ObjectiveTo clone full-length cDNA of rat galectin-9 and construct recombinant adenovirus granule containing rat galectin-9 gene. MethodsThe galectin-9 gene was amplified by RT-PCR from rat liver tissue and inserted orientationally into plasmid pDC316-GFP digested by restriction endonucleases NotⅠ and HindⅢ. The recombinant pDC316-GFP-galectin-9 shuttle plasmid was identified by PCR, restriction endonuclease digestion and sequencing, and then co-transfected with rescue plasmid pBHGlox△E1.3Cre into HEK-293 cells by liposome reagent. Recombinant adenovirus vector containing rat galectin-9 gene (Ad5-galectin-9) was generated by sitespecific recombination and confirmed by PCR, and then Ad5-galectin-9 was propagated in HEK-293 cells and purified. The infectious titer of viral stock was determined by TCID50 assay. ResultsConstruction of pDC316-GFP-galectin-9 shuttle plasmid was confirmed to be correct by PCR, restriction endonuclease digestion and sequencing. Construction of recombinant adenovirus Ad5-galectin-9 was confirmed to be correct by PCR. The infective titer of Ad5-galectin-9 was 1.4×109 U/ml. ConclusionRecombinant adenovirus vector containing rat galectin-9 gene (Ad5-galectin-9) is successfully constructed, which provides the foundation of further research on the function of galectin-9 gene.
Objective Targeted adenoviral gene delivery from peripheral nerves was used to integrally analyse the characterization and time course of LacZ gene (AdLacZ) retrograde transfer to spinal cord and transgene product anterograde labeling ofperipheral nerve. Methods Recombinant replication-defective adenovirus containing AdLacZ was administrated to the cut proximal stumps of median and tibial nerves in Wister rats. Then the transected nerve was repaired with 10-0 nylon sutures. At different time point postinfection the spinal cords of C5 to T1 attached with DRGs and brachial plexuses, or L2 to L6 attached with DRGs and lumbosacralplexuses were removed. The removed spinal cord and DRGs were cut into 50 μm serialcoronal sections and processed for X-gal staining and immunohistochemical staining. The whole specimens of brachial or lumbosacral plexuses attaching with theirperipheral nerves were processed for X-gal staining. The number of X-gal stained neurons was counted and the initial detected time of retrograde labeling, peaktime and persisting period of gene expression in DRG sensory neurons, spinal cord motor neurons and peripheral nerves were studied. Results The gene transfer was specifically targeted to the particular segments of spinal cord andDRGs, and transgene expression was strictly unilaterally corresponding to the infected nerves. Within the same nerve models, the initial detected time of gene expression was earliest in DRG neurons, then in the motor neurons and latest in peripheral nerves. The persisting duration of β-gal staining was shortest in motor neurons, then in sensory neurons and longest in peripheral nerves. The initial detected time of β-gal staining in median nerve models was earlier in mediannerve models compared with that in the tibial nerve models. Although the initial detected time and the beginning of peak duration of β-gal staining were not same, the decreasing time of β-gal staining in motor and sensory neurons of thetwo nerve models were started at about the same day 8 post-infection. The labeled neurons were more in tibial nerve-models than that in median nerve models. Within the same models, the labeled sensory neurons of DRGs were morethan labeled motor neurons of ventral horn. The β-gal staining was tenser in median nerves than that in tibial nerves. However the persisting time of β-gal staining was longer in tibial nerve models. Conclusion The b gene expression in neurons and PNS renders this system particularly attractive for neuroanatomical tracing studies. Furthermore this gene delivery method allowing specific targeting of motor and sensory neurons without damaging the spinal cord might offer potentialities for the gene therapy of peripheral nerve injury.
