ObjectiveTo investigate whether Akt1 gene transfection mediated by recombinant lentivirus (LVs) in the bone marrow mesenchymal stem cells (BMSCs) could enhance the ability of hypoxia tolerance so as to provide a theoretical basis for improving the effectiveness of stem cells transplantation. MethodLVs was used as transfection vector, enhanced green fluorescent protein (EGFP) was used as markers to construct the pLVX-EGFP-3FLAG virus vector carrying the Akt1 gene. The 3rd generation BMSCs from 3-5 weeks old Sprague Dawley rats were transfected with pLVX-EGFP virus solution as group B and with pLVX-EGFP-3FLAG virus solution as group C; and untransfected BMSCs served as control group (group A). At 2-3 days after transfection, the expression of green fluorescent was observed by fluorescence microscope; and at 48 hours after transfection, Western blot method was used to detect the expression of Akt1 protein in groups B and C. BMSCs of groups B and C were given hypoxia intervention with 94%N2, 1%O2, and 5%CO2 for 0, 3, 6, 9, and 12 hours (group B1 and group C1) . The flow cytometry was used to analyze the cell apoptosis rate and cell death rate, and the MTT method to analyze the cell proliferation, and Western blot to detect the expression of apoptosis related gene Caspase-3. ResultsAfter transfection, obvious green fluorescence was observed in BMSCs under fluorescence microscopy in groups B and C, the transfection efficiency was about 60%. Akt1 expression of group C was significantly higher than that of group B (t=17.525, P=0.013) . The apoptosis rate and cell death rate of group B1 increased gradually with time, and difference was significant (P<0.05) . In group C1, the apoptosis rate and cell death rate decreased temporarily at 3 hours after hypoxia intervention, then increased gradually, and difference was significant (P<0.05) . The apoptosis rate and cell death rate of group C1 were significantly lower than those of group B1 at each time point (P<0.05) except at 0 hour. MTT assay showed that absorbance (A) values of groups B and C were significantly higher than those of groups B1 and C1 at each time point (P<0.05) ; the A value of group B was significantly lower than that of group C at each time point (P<0.05) . The A value of group B1 was significantly lower than that of group C1 at 6, 9, and 12 hours after hypoxia intervention (P<0.05) . Western blot results showed that the Caspase-3 expression of group C1 significantly reduced when compared with group B1 at each time point (P<0.05) . ConclusionsAkt1 gene transfection mediated by recombinant LVs could significantly improve hypoxia tolerance of BMSCs by inhibiting the apoptosis, which could provide new ideas for improving the effectiveness of stem cells transplantation.
ObjectiveTo discuss the possibility of constructing injectable tissue engineered adipose tissue, and to provide a new approach for repairing soft tissue defects.MethodsHuman adipose-derived stem cells (hADSCs) were extracted from the lipid part of human liposuction aspirate by enzymatic digestion and identified by morphological observation, flow cytometry, and adipogenic induction. The hADSCs underwent transfection by lentivirus vector expressing hepatocyte growth factor and green fluorescent protein (HGF-GFP-LVs) of different multiplicity of infection (MOI, 10, 30, 50, and 100), the transfection efficiency was calculated to determine the optimum MOI. The hADSCs transfected by HGF-GFP-LVs of optimal MOI and being adipogenic inducted were combined with injectable fibrin glue scaffold, and were injected subcutaneously into the right side of the low back of 10 T-cell deficiency BALB/c female nude mice (transfected group); non-HGF-GFP-LVs transfected hADSCs (being adipogenic inducted) combined with injectable fibrin glue scaffold were injected subcutaneously into the left side of the low back (untransfected group); and injectable fibrin glue scaffold were injected subcutaneously into the middle part of the neck (blank control group); 0.4 mL at each point. Twelve weeks later the mice were killed and the implants were taken out. Gross observation, wet weight measurement, HE staining, GFP fluorescence labeling, and immunofluorescence staining were performed to assess the in vivo adipogenic ability of the seed cells and the neovascularization of the grafts.ResultsThe cultured cells were identified as hADSCs. Poor transfection efficiency was observed in MOI of 10 and 30, the transfection efficiency of MOI of 50 and 100 was more than 80%, so the optimum MOI was 50. Adipose tissue-like new-born tissues were found in the injection sites of the transfected and untransfected groups after 12 weeks of injection, and no new-born tissues was found in the blank control group. The wet-weight of new-born tissue in the transfected group [(32.30±4.06) mg] was significantly heavier than that of the untransfected group [(25.27±3.94) mg] (t=3.929, P=0.001). The mature adipose cells in the transfected group [(126.93±5.36) cells/field] were significantly more than that in the untransfected group [(71.36±4.52) cells/field] (t=30.700, P=0.000). Under fluorescence microscopy, some of the single cell adipocytes showed a network of green fluorescence, indicating the presence of GFP labeled exogenous hADSCs in the tissue. The vascular density of new-born tissue of the transfected group [(16.37±2.76)/field] was significantly higher than that of the untransfected group [(9.13±1.68)/field] (t=8.678, P=0.000).ConclusionThe hADSCs extracted from the lipid part after liposuction can be used as seed cells. After HGF-GFP-LVs transfection and adipose induction, the hADSCs combined with injectable fibrin glue scaffold can construct mature adipose tissue in vivo, which may stimulate angiogenesis, and improve retention rate of new-born tissue.
