CN102191266A - Method for enabling Dunaliella to accumulate high-content lycopene - Google Patents
Method for enabling Dunaliella to accumulate high-content lycopene Download PDFInfo
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Abstract
The invention relates to a method for biologically synthesizing lycopene, in particular to a method for enabling Dunaliella to accumulate high-content lycopene. The method comprises the following steps of: extracting Dunaliella genome DNA; cloning a lycopene-beta-cyclase (LycB) gene of the DNA; constructing an LycB gene knockout vector and transforming the vector into a Dunaliella salina cell; and screening and identifying to obtain LycB gene knockout Dunaliella, wherein the LycB gene expression of the Dunaliella is inhibited; the process of biologically synthesizing beta-carotene by using the cell is stopped at the lycopene stage; and under the stress condition, a large amount of lycopene can be accumulated in an organism and the lycopene content is 3 to 4 percent of the dry weight of the Dunaliella. The method is a new way of obtaining a large amount of natural lycopene with low price.
Description
Affiliated technical field
The present invention relates to the biosynthesizing lycopene method, especially a kind of Dunaliella salina (Dunaliella) that makes is accumulated high-load lycopene method.
Background technology
Lyeopene (Lycopene) is a kind of fat-soluble natural pigment, and its molecule belongs to carotenoids by 11 conjugated double bonds and 2 straight chain type hydrocarbon polymers that unconjugated double bond is formed.Mainly be present in the plants such as tomato, watermelon, red natsudaidai.Studies show that over past ten years, the anti-oxidant activity that Lyeopene is extremely strong, its ability of removing singlet oxygen is 100 times of vitamin-E, be 2.2 times of β-Hu Luobusu, the effect of removing hydroxy radical qiao is stronger 32 times than β-Hu Luobusu, is one of found powerful antioxidant of occurring in nature at present.Discover that Lyeopene has superior physiological function, it not only has anticancer, as to press down cancer effect, and for various adult diseases such as preventing cardiovascular disease, arteriosclerosis, enhancing human immune system and delaying senility etc. good effect is arranged also.About 2300 tons of total consumption of whole world Lyeopene in 2009, according to the appropriate authority prediction, the demand of Lyeopene over the next several years will be with about 10% speed increment.
Production methods of lycopene has three kinds of natural extract method, chemical synthesis and fermentation methods in the world at present.
Russia and U.S.'s Luo Shi medicine company have the lycopene product of chemosynthesis, production cost is lower, but its structure is non-alltrans, and physiological function is poor, and people have suitable doubt to the synthetic toxic side effect, so the chemosynthesis Lyeopene seldom is used for medicine and foodstuff additive.
Lyeopene in the market is the natural product that extracts from tomato mostly, but because the content of Lyeopene only is about 0.002% in the tomato, extract that difficulty is big, cost is high, purity is low, and plant tomato in a large number and be used for Lyeopene and extract a lot of land resources of needs consumption.
Utilize microbe fermentation method to prepare the Study of Lycopene aspect some reports are also arranged, U.S. Pat 3097146, US3369974 and Chinese patent 200510090996.0 have proposed to utilize trispore Bruce mould fermentative preparation lycopene method, but these methods all need to add chemical agent such as aminopyridine disturbs the biosynthesizing path of moulds to realize the accumulation of Lyeopene, and the residual health to human body of chemical additive in product can have a negative impact.Chinese patent 200710122895 has been invented a kind of bacterium (streptomyces rimosus) fermentation accumulation lycopene method of utilizing, but owing to be subjected to its synthetic precursor supply quantitative limitation, produce the Lyeopene productive rate only in 0.4%~0.7% dry cell weight scope according to this method, still do not have substantial breakthrough and raising.
Also there are some good tries the content aspect that method by genetically engineered and metabolic engineering improves Lyeopene in the tomato.Take the lead in selecting the hybridization tomato that content of lycopene is 4~5 times of common tomatoes as Israel Lycored Natural Product Industries company.Britain imports bacterium phytoene dehydrogenase gene crtI in the tomato cell, and having cultivated content of lycopene is the transgenic Fructus Lycopersici esculenti new variety of 3.5 times of common tomatoes.Though these researchs have improved the content of Lyeopene in the raw material to a certain extent, aggregate level is still very low.
