Objective To investigate a change in the differentiation and biological function of the cultured rat fibroblast (FB) transfected by the myoblast determining gene (MyoD) and the connexin 43 (Cx43) gene and to explore the possible mechanism of the MyoD and Cx43 genes on treatment of ischemic heart disease (IHD). Methods The gene cloning technology was used to construct the eukaryotic expressed plasmid vector pLenti6/V5-DEST-MyoD and pLenti6/V5DEST-Cx43 in which MyoD cDNA or Cx43 cDNA was inserted. The RFL-6 FB cells were transfected with exogenetic MyoD cDNA or Cx43 cDNA via lipofectamine, followed by the Blasticidin (50 μg/ml) selection, according to the lentiviral expression system (ViraPower) protocol. The expression and the biological functions of MyoD and Cx43 in the transfectants were testified by RT-PCR, Western blot, and molecular and immunocytochemical methods. The mophological structure changes of the cells were observed under microscope before and after the transfection. Results The expression of MyoD and Cx43 was detected in the MyoD and Cx43 genes transfected FB with RT-PCR and Western blot. The immunocytochemical methods indicated the expressionsof the MyoD and Cx43 genes, while desmin and αactin were found in these cells. The myotubes were found from the cultures incubated a week in the differentiation medium, in which the transfected cells had a characteristic of the filamentsin their cytoplasm and showed a myoblast morphology. Conclusion MyoD cDNA can induce the cultured FB to differentiate into the myoblasts and Cx43 cDNA can enhance the gap junctional intercellular communication between the cell and the cell. Thus, a further experimental foundation for the therapy of IHD can be provided.
Objective To build the lentiviral vectors of pigment epithelial derived factor (PEDF) gene, and investigate their expression in human umbilical cord mesenchymal stem cells (hUCMSCs). Methods The PEDF lentiviral vectors (LV-PEDF) were built by DNA recombination and confirmed by DNA sequencing. hUCMSCs were transfected by LV-PEDF with MOI 10, 30, 50, respectively. The transfection efficiency was observed under fluorescence microscope. Cell immunofluorescence, immunocytochemistry and real-time PCR methods were used for detecting the expression of PEDF and VEGF. Results The PEDF cDNA was sub-cloned into pCDH-CMV-MCS-EF1-copGFP vector successfully. DNA sequencing analysis confirmed that PEDF gene sequence was exactly the same with that reported in GenBank. pCDH-PEDF infected cells could show green fluorescence under fluorescence microscope. The transfection efficiency was 72.1% in PEDF-MSCs. Immunofluorescence and immunochemical staining confirmed that PEDF protein was overexpressed in hUCMSCs. The relative expression of PEDF mRNA in experimental group and control group was (0.170±0.028) and (0.015±0.007) respectively by RT-PCR, the difference was statistically significant (P<0.001). The relative expression levels of VEGF mRNA in the two groups were (0.265±0.022) and (0.285±0.049), respectively, with no significant difference (P>0.05). Conclusions We successfully built a lentivirus vector carrying PEDF gene and obtained hUCMSCs with overexpressed PEDF.
