CN103013946B - Cordyceps sinensis hexadecane coenzyme A hydrolytic enzyme, gene and applications of hydrolytic enzyme and gene - Google Patents

Cordyceps sinensis hexadecane coenzyme A hydrolytic enzyme, gene and applications of hydrolytic enzyme and gene Download PDF

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CN103013946B
CN103013946B CN201210492892.2A CN201210492892A CN103013946B CN 103013946 B CN103013946 B CN 103013946B CN 201210492892 A CN201210492892 A CN 201210492892A CN 103013946 B CN103013946 B CN 103013946B
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hexadecane
gene
coenzyme
hydrolytic enzyme
unsg
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CN103013946A (en
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郑裕国
柳志强
吴晖
李邦良
许静
林善
许峰
薛亚平
袁水金
王鸿艳
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Zhejiang University of Technology ZJUT
Hangzhou Zhongmei Huadong Pharmaceutical Co Ltd
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Zhejiang University of Technology ZJUT
Hangzhou Zhongmei Huadong Pharmaceutical Co Ltd
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Abstract

The invention relates to a hexadecane coenzyme A hydrolytic enzyme synthesized from Bailing production bacterium cordyceps sinensis hirsutslla sinensis and docosahexaenic coenzyme A, a gene for coding the hexadecane coenzyme A hydrolytic enzyme and applications of the hydrolytic enzyme and the gene. The amino acid sequence of the hexadecane coenzyme A hydrolytic enzyme has above 90 percent of homology with a sequence shown in SEQ ID No.1 or SEQ ID No.3. According to the invention, the metabolic pathways of synthesizing the docosahexaenic acid by the hexadecane coenzyme A hydrolytic enzyme is researched in detail from the principle; cloning DNA (Deoxyribose Nucleic Acid) comprising the nucleotide sequence provided by the invention can be transferred into an engineering bacterium through transduction, transformation and transfer; through regulating the expression of a docosahexaenic acid biosynthetic gene, the high expressivity of the host hexadecane coenzyme A hydrolytic enzyme synthesized is endowed, and an effective path is provided for enlarging the yield of the docosahexaenic acid; and the hexadecane coenzyme A hydrolytic enzyme has an important application prospect.

Description

A kind of Cordyceps sinensis n-Hexadecane Co A hydrolase, gene and application thereof
(1) technical field
The present invention relates to a kind of participation two dodecahexaene coenzyme A from " hundred makes " production bacterium Cordyceps sinensis China pilose spore to set out the n-Hexadecane Co A hydrolase (palmitoyl-CoA hydrolase) of anabolism docosahexenoic acid, the gene of this enzyme of encoding and application thereof.
(2) background technology
Cordyceps sinensis (Cordyceps sinensis (Berk.) Sacc.) is that Cordyceps fungus colonizes in the stroma on lepidopteran (Lepidoptera) Hepialidae insect (Hepialus armoricanus Oberthur) larva and the complex body (comprising stroma and polypide) on larva corpse.Cordyceps sinensis is traditional fungi herb resource that a class is treasured, and has the feature of meta-bolites and diverse biological activities, shows huge application and development prospect at biomedicine field.Cordyceps sinensis extensively, obviously receives much concern with its multiple medicinal efficacy, worldwide enjoys high praise.The traditional Chinese medical science is thought, Cordyceps sinensis enters lung kidney two warp, can tonifying lung cloudy, again can kidney-replenishing, cure mainly and suffer from a deficiency of the kidney, impotence and seminal emission, soreness of waist and knee joint, weak after being ill, chronic cough is weak, and phthisical cough phlegm blood, spontaneous sweating etc. are unique a kind of Chinese medicine that can balance simultaneously, regulate negative and positive.Modern pharmacology confirms, and Cordyceps sinensis has the biological activity widely such as immunomodulatory, antibacterial, antitumor, anti-oxidant, anti-ageing, hypoglycemic blood fat, gonadotropic Effect.
Cordyceps fungus is a kind of ascomycetes, has Conidial Stage (anamorph) and thecaspore stage (teleomorph) in its life history.And in the actual production such as artificial culture, liquid fermenting, use the Cordyceps fungus in imperfect stage, thus the qualification of Anamorph of Cordyceps Sinensis is extremely important.Chinese scholars is done a lot of work in Cordyceps Resources investigation, anamorph confirmation, activeconstituents compartment analysis and the mechanism of action, Application and Development.Cordyceps sinensis China pilose spore has been proved to be the anamorph existence form of Cordyceps sinensis, has the activeconstituents identical with natural cordyceps and drug effect.