Dunaliella salina (Dunaliella), for one of many whips of Chlorophyta algae section belongs to, it is salt unicell green alga that give birth to, acellular wall, biosynthesizing β-Hu Luobusu expeditiously, the accumulation β-Hu Luobusu reaches as high as 14% of dry weight in Dunaliella salina wherein (Dunaliella salina) cell, be the highest organism of content beta-carotene, be higher than other biology far away.Dunaliella salina utilizes sunlight and carbonic acid gas to grow fast under the open environment in the open in addition, and wherein the rate of propagation of Dunaliella salina reaches about 10g/m
2/ day, so Dunaliella salina is the fine resource of producing natural beta-carotin, the whole world has many companies to utilize Dunaliella salina to produce β-Hu Luobusu, as the composition of medicine or heath food.
Lyeopene and β-Hu Luobusu all are the carotenoid materials, they have close chemical structure, allow Dunaliella salina idea of synthesizing, accumulating Lyeopene direct as the biosynthesizing β-Hu Luobusu have a great attraction, because also do not find to synthesize, to accumulate with high efficient like this biology of Lyeopene up to now in the world.
Summary of the invention
The objective of the invention is to set up a kind of Dunaliella salina (Dunaliella) that makes and accumulate high-load lycopene method.
The correlative study of the synthetic β-Hu Luobusu approach of plant biological shows, Lyeopene is the precursor of biosynthesizing β-Hu Luobusu, Lyeopene is at Lyeopene-beta cyclase (Lycopene β-cyclase, LycB) under the katalysis, earlier with two ends of Lyeopene molecule one of be cyclized into gamma carotene, and then with the other end cyclisation formation β-Hu Luobusu, LycB is the key enzyme that Lyeopene is converted into β-Hu Luobusu.What Fig. 1 showed is plant β-Hu Luobusu biosynthesizing path, if there is not the participation of LycB, Lyeopene just can not cyclisation, and the process of biosynthesizing β-Hu Luobusu will end at the Lyeopene synthesis phase.
The accumulation of Lyeopene studies confirm that in the tamato fruit, the accumulation of Lyeopene is that upstream phytoene synthase gene (psy gene) and phytoene dehydrogenase gene (pds gene) are expressed and strengthened and result that downstream lycB genetic expression weakens, and its control methods are the transcriptional control of genes involved.
In the process of Dunaliella salina biosynthesizing β-Hu Luobusu, two step cyclizations all must participate in just finishing by LycB, and LycB is the product of lycB genetic expression, therefore, just can realize by the lycB expression of gene that suppresses Dunaliella salina that Lyeopene is not converted into β-Hu Luobusu in the Dunaliella salina body and under a large amount of accumulation.
The desirable approach that suppresses Dunaliella salina lycB genetic expression is with the lycB gene knockout (knock-out) in the Dunaliella salina genome.The present invention will be by making up effective Dunaliella salina lycB gene knockout carrier, and change carrier over to the Dunaliella salina cell, obtained knocking out the Dunaliella salina of lycB gene again through screening, this new Dunaliella salina can be accumulated high-load Lyeopene, makes the mankind obtain natural lycopene in a large number, easily with a kind of brand-new mode.
Detailed process of the present invention is:
The first step is extracted the Dunaliella salina genomic dna.
With cetyl trimethylammonium bromide method (CTAB method) or other currently known methods.Described Dunaliella salina (Dunaliella) is Dunaliella salina (Dunaliella salina) or pasteur Du algae (Dunaliella bardawil) or two Dunaliella salina (Dunaliella biocuiate) etc., wherein preferably accumulate the stronger Dunaliella salina of β-Hu Luobusu ability (Dunaliella salina) or pasteur Du algae (Dunaliella bardawil), particularly Dunaliella salina (Dunaliella salina).
In second step, Dunaliella salina lycB full-length gene is checked order.
The sequence measurement commonly used according to the genetically engineered field carries out, and also examining order can be entrusted to the biotech company that the order-checking service is provided specially.Usually utilize the order-checking of genetic analysis instrument, design earlier is many to be carried out the segmentation clone, checks order and obtain fragment sequence primer, and the lycB full-length gene is obtained in assembling then.
