-2) BsMtTAT (1203-1) + + CmHIVdelXmn (1133-al) + + + Vif,Vpr, Vpu CmHIVdelKpnAvr(Gag2TRE) + + + + Vpu 15 (1160-al) The plasmid CmHiEnv5 (1104-bl) , has the Nrul to Hindlll fragement of pH3Mpy, containing the Cytomegalovirus immediate early gene enhancer and HIV promoter and tar element, linked to [HIV Envelope Env5 Cassette - what plasmid is this?/ (5671-8572, Avail to Kpnl).

Plasmid CmHiTgfbEnvS (1113-al) contains the Nrul to Pstl enhancer:promoter fragment of pH3MPy linked to chimeric TGF-y3:HIV env gene; the simiam TGF-beta gene, providing the „ 5'untranslated region and signal peptide, is fused directly zb at the signal cleavage site of the HIV env gene, extending from nucleotide 5856 to the Kpnl site at nucleotide 8572.

Plasmid CmHiGag2Rre (1158-al) contains the Nrul to Xbal enhancer:promoter fragment of pH3MPy linked to HIV gag and 30 pol coding sequences extending from the BssHII site at 718 nucleotide 257 to the Asp site at nucleotide 3372. This is the same region of gag coding sequence contained in the recombinant vaccinia virus v-gag2, and includes the entire gag reading frame followed by about half of the pol reading frame. Also included in this region are sequences which encode the HIV protease and much but not all of the region IE 904161 -47encoding reverse transcriptase. An Xbai linker providing translational termination codons was ligated to the Asp718 site. This is followed by a fragment of the HIV env gene, extending from Bglll at 7178 to HindHI at 7698, containing 5 the Rev responsive element. Plasmid CmvGag2Rre (1159-al) is identical except that the Nrul to Xbai cytomegalovirus enhancer and promoter fragment derived from the expression vector CDM8 (Invitrogen) was used.

Plasmid CmHiRev (1132-cl), contains the Nrul to Pstl ,q enhancer:promoter fragment of pH3MPy upstream of an intronless HIV Rev gene, extending from the Bsu36I site at nucleotide 5500 to the KpnI site at nucleotide 8572, with nucleotides 5590-7935 deleted. Plasmid CmvRev (1152-al) is identical, except that the Nrul to Xbai cytomegalovirus enhancer and promoter fragment derived from the expression vector CDM8 (Invitrogen) was used.

Plasmid CmHiTat (1132-bl) contains the Nrul to Bglll enhancer: promoter fragment of pH3MPy upstream of an intronless HIV tat gene, extending from Sail site at nucleotide 5331 to the KpnI site at nucleotide 8572, with nucleotides 5590-7935 deleted.

Plasmid BsMtRev (1202-2) contains a 1.7 kilobase fragment of the mouse metallothionein-I gene extending from an EcoRI site at approximately position -1700 to the transcriptional start site, upstream of an intronless HIV rev gene, extending from the Bsu36I site at nucleotide 5500 to the KpnI site at nucleotide 8572, with nucleotides 55907935 delted.

Plasmid BsMtTat (1203-1) contains a 1.7 kilobase fragment of the mouse metallothionein-I gene extending from , - Νλπ.ϊ si t - .,L appix->;ii::ately petition -1700 La the transcriptional start site, upstream of an intronless HIV tat gene, extending from the Sail site at nucleotide 5331 to the KpnI site at nucleotide 8572.

Plasmid CmHIVdelXmn (1133-al) contains the same hybrid CMV:HIV Enhancer: Promoter derived from the expression vector -48pH3MPy used in plasmids described above. This plasmid incorporates HIV 5' leader RNA sequences to the XmnI site at nucleotide 384 just inside the N-terminus of the gag reading frame; contained within this segment is the splice donor 5 site that is spliced to acceptor sites located upstream of many HIV genes, including those encoding the tat, rev and env proteins. The XmnI site at nucleotide 384 is joined through an Xbai linker (which contains a TAG translation termination codon, stopping translation of a gag N-terminal peptide after about 20 amino acid residues) to an XmnI at nucleotide 4034 near the C-terminus of the pol reading frame. HIV sequences then continue to the Kpnl site at nucleotide 8572, through the region encoding both HIV regulatory and minor structural proteins including vif, vpr, tat, rev, vpu, and for the HIV env protein. This plasmid should be able to encode each of the HIV proteins listed above through splicing between the 5' splice donor site located just before the N-terminus of the gag gene and splice acceptor sites located upstream of the various protein coding reading frames.

The plasmid CmHIVdelKpnAvr(Gag2TRE) (1160-al) contains hybrid CMV-HIV Enhancer: Promoter driving expression of the entire gag reading frame and the N-terminal portion of the pol reading frame (contained in the recombinant vaccinia virus v-gag2) directly joined in the 3' portion of the HIV genome containing sequences encoding the tat, rev and env proteins. In this plasmid the Nrul to EcoRI Cytomegalovirus immediate early gene enhancer segment of expression vector P3MPy is linked to HIV promoter sequence begining at nucleotide -69; HIV leader RNA sequences continue through the gag gene and into the pol gene to the KpnT site at nucleotide 3372, joined to a polylinker which includes an Nhel containing a TAG translation termination codon for the pol reading frame. This Nhel site is joined to an Avril site at nucleotide 5207 in the vpr reading frame. HIV sequences then continue to the Kpnl site at nucleotide 8572. -49This vector contains all of the sequence elements believed to important for the synthesis, splicing, cytoplasmic transport, translation, processing and function of HIV gag, protease, tat, rev, and env proteins. This plasmid should be able to encode HIV gag from unspliced mRNA and for each of the other HIV proteins listed above through splicing between the 5' splice donor site located just before the Nterminus of the gag gene and splice acceptor sites located upstream of the various protein coding reading frames. It ,q also includes the tar element located within the first sixty nucleotides of the HIV primary mRNA transcript which is required for tat transactivation from the HIV promoter, and the Rre (rev responsive element) located between nucleotides 7315 and 7559 which is required for rev catalyzed cytoplasmic localization of mRNAs encoding HIV structural proteins. Not contained in this plasmid vector are a central region of the HIV genome encoding the C-terminal half of the pol reading frame, including part of the reverse transcriptase protein and all of the integrase protein, all of the vif reading frame and the N-terminus of the vpr reading frame; also absent from this vector is most of the 5' LTR and all of the 3' LTR as well as most of the nef reading frame. 8.2. GENERATION OF RECOMBINANT-MADE HIV-l PARTICLES IN STABLE CHO CELL TRANSFECTANTS Plasmid vectors CmHIVdelKpnAvr(Gag2TRE) and CmHiEnv5 were transfected into dhfr- CHO cells. Transfected cell lines were selected by cotransfection with plasmid pSV2dhfr. 2θ CHO transfectante contained immunoreactive mature gag and env nrotojns, neoreted irs a particulate form with sedimentation properties similar to those of the HIV virion and the recombinant-made HIV-l particles produced as described in Section 6., et seq., supra. 8.2.1. TRANSFECTION AND SELECTION OF CELLS -50CHO cells (dhfr-) were transfected following growth in Ham's F12 nutrient mixture (without hypoxanthine) supplemented with 10% fetal bovine serum and 150 pg/ml proline in 60 mm tissue culture dishes to 50% confluency, transfer to serum free medium, incubation for 5 hours with a mixture of Lipofectin (BRL), the HIV expression plasmids CmHIVdelKpnAvr(Gag2TRE) (1160-al) and CmHiEnv5 (1104-bl), and the selectable plasmid pSV2dhfr, removal of the Lipofectin:DNA mixture and transfer back to medium 10 contianing serum. Two or three days post-transfection the cultures were transferred to selective medium, DMEM plus 10% FBS and proline. Two days later the cultures were trypsinized, and aliquots containing approximately 0.08% and 0.40% of the cells (estimated to contain approximately 1 and x 10J transfected cells, respectively) were transferred to well tissue culture wells. Aliquots containing 7.8% of the cells were also transferred to 6 well tissue culture dishes.

After 13 days of further culture in selective medium, a set of 6 well plates were fixed and cells were immunostained for expression of HIV proteins by incubation with serum from an AIDS patient (TriMar), followed by horseradish peroxidase conjugated goat anti-human antibody, and a peroxidase substrate (3-amino-9-ethyl-carbazole). There were 15-20 colonies of selected cells per well; approximately 10% of these colonies were found to contain HIV proteins by the immunostaining assay. This analysis indicated that only about 10 to 15 wells per 96 well plate seeded with the lower number of cells should contain a colony of transfected cells, and that a fraction of these would likely express HIV proteins .

Tissue culture media from individual wells of the 96 well plates were then collected and assayed by a gag protein antigen EIA for secreted gag protein (Section 6.1.2, supra). a number of candidate wells were identified by this assay. Twelve potentially positive wells, four wells derived from -51each of three independent transfections, were then chosen for expansion. Visual insepection of positive wells at this point revealed that some wells were essentially confluent, others had only small colonies of growing cells, and others apparently contained no viable cells. Cells from all three classes of potentially positive wells were expanded; wells were trypsinized and cells transferred to 6 well dishes for expansion.

In addition, a small fraction of the cells from each IQ candidate cell line was seeded into duplicate wells of a 24 well plate. After five days of growth, wild type HeLa cells or HeLa T4 cells (transfected with and expressing the CD4 protein) were added to each well. The following day, gag expression and env function was assayed by a focal immunoassay. Briefly, cells were fixed and incubated with a human anti-HIV serum, followed by a horseradish peroxidase linked goat anti-human antibody, and a peroxidase substrate (3-amino-9-ethyl-carbazole). Four cell lines, falling into two classses, were positive by this assay. Two lines (3010-C1 and 3010-C6) had only a small number of cells, but these stained very intensely and efficiently formed giant syncitia with HeLa T4 cells, but not with wild type HeLa cells. Two other lines (3010-C5 and 3010-C13) had many positive cells, but these stained less strongly and only a fraction formed syncitia with HeLa T4 cells. Cells from other lines failed to stain. The antibody staining of the positive cells suggests that they are synthesizing gag proteins, and the formation of syncitia with HeLa T4 cells demonstrates that they have functional gpl20 and gp41 envelope proteins on their cell surface.