Natural cs has strict parasitics and special ecotope, therefore its output is very low, and price is high.Wild cordyceps owing to restricting by factors such as growing environments, scarcity of resources.Owing to making little progress on artificial culture in recent years, the research of wild cordyceps surrogate focused mostly on liquid fermenting.Utilizing liquid submerged fermentation to cultivate Cordyceps mycelium, extract or fermented liquid, is a kind of effective way solving Cordyceps sinensis medicine source.Chinese caterpillar fungus fermentation produces Chinese caterpillar fungus substitute, both can these precious resources of available protecting Chinese caterpillar fungus, and the restriction that climate, geographical environment and Chinese caterpillar fungus parasitic conditions are not strict again, is suitable for industrialization scale operation.The substitute produced is as also similar to natural cs with drug effect in its composition of mycelium, is thus devoted to the fermentation culture of Cordyceps mycelium both at home and abroad always.The mycelia that aweto cultured by artificial fermentation China pilose spore obtains, through toxicity, pharmacology, plant research, prove with natural cs chemical constitution, pharmacological action basically identical, natural cs can be replaced to produce cordyceps product, to make up the shortage of natural resources, by the optimization to fermentation condition, the amount of mycelial biomass and meta-bolites is all significantly improved.
In recent years, along with the develop rapidly of natural product chemistry and modern chromatographic techniques, in worm grass product research and development, progressively turn to deeper functional metabolic Study on product by the direct utilization of Chinese caterpillar fungus raw material or crude extract.Large quantifier elimination is done to Chinese caterpillar fungus meta-bolites both at home and abroad, meta-bolites mainly comprises several large compounds such as nucleosides, polysaccharide, polypeptide, sterol, and wherein the representative research of functional metabolic product in biosynthesizing, pharmacological action etc. such as purines nucleosides, Cordyceps polysaccharide, N.F,USP MANNITOL wins initial success.
Unsaturated fatty acids refers to the lipid acid containing one or more double bond in molecule, and its fusing point comparatively saturated fatty acid is low.Unsaturated fatty acids is a kind of lipid acid forming body fat, and the lipid acid of needed by human, unsaturated fatty acids, according to the difference of double bond number, is divided into monounsaturated fatty acids and polyunsaturated fatty acid two kinds.Polyunsaturated fatty acid (Polyunsaturated Fatty Acids, PUFAs) relative saturation lipid acid has more effect, it can reduce blood cholesterol and triglyceride level, regulate heart function, reduce blood viscosity, improve blood microcirculation, improve the activity of brain cell, memory and thinking ability, strengthen the function etc. of human defensive system, in addition it can also be got rid of " rubbish " unnecessary in human body, namely owing to taking the photograph the superabundant fat that the excessive saturated fatty acid of people is formed, thus reaches the object of fat-reducing.Therefore, its potential medical pharmaceutical use receives the extensive concern in the world, causes the great attention of the industry such as food, medical even makeup.
Yung-Sheng in 1999 draws the △ 6 and △ 12 fatty acid dehydrogenase gene that have cloned Mortierella alpina (Mortiere Uaalpina) and expresses in yeast saccharomyces cerevisiae.2004, △ 3 desaturase in tung oil tree was proceeded to yeast by the people such as Dyer, successfully obtained and produced linolenic yeast.△ 12 desaturase of blue or green for algae bacterium (Cyanobacterium) is proceeded to potato by the people such as Maali-Amiri in 2007, successfully detects that potato fatty acid component there occurs considerable change.2008, △ 6 desaturase of volume branch Mucor turned in people's transgene tobacco by the people such as Hao, have successfully been obtained the bacterial strain of high yield gamma-linolenic acid.In addition, the relevant gene of many fatty acid desaturases is also had to be cloned and Transformation Application.Because most of desaturase is embrane-associated protein, its separation and purification is very difficult, and the desaturase that separation and purification is also identified cans be counted on one's fingers, and the research of the overwhelming majority is carried out around delta 8 desaturase genes and expression regulation thereof.
At present, the unsaturated fatty acids applied produces bacterium based on subtilis, and as the Cordyceps fungus of important anabolism unsaturated fatty acids, also only rest in the research of meta-bolites composition analysis and effect, also rarely found to the research of genes involved and albumen in Cordyceps fungus unsaturated fatty acids metabolic pathway of synthesizing.
(3) summary of the invention
The object of the invention is for the above deficiency that exists and the technical issues that need to address, the enzyme of bacterium Cordyceps sinensis China pilose spore anabolism docosahexenoic acid is produced to " hundred make " and encoding gene is furtherd investigate, provide " hundred makes " production bacterium Cordyceps sinensis China pilose spore and participate in two dodecahexaene coenzyme As and to set out the enzyme of anabolism docosahexenoic acid, encoding gene and application thereof.
The technical solution used in the present invention is:
Participate in two dodecahexaene coenzyme As to set out the n-Hexadecane Co A hydrolase of anabolism docosahexenoic acid, with sequence shown in SEQ ID No.1 or SEQ ID No.3, there is more than 90% homology; This enzyme can prepare corresponding docosahexenoic acid by catalysis two dodecahexaene coenzyme A.Due to the singularity of aminoacid sequence; the fragment of any peptide protein containing aminoacid sequence shown in SEQ ID NO.1 or SEQ ID No.3 or its variant; as its examples of conservative variations, bioactive fragment or derivative; as long as the fragment of this peptide protein or peptide protein variant and aforementioned amino acid sequences homology, more than 90%, all belong to the row of scope.Concrete described change can comprise amino acid whose disappearance, insertion or replacement in aminoacid sequence; Wherein, the conservative property for variant changes, and the amino acid replaced has the structure similar to original acid or chemical property, and as replaced Isoleucine with leucine, variant also can have non-conservation and change, as replaced glycine with tryptophane.
