Phenotypic Correction of a Mouse Model of Hemophilia B by In Vivo Genetic Correction of the F9 Gene

Abstract LBA-5 Inherited hematologic disorders have the potential to be effectively treated by gene therapy, with recent successes reported for several genetic disorders using viral vector-mediated gene transfer (ADA-SCID, NEJM 2009; β-thalassemia, Nature 2010). However, these trials and others illustrate some of the disadvantages and risks of using viral vector-based gene addition strategies, including loss of endogenous gene regulation and random insertion leading to potential for insertional mutagenesis. An alternative approach is gene correction, where in situ correction of a gene mutation allows endogenous gene regulation and decreases risks related to random integration. Gene correction is based on gene targeting, the therapeutic utility of which has historically been limited to mouse embryonic stem cells due to low homologous recombination rates in other cell types. However, a recently developed class of fusion proteins, zinc finger nucleases (ZFNs), have been shown to increase targeting efficiency 2–3 logs by inducing site-specific DNA double strand breaks at the intended targeting site. ZFNs have permitted high efficiency therapeutic gene targeting in a variety of cultured cells previously thought intractable to these processes, but ZFN-mediated gene correction has yet to be successfully achieved in vivo in an animal model of disease. Here we show ZFN-mediated therapeutic gene targeting of a mutated F9 gene in vivo, resulting in phenotypic correction of a mouse model of hemophilia B (HB). We first generated ZFNs targeting intron 1 of the human F9 gene (F9 ZFNs). We hypothesized the F9 ZFNs would mediate insertion of a wild-type F9 exons 2–8 minigene into intron 1 via gene targeting, thus bypassing the 95% of F9 mutations that occur in exons 2–8. We next generated a humanized HB mouse model with a deletion of the mouse F9 gene and knock-in (at the ROSA 26 locus) of a catalytic domain-deleted human F9 mini-gene (hF9mut) transgene. Adeno-associated viral (AAV) vector delivery of the F9 ZFNs to hF9mut mouse liver resulted in cleavage of the intron 1 target site in 45% of hepatocytes. We then generated an AAV donor vector containing a w.t. exons 2–8 insert flanked by arms of homology. Co-delivery of the AAV-ZFN and AAV-donor vectors to neonatal hF9mut mice (n=16) resulted in circulating F.IX levels of 120–350 ng/mL (2-7% of normal), whereas mice receiving AAV-ZFN alone (n=17) or AAV-mock & AAV-donor (n=15) had no detectable F.IX expression (detection limit 15 ng/mL), or Disclosures: Doyon: Sangamo Biosciences: Employment. Li:Sangamo Biosciences: Employment. Wong:Sangamo Biosciences: Employment. Paschon:Sangamo Biosciences: Employment. Rebar:Sangamo Biosciences: Employment. Gregory:Sangamo Biosciences: Employment. Holmes:Sangamo: Employment. High:Sangamo Biosciences: Consultancy; Children's Hospital of Philadelphia: Patents & Royalties.