The present invention carries out segmentation clone, order-checking, assembling according to 6 pairs of primers of GenBank accession number EU327877 sequences Design to Dunaliella salina Y6 strain (Salt Research Institute China National Salt Industry Corporation), has obtained the lycB gene order of Y6, sees sequence table SEQ ID NO:1.Detailed technical scheme will explanation in embodiment 1.
In the 3rd step, the lycB gene knockout carrier makes up.
In the lycB gene knockout carrier, comprise the selection markers gene that is used to screen, and inserted 5 ' homologous recombination district of 3 of lycB gene ' end homologous recombination district and lycB gene.Described selection markers gene is chloramphenicol resistance gene, G-30027 resistant gene, fluorescence protein gene etc., the preferred chloramphenicol resistance gene of the present invention, G-30027 resistant gene.
The initial plasmid that the present invention can adopt has a lot of selections, comprises pCAMBIA1301, and this is that the researchist of this professional domain is known.。
With plasmid pCAMBIA1301 (GenBank Locus:AF234297) is that the building process that skeleton contains the lycB gene knockout carrier of chloramphenicol resistance gene is:
At first the hygromycin gene in the pCAMBIA1301 plasmid (hpt) is cut with restriction enzyme XhoI enzyme, replace with the chloramphenicol resistance gene (cat is from carrier pBC SK+) of 660bp, obtain p1301-cat.Then p1301-cat and pBluescript II KS (+) (GenBank Locus:X52327) are cut with the SacII enzyme, connect, get carrier pBS-1301-cat.Again pBS-1301-cat is cut with the XcmI enzyme, get carrier pBS-1301-cat-Xcm certainly continuously.Initial carrier has three NotI restriction enzyme sites, but after the fragment of removing between the XcmI restriction enzyme site, therefore the only surplus NotI restriction enzyme site of carrier cuts evaluation with the NotI enzyme.Again with carrier pBS-1301-cat-Xcm NcoI/BstEII double digestion, remove the long beta-glucosiduronatase gene (gus) of its 1.8kb, connect the diphtheria toxin A chain gene (dtA, GenBank Locus:AY611535) of 0.6kb, obtain carrier pBS-1301-cat-Xcm-DTA.Cut carrier pBS-1301-cat-Xcm-DTA with the SbfI enzyme at last, insert 3 of lycB gene ' end homologous recombination district, the NotI enzyme is cut 5 ' homologous recombination district that carrier inserts the lycB gene, obtains knockout carrier pDs-GKO-cat.
In the 4th step, transforming the lycB gene knockout carrier into, screening, the PCR of Dunaliella salina cell, transformant identify.
Transforming the lycB gene knockout carrier into, Dunaliella salina cell method can be electric shocking method, polyoxyethylene glycol (PEG) method, particle bombardment, granulated glass sphere paddling process etc., these methods are that the genetically engineered field is used always, these methods are different aspect transformation efficiency, preferred simple and effective electric shocking method.
With electric shocking method the lycB gene knockout carrier is transformed into Dunaliella salina cell: in ice bath with 3kV/cm~8kV/cm electric shock Dunaliella salina cell suspending liquid.Electric shocking method can reach higher 0.05%~0.2% transformation efficiency in the present invention.
Carry resistance marker transformant can screen with resistant panel, the transformant that carries fluorescent protein labeling is differentiated the separate apparatus screening with fluidic cell.Accompanying drawing 2 is the flat boards that utilize the chlorampenicol resistant screening after electricity transforms.
Select single algae falls and extract DNA after enlarged culturing, and PCR detects cat gene, dtA gene and knocks out fragment then.Detected result shows that the algae pnca gene group that screening obtains exists cat gene, dtA gene and knocks out fragment, proves that the lycB gene is successfully knocked out.
To confirm that the Dunaliella salina that the lycB gene is knocked out amplifies breed, with the content of Lyeopene in high pressure liquid chromatography (HPLC) the detection frond, the result shows that resulting Dunaliella salina can be accumulated high-load Lyeopene.
