Prokaryotic Expression and Purification of Heat Shock Factor HSF1 in Arabidopsis thaliana

[ Objective ] This study was to express and purify Arabidopsis thaliana heat shock factor HSF1. [ Method ] Using Escherichia coli M15 harboring HSF1 （pQE32/His6-HSF1, pREP4） as experimental materials, HSF1 was induced to express with isopropyl-β-D-galactoside （IPTG） ; then the expression product was purified using Ni-NTA-agarose affinity chromatography and analyzed by SDS-PAGE. [Result] HSF1 of Arabidopsis thaliana was successfully expressed and purified. [ Conclusion] This study provides materials for understanding the blinding site of HSF1 on Arabidopsis thaliana chromosome, further laying a good foundation for revealing the regulatory mechanism and physiological function of HSF1.

Prokaryotic Expression, Purification and Characterization of a Novel Rice Seed Lipoxygenase Gene OsLOX1

Lipoxygenase （LOX, EC1.13.11.12） is a key enzyme during the degradation of lipids in animals and even plants, and also the first key enzyme responsible for the biosynthesis of jasmonate. To purify and characterize the OsLOX1 gene from rice seeds, the entire coding region of the OsLOX1 gene was inserted into an expression vector pET30a（＋） and transformed into Escherichia coil BL21 （DE3）. Expression of the fusion protein was successfully induced by isopropyl-β-D- thiogalactopyranoside （IPTG） and the purified recombinant protein was obtained by His.Bind Kits. Further assay showed that the purified recombinant protein exhibited the LOX activity. The optimum pH was 4.8 （acetate buffer） and the optimum temperature was 30℃ for the above enzyme. Thus, the recombinant might confer an available usage for the synthesis of jasmonate in vitro, and also provides a possibility for elucidating the inter-relationship between the primary structure of the plant seed lipoxygenase protein and its physiological functions.

Prokaryotic Expression and Purification of Ds MAPK from Dunaliella salina

Dunaliella salina is an important model organism for investigating the salt tolerance mechanism of plant. MAPK is the key gene in the molecular pathway of salt tolerance of plant. In this experiment, the open reading frame （ORF） of DsMAPK gene was amplified by PCR. The target fragment was cloned in pGS-21a, a prokaryotic expression vector with GST-tag. The recombinant plasmid pGS-21a- DsMAPK was then transformed into E. coil BL21 （DE3）. The expression was induced with IPTG. Then the expression form of the recombinant protein was analyzed. The expression products were purified with GST-SefinoseTM Kit and identified with SDS-PAGE and Western blot. The results showed the recombinant expression vector pGS-21a-DsMAPK was constructed successfully, and the molecular weight of the expressed recombinant protein was as same as expected. Western blot analysis showed the purified recombinant protein could be identified specially by the anti- GST antibody and had a good immunological activity. The successful expression of DsMAPK will lay a basis for the further research on the role of DsMAPK in the salt tolerance mechanism at the protein level.

Prokaryotic Expression,Purification,Antibody Production of a NH_2-Terminal Fragment of mCLCA3 Protein and Analysis of mClCA3 Protein Expression in Asthmatic Mouse Lung

mCLCA3 is a member of calcium activated chloride channel（CACC） family that may play an important role in mucin packaging and secretion in asthmatic and cystic fibrosis lung. To study the protein structure and expression of mCLCA3 in asthmatic mouse lung, an N-terminal 269 amino acid peptide of mCLCA3 was expressed in E. coli, purified to homogeneity and rabbit polyclonal antibodies against this peptide were generated. Immunohistochemistry of asthmatic mouse lung using the antibody indicated exclusive mCLCA3 expression in mucin granules of goblet cells in airway surface and lumen, Immunoblot analysis of lavage fluid from asthmatic mouse lung revealed a single 90 kDa protein form of mClCA3. The results demonstrate that the 90 kDa N-terminal peptide, neither the flail-length protein nor the reported N-terminal 35 kDa cleaved form of mClCA3 is the major functional form involved in the packaging and exocytosis of mucin granules in asthmatic goblet cells.