After further expansion of each of the candidate lines, cell lysates were analyzed by Western blot for HIV protein synthesis. Cells in 60 mm or 100 mm tissue culture dishes were washed twice with PBS and collected directly into 300 μΐ or 750 μΐ of Laemmli sample buffer. Afer boiling, the total cellular protein in the sample was resolved by -52electrophoresis on a 10% polyyacrylamide gel or an 8-16% gradient polyacrylamide gel. Aliquots of HIV, CEM cells infected with HIV, and BSC-40 cells infected with vaccinia recombinants v-gagl, v-gag2, or v-env5 were included as 5 controls. The contents of the gel were electro-transferred to a sheet of nitrocellulose filter. The filter was reacted with either AIDS patient serum or serum from a rabbit immunized with gpl60 derived from v-env5 infected cells, extensively washed, reacted with 125-1 labeled Protein A, ,q and extensively washed again. The products were then visualized by autoradiography with X-ray film.

The four positive lines identified in the previous assay, were also found to be positive for gag proteins. 3010-C1 and 3010-C6 lysates contained several-fold more gag than did 3010-C5 and 3010-C13 lysates. Lines that were negative in the previous assay were also negative for gag by Western blot. Most of the immunoreactive material comigrated with the p55 precursor and as a slighter smaller species not corresponding to a major product in HIV or in cells infected with HIV or vacGagl; only very minor amounts of mature p24 and pl7 gag proteins were detectable in cell lysates. This analysis also demonstrated the presence of gpl60, gpl20 and gp41 envelope proteins in cell lysates of the positive cell lines. 8.2.2. CHARACTERIZATION OF RECOMBINANTMADE HIV-l PARTICLES To demonstrate that the gag and env proteins synthesized in these cells were assembled into virus-like particles and 3θ secreted, culture supernatants were collected and cleared by in'.' The particle fraction was collected by centrifugation (either 32,000 rpm in the SW55 rotor, 27000 rpm in the SW41 rotor, or 19000 rpm in the Type 19 rotor). Western blot analysis demonstrated that this material contains both gag and env proteins. The primary gag proteins detected in the particles are the mature p24 ,Ε 904161 -53and ρ17 species; smaller amounts of the p55 and p40 precursors could also be detected. In contrast, precursor species accounted for most of the material in cell lysates. Gpl60, gpl20, and gp41 envelope proteins were all detected in the particles.

Comparison of Western blots suggests that only a small fraction of the gag and env proteins contained in the cells are secreted as particles. Quantitative gag antigen EIA analysis of multiple 3010-C6 cell-derived particle ,q preparations suggested yields of 3-17 ng gag per ml of culture medium. Particles from the 3010-C6 cell line were also analyzed by sedimentation into a sucrose gradient (2 hours at 50,000 rpm in the SW55 rotor, 15-60% sucrose). As shown in FIG. 10, both gag antigen EIA and Western blot ,5 assay of fractions from the gradient showed that the particles banded in a single peak at approximately 35-40% sucrose. 8.3. ALTERNATIVE STRATEGIES FOR EXPRESSION OF ENV AND GAG PROTEINS AND GENERATION OF RECOMBINANT20 MADE HIV-l AND PARTICLES IN MAMMALIAN CELLS In this section, a number of variations representing alternative strategies for the expression of HIV proteins and recombinant-made HIV particles in transfected cells are described. Possible variations include, but are not limited 25 to, (1) the transfection of complex plasmid vectors containing multiple HIV structural and/or regulatory genes, (2) the co-transfection of multiple plasmid vectors containing different HIV genes, (3) the use of both constituitive and regulatable enhancer/promoter elements to drive the expression of HIV proteins, (4) the use of regulat«d expression ox HIV reguLatory proteins i:iciud.i ng tat and/or rev to indirectly control the expression of HIV gag and env structural proteins, and (5) the expression of HIV proteins in different cell types. Such variations may be useful in optimizing various parameters of the system, -5435 and provide for the independent manipulation of the protein components of the particles and the levels of expression in different cell types.

Plasmids and combinations of plasmids were tested by 5 transient transfection into HeLa (and in a few cases BSC-40 and Vero) cells by standard calcium phosphate transfection procedures. Products were analyzed by polyacrylamide gel electrophoresis of total cell lysates or of recombinant-made HIV particles collected from culture medium by high speed ,q centrifugation, electro-transfer to nitrocellulose filters, and probing with specific anti-sera. For analysis of env proteins, the filter was probed with 125-1 labeled monoclonal antibody 110-4 (Section 6.1.2., supra), which binds an epitope in the V3 region of gpl60 and gpl20; for analysis of gag proteins the filter was probed with AIDS patient serum (TriMar) followed by 125-1 labeled Protein A. The products were then visualized by autoradiography with X-ray film. 8.3.1. EXPRESSION OF HIV PROTEINS IN HeLa CELLS CAN BE OBTAINED FROM MANY DIFFERENT PLASMIDS AND COMBINATIONS OF PLASMIDS Expression of HIV gag and env proteins can be obtained by transfection of complex plasmids encoding multiple HIV proteins, including both structural and regulatory proteins; 2$ alternatively, multiple plasmids encoding different HIV proteins can be transfected together.

Transfection into HeLa cells of plasmids coding individually for env (CmHiTgfbEnvS or CmHiEnv5), or for gag (CmHiGag2Rre), in combination with plasmids encoding tat and rev proteins results in the expression of immunoreactive yplCCi and pyl20 HIV envelope proteins or in the expression of immunoreactive HIV gag related proteins including the p55 primary translation product, p47 and p39 processing intermediates, and p24 and pl7 mature gag proteins.

Alternatively, transfection into HeLa cells of plasmid -55vectors (CmHIVdelXmn or CmHIVdelKpnAvr(Gag2TRE)), which contains in a single transcriptional unit the functional coding sequences for the both the tat and rev regulatory proteins and the env, or both env and gag, structural protein(s) also results in the synthesis of both precursor and mature env or gag and env proteins. Co-transfection of CmHIVdelXmn with CmHiGag2Rre or CmVGag2Rre also results in the synthesis of both gag and env proteins. Each of the plasmids or combinations CmHIVdelKpnAvr(Gag2TRE) (1160-al), 10 CmHIVdelXmn (1133-al) + CmHiGag2Rre (1158-al), and CmHIVdelXmn (1133-al) + CmvGag2Rre (1159-al) also results in the secretion of recombinant-made HIV particles into the culture medium.

Thus, the expression of gag and env structural proteins and the production of recombinant-made HIV articles using this system may be achieved by multiple routes. Comparisons of the levels of expression achieved with different plasmid combinations are shown in Table II, below, demonstrating that different combinations may be optimal for the expression of different proteins. For exanple, env appears to be more efficiently expressed when co-transfected with plasmids coding separately for tat and rev proteins. On the other hand, gag may be more efficiently expressed from a plasmid such as CmHIVdelKpnAvr(Gag2TRE) (1160-al), which contains in a single transcriptional unit the functional coding sequences for both regulatory proteins. Intermediate levels of both proteins were obtained by co-transfection of the complex plasmid CmHIVdelKpnAvr(Gag2TRE) (1160-al) and a separate env coding plasmid.

TABLE II RELATIVE LEVELS OF EXPRESSION OF env AND gag PROTEINS OBTAINED USING DIFFERENT COMBINATIONS OF PLASMIDS Plasmids env gag CmHiEnv5 + CmHiTat + CmHiRev ++++ CmHiGag2Rre + CmHiTat + CmHiRev - ++ CmvGag2 + CmvRev _ + CmHIVdelXmn + - CmHiGag2Rre + CmHIVdelXmn + ++++ CmHIVdelKpnAvr(Gag2TRE) + ++++ CmHiEnv5 + CmHIVdelKpnAvr(Gag2TRE) +++ +++ Relative expression levels of gag and env obtained after transfection with various combinations of plasmids are indicated in arbitary units; gag and env expression levels were determined independently, and are not necessarily represented by the same scale.

In these examples, rev is important for the efficient cytoplasmic localization of mRNAs encoding HIV structural proteins, and is dependent on a cis-acting regulatory element, termed the rev responsive element (Rre), located within the portion of the HIV env gene encoding the Nterminal portion of the gp41 molecule, which was introduced into the gag plasmids as a Bglll to Hindlll fragment from the envelope gene, and may be intrisinically necessary for efficient expression of HIV gag and env proteins. The tat piOtCx-l xS x i'l L-O l. I ci 1'i C. I. G Γ tl! I · J J./IQ G £ f.ilSCr X -J ί. A Ol i 5.11 1 ί i ci t Gci from the HIV promoter by its interaction with a cis-acting regulatory element, called tar, located within the first 75 nucleotides of HIV RNA transcripts. The tar gene is present in the CmHi hybrid enhancer element utilized by CmHiGag2Rre, CmHiTgfbEnvS, and CmHiRev. -57Expression of gag or env can be made independent of tat by co-transfection of plasmids such as CmvGag2Rre and CmvRev, since these plasmids do not contain the tar region. However, gag expression from transfection of CmvGag2Rre + 5 CmvRev is lower than from transfection of CmHiGag2Rre + CmHiTat - CmHiRev. Since the enhancer:promoter of the cytomegalovirus immediate early gene is known to be a very strong transcriptional element, this demonstrates that the combination of the CMV:HIV Enhancer:Promoter element plus ,q the HIV tat gene may be an especially strong expression system. Similar observations were also made in the context of env protein expression. Hybrids between the other enhancer elements and the HIV promoter/tar element may have other useful properties.

These results demonstrate that different HIV structural proteins may differ in their reguirements for HIV regulatory proteins or other factors to realize maximal expression, and that by choosing appropriate plasmids or combinations of plasmids the ratio of gag to env proteins may be controlled.