The invention has the advantages that:
The screening of structure, conversion and transformant by Dunaliella salina Lyeopene-beta cyclase gene knockout carrier, obtain knocking out the Dunaliella salina of lycB gene, the lycB expression of gene of this Dunaliella salina is suppressed, the process of its biosynthesizing β-Hu Luobusu is blocked at the Lyeopene stage, and then in its organism a large amount of accumulation Lyeopenes, this accumulation is the bio-metabolic process of frond nature, need not to add any chemical inhibitor.The Dunaliella salina of the lycB gene knockout that obtains by the present invention, under 10% salt concn (coercing), culture and just can accumulate Lyeopene in a large number, the HPLC detected result shows, the content of its Lyeopene can reach 3%~4% of organism dry weight, above 1000 times of tomato, be the highest biology of known up to now content of lycopene.Achievement of the present invention will provide brand-new solution for the mankind obtain Lyeopene in a large number, at an easy rate.
The present invention has obtained the total length lycB genes of SEQ ID NO:1 of Dunaliella salina Y6, this Dunaliella salina Y6 is a most frequently used Dunaliella salina kind of commercially producing β-Hu Luobusu, coerce the amount that to accumulate β-Hu Luobusu under the environment at high light, high salt etc. and can reach 10%~14% of organism dry weight, therefore, this lycB gene order gene knockout of being applied to Dunaliella salina Y6 has good potential value.
Description of drawings
Fig. 1 is a plant β-Hu Luobusu biosynthetic pathway.
Fig. 2 utilizes the chlorampenicol resistant plate screening to transform algae after electricity transforms.
Fig. 3 is the HPLC analysis of spectra of Dunaliella salina Y6 and mutant strain 4#40A1, and peak I is a β-Hu Luobusu, and peak II is a Lyeopene.
Embodiment
Related method is the ordinary method of this technical field if no special instructions among the following embodiment, and used zymin is the product of TaKaRa company if no special instructions, and the dna sequence dna of related primer epiphase in sequence should be listed.
The structure of embodiment 1, Dunaliella salina Lyeopene-beta cyclase gene knockout carrier
The extraction of step 1, Dunaliella salina genomic dna
The centrifugal collection of 5000r/min DsMG liquid nutrient medium (Mu Chunlin, Chen Xiwen, Hou Zhaoli. the separation of industrial production β-Hu Luobusu Dunaliella salina and kind are identified. salt industry and chemical industry, 2009,38 (4): 25~29) the Dunaliella salina cell of Pei Yanging, adding 750 μ L by every 100mg cell prepares liquid and (contains the 2.5mL extracting solution, 2.5mL karyorhexis liquid, 1mL 5% (w/v) N-sodium lauroyl sareosine, behind the mixing, take by weighing the 0.024g bisulfite and receive, dissolving, mixing.Extracting solution is 350mmol/L sorbyl alcohol, 100mmol/LTris (pH7.5), 5mmol/L EDTA.Karyorhexis liquid is 200mmol/L TrisHCl (pH7.5), 50mmol/L EDTA, 2.0mol/LNaCl, 2%CTAB), hatch 2h (every 15min puts upside down mixing once) for 55 ℃, packing, each centrifuge tube 750 μ L; Every pipe adds 750 μ L chloroform/primary isoamyl alcohol (24: 1), puts upside down mixing, the centrifugal 5min of room temperature 12000r/min; Get supernatant, add 500 μ L cold isopropanols, put upside down mixing, until seeing that the centrifugal 5min of room temperature 12000r/min appears in linear DNA; Wash DNA precipitation twice, dry air with 75% ice-cold ethanol; Add 500 μ L TE dissolving DNAs, 55 ℃ add an amount of RNase A digestion RNA; Twice of phenol/chloroform/primary isoamyl alcohol (25: 24: 1) extracting; The 3mol/L sodium acetate that adds 1/10 volume, the cold dehydrated alcohol of 2.5 times of volumes is put-20 ℃ more than the 1h, and 4 ℃ of centrifugal 15min of maximum speed of revolution abandon supernatant; Wash DNA precipitation twice with 75% ice-cold ethanol, dry air adds 100 μ L TE dissolving DNAs ,-70 ℃ of preservations.
