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.

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.

Construction of recombinant plasmid and prokaryotic expression in E. Coli and biological activity analysis of human placenta arresten gene

BACKGROUND: The proliferation and metastasis of cancers depend on angiogenesis. This property provides the feasibility for the treatment of cancer by inhibition of angiogenesis, and many angiogenic inhibitors have been demonstrated to effectively inhibit angiogenesis and consequently the growth of solid cancer. As for the newly identified angiogenesis inhibitor, arresten, some studies have found its high activity on restrainting tumor vessel. This study was to assess the anti-angiogenic activity of arresten. METHODS: The arresten gene was obtained from a healthy puerpera's placenta tissue by the reverse transcriptase-polymerase chain reaction (RT-PCR) method, and molecular cloning to prokaryotic expression plasmid pBV220 by recombination strategy. The prokaryotic expression plasmid pBV220/arr was identified by restriction enzyme digestion and sequenced. The pBV220/arr was transformed into E. coli JM109, DH5α, BL21 and BL21 (DE3) by the CaCl_2 transformation method. The arresten expression level was detected by SDS-PAGE. The expressed product was purlfled, re-naturalized and detected for its biological activity of inhibiting the angiogenesis of chorioallantoic membrane (CAM). RESULTS: The arresten gene was cloned and pBV220/arr was constructed. The arresten expression level of protein was highly increased after pBV220/arr was transformed into E. coli BL21 (DE3). SDS-PAGE showed that the expressed arresten proteins were mainly inclusion bodies and had a molecular weight of 26 kDa. The expressed arresten protein showed evident biological activities. CONCLUSIONS: The successful construction of recombinant plasmid pBV220/arr and the effective expression in E. coil have laid a foundation for further study of its anti-angiogenic function and may pave the way for future antitumor application.

Construction of Prokaryotic Expression Vector for pbv220/NT4-ADNF-9

Objective To construct a prokaryotic expression vector bearing fusion gene NT4-ADNF-9 for future studies on genetic therapies for sensorineural deafness. Methods Double strand ADNF-9 cDNA was synthesized using asymmetrical primer/ templates and ligated to the 3’ terminal of signal and leader peptides of neurotrophin 4 (NT4). The fusion gene NT4 -ADNF-9, was subcloned into prokaryotic expression vector pBV220, and named pBV220/ NT4-ADNF-9. DNA sequence of the fusion gene was analyzed. The fusion protein was isolated by SDS-PAGE and its bioactivity was evaluated using primary culture of day 8 chicken embryonic DRGcells. Results The correct sequence of fusion gene NT4-ADNF-9 was successfully subcloned into the pBV220 vector. The expressed ADNF-9 protein showed its effects in promoting cell survival and neurite growth. Conclusion Prokaryotic expression vector pBV220/NT4-ADNF-9 was constructed successfully and the expressed fusion protein demonstrated satisfactory bioactivity.

Construction and Expression of Sugarcane UGPase cDNA Prokaryotic Expression Vector

UGPase （UDP-glucose pyrophosphorylase）, one of the primary enzymes concerned with carbohydrate metabolism, catalyzes the formation of UDPG. By inserting the UGPase cDNA fragment cloned from Saccharum officinarum into PQE-30, the prokaryotic expression vector of PQE-UGP was successfully constructed. Then the vector plasmid of PQE-UGP was transformed into host bacteria M 15 and the expression of target gene was induced by Isopropyl β-D-1-Thiogalactopyranoside （IPTG）. The research laid foundation for study on the prokaryotic expression of UGPase.

Construction of expression vector for NT4-ADNF-9 fusion gene

Objective To construct the prokaryotic expression vector bearing fusion gene NT4-ADNF-9 and lay foundation for further study on genetic therapy of neurosensory deafness. Methods By means of asymmetrical primer/ template,double stranded cDNA of activity dependent neurotrophic factor-9 (ADNF-9) was obtained,which included restriction enzymes sites on the two extremities. ADNF-9 cDNA was ligated to the signal and leader peptides of neurotrophin 4 (NT4),and the fusion gene was named NT4-ADNF-9. Then it was subcloned into prokaryotic expression vector pBV220,and called pBV220/ NT4-ADNF-9. Results Evidences of DNA sequence analysis and restriction enzymes digestion showed that we recombined ADNF-9 cDNA to the 3’terminal of the signal and leader peptides of NT4,and the fusion gene was subcloned into pBV220 successfully. Bioactivity of the products was proved that it could support the cell survival and neurite growth in the primary cultures of dorsal root ganglia (DRG) of embryonic day-8 chicken neurons as compared to the control. Conclusion Prokaryotic expression vector pBV220/NT4-ADNF-9 can be constructed successfully and the bioactivity is satisfactory.

Developmental stage-related expression and identification of murine erythroid differentiation-denucleation factor (MEDDF)

Using MEDDF cDNA fragment in plasmid pBS-SK-MEDDF as template the coding sequence was cloned into pGEM-T-Easy plasmid by PCR method to delete non-coding sequence. After DNA sequencing it was confirmed that the clone sequence was correct, the coding region then was inserted into the vector pET-30α between BamH I and Hind III to construct eukaryotic expression vector. It was found that the specific protein was up to 40% of total bactorial proteins in certain high-expression E. coli. High titer of anti-sera was detected by inoculating New Zealand rabbits with purified MEDDF protein as an antigen. By using immunocytochemical staining it was demonstrated that the expression of MEDDF was exhibited in a developmental stage-specific manner, suggesting that MEDDF may play a certain role in the initiation of murine erythroid terminal differentiation and nuclear condensation. As for the expression of MEDDF appearing in granu-locytes and megakaryocyter in murine bone marrow, it may indicate that there is an original relationship between the proteins and differentiation of murine myelogenous lineage.