Expression and Purification of the Major Outer Membrane Protein of Chlamydia Trachomatis in Prokaryotic Cell

To clone and construct the recombinant plasmid containing the major outer membrane protein (MOMP) gene of Chlamydia trachomatis (C.trachomatis) and to express the fusion protein in E.coli BL21, the MOMP gene was amplified by polymerase chain reaction (PCR) from genome of C.trachomatis serovar D. The fragment was cloned into the prokaryotic expression vector pET-22b(+) after digestion with BamHⅠ and NotⅠ and transformed into E.coli XL1-Blue. Recombinants were selected by enzyme digestion and sequencing and the recombinant plasmid with MOMP gene was then transformed into E.coli BL21 with IPTG to express the target gene. The expression recombinant proteins were purified by Ni-NTA affinity chromatography, and identified by SDS-PAGE and Western blot. It was found that a 1.2?kb MOMP gene was isolated. The DNA sequence of MOMP was found to be just the same as the sequence published by GenBank. A recombinant plasmid containing MOMP gene was constructed to express the fusion proteins in E.coli. SDS-PAGE analysis showed that the relative molecular weight of the recombinant protein was about 47?kDa that was consistent with the theoretical predicted value, and the specificity of the expressed protein was conformed by Western blot. It concluded that the MOMP gene could be expressed in the prokaryotic system, by which it provided the foundation for the future studies on the biological activities of C.trachomatis and for the development of vaccine against this pathogen.

Prokaryotic expression, purification of a novel candidate tumor suppressor gene FUS1 and characterization of its polyclonal antibodies

FUS1 is a novel candidate tumor suppressor gene identified in human chromosome 3p21.3. Its expression showed significantly reduction or even loss in lung cancer and other types of cancers. In order to further investigate the biological function of FUS1 protein, FUS1 cDNA from MRC-5 cells was amplified by RT-PCR and cloned into prokaryotic expression vector pQE-30. The recombinant expression plasmids were transformed into M15 strain and grown at 20℃ or 37℃. SDS–PAGE analysis revealed that the accumulation of the recombinant protein FUS1 (rFUS1) in inclusion body forms reached maxium amount when induced with 0.5 mM IPTG for 5 h at 37℃. The inclusion bodies were solubilized in 2M urea and purified by a 6 ×His tagged affinity column under denaturing condition. The purified rFUS1 was identified by electrospray ionization-mass spectrometry (ESI-MS) and tested for purity by HPLC chromatography. The purified rFUS1 proteins were then used to immunize rabbits to obtain anti-human FUS1 polyclonal antibodies, which were suitable to detect both the recombinant exogenous FUS1 and the endogenous FUS1 from tissues and cells by western blot and immunohistochemistry, Available purified rFUS1 proteins and self-prepared polyclonal antibodies against FUS1 may provide effective tools for further studies on biological function and application of FUS1.

Cloning, prokaryotic expression,purification and sequence analysis of 20S proteasome subunit gene from T.harzianum

The gene encoding the 20S proteasome subunit（PR29） was cloned from cDNA library of Trichoderma harzianum and expressed in Escherichia coli BL21 （D3） using a pET-28a expression system. The molecular weight of the protein was found to be approximately 29 kDa, as estimated by SDS-PAGE on gels. The target protein was insoluble when induced at 22℃ with 0.4 mmol/L IPTG, while dissoluble if induced at 37℃ with 0.8mmoL/L IPTG. The expressed product was purified through Ni-magnetic beads His Bind. The purity of the fusion protein reached above 80%. The entire eDNA sequence consisted of 1094 bp with 173 and 135 bp in 5＇ and 3＇ untranslated regions respectively. The gene encoding 261 amino acids has no signal peptide sequence. These results could provide a basis for validating the func-tions of PR29. It also provided a preliminary indication for further study of the mechanism and function of proteasome, and more information of proteasome mechanism in T.harzianum could be obtained.

Eukaryotic expression, purification and activity characterization of human soluble DSG2 extracellular domain protein

Objective:To construct a secretory eukaryotic expression vector of DSG2 fused with the Fc region of the human IgG,to validate its expression in 293T cells,and to purify the secretory protein with biological activity.Methods:The DSG2 extracellular domain fragment gene(DSG2ex),was amplified by PCR,and was inserted into the eukaryotic expression plasmid pCMV3-IgG1 to construct the recombinant eukaryotic expression plasmid-pCMV3-DSG2ex-IgG1.The successfully constructed eukaryotic expression plasmid was transfected into 293T cells to express and secrete DSG2 extracellular domain protein.The targeted protein was purified from the cell culture supernatant by Protein A affinity chromatography and confirmed by Western Blotting and ELISA.Results:The pCMV3-DSG2ex-IgG1 eukaryotic expression plasmid was successfully constructed.The highest protein expression level was obtained with 293T cells after 96 h of transfection.The relative molecular mass of the purified product was between 100 and 130 kDa was estimated by SDS-PAGE,which was consistent with the expectation.The yield of the purified protein reached 0.8 mg/ml with a purity over 90%.The purified DSG2 extracellular domain protein with IgG1 tag was recognized by IgG monoclonal antibodies by Western blotting.Moreover,the ELISA results showed that the prepared DSG2 extracellular domain protein had significant binding activity to human type 55 adenovirus Fiber Knob protein(HAdV-55).Conclusion:A simple and efficient method for eukaryotic expression and purification of human soluble DSG2 extracellular domain protein was successfully established,and biologically active DSG2 extracellular domain protein was purified,which laid the foundation for the later study of its protein function and anti-adenovirus drugs.