Preferably, described n-Hexadecane CoA hydrolase enzyme amino acid sequence such as SEQ ID No.1(is designated as unsG 1albumen) or SEQ ID No.3 shown in (be designated as unsG 2albumen).
N-Hexadecane Co A hydrolase of the present invention produces bacterium Cordyceps sinensis China pilose spore from " hundred make ".
The path being obtained corresponding docosahexenoic acid by two dodecahexaene coenzyme A anabolism is as follows:
The invention still further relates to described n-Hexadecane Co A hydrolase and prepare application in docosahexenoic acid at biocatalysis two dodecahexaene coenzyme A.
The invention still further relates to the encoding gene of above-mentioned n-Hexadecane Co A hydrolase, namely n-Hexadecane CoA hydrolase gene, concrete, and this encoding gene can be the gene order with polynucleotide shown in SEQ ID NO:2 or SEQ ID No.4 with more than 90% homology.Due to the singularity of nucleotide sequence, shown in any SEQ ID NO:2 or SEQ ID No.4, the variant of polynucleotide, as long as itself and this polynucleotide have more than 90% homology, all belongs to the row of scope.The variant of described polynucleotide refers to a kind of polynucleotide sequence having one or more Nucleotide and change.The variant of these polynucleotide can make raw displacement varient or the varient of non-life, comprises and replaces varient, Deletion variants and insertion varient.As known in the art, allelic variant is the replacement form of polynucleotide, and it may be the replacement of polynucleotide, disappearance or insertion, but can not from the function of peptide protein changing in fact its coding.
Preferably, described n-Hexadecane CoA hydrolase gene nucleotide sequence such as SEQ ID No.2(is designated as unsG 1gene) or SEQ ID No.4(be designated as unsG 2gene) shown in.
Described gene can be used for building can prepare the genetic engineering bacterium of docosahexenoic acid, to expand the output of docosahexenoic acid or derivatives thereof by biocatalysis two dodecahexaene coenzyme A.
Main points of the present invention there are provided the nucleotide sequence shown in the aminoacid sequence shown in SEQ ID NO:1 or 3 and SEQ ID NO:2 or 4, when this aminoacid sequence known and nucleotide sequence, the acquisition of this aminoacid sequence and nucleotide sequence, and related vector, host cell acquisition, be all apparent to those skilled in the art.
Beneficial effect of the present invention is mainly reflected in: the present invention studies in detail two dodecahexaene coenzyme A synthesis docosahexenoic acid pathways metabolisms principle, the cloned DNA comprising nucleotide sequence provided by the present invention can be used for proceeding in engineering bacteria by the method for transduction, conversion, Conjugative tiansfer, by regulating the expression of docosahexenoic acid biosynthesis gene, give the high expression level of host's n-Hexadecane Co A hydrolase, for the output expanding docosahexenoic acid or derivatives thereof provides effective way, there is major application prospect.
(4) accompanying drawing explanation
Fig. 1 is the denaturing formaldehyde gel electrophorogram that " hundred make " produces bacterium Cordyceps sinensis China pilose spore total serum IgE;
Fig. 2 is Fatty acid biosynthesis metabolism approach annotated map;
Fig. 3 is fatty acid metabolism approach annotated map;
Fig. 4 is unsaturated fatty acids metabolic pathway of synthesizing annotated map;
Fig. 5 is n-Hexadecane CoA hydrolase gene pcr amplification product gel electrophoresis figure;
Fig. 6 is cloning vector pMD18-T Vector and expression vector pET-28a physical map;
Fig. 7 is restructuring cloned plasmids pMD18-T/unsG physical map;
Fig. 8 is recombinant expression plasmid pET-28a/unsG building process schematic diagram;
Fig. 9 is recombinant expression plasmid pET-28a/unsG physical map;
Figure 10 is the SDS-PAGE figure of n-Hexadecane CoA hydrolase zymoprotein.
(5) embodiment
Below in conjunction with specific embodiment, the present invention is described further, but protection scope of the present invention is not limited in this:
Embodiment 1: " hundred make " produces the cultivation of bacterium Cordyceps sinensis China pilose spore
Bacterium source: first gather natural cordyceps from Qinghai, and taken back Hangzhou and carry out separation screening, obtain L0106 bacterial strain, and be China pilose spore (Hirsutella Sinensis) through this bacterial strain of strain identification, this culture presevation is in China typical culture collection center, deposit number is CCTCC No:M 2011278, discloses in the patent CN102373190A of previously application.
