Correction of hyperbilirubinemia in gunn rats by surgical delivery of low doses of helper-dependent adenoviral vectors.

Helper-dependent adenoviral (HDAd) vectors are attractive for liver-directed gene therapy because they can drive sustained high levels of transgene expression without chronic toxicity. However, high vector doses are required to achieve efficient hepatic transduction by systemic delivery because of a nonlinear dose response. Unfortunately, such high doses result in systemic vector dissemination and dose-dependent acute toxicity with potential lethal consequences. We have previously shown in nonhuman primates that delivery of HDAd in surgically isolated livers resulted in a significantly higher hepatic transduction with reduced systemic vector dissemination compared with intravenous delivery and multiyear transgene expression. Encouraged by these data, we have now employed a surgical vector delivery method in the Gunn rat, an animal model for Crigler-Najjar syndrome. After vector delivery into the surgically isolated liver, we show phenotypic correction at the low and clinically relevant vector dose of 1 × 10(11) vp/kg. Correction of hyperbilirubinemia and increased glucuronidation of bilirubin in bile was achieved for up to 1 year after vector administration. Surgical delivery of the vector was well tolerated without signs of acute or chronic toxicity. This method of delivery could thereby be a safer alternative to liver transplantation for long-term treatment of Crigler-Najjar syndrome type I.

Codon swapping of zinc finger nucleases confers expression in primary cells and in vivo from a single lentiviral vector.

BACKGROUND: Zinc finger nucleases (ZFNs) are promising tools for genome editing for biotechnological as well as therapeutic purposes. Delivery remains a major issue impeding targeted genome modification. Lentiviral vectors are highly efficient for delivering transgenes into cell lines, primary cells and into organs, such as the liver. However, the reverse transcription of lentiviral vectors leads to recombination of homologous sequences, as found between and within ZFN monomers. METHODS: We used a codon swapping strategy to both drastically disrupt sequence identity between ZFN monomers and to reduce sequence repeats within a monomer sequence. We constructed lentiviral vectors encoding codon-swapped ZFNs or unmodified ZFNs from a single mRNA transcript. Cell lines, primary hepatocytes and newborn rats were used to evaluate the efficacy of integrative-competent (ICLV) and integrative-deficient (IDLV) lentiviral vectors to deliver ZFNs into target cells. RESULTS: We reduced total identity between ZFN monomers from 90.9% to 61.4% and showed that a single ICLV allowed efficient expression of functional ZFNs targeting the rat UGT1A1 gene after codon-swapping, leading to much higher ZFN activity in cell lines (up to 7-fold increase compared to unmodified ZFNs and 60% activity in C6 cells), as compared to plasmid transfection or a single ICLV encoding unmodified ZFN monomers. Off-target analysis located several active sites for the 5-finger UGT1A1-ZFNs. Furthermore, we reported for the first time successful ZFN-induced targeted DNA double-strand breaks in primary cells (hepatocytes) and in vivo (liver) after delivery of a single IDLV encoding two ZFNs. CONCLUSION: These results demonstrate that a codon-swapping approach allowed a single lentiviral vector to efficiently express ZFNs and should stimulate the use of this viral platform for ZFN-mediated genome editing of primary cells, for both ex vivo or in vivo applications.