Objective To investigate effect of hepatocyte growth factor (HGF) after lentivirus-mediated RNA interference (RNAi) targeting c-Met on invasion of colonic carcinoma cell line SW480. Methods The experiment was assigned into 3 groups: NC group, the normal cells were infected by the shRNA negative control virus (the NC-20 andNC-40 represented the negative group which were added 20 ng/mL and 40 ng/mL respectively HGF after being infected); KD group, the normal cells were infected by the shRNA-c-Met target virus (the KD-20 and KD-40 represented the interfered group which were added 20 ng/mL and 40 ng/mL HGF respectively after being infected; KD1, KD2, KD3, and KD4 represented the different RNAi targets for the purpose gene); CON group, the normal cells were not infected by any virus. The lentiviral vector shRNA-c-Met was constructed and verified by polymerase chain reaction (PCR) and DNA sequencing. The SW480 cells were infected with the shRNA-c-Met after packed with lentivirus plasmid. Fourty-eight hours transfection later, the c-Met mRNA of the transfected SW480 cell was detected by real time PCR and the c-Met protein was examined by Western blot. Seventy-two hours after transfection, the cell apoptosis was detected by flow cytometry and the invasions in the different cells with stable transfection were detected by Transwell test. Results The RNAi sequence targeting c-Met gene was successfully inserted into the lentiviral vector. The shRNA-c-Met transfection resulted in an obviously reduced expression of c-Met mRNA in the SW480 cells. The efficency of gene knock down of the KD4 (the cells with No.4 target spot knocked down) was 81.4%. The shRNA-c-Met tansfection resulted in an obviously reduced expression of c-Met protein in the SW480 cells. After transfection, the apoptosis rate of the KD group was significantly higher than that in the NC group (P<0.001) or the CON group (P<0.001). The invasion ratios in the NC group, NC-20 group, and NC-40 group were significantly higher than those in the KD group (P<0.001), KD-20 group (P=0.015), and KD-40 group (P=0.017), respectively; which in the NC-20 group and NC-40 group were increased as compared with the NC group (P<0.001,P<0.001), and in the NC-40 group was increased as compared with the NC-20 group (P=0.005). The invasion ratios in the KD-20 group and KD-40 group were increased as compared with the KD group (P<0.001,P<0.001), and in the KD-40 group was increased as compared with the KD-20 group (P=0.014). Conclusion Lentivirus-mediated RNAi targeting c-Met could effectively suppress expression of c-Met in SW480 cells and could reduce invasion of HGF on SW480 cells with knocked down c-Met.
ObjectiveTo explore the effects of PKD1 gene on mouse aortic smooth muscle (MOVAS) cells autophagy.MethodsThe shRNA and over-expression lentiviral vectors for the target gene of PKD1 were constructed. MOVAS cells were infected by a number of successful packaging shRNA (PKD1 knockdown) or ETS-1 (PKD1 over-expressing) lentiviral vectors, and qPCR was used to test interference and over-expressing effects. Then qPCR and Western blotting were used to detect the expression levels of autophagy markers including Atg5, Beclin1 and LC3 in control group, shPKD1 group and ETS-1 group.ResultsCompared with the control group, PKD1 mRNA level was decreased in the shPKD1 group (P<0.05); ETS-1 and PKD1 mRNA levels were increased in the ETS-1 group (P<0.05). In contrast with the control group, the mRNA levels of autophagy markers including Atg5 (P<0.05) and Beclin1 (P<0.01) were obviously decreased in the shPKD1 group, but they were obviously increased in the ETS-1 group (P<0.001). Protein levels of Atg5, Beclin1 and LC3 were significantly decreased in the shPKD1 group (P<0.05), but they were increased obviously in the ETS-1 group (P<0.05) in contrast with the control group.ConclusionPKD1 gene is involved in MOVAS cells autophagy, low expression of PKD1 gene can inhibit autophagy and high expression of PKD1 promotes autophagy in vascular smooth muscle cells.
ObjectiveTo investigate the effect of small interfering RNA (siRNA) lentivirus-mediated silencing of P75 neurotrophin receptor (P75NTR) gene on osteogenic differentiation of bone marrow mesenchymal stem cells (BMSCs) in rats.MethodsThree lentivirus-mediated P75NTR gene siRNA sequences (P75NTR-siRNA-1, 2, 3) and negative control (NC)-siRNA were designed and transfected into the 3rd generation Sprague Dawley (SD) rat BMSCs. The cells morphological changes were observed under an inverted microscope, and the expressions of P75NTR gene and protein in cells were detected by real-time fluorescence quantitative PCR and Western blot. Then the best silencing P75NTR-siRNA for subsequent osteogenic differentiation experiments was screened out. The 3rd generation SD rat BMSCs were randomly divided into experimental group, negative control group, and blank control group (normal BMSCs). The BMSCs of negative control group and experimental group were transfected with NC-siRNA and the selected P75NTR-siRNA lentiviral vector, respectively. The cells of each group were cultured by osteogenic induction. The expressions of osteogenic related proteins [osteocalcin (OCN) and Runx related transcription factor 2 (Runx2)] were detected by Western blot; the collagen type Ⅰ expression was observed by immunohistochemical staining; the osteogenesis of BMSCs was observed by alkaline phosphatase (ALP) detection and alizarin red staining.ResultsAfter lentivirus-mediated P75NTR transfected into BMSCs, the expressions of P75NTR mRNA and protein significantly reduced (P<0.05), and the best silencing P75NTR-siRNA was P75NTR-siRNA-3. After P75NTR gene was silenced, MTT test showed that the cell proliferation in the experimental group was significantly faster than those in the two control groups (P<0.05). After osteogenic induction, the relative expressions of OCN and Runx2 proteins, collagen type Ⅰ expression, and ALP activity were significantly higher in the experimental group than in the two control groups, the differences were significant (P<0.05). With the prolongation of osteogenic induction, the mineralized nodules in the experimental group gradually increased.ConclusionSilencing the P75NTR gene with siRNA lentivirus can promote the osteogenic differentiation of rat BMSCs and provide a new idea for the treatment of bone defects.