Prokaryotic Expression of Pseudomonas Aeruginosa Lipase Gene

[Objective] The aim of this study was to investigate the prokaryotic expression of pseudomonas aeruginosa Lipase gene.[Method]Lipase gene was amplified by PCR from the genome DNA of pseudomonas aeruginosa,and its nucleotide sequence was determined.The prokaryotic expression vector of Lipase gene was constructed by the gene recombination technique.The protein expression was induced for 4 hours by IPTG with the final concentration of 1.0 mmol/L,and then SDS-PAGE electrophoresis was analyzed.[Result]The sequence of mature peptides in Lipase gene cloned from pseudomonas aeruginosa had a 99.36% homology with that of pseudomonas aeruginosa lipase submitted in NCBI,so the prokaryotic expression vector of Lipase gene pET32a-Lip was successfully constructed.Furthermore,the results of SDS-PAGE electrophoresis showed that the target gene was expressed highly and effectively.[Conclusion]The cloned pseudomonas aeruginosa lipase with its signal peptide could be normally expressed in E.coli and also used for further study.

Cloning and Prokaryotic Expression of FnBP Ligand Binding Gene of Staphylococcus aureus

[Objective] The study aimed to clone the FnBP ligand binding gene of Staphylococcus aureus and run prokaryotic expression by constructing a prokaryotic expression vector. [Method] The gene encoding FnBP ligand binding gene was amplified from S.aureus chromosomal DNA by PCR technique. After T-A cloning, plasmid pMD18- FnBP was constructed. pMD18- FnBP and pET28a(+)were digested by BamH Ⅰ and EcoR Ⅰ double enzymes, then the purified FnBP ligand binding gene was subcloned into the expression vector pET28a(+), and the prokaryotic expression vector pET28a-FnBP was thus constructed. The constructed plasmid pET28a-FnBP was transformed into Escherichia coli BL21(DE3) competent cells. The bacterium was induced by IPTG and the expressed products were analyzed by SDS-PAGE and Western blot. [Result] The gene fragment with the length of 370 bp was amplified by PCR approach. One approximately 30 kD exogenous protein was observed in SDS-PAGE analysis. Western blot analysis indicates the protein has antigenicity of S.aureus. [Conclusion] The FnBP ligand binding gene of S.aureus was successfully cloned and expressed in prokaryotic cells.

Expression of Porcine Reproductive and Respiratory Syndrome Virus ORF7 Gene and Purification and Immunological Activity Analysis of the Recombinant Protein

[Objective] The aim of this study was to realize efficient expression of the porcine reproductive and respiratory syndrome virus （PRRSV） ORF7 gene in genetic engineering bacteria and analYze the immunological activity of the recombinant protein after purification. [ Method] The constructed recombinant expression vector pET-ORF7 was transformed into Escherichia co1BL21 （DE3） and induced by IPTG under the optimal condition. After analysis of SDS-PAGE and Western Blot, the expression products were purified by Ni-NTA His · Bind Resin chrom- atographic column under denaturing condition and renatured by gradient dialysis. Subsequently, the immunological activity of the renatured recombinant protein was detected by Westem Blot and indirect ELISA. [ Result] The recombinant plasmid pET-ORF7 expressed in E. coli successfully, and the fusion protein was in the form of inclusion body. By SDS-PAGE detection, the molecular weight of the expression protein was approximate 33 kD, according with the expectation. Analysis by Bandscan software showed that the expressed fusion protein was about 50% of total bacterial protein of BL21 （DE3）. Wastem Blot and indirect ELISA detection showed that the renatured protein could react with PRRSV positive serum specifically, indicating its good immunological activity. [ Conclusion] This study lays a foundation for the preparation of PRRSV monoclonal antibody and diagnostic kit.