The clone of step 2, Dunaliella salina lycB gene
According to GenBank accession number EU327877 sequences Design six couples of primer LycB-1-F/R, LycB-2-F/R, LycB-3F/R, LycB-4-F/R, LycB-5-F/R, LycB-6-F/R, the lycB full-length gene of Dunaliella salina Y6 is carried out segmentation clone, order-checking.The sequence of primer LycB-1-F is CTAGATTGCATACAGAACAG, and the sequence of primer LycB-1-R is GCTGAGC ATCTGTGTAAG; The sequence of primer LycB-2-F is TGACCAAGAGTTCAACCCAG, and the sequence of primer LycB-2-R is CTTTGCACCTTTGTCAATGAG; The sequence of primer LycB-3-F is GATTGCTGTAAGCCAACCCAC, and the sequence of primer LycB-3-R is ACAAGAAAGCATCCTGAGGACC; The sequence of primer LycB-4-F is ATCGGTAGCCTGAAACCAC, and the sequence of primer LycB-4-R is ATCAGGCAGTACTCCTCATCC; The sequence of primer LycB-5-F is AACCCATGTACAAGGTAG ACCC, and the sequence of primer LycB-5-R is AATATCACACCTCATGCCAATG; The sequence of primer LycB-6-F is GGTT ATGAACTCACTTACTCCG, and the sequence of primer LycB-6-R is TTGCTTGTAGTACCCAGTCAC.
The PCR system is 15 μ L, contains 1ng Dunaliella salina Y6 genomic dna, the 10 μ mol/L upstream primers of 0.18 μ L, the 10 μ mol/L downstream primers of 0.18 μ L, the 5U/ μ L Ex Taq of 0.075 μ L, 1 * Ex Taq damping fluid, the 2.5mol/LdNTPs of 1.2 μ L.PCR is reflected on the TaKaRa PCR Thermal Cycler 600 and carries out.
The PCR reaction conditions is: 94 ℃ of 5min; 40 three temperature cycle (94 ℃ of 40s, 58 ℃ of 32s, 72 ℃ of 110s), 72 ℃ are extended 7min again.0.7% agarose gel electrophoresis Separation and Recovery PCR product band is connected with pMD19-T Simple Vector, transformed into escherichia coli DH5 α-FT, and the positive bacteria that bacterium colony PCR determines checks order.Through assembling, obtain the lycB full-length gene of the long Y6 of 9035bp, its sequence is seen sequence table SEQ ID NO:1.
The structure of step 3, Dunaliella salina lycB gene knockout carrier
With pCAMBIA1301 is that skeleton carries out the knockout carrier structure, and its step is as follows:
A. the hygromycin gene in the pCAMBIA1301 plasmid (hpt) is cut with restriction enzyme XhoI enzyme, replace with the chloramphenicol resistance gene (cat) of 660bp, obtain p1301-cat.
B. p1301-cat and pBluescript II KS (+) are cut with the SacII enzyme, connect, obtain carrier pBS-1301-cat.
C. pBS-1301-cat is cut with the XcmI enzyme, plasmid obtains carrier pBS-1301-cat-Xcm from connecting.Originally carrier has three NotI restriction enzyme sites, but after the fragment of removing between the XcmI restriction enzyme site, therefore the only surplus NotI restriction enzyme site of carrier cuts evaluation with the NotI enzyme.
D. with carrier pBS-1301-cat-Xcm NcoI/BstEII double digestion, remove the gus gene of 1.8kb, be connected into the dtA gene of 0.6kb, obtain carrier pBS-1301-cat-Xcm-DTA.
E. cut carrier pBS-1301-cat-Xcm-DTA with the SbfI enzyme, insert 3 of lycB gene ' end homologous recombination district, the NotI enzyme is cut 5 ' homologous recombination district that carrier inserts the lycB gene, obtains knockout carrier pDs-GKO-cat.The knockout carrier pDs-GKO-cat that final structure is finished carries out the key position order-checking, and the sequence that obtains is entirely true.3 ' end homologous recombination district utilizes primer Ds-T-3-F/R amplification gene group gained, and 5 ' homologous recombination district utilizes primer Ds-T-5-F/R amplification gene group gained.The sequence of primer Ds-T-5-F is AAGCGGCCGCCTCAGAAAAAATTGCTAACTCACAAACCATC, and the sequence of primer Ds-T-5-R is AAGCGGCCGCCACCAAGGAAGTCTCTTCCAAGAACAC; The sequence of primer Ds-T-3-F is AACCTGCAGGTGAACAACCCCTTCTAGCCCAATG, and primer Ds-T-3-R sequence is AACCTGCAGGTTAGGAATCCATCACAAGCCAATACCC.