By this strain inoculation in inclined-plane, (this is the liquid formulations before solidification to culture medium prescription, by following proportions well after bevel again) be glucose 2.0%(w/v, 1% represents in 100mL substratum containing 1g, down together), Semen Maydis powder 1.0%, murphy juice 0.5%, dextrin 0.5%, yeast powder 0.5%, wheat bran 1.0%, dried silkworm chrysalis meal 2.0%, peptone 1.0%, magnesium sulfate 0.05%, potassium primary phosphate 0.05%, agar powder 1.0%, surplus is water, cultivates 25 days at 12 ~ 16 DEG C; Then by strain inoculation in fermention medium, culture medium prescription is glucose 1.0%, molasses 1.0%, dried silkworm chrysalis meal 0.5%, soybean cake powder 1.0%, yeast extract paste 0.5%, magnesium sulfate 0.01%, potassium primary phosphate 0.02%, surplus is water, be placed on shaking table, temperature 12 ~ 16 DEG C is cultivated 25 days, after cultivation terminates aseptically, carries out solid-liquid separation, and solid is placed in sterilized equipment, for subsequent use.
Embodiment 2: " hundred make " produces the extraction of bacterium Cordyceps sinensis China pilose spore total serum IgE
Total serum IgE is extracted with TRIzol reagent, step is specially: 1) liquid nitrogen grinding: get the new fresh thalli of 1g and put into mortar, repeatedly adding liquid nitrogen is fully ground to Powdered, be dispensed in the 1.5mL centrifuge tube of precooling, add 1mL TRIzol reagent, mixing, leaves standstill 5min on ice, nucleic acid-protein mixture is separated completely.2) RNA is separated: add 0.2mL chloroform, firmly concussion mixing 15s, and leave standstill 2 ~ 3min on ice, 4 DEG C, the centrifugal 15min of 12000rpm, layering, gets upper strata aqueous phase, about 600 μ L.3) RNA precipitation: add 500 μ L Virahols, leaving standstill 10min on ice, 4 DEG C, the centrifugal 10min of 12000rpm, abandon supernatant.4) RNA washing: add 1mL 75%(v/v) ethanol, hangs precipitation, leaves standstill 10min on ice, 4 DEG C, the centrifugal 15min of 7500rpm; Repeat washing step above, then wash one time.5) RNA is dissolved: be placed in by centrifuge tube and open wide dry 5 ~ 10min on ice, add appropriate DEPC water dissolution.
Embodiment 3: " hundred make " produces the order-checking of bacterium Cordyceps sinensis China pilose spore RNA sample
After extracting sample total serum IgE, with Oligo(dT) enrichment with magnetic bead mRNA.Add fragmentation buffer and mRNA is broken into short-movie section (200 ~ 700bp), take mRNA as template, Article 1 cDNA chain is synthesized with hexabasic base random primer (random hexamers), then Article 2 cDNA chain is synthesized, do end reparation after adding EB buffer solution elution through QiaQuick PCR kit purifying, add polyA and connect sequence measuring joints again, then clip size selection is carried out with agarose gel electrophoresis, finally carry out pcr amplification, the sequencing library Illumina GA IIx built up checks order.The raw image data obtained that checks order is converted into sequence data through base calling, i.e. raw data or raw reads.Only containing the reads of adaptor sequence in removing primitive sequencer reads, standby with subsequent analysis.
Embodiment 4: " hundred make " production bacterium Cordyceps sinensis China pilose spore RNA is short reads sequence assembling
Use short reads composite software SOAPdenovo(Li, Zhu et al. De novo assembly of human genomes with massively parallel short read sequencing [J]. Genome Res, 2010,20:265-272.) do transcript profile and from the beginning assemble.First the reads with certain length overlap is linked to be the longer Contig fragment not containing N by SOAPdenovo.Then Contig is returned in reads comparison, determine from the distance between the different Contig of same transcript and these Contig by paired-end reads, these Contig connect together by SOAPdenovo, and middle unknown nucleotide sequence N represents, so just obtains Scaffold.Utilize paired-end reads to do filling-up hole process to Scaffold further, finally obtain containing N minimum, the Unigene sequence that two ends can not extend again.Finally, Unigene sequence and albumen database nr, Swiss-Prot, KEGG and COG are done blastx comparison (evalue<0.00001), get the sequence direction that the best albumen of comparison result determines Unigene.If the comparison result between different sink is contradictory, then press nr, Swiss-Prot, the priority of KEGG and COG determines the sequence direction of Unigene, with above four storehouses all to less than Unigene software ESTScan(Iseli, Jongeneel et al. ESTScan:a program for detecting, evaluating, and reconstructing potential coding regions in EST sequences [J]. In Proceedings of 9th InternationalConference on Intelligent Systems for Molecular Biology. AAAIPress, Menlo Park, CA, pp. 1999, 138-148.) predict its coding region and determine the direction of sequence.For determining that the Unigene in sequence direction provides the sequence in its direction from 5' to 3', for determining the sequence that the Unigene in sequence direction provides composite software and obtains.