Objective To construct the lentiviral vector containing homo sapiens forkhead box C2 (Foxc2) gene and to detect its expression in bone marrow mesenchymal stem cells (BMSCs) of rabbits. Methods Human Foxc2 gene coding region fragment was obtained by RT-PCR and then cloned into the plasmid of LV-green fluorescent protein (GFP) to prepare Foxc2 lentiviral plasmid. Foxc2 lentiviral plasmid, pGC-LV, pHelper1.0, and pHelper2.0 were co-transfected into 293T cells to obtain recombinant virus containing Foxc2 gene. The lentiviral titer was detected. BMSCs were isolated from bone marrow of rabbit and infected with Foxc2 recombined lentiviral, then the optimum multiplicity of infection (MOI) was determined by detecting the intensity of fluorescence expression. The expression of Foxc2 in the infected BMSCs was determined at 1, 3, and 7 days after transfection by inverted fluorescence microscope and Western blot. After osteogenic induction, Alizarin red staining was done to observe the formation of mineralized nodule. Results The Foxc2 recombinant lentiviral vector was constructed and was confirmed by restriction enzyme digestion and sequencing analysis. It could efficiently transfect 293T cells and express in 293T cells. The lentiviral titer was 2 × 108 TU/mL. The optimum MOI was 200. The inverted fluorescence microscope observation showed that the Foxc2 gene expressed in 84.5% ± 4.8% of infected BMSCs at 3 days after transfection. The expression of Foxc2 in infected BMSCs was stable and high, and increased gradually within 7 days after transfection by Western blot. At 2 weeks after osteogenic induction, Alizarin red staining showed that there were a large number of red calcified matrix deposition in the cytoplasm. Conclusion Foxc2 recombined lentivirus with high viral titer is successfully constructed and packaged, and the Foxc2 gene can be transfected into BMSCs with stable and high expression of Foxc2 in infected cells, and these cells may be applied for gene therapy of avascular necrosis of the femoral head.
Objective To construct gene-modified hepatic stem cells (WB-F344 cells), which have rat IL-13 gene and can secrete the recombinant rat IL-13 cytokine in the cells. Methods Firstly, the rat IL-13 sequences were synthesized. Then the sequences were amplificated in bacterium coli after recombinated with pWPXL-MOD plasmid. After PCR and sequence identification, the positive clones were packaged into lentivirus. After detecting the virus titer, the WB-F344 cells with constructed lentivirus vector with rat IL-13 gene were cultured, then the valid targets (expression level of the IL-13) were detected by real time-PCR and Western blot in cultured WB-F344 cells on 5 days. Results The valid DNA of rat IL-13 was recombinated and packaged in lentivirus vector. The recombinant gene sequence was correct by checking with gene sequence test. Then the recombinant was introducted into the WB-F344 cells cultures. The best multiplicity of infection (MOI) value for effective transfection was 5. IL-13 had been detected on day 5 after transfection by checking with real-time PCR and Western blot. Conclusion The recombinant rat IL-13 gene with lentivirus vector is constructed and gene-modified WB-F344 cells are cultured successfully, which can be used in next animal experiment.
【 Abstract】 Objective To construct a lentiviral expression vector carrying Nogo extra cellular peptide residues 1-40(NEP1-40) and to obtain NEP1-40 efficient and stable expression in mammalian cells. Methods The DNA fragment ofNEP1-40 coding sequence was ampl ified by PCR with designed primer from the cDNA l ibrary including NEP1-40 gene, and then subcloned into pGC-FU vector with in-fusion technique to generate the lentiviral expression vector, pGC-FU-NEP1-40. The positive clones were screened by PCR and the correct NEP1-40 was confirmed by sequencing. Recombinant lentiviruses were produced in 293T cells after the cotransfection of pGC-FU-NEP1-40, and packaging plasmids of pHelper 1.0 and pHelper 2.0. Green fluorescent protein (GFP) expression of infected 293T cells was observed to evaluate gene del ivery efficiency. NEP1-40 protein expression in 293T cells was detected by Western blot. Results The lentiviral expression vector carrying NEP1-40 was successfully constructed by GFP observation, and NEP1-40 protein expression was detected in 293T cells by Western blot. Conclusion The recombinant lentivirus pGC-FU-NEP1-40 is successfully constructed and it lays a foundation for further molecular function study of NEP1-40.