These results also indicate that plasmids encoding different HIV proteins may be independently introduced into cells. As one example, a cell line producing recombinantmade HIV particles may be further transfected with a plasmid encoding a minor HIV protein such as vpu or vif to alter the production levels and/or properties of the recombinant-made HIV particles. As another example, cell lines transfected with a plasmid encoding tat, rev and gag proteins, which therefore produce particles containing only gag proteins, could be selected and subsequently transfected with different env coding plasmids to generate particles containing env proteins from different strains or having other strutural alterations. For example, upon comparing the expression of env proteins from genes containing either the natural signal sequence of the HIV env genes (CMHIEnvS) or a fusion between the signal sequence of simian TGF-beta-1 and the N-terminus of mature gp!60 (CmHiTgfbEnvS), equally -58efficient expression was observed. 8.3.2. REGULATION OF HIV env PROTEIN EXPRESSION BY THE USE OF REGULATABLE PROMOTERS_ In another embodiment, dhfr- CHO cells were transfected . with the plasmid combination CmHiTgfbEnvS + CmHiTat + CmHiRev, along with the selectable plasmid pSV2dhfr.

Initial examination of cell lines selected in this experiment did not reveal detectable levels of HIV env expression. Cells were then further selected by growth in increasing levels of methotrexate for amplification of the transfected selectable pSV2dhfr plasmid and co-amplification of the HIV tat, rev and env coding plasmids in the hope that this would select for amplification of low levels of HIV env expression. One cell line was identified in which HIV env proteins were being synthesized. However, selection for further amplification of the dhfr gene and the cotransfected HIV protein encoding plasmids by growth in progressively higher concentrations of methotrexate did not lead to increased env protein expression. Rather, continued selection was required to maintain env protein expression levels, as envelope protein expression levels decreased in cells grown without escalating selection. Cells expressing higher levels of env proteins also seemed to grow more slowly and to a lower density than cells lines that had reverted to lower levels of env protein expression. These results suggest that envelope protein expression is toxic in these cells, and may therefore represent a limitation on the attainable levels of env protein expression.

This limitation may be overcome by the use of plasmids utilizing regulatable promoters controlling the expression of HIV proteins. Such plasif.ics can ba trunsxected into cells which would initially be grown in the uninduced state, then be induced to high levels of HIV protein expression to allow short-term high levels of production before the onset of the toxic effect. -59As an example of such an approach, plasmids individually encoding tat and rev proteins under the control of the metal regulated mouse metallothionein-I promoter were constructed. Co-transfections of HeLa cells with the plasmid combinations, (a) CmHiTgfbEnvS + CmHiTat + CmHiRev, (b) CmHiTgfbEnvS + BsMtTat + CmHiRev, and (c) CmHiTgfbEnvS + CmHiTat + BsMtRev, followed by Western blot analysis of total cellular lysates were all shown to produce immunoreactive gpl60 and gpl20 HIV envelope proteins (FIG. ,θ 11). Transfection with CmHiTgfbEnvS + CmHiTat + CmHiRev generated the highest level of env protein expression. More significantly, in the transfections utilizing that Mt promoter, expression levels were found to be induced several-fold by the addition of zinc to the tissue culture medium about a day prior to harvest. (See FIG. 11).

These results demonstrate that regulatable promoters can be used to modulate the expression of HIV proteins, and that the expression of HIV structural proteins can be indirectly regulated by modulation of the HIV tat and rev regulatory proteins. Other examples of this approach include the use of regulatable promoters to control expression from complex plasmids encoding multiple HIV proteins, or the construction of novel inducible regulatory elements, for example, such as a hybrid Mt:Hi enhancer promoter containing the metal regulatory elements of the metallothionein promoter linked to the promoter and tar region of HIV. 8.3.3 . EXPRESSION OF HIV PROTEINS IN BSC-40 AND VERO CELLS In this example various plasmid combinations encoding HIV tat, rev, env and gag proteins, including CmHiGag2Rre + CmH.iEnvS + CmHiTat + CmHiRev together, and CmHIVdelKpnAvr(Gag2TRE), were transfected into HeLa, BSC-40 and Vero cells. The basic pattern of expression of gag and env, both with respect to the products made and expression efficiency are similar in all three cell lines. However, overall expression levels are highest in HeLa cells, -60approximately 3-fold lower in BSC-40 cells, and another 5fold lower in Vero cells.

These results, along with those described above with CHO cells, demonstrate that a variety of cell lines, derived 5 from different species and different organs can be used to express HIV proteins, so that cells with particular desired characteristics can be chosen for particular applications. 9. EXAMPLE: GENERATION OF RECOMBINANT HIV-l PARTICLES HAVING MODIFIED STRUCTURAL CHARACTERISTICS USING RECOMBINANT 10 VACCINIA VIRUS EXPRESSING TRUNCATED FORMS OF HIV-l ENVELOPE ANTIGENS Two recombinant vaccinia viruses which direct the expression of truncated HIV-l gpl60 in infected BSC-40 cells are described below. These recombinant vaccinia viruses may be used as vectors, in conjunction with v-gag2 (Section 6., et seq., supra) or other core antigen-encoding vectors, for generating recombinant HIV-l particles which may have enhanced anti-viral and/or immunogenic properties using the system described in Section 6., supra. 9.1. RECOMBINANT VACCINIA VIRUS V-ED2 A recombinant plasmid was constructed which contained the HIV-l env encoding sequence from nucleotide numbers 5705 to 8068 inserted into vaccinia recombination vector pGS62 at the BamHI site downstream from the 7.5K promoter. The HIV-l 25 sequence was derived as a 2.36 Kbp BamHI fragment from plasmid pv-env5 (copending United States Patent Application Serial No. 07/593,401, filed October 5, 1990). The fragment contained the entire coding sequence of gpl20 and the N3θ terminal 241 amino acids of gp41, including 49 amino acid residues of the cytoplasmic region of gp41 at the C-terminus of the proposed transmembrane sequence. The chimeric gene containing the 7.5K promoter and the HIV-l env sequences was inserted into the vaccinia virus thymidine kinase gene according to procedures described in copending United States Patent Application Serial No. 07/593,401, filed October 5, -611990.

The resultant recombinant virus v-ED2 directs the expression of a truncated gpl60 which is cleaved into gpl20 and gp41 as efficiently as wild-type gpl60 (FIG. 12). HeLa CD4 cells infected with v-ED2 formed syncytia (multinucleated giant cells, characteristic of HIV-l infection) more readily than v-env5, which expresses a full-length gpl60 envelope glycoprotein precursor. These results indicate that the envelope glycoproteins produced by 10 v-ED2 may be functionally more active or more efficiently presented than wild-type envelope glycoproteins. 9.2. RECOMBINANT VACCINIA VIRUS V-ENV5DCT Recombinant virus V-ENV5DCT was constructed to contain the entire env coding sequence of HIV-lv (BRU isolate; Wain-Hobson et al., 1985, Cell 40:9317), except for the Cterminal 13 amino acids of gp41. The deletion mutation was introduced by an oligonucleotide mutagenesis procedure as described (Kunkel et al., 1987, Meth. In Enzymol. 154:3672o 382). The chimeric gene containing the 7.5K promoter and the mutated HIV-l env sequences was inserted into the vaccinia virus thymidine kinase gene according to procedures described in copending United States Patent Application Serial No. 07/593,401, filed October 5,1990.

. EXAMPLE: GENERATION OF RECOMBINANT HIV-l PARTICLES HAVING MODIFIED STRUCTURAL CHARACTERISTICS USING RECOMBINANT VACCINIA VIRUSES EXPRESSING UNPROCESSED GP160 Two recombinant vaccinia viruses which direct the 30 expression of a gpl60 precursor envelope glycoprotein having ΐ.:·-ι Latieiif i.-i Lw proi. coly Lie e lea vat. ·; site(:·) between gpl20 and gp41 are described herein. These recombinant vaccinia viruses may be used as vectors in conjunction with v-gag2 or other core-antigen-encoding vectors for generating 35 recombinant HIV-l particles which may have enhanced antiviral and/or immunogenic properties using the system -62described in Section 6., supra. .1. RECOMBINANT VACCINIA VIRUS V-160NC A recombinant plasmid (pv-160NC) was constructed that contained a mutated gpl60-coding sequence from nucleotide numbers 5803 to 8495 inserted downstream from the 7.5K promoter in vaccinia recombination vector pGS62. The mutations were introduced by oligonucleotide-directed mutagenesis essentially as described (Kunkel et al., 1987 10 (Meth. Enzymol. 154:367-382). The mutated sequences are shown below (*f* represents cleavage site between gpl20 and gp41): HIV-l BR env gpl20 t gp41 Gin Arg Glu Lys Arg t Ala wild-type* ...CAG AGA GAA AAA AGA t GCA... V-160NC ...CAG ATA GAA GAA TTC t GCA... Gin lie Glu Glu Phe t Ala The chimeric gene was inserted into the vaccinia virus genome at the thymidine kinase gene by in vivo recombination as described in copending United States Patent Application Serial No. 07/593,401, Filed October 5, 1990. The resulting recombinant virus directs the expression of a gpl6O precursor envelope glycoprotein that is not cleaved into gpl20 and gp41. .2. RECOMBINANT VACCINIA VIRUS V-11K160NC A recombinant vaccinia virus containing the same mutated HIV-l env gene as V-160NC (Section 10.1., supra), but under the control of vaccinia virus 11K promoter was constructed.

A 2.26 Kbp BamHI fragment was excised from plasmid pv-160NC and was inserted into a derivative of vaccinia recombination 35 vector pSClO (Chakrabarti et al., 1985, Mol. Cell. Biol. 5:3403-3409) at the EcoRI site downstream from the 11K -63promoter. This generated a chimeric gene containing the vaccinia virus 11K promoter and the entire coding sequence for the mutated gpl60. The chimeric gene was inserted into the vaccinia virus genome at the thymidine kinase gene. The resultant recombinant virus directs high level production of mutant HIV-l gpl60 in infected cells. 11. EXAMPLE: RECOMBINANT VACCINIA VIRUS EXPRESSING HIV-l vpu GENE The assembly and production of recombinant-made HIV-l 10 . . ... particles requires no HIV-l-specific proteins other than the co-expression of HIV-l envelope and core antigens. However, other factors, both of viral and cellular origins, may participate and enhance this process. One such factor is a viral protein encoded by vpu. This protein is a nonglycosylated polypeptide of 16 Kd apparently associated with the inner surface of the cytoplasmic membrane. Although vpu is not required for particle formation, mutations in vpu result in a decrease in virions released from infected cells (Terwilliger et al, 1989, Proc. Natl. Acad. Sci. U.S.A. 86:5163-5167; Strebel et al., 1989, J. Virol. 63:3487-3791). The mechanism of vpu action is not known and its role in particle formation in a recombinant system, such as the one described here, has not been defined. It is anticipated that accessory molecules, such as vpu, may play a role in facilitating the process of virion assembly and/or release. The following example describes a system with which the potential role of such accessory molecules could be examined and their utility in recombinant particle production 3θ demonstrated.