Embodiment 5: " hundred make " produces bacterium Cordyceps sinensis China pilose spore Unigene functional annotation
Functional annotation information provides the protein function annotation of Unigene, Pathway annotation, COG functional annotation and Gene Ontology(GO) functional annotation.First, by blastx by Unigene sequence alignment to albumen database nr, Swiss-Prot, KEGG and COG(evalue<0.00001), obtain the albumen with given Unigene with highest serial similarity, thus obtain the protein function annotation information of this Unigene.The Pathway annotation of Unigene can be obtained further according to KEGG annotation information.Compared by Unigene and COG database, the function that prediction Unigene is possible also does function statistic of classification to it.According to nr annotation information, use Blast2GO software (Conesa, Gotz et al. Blast2GO:a universal tool for annotation, visualization and analysis in functional genomics research [J]. Bioinformatics, 2005,21 (18): 3674-3676.) the GO annotation information of Unigene is obtained.After obtaining the GO annotation of each Unigene, with WEGO software (Ye, Fang et al. WEGO:a web tool for plotting GO annotations [J]. Nucleic Acids Research, 2006,34:293-297.) GO functional classification statistics is done, from the gene function distribution characteristics being macroscopically familiar with these species to all Unigene.
Embodiment 6: " hundred make " is produced bacterium Cordyceps sinensis China pilose spore docosahexenoic acid pathways metabolism and analyzed
Fig. 2 is the Fatty acid biosynthesis metabolism (map00061) in KEGG pathways metabolism annotation, Fig. 3 is the fatty acid metabolism (map00071) in KEGG pathways metabolism annotation, Fig. 4 is the unsaturated fatty acids anabolism (map01040) in KEGG pathways metabolism annotation, the enzyme annotated is that " hundred make " detected produces bacterium Cordyceps sinensis China pilose spore docosahexenoic acid pathways metabolism relevant enzymes, as can be seen from the figure, n-Hexadecane Co A hydrolase 2 Unigene from the corresponding docosahexenoic acid of two dodecahexaene coenzyme A synthesis are detected.By the ORF Finder software on-line checkingi in NCBI, have found the open reading frame (SEQ ID No.2, No.4) of this gene and obtain corresponding protein sequence (SEQ ID No.1, No.3).
Embodiment 7: " hundred make " produces bacterium Cordyceps sinensis China pilose spore n-Hexadecane CoA hydrolase gene design of primers
Use GENE RUNNER primer-design software according to predicting each gene open proofreading dna primers obtained, the n-Hexadecane CoA hydrolase gene of bacterium China pilose spore anabolism docosahexenoic acid is produced for clone's " hundred make ", primer by Shanghai Sheng Gong biotechnology company limited synthesize, primer sequence as follows listed by:
UnsG 1gene: forward primer 5 ' ATAGAATTCATGGTGAATGCGCGGCAGCC3 '
Reverse primer 5 ' ATAAAGCTTTCACCGCCCTGCGCTGCCC 3 '
UnsG 1mrna length is 606bp.
UnsG 2gene: forward primer 5 ' AGCGAATTCATGTGCGTCCAACACAAGGTG 3 '
Reverse primer 5 ' AGAAAGCTTCTATGCTGCGAAAATGTCGGGG3 '
UnsG 2mrna length is 648bp.
Embodiment 8: " hundred make " produces the preparation of bacterium Cordyceps sinensis China pilose spore cDNA first chain
After the method first provided according to embodiment 1 turns out sutella sinensis fermented mycelium, the method provided according to embodiment 2 again carries out the extraction of total serum IgE to China pilose spore, carry out by following the synthesis that " hundred make " produces bacterium Cordyceps sinensis China pilose spore cDNA first chain, for follow-up each gene clone experiment after obtaining total serum IgE.
Adopt PrimeScript 1st Strand cDNA Synthesis Kit test kit (TaKaRa) reverse transcription synthesis cDNA first chain from Total RNA, experimental procedure is as follows:
1) in Microtube pipe, following mixed solution is prepared.
2) sex change, annealing operation are conducive to the sex change of template ribonucleic acid and the specificity annealing of reverse transcription primer and template, and can improve reverse transcription reaction efficiency, so carry out sex change, annealing reaction in PCR instrument, condition setting is as follows:
65℃,5 min
3) annealing terminates the rear centrifugal several seconds mixed solution of template ribonucleic acid/primer etc. is gathered in bottom Microtube pipe.
4) in above-mentioned Microtube pipe, following inverse transcription reaction liquid is prepared.
5) in PCR instrument, reverse transcription reaction is carried out by following condition.
42℃ 15~30 min
70℃ 15 min
Generalized case, a PolyA structure is had at eukaryote mRNA 3 ' end, the quantity of A base is not at ten to hundreds of etc., utilize this structure can utilize Oligo (dT) primer, under the effect of ThermoScript II, take mRNA as templated synthesis cDNA first chain, the present invention adopts the sequence in the dT region developed alone by TaKaRa (providing in PrimeScript 1st Strand cDNA Synthesis Kit) to be primer, if the mRNA integrity obtained is better, cDNA first chain of all zymoprotein encoding genes in species so can be obtained by process of reverse-transcription.
