AIM: To study the expression of human insulin gene wrapped with chitosan nanoparticles in NIH3T3 cells and diabetic rats. METHODS: pCMV.Ins, an expression plasmid of the human insulin gene, was constructed. In total, 100 microg pCMV.Ins wrapped with chitosan nanoparticles (chitosan-pCMV.Ins) was transfected to NIH3T3 cells and diabetes rats through lavage and coloclysis, respectively. The transfected cells were grown in Dulbecco's modified Eagle's medium, containing G418, for 72 h after transfection. The clones were selected and continued to grow in G418 medium for 24 d. The expression of human insulin was detected by immunohistochemistry. Human insulin in the culture medium of transfected cells was measured. Fasting blood glucose and plasma human insulin of diabetic rats were measured for 5 d after transfection. RT-PCR and Western blotting were performed to confirm the expression of the human insulin gene in diabetic rats. RESULTS: Approximately 10% of NIH3T3 cells transfected by chitosan-pCMV.Ins expressed human insulin. Human insulin in the culture medium of NIH3T3 cells transfected by chitosan-pCMV.Ins significantly increased compared with that of the control group (P<0.01). Fasting blood glucose levels of the lavage group and the coloclysis group decreased significantly in 5 d (P<0.01) in comparison, while plasma insulin levels were much higher (P<0.01). The human insulin gene mRNA and human insulin were only detected in the lavage and the coloclysis groups. CONCLUSION: The human insulin gene can be transfected and expressed successfully by chitosan- pCMV.Ins in NIH3T3 cells and diabetes rats, which indicates that chitosan is a promising, non-viral vector for gene expression.
AIM: To study the expression of humaninsulin gene wrapped with chitosan nanoparticles in NIH3T3 cells and diabeticrats. METHODS: pCMV.Ins, an expression plasmid of the humaninsulin gene, was constructed. In total, 100 microg pCMV.Ins wrapped with chitosan nanoparticles (chitosan-pCMV.Ins) was transfected to NIH3T3 cells and diabetesrats through lavage and coloclysis, respectively. The transfected cells were grown in Dulbecco's modified Eagle's medium, containing G418, for 72 h after transfection. The clones were selected and continued to grow in G418 medium for 24 d. The expression of humaninsulin was detected by immunohistochemistry. Humaninsulin in the culture medium of transfected cells was measured. Fasting blood glucose and plasma humaninsulin of diabeticrats were measured for 5 d after transfection. RT-PCR and Western blotting were performed to confirm the expression of the humaninsulin gene in diabeticrats. RESULTS: Approximately 10% of NIH3T3 cells transfected by chitosan-pCMV.Ins expressed humaninsulin. Humaninsulin in the culture medium of NIH3T3 cells transfected by chitosan-pCMV.Ins significantly increased compared with that of the control group (P<0.01). Fasting blood glucose levels of the lavage group and the coloclysis group decreased significantly in 5 d (P<0.01) in comparison, while plasma insulin levels were much higher (P<0.01). The humaninsulin gene mRNA and humaninsulin were only detected in the lavage and the coloclysis groups. CONCLUSION: The humaninsulin gene can be transfected and expressed successfully by chitosan- pCMV.Ins in NIH3T3 cells and diabetesrats, which indicates that chitosan is a promising, non-viral vector for gene expression.