Construction of a High-efficient Expression Vector of Δ^(12) Fatty Acid Desaturase in Peanut and Its Prokaryotical Expression

A full-length sequence coding for △^12 fatty acid desaturase gene from peanut（Arachis hypogaea L.）was cloned into the expression vector, pRSETB, to generate recombinant plasmid pRSET/HO-A, which was subsequently transformed into expression Escherichia. coli BL21（DE3）pLysS. The △^12 fatty acid desaturase was highly expressed in E. coli BL21（DE3）pLysS in the presence of isopropyl-D-thiogalactopyranoside （IPTG）. The fusion protein was purified and used to form a reaction system in vitro by adding oleic acid as substrate and incubating it at 20℃ for 6 h. Total fatty acids was extracted and methlesterified and then analyzed with gas chromatography. A novel peak corresponding to linoleic acid methyl ester standards was detected with the same retention time. GC-MS （gas chromatogram and gas chromatogram-mass spectrometry） analysis showed that the novel peak was linoleic acid methyl ester. These results exhibited △^12 fatty acid desaturase activity, which could convert oleic acid to linoleic acid specifically.

Study on the Knockout and the Soluble Prokaryotic Expression of VP5 Protein Transmembrane Region of IBDV

[Objective] The research aimed to construct the prokaryotic expression vector of VP5 protein of IBDV.The transmembrane region sequence of VP5 protein was knocked out.Moreover,the expression,separation and purification of objective protein were carried out.[Method] PCR technology was used to respectively amplify the extracellular and intracellular fragments of VP5 gene of IBDV.Then,the two fragments were simultaneously linked to pET-28b（＋）,and it was the vector-intracellular fragment-extracellular fragment-vector.The recombinant expression plasmid pET-VP5-FC and the improved pET-VP5-SC of VP5 whose transmembrane region gene fragment was knocked out were constructed.Then,the expression plasmid was transformed into BL21（DE3）.After IPTG induction,the recombinant protein was purified by Ni affinity chromatography and the gel filtration chromatography.[Result] The soluble expressed VP5 of IBDV was obtained.[Conclusion] The research laid the foundation for further studying the structure and function of VP5 protein.

Expression,Purification and Activity Detection of VP1 of A-type FMDV

[Objective] The research aimed to induce the expression of FMDV structural protein VP1 in E.coli and purify the protein,then detect the activity.[Method] The fragment coding VP1 was amplified by PCR and doubly digested with BamH Ⅰ and XhoⅠ,then cloned into expression vector pGEX-4T-1 and pPROExHTb respectively to get recombinant plasmid pGEX-4T-1-VP1 and pPROExHTb-VP1.The recombinant plasmid pGEX-4T-1-VP1 and pPROExHTb-VP1 was transformed into E.coli BL21(DE3)and induced by IPTG,fusion protein was identifie...

Cloning and Prokaryotic Expression of NS1 Gene of Porcine Parvovirus (PPV) SD1 Strain

[Objective] The research aimed to provide the theoretical basis for establishing a rapid diagnosis method for porcine parvovirus（PPV）. [ Method] One pair of primers were designed according to PPV genome sequences on GenBank website and the sequences of prokaryotic expression vector pET30a （ ＋ ） with multiple cloning sites. The whole sequence of NS1 gene in PPV SD1 strain was amplified by using PCR technology and the positive recombinant plasmid was analyzed by sequencing and homology comparison. The prokaryotic expression recombinant plasmid PET30a/NS1 was constructed to make its induction expression in Escherichia coll. [ Result] The target fragment with the length of 2 208 bp was obtained from PCR amplification. The nucleotide homologies between the cloned NS1 gene and the reported relevant PPV genes were from 97.3 % to 99.4 %, which indicated that NS1 gene had high conservation. But it had a 12-basepair successive deletion near the hydroxyl end. The cloned PPV NS1 gene was successfully expressed in prokaryotic cell, and its expression products existed mostly in inclusion bodies. [ Conclusion] The results of SDS-PAGE detection showed that the molecular weight of PPV NS1 protein was 86 KD.

Molecular Cloning, Sequence Analysis and Prokaryotic Expression of Ovine Activin Receptor Type IIB(ActRIIB) Gene

Objective] This study aimed to clone ovine activin receptor type llB （Ac-tRIIB） gene, construct the prokaryotic expression vector and express the target gene in vitro, thus providing basis for further function verification. [Method] The template cDNA which was reversely transcribed from total RNA of sheep liver tissue, was subjected to polymerase chain reaction （PCR） using specific primers of ActRIIB. The ful-length cDNA of ovine ActRIIB was obtained by pMD18-T cloning and sequencing for bioinformatics analysis. Ovine ActRIIB encoding sequence was subcloned into prokaryotic expression vector pET41a with restriction sites BamHl/Notl, and then transformed into BL21 （DE3）. The induced products by lPTG were analyzed with SDS-PAGE and Western Blot. [Result] The amplified ful-length cDNA of ovine Ac-tRllB gene was 1 564 bp in length （Genbank accession number： JX422071.1） with an open reading frame of 1 539 bp, encoding 512 amino acides. Ovine ActRllB shared the highest homology （99.6%） with bovine ActRllB. ActRllB had highly ho-mologous C-terminal domains and belonged to the TGFβ family. After prokaryotic expression, an approximately 92 kD His-tagged ActRllB recombinant protein was obtained, which was consistent with the excepted result. [Conclusion] Cloning and successful expression of ovine ActRIIB laid solid foundation for further investigation of its biological function.