Embodiment 9: " hundred make " produces the detection of the clone of bacterium Cordyceps sinensis China pilose spore anabolism docosahexenoic acid functional gene n-Hexadecane Co A hydrolase unsG gene, expression and protein vigor
1, the pcr amplification of n-Hexadecane Co A hydrolase unsG gene
With cDNA first chain obtained in embodiment 8 for template, with the unsG of synthesis in embodiment 7 1gene primer: 5 '-ATA GAA TTC ATG GTG AAT GCG CGG CAG CC3 ' and 5 ' ATA AAG CTT TCA CCG CCC TGC GCT GCC C-3 ', unsG 2gene primer: 5 '-AGC GAA TTC ATG TGC GTC CAA CAC AAG GTG-3 ' and 5 '-AGA AAG CTT CTA TGC TGC GAA AAT GTC GGG G-3 ' carries out Pfu archaeal dna polymerase pcr amplification reaction, and condition setting is as follows:
Pfu pcr amplification reaction system:
Pfu DNA Ploymerase pcr amplification condition:
2, n-Hexadecane Co A hydrolase unsG gene PCR product detected through gel electrophoresis
Concrete detection method is: 1) make it be uniformly dissolved the sepharose microwave-oven-heating of prepare 0.9%; 2) get 15mL gel, when gel is cooled to about 50 DEG C, add 1 μ L staining fluid Gold view, pour into after mixing on treatments of Electrophoretic Slab Gels, after removing bubble, insert point sample comb; 3), after gel sets, the careful point sample that takes out is combed, and offset plate is put into electrophoresis chamber (loading wells one end is near the negative pole of electrophoresis chamber), adds TAE electrophoretic buffer in electrophoresis chamber; 4) get 5 μ L samples and then add 6 × Loading Buffer 1.5 μ L and ddH 2o 4 μ L uses liquid-transfering gun loading after mixing, and applied sample amount is 10 μ L; 5) connect the supply lead between electrophoresis chamber and electrophoresis apparatus, just very red, negative pole is black; 6) power-on, start electrophoresis, maximum voltage is no more than 5 V/cm; 7) electrophoresis can be stopped when sample ran 2/3 of offset plate; 8), after cutting off the electricity supply, gel taken out and puts into the observation of gel imaging instrument, take pictures.
Transcript profile order-checking prediction n-Hexadecane Co A hydrolase unsG 1the size of gene is 606bp, unsG 2the size of gene is 648bp, and agarose gel electrophoresis result shows that Successful amplification has gone out n-Hexadecane Co A hydrolase unsG 1the size of gene is about 600bp, unsG 2the size of gene is about 650bp.Fig. 5 is that " hundred make " produces bacterium China pilose spore anabolism docosahexenoic acid functional gene PCR primer gel electrophoresis figure.
3, n-Hexadecane Co A hydrolase unsG gene PCR product add base A process and purifying
Because Pfu archaeal dna polymerase PCR primer end is flush end, connect so just can be used for carrier T also need to carry out adding base A process, purifying after glue reclaims after.It is as follows that glue recovery product adds base A system:
In PCR instrument, 72 DEG C add A base 20 min, finally purify with AxyPrep PCR cleaning agents box.
4, the connection of n-Hexadecane Co A hydrolase unsG gene and cloning vector
Cloning vector pMD18-T Vector is purchased from TaKaRa company (TaKaRa code D101A), and its physical map is shown in Fig. 6, by n-Hexadecane Co A hydrolase unsG 1, unsG 2gene is connected construction recombination plasmid pMD18-T/unsG with cloning vector 1and pMD18-T/unsG 2, physical map is shown in Fig. 7, linked system and condition of contact as follows.
Linked system:
Condition of contact: 16 DEG C, 16h; Deactivation: 65 DEG C, 15min.
5, n-Hexadecane Co A hydrolase recombinant plasmid pMD18-T/unsG 1and pMD18-T/unsG 2conversion
By recombinant plasmid pMD18-T/unsG 1and pMD18-T/unsG 2proceed to the recombinant bacterium E. coli JM109/pMD18-T/unsG building in intestinal bacteria E. coli JM109 and carry n-Hexadecane Co A hydrolase unsG gene respectively 1with E. coli JM109/pMD18-T/unsG 2, concrete steps are: 1) go in competent cell E. coli JM109 by 10 μ L reaction systems, ice bath 30min; 2) thermal shock: 42 DEG C, 90s; 3) ice bath: 2-3min; 4) 800 μ L liquid LB are added, 37 DEG C, 250rpm, 1h; 5) spread plate (containing Amp resistance); 6) 37 DEG C of incubator overnight incubation.
6, n-Hexadecane Co A hydrolase E. coli JM109/pMD18-T/unsG 1with E. coli JM109/pMD18-T/unsG 2the screening of positive recombinant bacterium
Bacterium colony PCR can extract genomic dna, and directly with the DNA exposed after thalline pyrolysis for template carries out pcr amplification, the method is easy and simple to handle, quick, can Rapid identification bacterium colony be whether positive bacterium colony containing object plasmid, comparatively common in conversion qualification.In experiment, carrying out bacterium colony PCR by being inoculated into single bacterium colony corresponding in liquid nutrient medium, whether proceeding to goal gene to verify.First, add in the 1.5mL centrifuge tube containing 50 μ L sterilized waters with toothpick picking list bacterium colony, boiling water bath 30min, then centrifugal using supernatant as template, carry out pcr amplification, PCR program setting is Taq enzyme amplification general procedure.The agarose gel electrophoresis of 0.9% is finally adopted to detect bacterium colony PCR primer.