A recombinant vaccinia virus was constructed thatcontained the entire HIV-l vpu-coding sequence. A 290-bp fragment of HIV-l cDNA from nucleotide numbers 5636-5927 was inserted into vaccinia recombination vector pGW62 between the Smal and EcoRI sites downstream from the 7.5K promoter. This fragment contains the coding sequence of vpu as well as -647 bp of 5'- and 37 bp of 3'-untranslated sequences. The chimeric gene was then inserted into the vaccinia virus genome by in vivo recombination. The effect of vpu on recombinant particle formation and release can be demonstrated in cells co-infected with v-vpu and V-G2E5 as described in Section 7, et seq., supra. 12. EXAMPLE: ANTIVIRAL EFFECT OF RECOMBINANT-MADE HIV-l PARTICLES This example demonstrates the ability of the recombinant-made HIV-l particles of the invention to reduce or abrogate the infectivity of CD4+ lymphocytes by HIV in vitro. The results indicate that recombinant-made HIV-l particles effectively inhibit HIV-l infection in dosedependent manner. 12.1. INFECTIVITY ASSAY T-lymphoblastoid cells (CEM) were seeded into 24 well 4 culture plates at 4x10 cells/well m 0.4 ml culture media (RPMI-1640 supplimented with 10% Fetal Calf Serum).

Duplicate wells then received varying amounts (see TABLE 1) of recombinant-made HIV-l particles in 0.4 ml media. The added particles were quantitated by the equivalent p24 gag concentration determined by EIA (Section 6.1.2., supra).

Control wells received no particles but were corrected for 25 volume by the addition of 0.4 ml media. Cells and particles were allowed to incubate at 37’C for 3 hours prior to addition of HIV. A set of duplicate wells corresponding to each of the various particle concentrations received (1) no HIV input, (2) low virus input of 40 TCID5Q (tissue culture infectious dose units 50) corresponding to 5pg p24 crag, or (3) high virus input of 400 TCTDj-θ, corresponding to 50pg p24. At day three post-infection, the culture media was withdrawn from the wells and replaced with fresh media containing the appropriate original concentration of particles. At day five and then day six post-infection, -65aliquots of cells were collected from all wells and assayed for infectivity by determining intracellular expression of HIV antigens using an indirect immunofluorescence assay employing human polyclonal anti-HIV sera as primary 5 antisera, followed by goat anti-human IgG fraction conjugated to fluorescene as secondary sera. 12.2. RESULTS The infectivity assay results presented in TABLE 1, below, indicate that recombinant-made HIV-l particles can block the infectivity of CEM cells by HIV virions in a dose dependent fashion. It can also be concluded that the recombinant particles themselves are non-infectious and do not replicate in the cell, since no intracellular fluorescence was detected in cells incubated with a high concentration of recombinant-made HIV-l particles (FIG. 13, Panel A). Additionally, whereas multiple syncytia were observed in cell cultures receiving either of the HIV inputs (FIG. 13, Panel C), recombinant particles did not induce any 2θ syncytia formation. -66TABLE III INHIBITION OF HIV VIRUS INFECTIVITY BY RECOMBINANT-MADE HIV-l PARTICLES RECOMBINANTMADE HIV-l CEM PARTICLES VIRUS* 2 FLUORESCENCE % CELLS_(FOLD EXCESS) _(TCID J_DAY 5 DAY 6 + 0 0 0 0 + 60 0 0 0 + 600 0 0 0 + 0 40 20 >90 + 60 40 10-20 >90 + 600 40 <1 10 + 0 400 90 >90 + 60 400 60-80 >90 + 600 400 30 >90 Fold excess of particles to virus was in relation to equivalent amount of p24 protein.

... Human Immunodeficiency Virus Type 1 (HIV-l), strain LAV-1 20 _ 13. EXAMPLE: RECOMBINANT-MADE HIV-l PARTICLES INHIBIT HIV-l INFECTION OF CULTURED PERIPHERAL BLOOD LYMPHOCYTES ISOLATED FROM HIV-l SEROPOSITIVE DONOR The example presented in Section 12., supra demonstrates 25 that recombinant-made HIV-l particles inhibited HIV-l infection of T-lymphoblastoid cells (CEM) in vitro in a dose dependent manner. The following example confirms that the recombinant-made HIV-l particles have antiviral effect using a cultured peripheral blood lymphocyte (PBL) system. The 30 PBLs used in this system are isolated from HIV-l infected sv.j..-positive donois, and the frequency of infected cells within the isolated PBL fraction ranges from 0.04% - 1.3% (Psallidopoulos, M.C. et al., 1989, J. Virol. 631:46264644). During culture, the virus infection spreads to the 35 uninfected CD4 cells by cell-free and cell-cell -67transmission. Recent results from other groups (Daar, E.S., et al. 1990 Proc. Natl. Acad. Sci. U.S.A. 87:6574-6578) suggested that laboratory isolates of HIV-l responded differently than primary patient isolates to netralization and to the effects of antiviral agents, such as soluble CD4. Therefore, using the cultured peripheral blood lymphocytes system to evaluate the antiviral effects of recombinant-made HIV-l particles may be a more biologically relevant system than the CEM cell system described in Section 12., supra. 13.1. INFECTIVITY ASSAY Peripheral blood lymphocytes (PBLs) were harvested from the blood of HIV-l seropositive donors by fractionation of the buffy coat material over a Hypaque ficoll cushion. The 15 cells were then incubated in culture media (RPMI-1640 supplemented with 10% Human Serum), and the CD8+ lymphocytes were depleted by treatment with CD8, CD16, and CD20 specific monoclonal antibodies for 1 hr at 37’C followed by the addition of rabbit complement for 1 hr at 4 °C (Zarling, J.M. 2o et al., 1990, Nature (London) 347: 92-95). The resulting cell preparation consisted mainly of CD4+ lymphocytes, B lymphocytes and macrophages. The cells were seeded into 24 well plates at IM cells/well in 0.5 ml culture media. Duplicate wells received varying concentrations (see Tables 25 IV and V) of either recombinant-made HIV-l particles, psoralen-U.V.-inactivated HIV-l virions, or purified HIV-l envelope glycoprotein precursor gpl60. All wells were then supplemented with 0.5 ml of culture media containing MAb G19.4 reactive with T cell CD3 antigen (Hoxie, J.A., et al. 30 1986 Science 234:1123-1127) at lug/ml final concentration as well as inter! euken 2 (TL-2) et a final r'nricenfr--f in’·· η + Γ·β-. Activation of T cells with a soluble CD3 MAb has been shown to induce the replication of latent HIV-l virus (Zarling, J.M. et al., 1990, Nature (London) 347: 92-95).

Four or five days following activation (donors Z29,Z30 or donors Z31,Z39 respectively), the culture media was -68withdrawn from the wells and the cells were washed with PBS supplemented with 10% human serum and replaced with fresh culture media. Identical samples were either allowed to incubate with the fresh media alone (see below) or were again supplemented with the appropriate concentrations of recombinant-made HIV-l particles or inactivated HIV-l virus. At certain intervals following the secondary addition of the particles or inactivated virus, as indicated in Table IV, samples of culture media were harvested from the wells and 10 analyzed for p24^a^ content by specific EIA (Section 6.1.2., supra). Additionally, cells were concomitantly collected and examined for HIV-l protein expression by indirect fluorescence using a mixture of monoclononal antibodies reacting with gpl20 and p24^ag.

Cells that had the recombinant-made particles or inactivated virus washed out on day four or five, were passaged on day 8 into new wells containing immobilized anti-CD3 MAb to induce continued replication of the cells.

On day 11, samples of culture supernatants were assayed for p24^ag production by EIA (see Table V). This portion of the experiment was designed to assess whether the inhibition of virus production detected following treatment with the recombinant-made HIV-l particles was a reversible phenomenon. 13.2. RESULTS The results of the infectivity assays are presented in Tables IV and V. The recombinant-made HIV-l particles inhibited the spread of virus infection through the culture in samples derived from four different seropositve patients. Thio inhibition war. der.rndnnt and wan de'.actaWc at. 0.1 pg/ml egivalent of p24ytlLj protein in samples treated with recombinant-made HIV-l particles. Although the psoralen/U.V. inactivated virus similarly inhibited the spread of virus infection in the cultures, in some instances (Table IV, donor Z29, day 6 samples), 10-fold more -69inactivated virus was needed compared to the recombinantmade HIV-l particles.

The persistent inhibition of p24*^a^ production by cells that had washed free of the recombinant-made HIV-l particles or the inactivated virus on day four (Table V) suggested that the removal of the particles was not sufficient to reverse the phenomenon. Interestingly, the data also suggested that the recombinant-made HIV-l particles were more efficacious in this inhibition than the inactivated 10 HIV-l virions (Table V, both donors). -70DONOR Z31 Z39 15 Z29 Z30 TABLE IV INHIBITION OF HIV-l VIRUS INFECTIVITY BY RECOMBINANT-MADE HIV-l PARTICLES - PERCENT INHIBITION TREATMENT DOSE(Mg/ml)1 OF p24? 9 PRODUCTION day 9 Particles 1 86 0.1 18 0.01 0 Particles 1 99 0.1 5 0.01 0 day 6 Particles 10 96 97 0.1 73 0.01 15 Inactivated 10 90 HIV 1 78 0.1 0 Particles 10 86 84 0.1 22 0.01 0 Inactivated 10 84 HIV 1 78 0.1 0 1Concentration of recombinant-made HIV-l particles and inactivated virus are listed with respect to the p24g g concentration. The relative envelope glycoprotein content of these preparations is 5-10% that of p24^ TABLE V INHIBITION OF HIV INFECTION BY THE RECOMBINANT-MADE HIV-l PARTICLES IS IRREVERSIBLE DONOR TREATMENT DOSE (pg/ml)1 PERCENT INHIBITION OF p24g 9 PRODUCTION Z29 Particles 10 >79 1 >51 0.1 0 0.01 0 Inactivated HIV 10 >44 1 0 0.1 0 Z30 Particles 10 99 1 91 0.1 52 0.01 4 Inactivated HIV 10 50 1 15 0.1 1 ^'Concentrations of treatments are as described in Table IV.2Inhibition of p24gag production was assayed on day 11 post-activation. The cells were washed on day 4 and allowed to recover in the absence of treatment. To insure cell growth the cells were cultured in the presence of 5% 11-2, and exposed to immobilized CD3 MAb on day 8. -7214. EXAMPLE: IMMUNOGENICITY OF RECOMBINANTMADE HIV-l PARTICLES IN VIVO_ The experiments described below were conducted to evaluate the in vivo immunogenicity of nonreplicating recombinant-made HIV-l particles using a small animal model. Rabbits were chosen for these studies since previous reports indicated the presence of neutralizing antibodies in rabbits immunized with various forms of HIV-based immunogens.

