Transduction with recombinant adenoassociated virus (AAV) vectors is limited by the need to convert its single-stranded (ss) genome to transcriptionally active double-stranded (ds) forms. For AAVmediated hemophilia B (HB) gene therapy, we have overcome this obstacle by constructing a liver-restricted mini-human factor IX (hFIX) expression cassette that can be packaged as complementary dimers within individual AAV particles. Molecular analysis of murine liver transduced with these self-complementary (sc) vectors demonstrated rapid formation of active ds-linear genomes that persisted stably as concatamers or monomeric circles. This unique property resulted in a 20-fold improvement in hFIX expression in mice over comparable ssAAV vectors. Administration of only 1 ؋ 10 10 scAAV particles led to expression of hFIX at supraphysiologic levels (8I U/mL) and correction of the bleeding diathesis in FIX knock-out mice. Of importance, therapeutic levels of hFIX (3%-30% of normal) were achieved in nonhuman primates using a significantly lower dose of scAAV than required with ssAAV. Furthermore, AAV5-pseudotyped scAAV vectors mediated successful transduction in macaques with pre-existing immunity to AAV8. Hence, this novel vector represents an important advance for hemophilia B gene therapy. IntroductionThe liver is an important target for gene therapy of a variety of genetic disorders, one of which is hemophilia B (HB), a lifethreatening bleeding disorder that arises from mutations in the blood coagulation factor IX (FIX) gene. By maintaining plasma FIX levels above 1% of normal (Ͼ 0.05 g/mL), the incidence of spontaneous hemorrhage is dramatically reduced and so the therapeutic end point for HB gene therapy is modest. 1 Currently, adeno-associated virus (AAV) vectors are the most promising for HB gene therapy and have been the focus of 2 recent clinical trials. 2 Efficient transduction with AAV is, however, limited by the need to convert its single-stranded (ss) genome into transcriptionally active double-stranded (ds) forms in target cells because of its dependence on host-cell-mediated DNA synthesis of the leading strand 3 or annealing of complementary genomes derived from separate virions. 4 Coinfection with adenovirus 5 or priming the target tissues with genotoxic agents 6,7 can enhance ds transgene formation, but the clinical use of these approaches is limited by potential toxicity. Rapid uncoating of the viral genome, as recently described with AAV8 vectors, allows efficient annealing of the ssAAV provirus to form double-stranded genomes. This unique biologic property is responsible for the 10-to 100-fold higher transduction of the liver with rAAV8 when compared with AAV2 vectors in murine models. [8][9][10] Even so, almost 10 13 AAV8 vector particles are required to achieve 100% hepatocyte transduction in mice, a level that is required for successful gene therapy of some metabolic disorders of the liver. 11 This high vector dose is problematic because it may (1) Supported by The Assisi Foundation of Memphis; the Ame...