The electricity conversion of embodiment 2, lycB gene knockout carrier pDs-GKO-cat and screening, the evaluation of transformant
A. cultivate the Dunaliella salina cell to logarithmic phase (1.0 * 10
6/ mL), and 4 ℃, the centrifugal 5min of 4000r/min, collecting cell;
B. operation on ice, the electric shock damping fluid (consists of: the NaCl of 0.28mol/L, the KCl of 5mmol/L, the CaCl of 25mmol/L
2, the Hepes of 20mmol/L, the N.F,USP MANNITOL of 200mmol/L, the sorbyl alcohol of 200mmol/L, 0.05% Tween-20, the glycerine of 0.4mol/L) and suspension cell, clean 2 times;
C. resuspended to cell density be 1.0 * 10
7/ mL; Get the resuspended algae liquid of 90~100 μ L, adding final concentration is the carrier of 10ng/ μ L and the milt DNA of 20ng/ μ L, mixing, ice bath 10min;
D.6kV/cm shock by electricity, ice bath 10min adds 1mL DsMG, secretly cultivates 12h;
E. light: dark=as to cultivate at 14: 10, be plated at last and cultivate (Figure of description 2) on the solid plate that contains 100 μ g/mL paraxin.
F. 5 of knockout carrier pDs-GKO-cat ' end homologous recombination district and 3 ' end homologous recombination district, lay respectively at the exon VI upstream and the intron VI downstream of lycB gene, and the cat gene has been inserted in the centre, so the lycB gene of knockout mutant strain will produce sudden change between the exon VI of lycB gene and intron VI.Therefore, we design CAT-F1/R1, DTA-F2/R2, LycB-F3/R3, DTA-J-F/R, CAT-F/R primer to the algae strain being detected cat gene, dtA gene and knocking out fragment.Method is: picking list algae falls to expanding to 1mL to be cultivated, and extracts its genome then, identifies respectively with PCR method.The sequence of primer CAT-F1 is AAAATCACTGGATATACCACCG, and the sequence of primer CAT-R1 is TCATTAAGCATTCTGCCGAC; The sequence of primer DTA-F2 is ATGGCAGCTATGGCTGGTCCTGATG, and the sequence of primer DTA-R2 is CTAGGATCGCCTGACACGATTTC; The sequence of primer LycB-F3 is GATTGCTGTAAGCCAACCCAC, and the sequence of primer LycB-R3 is ACAAGAAAGCATCCTGAGGACC; The sequence of primer DTA-J-F is GCCATGGCAGCTATGGCTGGTCCTGATG, and the sequence of primer DTA-J-R is CGGTCACCTGTAATCTAGGATCGCCTGACACGATTTC.
After operation steps is identified in above-mentioned electric conversion, screening, PCR, obtain the Dunaliella salina 4#40A1 that the lycB gene has successfully been knocked out, with this algae of following breed of 10% salinity, and be contrast with Dunaliella salina Y6.Separate frond in the following manner, extract Lyeopene, utilize the content of HPLC detection by quantitative Lyeopene, whether can accumulate high-load Lyeopene to confirm it.
Get algae liquid 50mL, the centrifugal 5min of 4000r/min removes supernatant; Add the 3mL acetone algae mud that suspends again, extracting is placed 1h for-20 ℃; The centrifugal 10min of 6000r/min; Get supernatant, 0.45 μ m membrane filtration; Get 15 μ L and carry out the HPLC analysis.The HPLC condition: chromatographic column is Comatex C18 (5 μ m, Φ 4.6 * 250mm), mobile phase A is an ethyl acetate, Mobile phase B is acetonitrile and water (9: 1, volume ratio), gradient: 0~16min 0~60%, 16~30min 60%, 30~35min 60%~100%, sample size is 15 μ L, column temperature is 35 ℃, and flow velocity is 1mL/min, and the detection wavelength is 502nm.The β-Hu Luobusu standard substance dissolve with trichloromethane, and Pure Lycopene is dissolved with methylene dichloride, measure the standard specimen of β-Hu Luobusu then with HPLC, obtain typical curve and equation of linear regression.HPLC analyzes Dunaliella salina and extracts the β-Hu Luobusu of sample and the content of Lyeopene, and accompanying drawing 3 is collection of illustrative plates that HPLC analyzes.