7, the order-checking of n-Hexadecane Co A hydrolase recombinant plasmid pMD18-T/unsG
After the positive recombinant bacterium LB liquid medium overnight incubation that bacterium colony PCR is detected, get 4mL bacterium liquid and extract plasmid, the operation instructions that method provides by AxyPrep plasmid DNA small volume of reagent box.Order-checking is completed by Sani bio tech ltd, Shanghai.Through sequence verification, sequence SEQ ID No.2 and SEQ ID No.4 is to recombinate to pMD18-T/unsG respectively 1and pMD18-T/unsG 2in.
8, n-Hexadecane Co A hydrolase recombinant expression plasmid pET-28a/unsG 1and pET-28a/unsG 2structure
Experimental basis foreign gene is in the principle of expression in escherichia coli, and expression vector pET-28a and n-Hexadecane Co A hydrolase unsG gene restriction enzyme site comparison situation, determine EcoR I and Hind III double enzyme site, and to recombination bacillus coli E. coli JM109/pMD18-T/unsG 1with E. coli JM109/pMD18-T/unsG 2carry out the cultivation of liquid LB test tube shaker, recombinant plasmid extraction respectively.
The recombinant plasmid pMD18-T/unsG of n-Hexadecane Co A hydrolase unsG gene 1and pMD18-T/unsG 2and expression vector pET-28a use respectively EcoR I/Hind III restriction enzyme 37 DEG C respectively enzyme cut process 6h, it is as follows that enzyme cuts system:
EcoR I/Hind III double digestion system:
Enzyme is cut and is terminated rear 65 DEG C of deactivation 15min, then respectively with Axygen DNA gel recovery test kit carry out reclaiming, purifying.
N-Hexadecane Co A hydrolase unsG gene and expression vector pET-28a connect with T4 ligase enzyme 16 DEG C again and spend the night after double digestion, purifying, and build recombinant expression plasmid, its building process is shown in Fig. 8, build the recombinant expression plasmid pET-28a/unsG obtained 1, pET-28a/unsG 2fig. 9 is shown in by collection of illustrative plates.Linked system is composed as follows:
Linked system:
9, n-Hexadecane Co A hydrolase recombinant expression plasmid pET-28a/unsG 1and pET-28a/unsG 2conversion and the screening of positive monoclonal
By heat-shock transformed in E. coli BL21 Host Strains for the expression plasmid built, be then applied on the LB agar plate containing kantlex (Kan) resistance, 37 DEG C of overnight incubation.From flat board, random choose list bacterium colony, carries out pcr amplification with the primer of each functional gene, selects positive colony.
10, the abduction delivering of n-Hexadecane Co A hydrolase recombinant bacterium
The mono-clonal being accredited as the positive is inoculated in 5mL to be contained in the LB liquid nutrient medium of Kan resistance, 37 DEG C, 250r/min overnight incubation.Get 1mL culture, transferred in 50mL to contain in the LB liquid nutrient medium of Kan resistance 37 DEG C, 250r/min is cultured to cell concentration OD600 and is about about 0.6 ~ 0.8.Certain density IPTG inducing culture 8h is added respectively in culture.Collect thalline for electrophoretic analysis and Enzyme activity assay.
11, n-Hexadecane Co A hydrolase recombinant bacterium expression product SDS-PAGE analyzes
With the E. coli BL21 bacterium proceeding to empty carrier and do not add inductor IPTG recombinant bacterium in contrast.Be accredited as positive recombinant bacterium after IPTG inducing culture certain hour, get 0.5mL Induced cultures, collected by centrifugation thalline, be resuspended in 50 μ L distilled water, add 50 μ L sample-loading buffers, boil 10min after mixing, carry out SDS-PAGE electrophoretic analysis, " A " swimming lane in Figure 10 is recombinant bacterium E. coli BL21/pET-28a/unsG 1the n-Hexadecane Co A hydrolase unsG expressed 1the SDS-PAGE figure of (through its aminoacid sequence of sequence verification as shown in SEQ ID No.1), " B " swimming lane is recombinant bacterium E. coli BL21/pET-28a/unsG 2the n-Hexadecane Co A hydrolase unsG expressed 2the SDS-PAGE figure of (through its aminoacid sequence of sequence verification as shown in SEQ ID No.3).
12, the protein-active of n-Hexadecane Co A hydrolase recombinant bacterium detects
(1) n-Hexadecane Co A hydrolase unsG 1protein-active detect:
Prepared by enzyme liquid: the recombinant bacterium E. coli BL21/pET-28a/unsG taking collection 10.5g phosphate buffered saline buffer (50mM, pH8.0) 15mL suspends, ultrasonication (power 350W, broken 2s, interval 2s, altogether ultrasonication 5min).
N-Hexadecane Co A hydrolase unsG 1transformation system: transform in bottle at 50mL and add E. coli BL21/pET-28a/unsG 1ultrasonication thalline 10mL, 0.1g bis-dodecahexaene coenzyme A, 30 DEG C, 150r/min transforms, transform after terminating, centrifuging and taking supernatant is standby with subsequent detection.