The humoral immune response of each immunized rabbit was evaluated by ELISA and Western Blot analysis. The ELISA 10 ... allowed the measurement of the overall HIV specific antibody titer, while the western blot analysis elucidated antibody reactivity with individual viral proteins. In addition, the cellular immune response elicited in two of the immunized rabbits was characterized. Results of these experiments 15 confirmed the ability of the recombinant made HIV-l particles to generate HIV-specific immune responses in immunized animals. 14.1. IMMUNOGENICITY ASSAY 20 Two New Zealand white female rabbits were immunized with either recombinant-made HIV-l particles (Section 6., supra) or psoralen inactivated HIV-l virus. The amounts of immunogens used were normalized according to their relative p24 gag protein concentrations as determined by capture EIA 25 (Section 6.1.2., supra). The immunization schedule is set forth in Table VI, below.

For the primary immunization (1*), the immunogens were formulated with Complete Freunds adjuvent at 1:1 ratio and 30 administered by intramuscular injections at amounts equivalent to 120ug p24 gag and 4-6ug gpl20 env proteins, live Weeks larer, the z’abbrts receivcJ secondary immunizations (2°, boost) by the subcutaneous route of material formulated in Incomplete Freunds adjuvent also at a 1:1 ratio. The amount of immunogen used in the 2° immunization was equivalent to 190ug p24 and 10-20ug gpl20 -73proteins.

Sera collected from animals at various time intervals were assayed for anti-HIV reactivity by ELISA using immobilized whole disrupted virus or immobilized purified gpl20 and/or Western blot analysis. Sera were also collected from each animal one week prior to the start of the experiment and used as preimmunization controls. For Western blot analysis, purified LAV-l virus was solubilized in SDS-PAGE sample buffer, and fractionated by 10 electrophoresis in a acrylamide gradient (7%-15%) slab gel. The fractionated viral proteins were transferred to a nitrocellulose filter using standard techniques. The filter was subsequently divided into identical strips and used in the Western blot analysis. Briefly, following blocking of the strips for 3 hours with blocking buffer (3% dried milk in PBS, BLOTTO) at 22’C, each strip was incubated with a 1:50 dilution, in BLOTTO 0.2% NP40, of specific rabbit serum sample overnight at 4 °C. The strips were then washed . 125 extensively, and incubated with I Protein A (ICN Radiochemicals) in BLOTTO 0.2% NP40 for 2 hours at 22 °C.

Protein bands were visualized by autoradiography. The sera were also tested for the presence of neutralizing antibodies that reduce the level of p24^a^ production, an indicator of virus production and release.

Presence of antibodies that neutralize the LAV-BRU isolate in the sera of the immunized rabbits were detected by using a in vitro CEM cell infectivity assay. Sera were heat inactivated and then serially diluted in culture medium (RPMI-1640 supplemented with 10% Fetal calf serum). Equal volumes of diluted serum and 30 TCIDCft of virus inoculum ou were mixed and incubated at 37° for 45 min. The challenged virus preparation (0.1ml) was added to 0.1ml cultures of CEM cells (2x10 cells) in 96-well microtiter plates and incubated at 37°C with occasional mixing. After 1 hour incubation, the virus-serum mixture was removed from the wells and replaced with culture medium containing the -74original rabbit serum at the appropriate diultion. After 5 days, the progress of the infection in the cultures was monitored by measuring the p24gag levels in the supernatants by EIA. ___: TABLE VI RABBIT IMMUNIZATION SCHEDULE ,q Rabbits 238,239 wk 0 : 1° immunization wk 5 : 2’ immunization wk33 : 3’ immunication (only rabbit 238) 241,243 wk 0 : 1° immunization wk 4 : 2’ immunization wkl8 : 3’ immunization (only rabbit 241) IMMUNIZATION1 RABBIT IMMUNOGEN 1’ 2 · 3 · 238 Recombinant-Made HIV-l Particles 12 0 ug 190 ug 14 0 ug 12 0 ug 100 ug 120 ug 239 Inactivated 120 ug 190 ug HIV-l 120 ug 100 ug Primary immunogens formulated in Complete Freunds Adjuvent and administered intramuscularly; secondary and tertiary immunogens formulated in Incomplete Freunds Adjuvent and administered subcutaneously. 14.2. RESULTS 14.2.1. ANTIBODY TITER DETERMINED BY ELISA FIG. 14 presents the relative antibody titers in serum samples collected prior to (Prebleed), as well as 2, 5, and 7 weeks following the 1* immunization as determined by ELISA for rabbits 238 and 239. Rabbit 238 (FIG. 14, graph A) -75exhibited a hightened immune response to HIV proteins after 5 weeks which was maintained following the 2° immunization (see week 7 data, i.e. 2 weeks post-boost). In contrast, substantial reactivity with HIV proteins was detected 2 5 weeks folowing 1’ immunization in rabbit 239 samples (FIG. 14, graph B), and diminished by 5 weeks. However, a prominent boosting effect in antibody titer was observed in serum sample collected from rabbit 239 at week 7.

One explanation for the poor boost response in rabbit 10 238 was that the 2’ immunization was administered to the animal during the peak immune response (see schedule of bleeds Table VI). In contrast, antibody titer was already declining in rabbit 239 (compare week 2 and week 5 bleeds) when the 2’ immunization was administered, thus the boost response was more dramatic.

Presented in FIG. 15 are the results of the ELISA assays conducted on all of the rabbit sera using either immobilized whole disrupted virus (panels 1 and 2) or immobilized purified envelope glycoprotein gpl20. The data 2q presented are the end point titers at different intervals following the primary immunization. The abscissa values represent the weeks post-primary immunizations when serum samples were collected. The arrows indicate the times of the secondary and tertiary immunizations (see Table VI). As shown, both rabbits immunized with the recombinant-made HIV-l particles (R238 and R241) as well as the rabbits immunized with the psoralen/U.V. inactiviated HIV-l virions (R239 and R243) generated a profile of antigen reactivity that correlated with the boost schedule. The titer of antibodies in the various rabbit sera reactive with the disrupted whole virus was primarily a reflection of the reactivity with the p2 4<=' llj protein, which constitutes approximately 90% of the protein content in both recombinant-made HIV-l and HIV-l virions. Reactivity to the whole virus was approxmiately two to three orders of magnitude higher than reactivity to gpl20, a disparity -76directly related to the low levels of the envelope glycoproteins (5-10%) in the particle structures. 14.2.2. NEUTRALIZATION OF HIV-l INFECTIVITY BY RABBIT ANTISERA 5 FIG. 16 shows that immunization with the recombinantmade HIV-l particles generated neutralizing antibodies to homologous HIV-l (LAV-1 strain, BRU isolate). As with the overall reactivity to viral proteins, the titer of the neutralizing antibodies correlated with the boost schedule.

FIG. 7C also shows that high neutralization titers were achieved in the sera of rabbits 238 and 241 immunized with recombinant-made HIV-l particles (FIG. 16, panel A). The titers reported correlate with 75% inhibition in p24^a^ production. 14.2.3. CELLULAR IMMUNE RESPONSE The cellular immune response elicited by immunization with the recombinant-made particles is summarized in TABLE VII below. These results indicate that lymphocytes isolated 20 from immunized rabbits proliferated in response to specific stimulation with HIV-l antigens, a response indicative of memory T cell activity necessary in cell-mediated immunity. The stimulation indicies were more significant following the tertiary immunizations in both rabbits immunized with the 25 recombinant-made HIV-l particles. The very high stimulation index measured for rabbit 243 was correlated with the overall high immune responses measured (FIG. 15, panel B; FIG. 16). -77TABLE VII HIV-SPECIFIC T CELL PROLIFERATIVE RESPONSE IN IMMNIZED RABBITS IMMUNOGEN ANIMAL STIMULATION ANTIGEN STIMULATION INDEX FIRST BOOST SECOND BOOST Recombinant 238 Inactivated 3.0 15.0 Particles HIV Recomb. Part. N.T. 8.4 241 Inactivated 2.2 5.4 HIV Recomb. Part. N.T. N.T. UV Psoralen 239 Inactivated 2.6 N.B. Inactivated HIV Recomb. Part. N.T. N.B. 243 Inactivated 95.0 N.B. HIV Recomb. 33.0 N.B.

Part.

N.B.: Not Boosted N.T.: Not Tested . .

Stimulation index: cpm [H]TdR mcoroporated into stimulated PB1, divided by cpm [HjTdR incorporated into stimulated PBL 14.2.4. WESTERN BLOT ANALYSIS OF ANTIBODY REACTIVITY The results of the Western blot analyses are presented in FIG. 8. The primary immune response in week 5 serum from rabbit 238 was directed against the gag proteins, with only gp41 env protein reactivity (FIG. 17, lane 1). Although no 2θ clear boosting effect was detected by ELISA from the week 7 serum sample of rabbit 238, Western blot analysis shows that there was i edistribution ot antibody response between the various gag proteins, and the emergence of new antibody reactivity with the higher molecular weight HIV proteins (Fig. 17, lane 2). In contrast, the prominent boosting effect with inactivated virus (FIG. 17, lane 3) was -78primarily due to enhanced reactivity with the gag proteins as well as the env gpl20 protein. Lanes 5, 6 and 7 of FIG. 17 represent reactivity of various concentrations (1:100, 1:1000, and 1:10000, respectively) of pooled human sera from 5 seropositive individuals and serve as control antibody.