Objective To investigate the effects of human insulin-like growth factor 1 (hIGF-1) gene transfected by recombinant adenovirus vector (Ad-hIGF-1) on the apoptosis of rabbit nucleus pulposus cells induced by tumor necrosis factor α (TNF-α). Methods The intervertebral disc nucleus pulposus were harvested from 8 healthy adult domestic rabbits (male or female, weighing 2.0-2.5 kg). The nucleus pulposus cells were isolated with collagenase II digestion and the passage 2 cells were cultured to logarithm growing period, and then they were divided into 3 groups according to culture condition: DMEM/F12 medium containing 10% PBS, DMEM/F12 medium containing 10% PBS and 100 ng/mL TNF-α, and DMEM/ F12 medium containing 10% PBS, 100 ng/ mL TNF-α, and Ad-hIGF-1 (multiplicity of infection of 50) were used in control group, TNF-α group, and Ad-hIGF-1 group, respectively. The results of transfection by adenovirus vector carrying hIGF-1 gene were observed by fluorescent microscopy; the expression of hIGF-1 protein was detected by Western blot, hIGF-1 mRNA expression by RT-PCR, and the cell apoptosis rate by TUNEL and flow cytometry. Results Green fluorescence was observed by fluorescent microscopy in Ad-hIGF-1 group, indicating that successful cell transfection. The expressions of hIGF-1 protein and mRNA were detected in Ad-hIGF-1 group by Western blot and RT-PCR, while the control group and TNF-α group had no expression. The cell apoptosis rates of TNF-α group, Ad-hIGF-1 group, and control group were 34.24% ± 4.60%, 6.59% ± 1.03%, and 0.40% ± 0.15%, respectively. The early apoptosis rates of TNF-α group, Ad-hIGF-1 group, and control group were 22.16% ± 2.69%, 5.03% ± 0.96%, and 0.49% ± 0.05%, respectively; the late cell apoptosis rates were 13.96% ± 4.86%, 10.68% ± 3.42%, and 0.29% ± 0.06%, respectively. Compared with TNF-α group, the cell apoptosis rates of Ad-hIGF-1 group and control group were significantly reduced (P lt; 0.05); the cell apoptosis rate of Ad-hIGF-1 group was significantly higher than that of control group (P lt; 0.05). Conclusion Ad-hIGF-1 could inhibit the apoptosis of nucleus pulposus cells induced by TNF-α.
Objective To investigate the feasibility of rabbit synovial-derived mesenchymal stem cells (SMSCs) differentiating into fibrocartilage cells by the recombinant adenovirus vector mediated by bone morphogenetic protein 2/7 (BMP-2/7) genes in vitro. Methods SMSCs were isolated and purified from 3-month-old New Zealand white rabbits [male or female, weighing (2.1 ± 0.3) kg]; the morphology was observed; the cells were identified with immunocytological fluorescent staining, flow cytometry, and cell cycles. The adipogenic, osteogenic, and chondrogenic differentiations were detected. The recombinant plasmid of pAdTrack-BMP-2-internal ribosome entry site (IRES)-BMP-7 was constructed and then was used to infect SMSCs. The cell DNA content and the oncogenicity were tested to determine the safety. Then infected SMSCs were cultured in incomplete chondrogenic medium in vitro. Chondrogenic differentiation of infected SMSCs was detected by RT-PCR, immunofluorescent staining, and toluidine blue staining. Results SMSCs expressed surface markers of stem cells, and had multi-directional potential. The transfection efficiency of SMSCs infected by recombinant plasmid of pAdTrack-BMP-2-IRES-BMP-7 was about 70%. The safety results showed that infected SMSCs had normal double time, normal chromosome number, and normal DNA content and had no oncogenicity. At 21 days after cultured in incomplete chondrocyte medium, RT-PCR results showed SMSCs had increased expressions of collegan type I and collegan type II, particularly collegan type II; the expressions of RhoA and Sox-9 increased obviously. Immunofluorescent staining and toluidine blue staining showed differentiation of SMSCs into fibrocartilage cells. Conclusion It is safe to use pAdTrack-BMP-2-IRES-BMP-7 for infecting SMSCs. SMSCs infected by pAdTrack-BMP-2-IRES-BMP-7 can differentiate into fibrocartilage cells spontaneously in vitro.
Objective To investigate the effect of TIMP-2 gene that was transfected by adenovirus on extracellular matrix of abdominal aortic through assessing the changes of morphology and histopathology of the rat models with abdominal aortic aneurysm. Methods The rat models with abdominal aortic aneurysm were constructed by intraluminally perfusing porcine pancreatic elastase. Twenty-four SD rats with aneurysm were then randomly divided into 3 groups: AdTIMP-2 group (perfused locally with solution of TIMP-2 gene transfected by adenovirus vector to abdominal aorta), AdCMV group (transfected by non-viral vector), and PBS group. After 14 days, the concentrations of elastin and collagen that were collected from the samples of aortic wall were measured by image analysis system and the fixed aortic tissues were examined by light microscopy and some other specific staining methods. Results None of abdominal aortic aneurysm developed in TIMP-2 gene transfected group, with significantly higher rates of developed aneurysm in the other groups (P<0.01). The diameters of arteries on day 14 in the AdTIMP-2 group were (2.33±0.06) mm, which were significantly smaller than those in the AdCMV group 〔(3.52±0.11) mm〕 and PBS group 〔(3.43±0.09) mm〕. The elastic fibers and collagenous fibers were preserved with more integrity in AdTIMP-2 group and inflammation cells that were observed in adventitia of artery were also less than those of the other groups. Conclusion TIMP-2 gene transfected by adenovirus vector could restore the degradation of extracellular matrix that was aroused by elastase and could block the formation of abdominal aortic aneurysm, which may provide a new strategy for the treatment of abdominal aortic aneurysm.