Gene therapy for human α 1-antitrypsin deficiency in an animal model using SV40-Derived vectors

Abstract

In most genetic diseases, the goal of gene therapy is to deliver a particular transgene; however, sometimes a deleterious gene product must be eliminated. Because of the promise of recombinant simian virus 40 (rSV40) vectors, we tested their ability to deliver a transgene and to target a transcript for destruction by direct administration of the vectors to the liver of an animal model for human alpha1-antitrypsin (alpha1-AT) deficiency. Therapy of human alpha1-AT deficiency requires stable transduction of resting hepatocytes, both to deliver wild-type alpha1-AT and to inhibit production of mutant alpha1-AT. Transgenic mice carrying the mutant human alpha1-AT PiZ allele were treated through an indwelling portal vein catheter with a simian virus 40 (SV40)-derived vector carrying a ribozyme designed to target the human transcript. Treated transgenic mice showed marked decreases of human alpha1-AT messenger RNA and the protein in the liver, and serum levels of human alpha1-AT were decreased to 50% +/- 5% of pretreatment values 3-16 weeks after transduction. Moreover, when normal mice were treated with an SV40-derived vector containing a modified human alpha1-AT complementary DNA engineered to be resistant to cleavage by the alpha1-AT ribozyme, they expressed human alpha1-AT messenger RNA and protein in their livers and serum levels of human alpha1-AT remained >1 microg/mL for 1 year. These results represent the initial steps toward a novel approach to the gene therapy of alpha1-AT deficiency.