目的 构建含小鼠血管内皮生长因子(mVEGF)的重组慢病毒表达载体,包装成病毒颗粒后感染NS-1小鼠骨髓瘤细胞株,以便进一步探索VEGF在骨髓瘤病理生理机制中的作用。 方法 聚合酶链反应法扩增mVEGF基因,克隆入含嘌呤霉素抗性的pCDH慢病毒表达载体,构建出表达mVEGF的慢病毒表达载体pCDH-mVEGF;采用磷酸钙法将慢病毒系统三质粒pCDH-mVEGF、psPAX2、pMD2.G共转染293FT细胞包装病毒,分别收集转染后48 h和72 h病毒上清并感染靶细胞NS-1,初次感染72 h后开始采用嘌呤霉素筛选稳定株,筛选2周后采用ELISA法检测稳定株细胞培养上清中mVEGF的表达,建立出稳定高表达mVEGF的NS-1小鼠骨髓瘤细胞株。 结果 成功构建重组慢病毒表达质粒pCDH-mVEGF,并包装成慢病毒颗粒,感染NS-1细胞株后获得靶基因的稳定高表达。 结论 成功构建出含mVEGF的慢病毒表达载体pCDH-mVEGF,慢病毒系统能有效介导目的基因在NS-1小鼠骨髓瘤细胞株中稳定表达,病毒包装成功并能有效感染NS-1细胞,为进一步探索VEGF在骨髓瘤病理生理机制中的作用奠定了基础。
Objective To study the interferencing and anti-tumor effects of lentiviral vector of siRNA targeting IGF1R and EGFR gene of the liver cancer cell. Methods The complementary DNA containing both sense and antisense Oligo DNA of the targeting sequence was designed, synthesized and connected to the pLVTHM vector, named pLVTHM-IGF1R, into whom the EGFR-siRNA expression frame containing H1 promotor synthesized by RT-PCR was cloned to generate pLVTHM-IGF1R-EGFR-siRNA. The 293T cells were cotransfected by 3 plasmids of pLVTHM-IGF1R-EGFR-siRNA, psPAX2 and pMD2G to enclose LVTHM-IGF1R-EGFR-siRNA, which was amplified in large amount and purified by caesium chloride density gradient centrifugation for measurement of virus titer. SMMC7721 cells infected by LVTHM-IGF1R-EGFR-siRNA were infection group, the untreated SMMC7721 cells and blank vector plasmid LVTHM were two control groups (SMMC7721 cell group and blank vector group). The effect of LVTHM-IGF1R-EGFR-siRNA on IGF1R and EGFR expressions of SMMC7721 cells were detected by RT-PCR and Western blot. The antitumor potential of LVTHM-IGF1R-EGFR-siRNA to SMMC7721 cells was evaluated by Cell Counting Kit-8 assay for cell growth and TUNEL for apoptosis respectively. Results LVTHM-IGF1R-EGFR-siRNA was constructed successfully. Functional pfu titers of LVTHM-IGF1R-EGFR-siRNA was 4.58×109 pfu/ml. Protein and mRNA expression of IGF1R and EGFR of infection group were less than those of blank vector group and SMMC7721 cell group (P<0.05), LVTHM-IGF1R-EGFR-siRNA was more effective to inhibit the proliferation and promote apoptosis of SMMC7721 cells (P<0.05). Conclusion LVTHM-IGF1R-EGFR-siRNA expressing IGF1R-EGFR-siRNA can inhibit the expression of IGF1R and EGFR, and may be used for further investigation of gene therapy of liver cancer.
ObjectiveTo construct a lentiviral vector carrying rat sirt1 gene and observe the expression of sirt1 in retinal ganglion cell (RGC) of rat. MethodsRat sirt1 cDNA was inserted into pLV5 vector. After identification by sequencing analysis and PCR, the recombinant sirt1expressinglentivirus vector was packaged by cotransfecting 293T cells with packaged plasmid.Then pLV5-sirt1 was used to infect the cultured Sprague-Dawley rat RGC cell in vitro.The expressions of sirt1 protein and mRNA in infected rat RGC were detected by quantitative real-time PCR and Western blot. ResultsThe sirt1 expression vector pLV5 was successful constructed and sequence was proved to be correct. The expression of sirt1 protein and mRNA in RGC was significantly increased than that in cells infected with control lentiviruses(P < 0.05). ConclusionWe have successful constructed a sirt1 expression lentivirus vector pLV5-sirt1 and it can increase the expression of sirt1 protein and mRNA in the rat retinal ganglion cells.