The HPLC analytical results shows that the content of lycopene of 4#40A1 accounts for 56.4 ± 3.5% of total carotinoid, far above 2.9% of Y6, is 19.45 times of Y6; Content beta-carotene reduces to 15.9 ± 2.9% by 61.9%, reduces to 25.7% of Y6.Calculate by dry weight, the content of lycopene of 4#40A1 is 3.5 ± 0.6%, surpasses more than 1000 times of tomato.
Reference
1, Chinese patent utilizes trispore Bruce mould fermentative preparation lycopene method for 200510090996.00 1 kinds;
2, Chinese patent application utilizes fermentation using bacteria to give birth to accumulation high-content lycopene method for 200,710,122,895 1 kinds.
3, Mu Chunlin, Chen Xiwen, Hou Zhaoli. the separation of industrial production β-Hu Luobusu Dunaliella salina and kind are identified. salt industry and chemical industry, 2009,38 (4): 25~29
Claims (8)
1. one kind makes Dunaliella salina (Dunaliella) accumulation high-content lycopene method, it is characterized in that suppressing Lyeopene-beta cyclase (LycB) expression of gene of Dunaliella salina, the cyclization of lycopene path of the carotenoid pathways metabolism of its cell is blocked.
2. the Dunaliella salina that makes according to claim 1 is accumulated the high-content lycopene method, it is characterized in that knocking out the lycB gene of Dunaliella salina.
3. the method that knocks out Dunaliella salina lycB gene according to claim 2 is characterized in that may further comprise the steps:
The first step is extracted the Dunaliella salina genomic dna
Second step, Dunaliella salina lycB full-length gene is checked order, obtain the lycB full-length gene.
The 3rd step made up Dunaliella salina lycB gene knockout carrier, inserted 5 ' homologous recombination district of 3 of lycB gene ' end homologous recombination district and lycB gene in constructed lycB gene knockout carrier.
In the 4th step, transforming the lycB gene knockout carrier into, screening, the PCR of Dunaliella salina cell, transformant identify.
4. Dunaliella salina lycB gene knockout carrier according to claim 3 is characterized in that containing chloramphenicol resistance gene or G-30027 resistant gene.
5. be any of following Dunaliella salina according to each described Dunaliella salina of claim 1-4: Dunaliella salina (Dunaliella salina), pasteur Du algae (Dunaliella bardawil), two Dunaliella salina (Dunaliella biocuiate).
6. root is Dunaliella salina (Dunaliella salina) or pasteur Du algae (Dunaliella bardawil) according to each described Dunaliella salina of claim 1-4.
7. be Dunaliella salina (Dunaliella salina) according to each described Dunaliella salina of claim 1-4.
8. according to each described Dunaliella salina lycB gene of claim 1-4, it is characterized in that its sequence is SEQ ID NO:1.
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Cited By (2)
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CN105087627A (en) * | 2015-09-10 | 2015-11-25 | 山东省农业科学院生物技术研究中心 | Application of sll0659 gene to synthesis of synechocystis carotenoids |
CN105087604A (en) * | 2015-09-10 | 2015-11-25 | 山东省农业科学院生物技术研究中心 | Application of sll0147 gene in synthesizing synechocystis carotenoids |
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CN1670211A (en) * | 2005-02-22 | 2005-09-21 | 华南理工大学 | Gene for coding lycopene beta cyclase(Lyc-B) of Dunaliella salina |
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Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
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CN105087627A (en) * | 2015-09-10 | 2015-11-25 | 山东省农业科学院生物技术研究中心 | Application of sll0659 gene to synthesis of synechocystis carotenoids |
CN105087604A (en) * | 2015-09-10 | 2015-11-25 | 山东省农业科学院生物技术研究中心 | Application of sll0147 gene in synthesizing synechocystis carotenoids |
CN105087604B (en) * | 2015-09-10 | 2018-12-25 | 山东省农业科学院生物技术研究中心 | A kind of application of sll0147 gene in synthesis cytoalgae carotenoid |
CN105087627B (en) * | 2015-09-10 | 2018-12-25 | 山东省农业科学院生物技术研究中心 | A kind of application of sll0659 gene in synthesis cytoalgae carotenoid |
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