Skeletal muscle-specific expression of human blood coagulation factor Ⅸ rescues factor Ⅸ deficiency mouse by AAV-mediated gene transfer

The efficacy of recombinant adeno-associated virus (AAV) vector to deliver and express human blood clotting factor DC (hFIX) gene in skeletal muscle of coagulation factor IX deficiency mouse strain (FactorIX-knockout) is e-valuated. The muscle creatine kinase enhancer (MCK) and βactin promoter ((3A) were used to drive the hFIX minigene (hFIXml), which was flanked by AAV inverted terminal repeats (ITRs). Following intramuscular injection of high liter (2.5 x 1011 vector genomes/mL) of AAV, increased hFIX expression (256 ng/mL of plasma) was achieved. The time course of hFIX expression demonstrated that the expression level gradually increased over a period of two weeks before anti-hFIX antibodies developed in mouse circulating plasma. Those results provided a promising evidence that rAAV-me-diated gene transfer and skeletal muscle-specific expression of hFIX is a feasible strategy for treating patients for hemophilia B.

Skeletal muscle-specific expression of human blood coagulation factor IX rescues factor IX deficiency mouse by AAV-mediated gene transfer

The efficacy of recombinant adeno-associated virus (AAV) vector to deliver and express human blood clotting factor IX (hFIX) gene in skeletal muscle of coagulation factor IX deficiency mouse strain (FactorIX-knockout) is evaluated. The muscle creatine kinase enhancer (MCK) and β-actin promoter (βA) were used to drive the hFIX minigene (hFIXml), which was flanked by AAV inverted terminal repeats (ITRs). Following intramuscular injection of high titer (2.5 × 10¹¹ vector genomes/mL) of rAAV, increased hFIX expression (256 ng/mL of plasma) was achieved. The time course of hFIX expression demonstrated that the expression level gradually increased over a period of two weeks before anti-hFIX antibodies developed in mouse circulating plasma. Those results provided a promising evidence that rAAV-mediated gene transfer and skeletal muscle-specific expression of hFIX is a feasible strategy for treating patients for hemophilia B. Project supported by the State High Technology Development Program (863-Z20-02-01), Shanghai Postdoctoral Foundation and National Natural Science Foundation of China (Grant No. 39880019).