. EXAMPLE: RECOMBINANT-MADE HIV-l PARTICLES BIND TO AND ARE INTERNALIZED WITHIN CD4+ CELLS Described herein is an experiment designed to test whether the recombinant-made HIV-l particles of the θ invention bind to CD4+ cells and enter by fusion with the plasma membrane as do HIV-l virions. .1. INTERNALIZATION ASSAY HeLa cells transfected with the gene encoding the CD4 molecule are used in this assay. These cells have been extensively characterized and have been shown to support productive HIV-l infection. Cells were grown in monolayers on a glass slide in Dulbecco's modified Eagles medium supplemented with 10% fetal calf serum. The cells were washed with PBS/1%FCS and incubated with 50^g/ml recombinant-made HIV-l particles for 2 hr at 37“C. The cells were then washed extensively and fixed with 3.7% paraformaldehyde solution. The fixed cells were incubated with a 1:100 dilution of a monoclonal antibodies mixture that reacts with the gpl20 and p24^a^ proteins of HIV-l for 30 min at 22’C. The cells were again washed extensively and incubated with 1:50 dilution of affinity purified goat anti-mouse antibodies conjugated to FITC. After 30 min at „ 22’C the cells were washed with PBS/1%FCS and mounted in mounting media for viewing. The samples were analyzed by Confocal Laser Scanning Microscopy (CLSM) to reveal intracellular staining. .2. RESULTS The assay results are represented by the CLS micrographs -79in FIG. 18. FIG. 18A shows a HeLaCD4+ cell exhibiting positive fluorescence following incubation with the recombinant-made HIV-l particles. FIG. 18B shows the same cell optically sectioned by CLSM, starting from the top of 5 the sample and progressing towards the slide surface in 1pm increments. The micrograph panels show that the fluorescence increases as more of the intracellular environment is revealed, indicating that the recombinantmade HIV-l particles were internalized following binding. 16. EXAMPLE: IMMUNOGENICITY OF RECOMBINANTMADE HIV-l PARTICLES IN NON-HUMAN PRIMATES The following examines the immunogenicity of recombinant-made HIV-l particles in a non-human primate species immunized with recombinant-made HIV-l particles, psoralen/UV-inactivated HIV-l virions, and recombinant vaccinia virus expressing HIV-l gag and env antigens. The results demonstrate that the recombinant-made HIV-l particles elicited both cell-mediated and humoral immune responses, including neutralizing antibodies to HIV-l. 16.1. IMMUNIZATION PROTOCOL Twelve macaques (Macaca fascicularis) were immunized with recombinant-made HIV-l particles, psoralen/UVinactivated HIV-l virions, or recombinant vaccinia virus 25 expressing HIV-l gag and env antigens, according to the following schedule: Group 30 (n=2) Primary Secondary Boosted Immunogen/Adjuvant Immunogen/Adjuvant at week 1. v-G2E5/none Particle/IFA 2 . v-G2E5/none rgpl60/IFA 3. Particle/IFA Particle/IFA 4. Particle/DETOX Particle/DETOX -80Inact.HIV/IFA Inact.HIV/IFA Inact.HIV/DETOX Inact.HIV.DETOX Immunizations with live recombinant vaccinia virus were , 7 performed with 1 x 10 plaque-forming-units of V-G2E5 Section 7., supra) per animal inoculated by skinscarification. Each dose of recombinant-made HIV-like particles and psoralen/UV-inactivated HIV virions contained 10 an equivalent of 200 μ% of p24 as determined by p24 antigen capture assay (Genetic Systems) and approximately 6 μg of gpl20 as determined by immunoblot assay. Recombinant gpl60 was purified from BSC-40 cells infected with recombinant vaccinia virus expressing the same antigen and was used at 6 μ

Claims (30)

1. WHAT IS CLAIMED:

1. A nonreplicating recombinant-made HIV particle comprising assembled core and envelope proteins

5 incorporating a plurality of immunogenic epitopes of native Human Immunodeficiency Virus.

2. A nonreplicating recombinant-made HIV particle comprising assembled core and envelope proteins ,q incorporating a plurality of immunogenic epitopes of native Human Immunodeficiency Virus and having a morphology substantially equivalent to native Human Immunodeficiency Virus.

15

3. The nonreplicating recombinant-made HIV particle of Claim 1 or 2 in which the core proteins comprise Human Immunodeficiency Virus Type 1 core proteins.

4. The nonreplicating recombinant-made HIV particle

20 Claim 3 in which the Human Immunodeficiency Virus Type 1 core proteins comprise p24.

5. The nonreplicating recombinant-made HIV particle of Claim 3 in which the Human Immunodeficiency Virus Type 1

25 core proteins comprise p24 and pl7.

6. The nonreplicating recombinant-made HIV particle of Claim 1 or 2 in which the envelope proteins comprise Human Immunodeficiency Virus Type 1 envelope proteins.

7. . The ηύϊ'.'ΐβρί Λ -itil .1 Γ·. ’ tii' ί * η>α> ·' U ’ {'tl < .··. C. i tof Claim 6 in which the HIV-I envelope proteins comprise gp41.

35

8. The nonreplicating recombinant-made HIV particle of Claim 6 in which the Human Immunodeficiency Virus Type 1

-85envelope proteins comprise gp41 and gpl20.

9. The nonreplicating recombinant-made HIV particle of Claim 6 in which the HIV-l envelope proteins comprise 5 gpl60.

10. The nonreplicating recombinant-made HIV particle of Claim 9 in which the gpl60 is not cleaved to yield gpl20 and gp41.

11. The nonreplicating recombinant-made HIV particle of Claim 9 in which the gpl60 is truncated.

12. The nonreplicating recombinant-made HIV particle ,5 of Claim 10 in which the gpl60 is truncated.

13. The nonreplicating recombinant-made HIV particle of Claim 1 and 2 in which the core proteins comprise HIV-2 core proteins.

14. The nonreplicating recombinant-made HIV particle of Claim 1 and 2 in which the envelope proteins comprise HIV-2 envelope proteins.

25 15. The nonreplicating recombinant-made HIV particle of Claim 1 and 2 in which the envelope proteins comprise both HIV-l and HIV-2 envelope proteins.

16. A nonreplicating recombinant-made HIV-l particle

30 comprising assembled HIV-l core and envelopes proteins ϊ pcrmn ·. l -.-5 γ-.·-,- n pi ora 1 ’ fy of immunogenic epitopes of native HIV-l.

17. A nonreplicating recombinant-made HIV-2 particle

35 comprising assembled HIV-2 core and envelope proteins incorporating a plurality of immunogenic epitopes of native

-86HIV-2.

18. A nonreplicating recombinant-made HIV particle comprising assembled HIV core and envelope proteins

5 incorporating a plurality of immunogenic epitopes of both native HIV-l and native HIV-2.

19. A vaccine formulation in which the immunogen comprises nonreplicating recombinant-made HIV particles of 10 Claim 1.

20. A vaccine formulation in which the immunogen comprises nonreplicating recombinant-made HIV particles of Claim 2.

21. A vaccine formulation in which the immunogen comprises nonreplicating recombinant-made HIV particles of Claim 3.

20 22. A vaccine formulation in which the immunogen comprises nonreplicating recombinant-made HIV particles of Claim 4.

23. A vaccine formulation in which the immunogen

25 comprises nonreplicating recombinant-made HIV particles of Claim 5.

24. A vaccine formulation in which the immunogen comprises nonreplicating recombinant-made HIV particles of

30 Claim 6.

25. A vaccine formulation in which the immunogen comprises nonreplicating recombinant-made HIV particles of Claim 7.

26. A vaccine formulation in which the immunogen

-87comprises nonreplicating recombinant-made HIV particles of Claim 8.

27. A vaccine formulation in which the immunogen

5 comprises nonreplicating recombinant-made HIV particles of Claim 9.

28. A vaccine formulation in which the immunogen comprises nonreplicating recombinant-made HIV particles of 10 Claim 10.

29. A vaccine formulation in which the immunogen comprises nonreplicating recombinant-made HIV particles of Claim 11.

30. A vaccine formulation in which the immunogen comprises nonreplicating recombinant-made HIV particles of Claim 12.

2q 31. A vaccine formulation in which the immunogen comprises nonreplicating recombinant-made HIV particles of Claim 13.

32. A vaccine formulation in which the immunogen

25 comprises nonreplicating recombinant-made HIV particles of Claim 14.

33. A vaccine formulation in which the immunogen comprises nonreplicating recombinant-made HIV particles of

30 Claim 15.

34. A vaccine formulation in which the immunogen comprises nonreplicating recombinant-made HIV particles of Claim 16.

35. A vaccine formulation in which the immunogen

-88comprises nonreplicating recombinant-made HIV particles of Claim 17.

36. A vaccine formulation in which the immunogen

5 comprises nonreplicating recombinant-made HIV particles of Claim 18.

37. A vaccine formulation in which the immunogen comprises a plurality of different nonreplicating 10 recombinant-made HIV particles.

38. A method for inhibiting the progression of Acquired Immunodeficiency Syndrome in an individual infected with Human Immunodeficiency Virus comprising administering

15. Nonreplicating recombinant-made HIV particles to the individual in an amount effective at inhibiting Human Immunodeficiency Virus infection.

39. A method for inhibiting the progression of

2o lymphadenopathy in an individual infected with Human

Immunodeficiency Virus comprising administering nonreplicating recombinant-made HIV particles to the individual in an amount effective at inhibiting Human Immunodeficiency Virus infection.

40. A method for inhibiting the progression of AIDSRelated Complex in an individual infected with Human Immunodeficiency Virus comprising administering nonreplicating recombinant-made HIV particles to the

30 individual in an amount effective at inhibiting Human Immunodel'ici...ncy Virus in·; ection .

41. A method for reducing the infectivity of CD4 + lymphocytes by Human Immunodeficiency Virus comprising

35 treating the lymphocytes with nonreplicating recombinantmade HIV particles in an amount effective at inhibiting

-89Human Immunodeficiency Virus infection.