Detection method: GC conditions: 30m × 0.32mm × 0.25mm fused-silica capillary column; Post initial temperature post initial temperature 190 DEG C, insulation 1min, is warming up to 230 DEG C with 6 DEG C/min, then constant temperature; Vaporizer temperature 250 DEG C; Carrier gas is high-purity He (99.999%); Pressure 62.6KPa before post; Flow rate of carrier gas 1.4mL/min; Sample size 1 μ L; Splitting ratio 60:1.Mass Spectrometry Conditions: ion source is EI source; Ion source temperature 230 DEG C; Quadrupole temperature 150 DEG C; Electron energy 70eV; Interface temperature 260 DEG C; Solvent delay 2min; Mass range 10-550u.
Detect through above-mentioned chromatographic condition and calculate, draw to draw a conclusion: n-Hexadecane Co A hydrolase recombinant bacterium E. coli BL21/pET-28a/unsG 1the high specific enzyme (Specific Activity) alive of expressed n-Hexadecane Co A hydrolase is 320 mol/min/mg, and substrate conversion efficiency is 80.73%.
(1) n-Hexadecane Co A hydrolase unsG 2protein-active detect:
Prepared by enzyme liquid: the recombinant bacterium E. coli BL21/pET-28a/unsG taking collection 20.5g uses phosphate buffered saline buffer (50mM, pH8.0) 15mL to suspend respectively, ultrasonication (power 350W, broken 2s, interval 2s, altogether ultrasonication 5min).
N-Hexadecane Co A hydrolase unsG 2transformation system: transform in bottle at 50mL and add E. coli BL21/pET-28a/unsG 2ultrasonication thalline 10mL, 0.1g bis-dodecahexaene coenzyme A, 30 DEG C, 150r/min transforms, transform after terminating, centrifuging and taking supernatant is standby with subsequent detection.
Detection method: GC conditions: 30m × 0.32mm × 0.25mm fused-silica capillary column; Post initial temperature post initial temperature 190 DEG C, insulation 1min, is warming up to 230 DEG C with 6 DEG C/min, then constant temperature; Vaporizer temperature 250 DEG C; Carrier gas is high-purity He (99.999%); Pressure 62.6KPa before post; Flow rate of carrier gas 1.4mL/min; Sample size 1 μ L; Splitting ratio 60:1.Mass Spectrometry Conditions: ion source is EI source; Ion source temperature 230 DEG C; Quadrupole temperature 150 DEG C; Electron energy 70eV; Interface temperature 260 DEG C; Solvent delay 2min; Mass range 10-550u.
Detect through above-mentioned chromatographic condition and calculate, draw to draw a conclusion: n-Hexadecane Co A hydrolase recombinant bacterium E. coli BL21/pET-28a/unsG 2the high specific enzyme (Specific Activity) alive of expressed n-Hexadecane Co A hydrolase is 308mol/min/mg, and substrate conversion efficiency is 79.69%.

Claims (5)

1. participate in a n-Hexadecane Co A hydrolase for two dodecahexaene coenzyme A anabolism docosahexenoic acids, it is characterized in that the aminoacid sequence of described n-Hexadecane Co A hydrolase is as shown in SEQ ID No.1.
2. n-Hexadecane Co A hydrolase as claimed in claim 1 prepares the application in docosahexenoic acid at biocatalysis two dodecahexaene coenzyme A.
3. the gene of n-Hexadecane Co A hydrolase described in coding claim 1.
4. gene as claimed in claim 3, is characterized in that the nucleotide sequence of described gene is as shown in SEQ ID No.2.
5. gene as claimed in claim 3 is building and can prepare application in the genetic engineering bacterium of docosahexenoic acid by biocatalysis two dodecahexaene coenzyme A.
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Citations (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN102373190A (en) * 2011-09-09 2012-03-14 浙江工业大学 Relevant enzymes for preparing mannitol by performing anabolism on Chinese caterpillar fungus and hirsutella sinensis, gene and application thereof

Family Cites Families (2)

* Cited by examiner, † Cited by third party
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CN101899411B (en) * 2009-08-12 2012-02-29 青岛生物能源与过程研究所 Engineering escherichia coli for preparing medium-carbon fatty alcohol
CN102690801B (en) * 2012-05-28 2014-07-02 浙江工业大学 Enzyme for synthesizing and metabolizing inosine monophosphate of Cordyceps sinensis(Berk.)Sacc. Hirsutella sinensis and application thereof

Patent Citations (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN102373190A (en) * 2011-09-09 2012-03-14 浙江工业大学 Relevant enzymes for preparing mannitol by performing anabolism on Chinese caterpillar fungus and hirsutella sinensis, gene and application thereof

Non-Patent Citations (3)

* Cited by examiner, † Cited by third party
Title
acyl-CoA thioesterase;Zheng P et al.;《GenBank: EGX94890.1》;20120504;1 *
Genome sequence of the insect pathogenic fungus Cordyceps miitaris, a valued traditional Chinese medicine;Zheng P et al.;《Genome Biol》;20111123;第12卷(第11期);1-21 *
工程大肠杆菌脂肪酸胞外分泌调控研究进展;孟鑫等;《食品科学》;20110315;第32卷(第5期);331-335 *

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