Construction of Prokaryotic Expression Vectors of EBP1 Gene from Nervilia Fordii (Hance) Schltr.

[Objective] To construct prokaryotic expression vectors encoding gene Erb3binding protein （EBP1）, which plays important roles in regulating plant organ size from Nervilia fordii （Hance） Schltr. [Methods] PCR products of NfEBP1 with particular restriction sites and expression vectors, pET-28 and pET-16b were digested. Ligation, transformation and selection were performed to construct the recombinant plasmids pET-28-NfEBP1 and pET-16-NfEBP1. The recombinant plasmids were transformed into E. coli BL21 using heat -shock transformation. [Results] Recombinant plasmids pET-28-NfEBP1-1188 and pET-16-NfEBP1-1188 were constructed and transformed into expressional host cells, E. coli BL21, and validated by colony PCR, sequencing and double digestion. [Conclusion] Prokaryotic expression vectors of EBP1 gene from N. fordii were successfully constructed, which laid the foundation for characterization of the gene function.

Cloning and Prokaryotic Expression of P23 Major Surface Protein Gene from Theileria sergenti

[Objective] The aim was to study cloning and prokaryotic expression of P23 major surface protein gene of Theileria sergenti. [Method] A pair of specific primers was designed according to the sequence of P23 major surface protein of T. sergenti (D84447).The P23 gene was amplified by PCR from genomic DNA of T. sergenti and cloned into pMD18-T vector to construct recombinant clonal vector pMD18-P23. Positive clones were identified by PCR screening and restriction digestion. A recombinant expression plasmid pGEX-4T-P23 was constructed by subcloning the cloned P23 gene into the linearized pGEX-4T-1 vector and transformed into E. coli BL21. After introduction by IPTG,the expressed fusion protein was identified by SDS-PAGE and Western-blotting. [Result] The cloned gene has a total length of 507 bp. Sequencing result showed that the nucleotide sequence of the cloned P23 gene shared 99.4% identity with that of P23 published in GenBank (D84447). The expressed fusion protein was 46 ku in molecular mass. Induction opportunity of zhours after culture inoculation was the best,the induction time of 6 h was the best,and induction temperature of 34 ℃ was the best as well,IPTG of 1 mmol/L had little effect on the expression. Western-blotting indicated that recombinant protein was recognized by specific antibody. [Conclusion] This study would lay a foundation for further research on the prevention and diagnose of T. sergenti.

Cloning, Analysis and Prokaryotic Expression of DsSP Gene from Dunaliella salina

[Objective] The purpose of this study was to clone a starch phosphorylase gene from Dunaliella salina and to preliminarily analyze its basic properties and protein expression. [Method] RT-PCR and RACE （rapid amplification of cDNA ends） method was used for gene cloning; basic properties of the gene were analyzed using bioinformatics method; prokaryotic expression vector PGS21a-DsSP was constructed and transformed into E. coil BL21; the fusion protein was purified and detected by GST-SefinoseTM Kit and Western Blot, respectively. [Result] A starch phos-phorylase gene （GenBank accession No. KF061044） named DsSP was successfully isolated from D. salina. Basic properties, subcellular localization, secondary structure and tertiary structure of the protein were analyzed and predicted. The fusion protein was found in the supernatant and inclusion bodies. The supernatant protein was successfully purified. Western Blot analysis showed that the fusion protein was successfully expressed in E. coil BL21. [Conclusion] This study laid experimental foun- dation for further clarifying the function and mechanism of DsSP.

Sequence Analysis of Transcription Factor AtWRKY35 and Construction of Prokaryotic Expression Vector

As members of a super gene family, WRKY transcription factors are widely distributed in higher plants. ln this study, bioinformatic analysis of WRKY35, a member of the WRKY gene family, was carried out. Results indicated that tran-scription factor WRKY35 harbors a WRKYGQK core domain and a Cys2His2 or Cys2His/Cys zinc finger in the 5’ end without transmembrane domain. After PCR amplification and restriction digestion, WRKY35 gene fragment was ligated to prokaryotic expression vector PET28. This study provided basis for expression anal-ysis of WRKY35 protein and subsequent functional identification of WRKY35 gene.