42. A nonreplicating recombinant-made retroviral particle comprising assembled retroviral core and envelope

5 proteins incorporating a plurality of immunogenic epitopes of native human retrovirus.

43. A nonreplicating recombinant-made retroviral particle comprising assembled retroviral core and envelope

IQ proteins incorporating a plurality of immunogenic epitopes of native human retrovirus and having a morphology substantially equivalent to native human retrovirus morphology.

15 44. The nonreplicating recombinant-made retroviral particle of Claim 42 or 43 in which the retroviral core proteins comprise HTLV-I core proteins.

45. The nonreplicating recombinant-made retroviral

16. 20 particle of Claim 42 or 43 in which the retroviral core proteins comprise HTLV-II core proteins.

46. The nonreplicating recombinant-made retroviral particle of Claim 42 or 43 in which the retroviral envelope

17. 25 proteins comprise HTLV-I envelope proteins.

47. The nonreplicating recombinant-made retroviral particle of Claim 42 or 43 in which the retroviral envelope proteins comprise HTLV-II envelope proteins.

' . r ' rr-rr- - 1 i.-: n t;; .. re com) in ant-mn ic retroviral particle of Claim 42 or 43 in which the retroviral envelope proteins comprises both HTLV-I and HTLV-II envelope proteins.

49. A nonreplicating recombinant-made HTLV-I particle

-90comprising assembled HTLV-I core and envelope proteins incorporating a plurality of immunogenic epitopes of native HTLV-I.

5 50. A nonreplicating recombinant-made HTLV-II particle comprising assembled HTLV-II core and envelope proteins incorporating a plurality of immunogenic epitopes of native HTLV-II.

10 51. A nonreplicating recombinant-made HTLV particle comprising assembled HTLV core and envelope proteins incorporating a plurality of immunogenic epitopes of both native HTLV-I and HTLV-II.

15 52. A vaccine formulation in which the immunogen comprises nonreplicating recombinant-made retroviral particles of Claim 42.

53. A vaccine formulation in which the immunogen

20 comprises nonreplicating recombinant-made retroviral particles of Claim 43.

54. A vaccine formulation in which the immunogen comprises nonreplicating recombinant-made retroviral

25 particles of Claim 44.

55. A vaccine formulation in which the immunogen comprises nonreplicating recombinant-made retroviral particles of Claim 45.

55. A vac·, ine formulation in whic.h the i mrfuuiogen comprises nonreplicating recombinant-made retroviral particles of Claim 46.

35 57. A vaccine formulation in which the immunogen comprises nonreplicating recombinant-made retroviral

-91particles of Claim 47.

58. A vaccine formulation in which the immunogen comprises nonreplicating recombinant-made retroviral

5 particles of Claim 48.

59. A vaccine formulation in which the immunogen comprises nonreplicating recombinant-made HTLV-I particles of Claim 49.

60. A vaccine formulation in which the immunogen comprises nonreplicating recombinant-made HTLV-I particles of Claim 50.

15 61. A vaccine formulation in which the immunogen comprises nonreplicating recombinant-made HTLV particles of Claim 51.

62. A method for inhibiting the progression of Adult T

2Q Cell Leukemia in an individual infected with HTLV-I comprising administering nonreplicating recombinant-made HTLV-I particles to the individual in an amount effective at inhibiting HTLV-I infection.

25 63. A method for inhibiting the progression of HTLVI- associated lymphoma in an individual infected with HTLV-I comprising administering nonreplicating recombinant-made HTLV-I particles to the individual in an amount effective at inhibiting HTLV-I infection.

64. ?. Fo»· ϊ nh·?hi +-5 pq 1 progress · on of KTLV-II- associated leukemia in an individual infected with HTLVII comprising administering nonreplicating recombinant-made HTLV-II particles to the individual in an amount effective

35 at inhibiting HTLV-II infection.

-9265. A method for reducing the infectivity of CD4 + lymphocytes by a human retrovirus comprising treating the lymphocytes with nonreplicating recombinant-made retroviral particles capable of binding to the CD4 cell surface 5 receptor in an amount effective at inhibiting human retrovirus infection.

66. A method for generating nonreplicating recombinant-made retroviral particles comprising:

(a) introducing nucleotide sequences encoding retroviral core, protease, and envelope proteins into a mammalian host cell;

(b) coexpressing mature retroviral core and envelope proteins within the mammalian host cell ;

(c) culturing the mammalian host cell; and (d) recovering the nonreplicating recombinant-made retroviral particles from the culture medium.

25 67. The method according to Claim 66 in which the nucleotide sequences encoding retroviral core, protease, and envelope proteins are introduced into the mammalian cell by infection with a live viral vector.

18. 30 68. The method according to Claim 66 in which the j-.n1 on)- 5 ·?.-> sequences encoding rctroviraI core, prolease, nnd envelope proteins are introduced into the mammalian cell by infection with a plurality of live viral vectors.

19. 35 69. The method according to Claim 67 in which the live viral vector comprises a recombinant vaccinia virus.

-9370. The method according to Claim 68 in which the live viral vectors comprise recombinant vaccinia viruses.

71. The method according to Claim 67 in which the live 5 viral vector comprises a recombinant retrovirus.

72. The method according to Claim 68 in which the live viral vectors comprise recombinant retroviruses.

1Q 73. The method according to Claim 66 in which the nucleotide sequences encoding retroviral core, protease, and envelope proteins are introduced into the mammalian cell by transfection with a DNA vector.

15 74. The method according to claim 58 in which the nucleotide sequences encoding retroviral core, protease, and envelope proteins are introduced into the mammalian cell by transfection with a plurality of DNA vectors.

2o 75. A method for generating nonreplicating recombinant-made HIV particles comprising:

(a) coinfecting a mammalian host cell with (i) a recombinant vaccinia virus carrying an HIV env

25 gene and (ii) a recombinant vaccinia virus carrying HIV gag and protease genes;

(b) coexpressing mature HIV env and gag encoded gene products within the infected mammalian

30 host cell;

(c) culturing the infected mammalian host cell; and (d) recovering the nonreplicating recombinant-made HIV particles from the culture medium.

-9476. The method according to Claim 75 further comprising infecting the mammalian host cell with a recombinant vaccinia virus carrying at least one HIV gene selected from the group tat, rev, vif, vpr and vpu.

77. The methods according to claim 75 further comprising infecting the mammalian host cell with a plurality of recombinant vaccinia viruses together carrying

10 at least two H vif, vpr and v 78. The which the HIV 15 79. The which the HIV 80. The which the HIV 20 81. The which the HIV 82. The 25 which the HIV 83 . The which the HIV 30 84 . The γη ο pip

cell.

85. A method for generating nonreplicating 35 recombinant-made HIV particles comprising:

-95(a) infecting a mammalian host cell with a recombinant vaccinia virus carrying HIV env, gag and protease genes;

5 (b) coexpressing mature HIV env and gag encoded gene products within the infected mammalian host cell;

(c) culturing the infected mammalian host cell;

10 and (d) recovering the nonreplicating recombinant-made HIV particles from the culture medium.

86. The method according to Claim 85 further comprising infecting the mammalian host cell with a recombinant vaccinia virus carrying at least one HIV gene selected from the group tat, rev, vif, vpr, and vpu.

87. The method according to Claim 85 further comprising infecting the mammalian host cell with a plurality of recombinant vaccinia viruses together carrying

at least two : 25 vif, vpr and · 88. The which the HIV 30 89. The which the HIV 90. The which the HIV

τλ UTV35

91. The method according to Claims 85,

86, or 87 in

-96which the HIV gag gene is an HIV-2 gag gene.

92. The method according to Claims 85, 86, or 87 in which the HIV protease gene is an HIV-l protease gene.

93. The method according to Claims 85, 86, or 87 in which the HIV protease gene is an HIV-2 protease gene.

94. The method according to Claims 85, 86, or 87 in ,0 which the mammalian host cell is an African Green Monkey cell.

95. A method for generating nonreplicating recombinant-made HIV particles comprising:

(a) transfecting a mammalian host cell with a recombinant plasmid carrying HIV env, gag, and protease genes;

(b) coexpressing mature HIV env and gag encoded gene products within the transfected mammalian host cell;

(c) culturing the transfected mammalian host

25 host cell; and (d) recovering the nonreplicating recombinantmade HIV particles from the culture medium.

30 96. The method according to Claim 95 in which the recombinant piasmid also carries at least one other HIV gene selected from the group tat, rev, vif, vpr and vpu.

97. The method according to Claim 95 further comprising transfecting the mammalian host cell with a recombinant plasmid carrying at least one HIV gene selected

-97from the group tat, rev, vif, vpr and vpu.

98. The method according to Claim 95 further comprising transfecting the mammalian host cell with a

5 plurality of recombinant plasmids together carrying at least two HIV genes selected from the group tat, rev, vif, vpr and vpu.

99. The method according to Claims 95, 96, 97 or 98 in 10 which the HIV env gene is an HIV-l env gene.

100. The method according to Claims 95, 96, 97 or 98 in which the HIV env gene is an HIV-2 env gene.

15 101. The method according to Claims 95, 96, 97 or 98 in which the HIV gag gene is a HIV-l gag gene.

102. The method according to Claims 95, 96, 97 or 98 in which the HIV gag gene is an HIV-2 gag gene.

103. The method according to Claims 95, 96, 97 or 98 in which the HIV protease gene is an HIV-l protease gene.

104. The method according to Claim 95, 96, 97 or 98 in 25 which the HIV protease gene is an HIV-2 protease gene.

105. A method for generating nonreplicating recombinant-made HIV particles comprising:

30 (a) transfecting a mammalian host cell with (i) a recombinant plasmid carrying at leaq+and HIV env gene and (ii) a recombinant plasmid carrying at least HIV gag and protease genes;

(b) coexpressing mature HIV env and gag encoded

-98gene products within the transfected mammalian host cells;

(c) culturing the transfected mammalian host

5 cell; and (d) recovering the nonreplicating recombinantmade HIV particles from the culture medium.