Objective To observe the influences of uncoupling protein 2 (UCP-2) rs660339 variants transfection on cell proliferation and apoptosis of human umbilical vein endothelial cell (HUVEC). Methods Two UCP-2 green fluorescent protein (GFP) lentivirus constructs were created with the rs660339 locus carried C or T (UCP-2C or UCP-2T), respectively. HUVEC were cultured after lentiviral infection of UCP-2C or UCP-2T. The expression of UCP-2C or UCP-2T was detected with real time polymerase chain reaction. Cell proliferation and cell apoptosis were compared among negative control (NC) group, UCP-2T group and UCP-2C group using CCK-8 cell viability and flow cytometry. Western blot and immunostaining were employed to examine the expression of Bcl-2 gene. Results The lentivirus constructs were successfully created. >80% of the transfected cells were found to express GFP under fluorescent microscope. The mRNA levels of UCP-2 gene were significantly increased (F=29.183,P=0.001) in the UCP-2T group and UCP-2C group. The CCK-8 assay revealed that on day two (F=15.970,P=0.004), day three (F=16.738,P=0.004), day four (F=5.414,P=0.045) post-infection, UCP-2T and UCP-2C group showed significantly greater proliferation than the NC cells. The apoptotic rate in the UCP-2T and UCP-2C group was significantly lower than NC group (F=277.138,P=0.000), and the apoptotic rate of UCP-2T was significantly lower than that of UCP-2C (P=0.003). The protein levels of Bcl-2 in the UCP-2T and UCP-2C group were significantly greater than that in the NC group (F=425.679,P=0.000), and the Bcl-2 expression of UCP-2T was greater than that of UCP-2C (P=0.002). The Bcl-2 density in the UCP-2T and UCP-2C group were greater than that in the NC group (F=11.827,P=0.008), while there was no difference between UCP-2T and UCP-2C group (P=0.404). Conclusion The variants of UCP-2 rs660339 may influence HUVEC proliferation and apoptosis, and UCP-2T showed a stronger effect of inhibiting apoptosis than UCP-2C.
ObjectiveTo build a lentiviral expression vector regulated by two targets 5 copies of HREs and hTERTp, express the target gene CDX2, and to test the activity of hTERT promoter by using LoVo cells for transfection. MethodsAfter the primer sets were designed, the hTERT promoter was cloned by PCR amplification from the genome of colon cancer. The CEA promoter was removed from the original vector pLEGFP-5HRE-CEAp by double digestion and PCR method, and then the hTERTp was introduced into the vector to construct the recombinant plasmid pLEGFP-5HRE-hTERTp. 5HRE-hTERTp was obtained by PCR, while the CMV promoter was removed from the original vector pLVX-EGFP-3FLAG by double digestion and PCR method, and then the 5HRE-hTERTp was introduced into the vector to construct the recombinant plasmid pLVX-5HRE-hTERTp-EGFP-3FLAG. The CDX2 was cloned by PCR amplification from GV230-CDX2-EGFP, and the EGFP was removed from the vector pLVX-5HRE-hTERTp-EGFP-3FLAG by double digestion, and then the CDX2 was introduced into the vector to construct the recombinant plasmid pLVX-5HRE-hTERTp-CDX2-3FLAG. LoVo cells ex vivo was transiently transfected by pLVX-5HRE-hTERTp-EGFP-3FLAG to evaluate the activity of hTERTp by detecting the expression of green fluorescence protein EGFP. ResultsPCR and sequencing analyzing showed that pLEGFP-5HRE-hTERTp, pLVX-5HRE-hTERTp-EGFP-3FLAG, and pLVX-5HRE-hTERTp-CDX2-3FLAG were sequenced correctly and the same as our designed. pLVX-5HRE-hTERTp-EGFP-3FLAG was successfully transfected into LoVo cells ex vivo and expressed green fluorescence protein EGFP, which showed that hTERTp was activated and promoted the expression of downstream gene. ConclusionThe lentiviral expression vector, pLVX-5HREhTERTp-EGFP-3FLAG and pLVX-5HRE-hTERTp-CDX2-3FLAG are successfully constructed, which lays the foundation of further research. But the function of dual-target regulation needs further proof.