106. The method according to Claim 105 further comprising transfecting the mammalian host cell with a recombinant plasmid carrying at least one HIV gene selected from the group tat, rev, vif, vpr and vpu.

107. The method according to Claim 105 further comprising transfecting the mammalian host cell with a plurality of recombinant plasmids together carrying at least two HIV genes selected from the group tat, rev, vif, vpr and

20 V P U ·

108. which the

The method according to HIV env gene is an HIV-l

Claims 105, env gene.

106 or 107 in

109. which the

The method according to HIV env gene is an HIV-2

Claims 105, env gene.

106 or 107 in

110. The method according to Claims 105, which the HIV gag gene is an HIV-l gag gene.

111. The method according to Claims 105, which the HIV gag gene is an KIV-2 gag gene.

106 or 107 in

106 or 107 in

112. The method according to Claims 105, 106 or 107 in 35 which the HIV protease gene is an HIV-l protease gene.

-99113. The method according to Claims 105, 106 or 107 in which the HIV protease gene is an HIV-2 protease gene.

114. The method according to Claims 95 or 105 in which 5 the mammalian host cell is a Chinese Hamster Ovary cell.

115. The method according to Claims 95 or 105 in which the mammalian host cell is a African Green Monkey cell.

q 116. The method according to Claims 95 or 105 in which the mammalian host cell is a Vero cell.

117. The method according to Claims 95 or 105 in which the mammalian host cell is a HeLa cell.

118. The method according to Claims 75, 85, 95 or 105 in which the HIV env gene encodes an uncleaved gpl60 protein.

119 in which

The method according to Claims 75, 85, 95 or 105 the HIV env gene encodes a truncated gp!60 protein.

120. A method for generating nonreplicating recombinant-made HIV-l particles comprising:

(a) coinfecting a BSC-40 host cell with recombinant vaccinia viruses v-env5 and v-gag2 as deposited with the ATCC:

(b) culturing the infected BSC-40 cell; and (c) recovering the nonreplicating recombinantmade HIV-l particles from the culture medium.

121. A method for generating nonreplicating — 100— recombinant-made HIV-l particles comprising:

(a) coinfecting a mammalian host cell with (i) a plurality of recombinant vaccinia

5 viruses each carrying a different HIV-l env gene and (ii) a recombinant vaccinia virus carrying HIV-l gag and protease genes;

(b) culturing the infected mammalian host cell;

10 and (c) recovering the nonreplicating recombinantmade HIV-l particles from the culture medium

122. A method for generating nonreplicating recombinant-made HIV-2 particles comprising:

(a) coinfecting a mammalian host cell with (i) a plurality of recombinant vaccinia viruses each carrying a different HIV-2 env gene and (ii) a recombinant vaccinia virus carrying HIV-2 gag and protease genes;

(b) culturing the infected mammalian host cell; and (c) recovering the nonreplicating recombinantmade HIV-2 particles from the culture medium

123. A method for generating nonreplicating recombinant-made HIV particles comprising:

(a) coexpressing HIV env encoded and HIV gag encoded structural proteins in

-101mammalian cells; and (b) recovering the nonreplicating recombinantmade HIV particles from the culture medium.

124. A method for generating nonreplicating recombinant-made HIV-l particles comprising:

(a) infecting a BSC-40 host cell with recombinant vaccinia virus V-G2E5 as deposited with the ATCC ;

(b) culturing the infected BSC-40 cell; and (c) recovering the nonreplicating recombinantmade HIV-l particles form the culture medium.

20 125. A method for generating nonreplicating recombinant-made HIV-l particles comprising:

(a) coinfecting a BSC-40 host cell with (i) recombinant vaccinia virus v-ED2 and (ii) recombinant vaccinia virus v-gag2;

(b) culturing the infected BSC-40 cell; and (c) recovering the nonreplicating recombinantmade HIV-l particles form the culture medium.

126. A method for generating nonreplicating recombinant-made HIV-l particles comprising:

(a) coinfecting a BSC-40 host cell with (i)

-102recombinant vaccinia virus V-ENV5DCT and (ii) recombinant vaccinia virus v-gag2;

(b) culturing the infected BSC-40 cell; and (c) recovering the nonreplicating recombinantmade HIV-l particles form the culture medium.

127. A method for generating nonreplicating recombinant-made HIV-l particles comprising:

coinfecting a BSC-40 host cell with (i) recombinant vaccinia virus V-160NC and (ii) recombinant vaccinia virus v-gag2;

culturing the infected BSC-40 cell; and recovering the nonreplicating recombinantmade HIV-l particles form the culture medium.

(a) (b) (c)

128. A method for generating nonreplicating recombinant-made HIV-l particles comprising:

(a) coinfecting a BSC-40 host cell with (i) recombinant vaccinia virus V-11K160NC and (ii) recombinant vaccinia virus v-gag2;

(b) culturing the infected BSC-40 cell; and (c) recovering the nonreplicating recombinantmade HIV-l particles form the culture medium.

129. A method for generating nonreplicating

-103recombinant-made HIV-l particles comprising:

(a) cotransfecting a mammalian cell with recombinant plasmids CmHIVdelKpnAvr(Gag2TRE)

5 (1160-al) and CmHiEnv5 (1104-bl) as deposited with the NRRL;

(b) coexpressing mature HIV env and gag encoded gene products within the transfected CHO

IO cells;

(c) culturing the transfected CHO cells; and (d) recovering the nonreplicating recombinant15 made HIV-l particles from the culture medium.

130. A method for generating nonreplicating recombinant-made HIV-l particles comprising:

(a) transfecting a mammalian cell with recombinant plasmids CmHIVdelKpnAvr(Gag2TRE) (1160-al) as deposited with the NRRL;

(b) coexpressing mature HIV env and gag encoded gene products within the transfected CHO cells;

(c) culturing the transfected CHO cells; and (J) L ·.··'. ...tlivj I i i e ΐιύΜ. .iCc.Liliy 1'fck’OjiiLiiiant— made HIV-l particles from the culture medium.

131. A method for generating nonreplicating recombinant-made HIV-l particles comprising:

-10410 (a) cotransfecting a mammalian cell with recombinant plasmids CmHiGag2Rre(1158-al) and CmHIVdelXmn(1133-al) as deposited with the NRRL;

(b) coexpressing mature HIV env and gag encoded gene products within the transfected CHO cells;

(c) culturing the transfected CHO cells; and (d) recovering the nonreplicating recombinantmade HIV-l particles from the culture medium.

132. A method for generating nonreplicating recombinant-made HIV-l particles comprising;

(a) cotransfecting a mammalian cell with recombinant plasmids CmHIVdelXmn(1133-al) and CmvGag2Rre(1159-al) as deposited with the NRRL;

(b) coexpressing mature HIV env and gag encoded gene products within the transfected CHO cells;

(c) culturing the transfected CHO cells; and (d) recovering the nonreplicating recombinantmade HIV-l particles from the culture medium.

133. A method for generating nonreplicating

35 recombinant-made HIV-l particles comprising:

-10510 (a) cotransfecting a mammalian cell with recombinant plasmids CmHiGag2Rre, CmHiEnvS, CmHiTat and CmHiRev as deposited with the NRRL;

(b) coexpressing mature HIV env and gag encoded gene products within the transfected CHO cells;

(c) culturing the transfected CHO cells; and (d) recovering the nonreplicating recombinantmade HIV-l particles from the culture medium.

134. The method according to Claims 129, 130, 131, 132 or 133 in which the mammalian cell is a BSC-40 cell.

or

135. The method according to 133 in which the mammalian cell

Claims 129, 130, is a HeLa cell.

131, 132 or

136. The method according to 133 in which the mammalian cell

Claims 129, 130, is a Vero cell.

131,

132

25 137. The method according to Claims 129, 130, 131, 132 or 133 in which the mammalian cell is a CHO cell.

138. The method according to Claims 129, 130, 131, 132 or 133 in which the mammalian cell is a dhfr-deficient CHO

30 cell.

139. Recombinant vaccinia virus v-gag2 as deposited with the ATCC and assigned accession number _.

35 140. Recombinant vaccinia virus V-G2E5 as deposited with the ATCC and assigned accession number _.

-10610

141. Recombinant vaccinia virus v-ED2.

142. Recombinant vaccinia virus V-ENV5DCT.

143. Recombinant vaccinia virus V-160NC.

144. Recombinant vaccinia virus V-11K160NC.

145. Plasmid CmHiVdelKpnAvr(Gag2TRE)(1160-al)

146. Plasmid CmHiEnv5(1104-bl).

147. Plasmid CmHiGag2Rre(1158-al).

148. Plasmid CmHIVdelXmn(1133-al).

149. Plasmid CmvGag2Rre(1159-al).

150. Plasmid CmHiTat.

151. Plasmid CmHiRev.

152. A nonreplicating recombinant-made HIV particle substantially as described herein.with reference to the Examples and/or the accompanying drawings.

153. A vaccine formulation substantially as described herein with reference to the Examples and/or the accompanying drawings.

154. Use of a nonreplicating recombinant-made HIV particle in the perparation of a medicament for the treatment of acquired immunodeficiency syndrome , lymphadenopathy, AIDS-related complex or in reducing the infectivity of CD4 + lymphocytes by Humam Immunodeficiency Virus.

107 155. A nonreplicating recombinant-made retroviral particle I substantially as described herein with reference to the

/. 5 Examples and/or the accompanying drawings.

£ j 156. Use of a nonreplicating recombinant-made HTLV-I particle | in the preparation of a medicament for the treatment of the

E progression of adult T-cell leukemia, the progression of

j.· 10 HTLV-I-associated lymphoma, the progression of

HTLV-II-associated leukemia in HTLV-II infection or for reducing the infectivity of CD4 + lymphocytes by a human retrovirus.

157 A method for generating nonreplicating recombinant-made retroviral particles substantially as described herein with reference to the Examples and/or the accompanying drawings.

20 158 Nonreplicating recombinant-made retroviral particles whenever produced by a process as claimed in any of claims 66 to 74 or 157.

159. A method of generating nonreplicating recombinant-made

25 HIV particles substantially as described herewith with reference to the Examples and/or the accompanying drawings.

160. Nonreplicating recombinant HIV particles whenever prepared by a process as claimed in any of claims 75 to 138 or

30 159.