Recombinant adeno-associated viral (rAAV) vectors have shown promise for use in liver-targeted gene delivery, but their effects have not been extensively investigated in the immature liver. Understanding the impact of liver growth on the efficacy of transduction is essential, because many monogenic liver diseases that are amenable to gene therapy will require treatment early in life. Here we show that rAAV2/8 transduces the neonatal mouse liver with high efficiency. With just one doubling in liver weight, however, there is a rapid reduction in vector genome numbers, irrespective of form, and the loss of episomal vector is almost complete by 2 weeks. Stable transgene expression is observed in a small percentage of hepatocytes, often in two- to eight-cell clusters, suggestive of genomic integration. Delivery at serially older ages was associated with progressively improved episome persistence and transgene expression. Vector re-administration was possible following initial neonatal administration, albeit at reduced efficacy because of an anticapsid humoral immune response. We also found that intraperitoneal (i.p.) delivery of rAAV2/8 was highly effective at all ages, and that promoter selection is the critical determinant of the intensity and pattern of transgene expression across the hepatic lobule. We conclude that successful use of rAAV to treat liver disease in early childhood will require optimally efficient vector constructs and probable re-administration.
Ornithine transcarbamylase (OTC) deficiency, the most common urea cycle disorder, is associated with severe hyperammonemia accompanied by a high risk of neurological damage and death in patients presenting with the neonatal-onset form. Contemporary therapies, including liver transplantation, remain inadequate with considerable morbidity, justifying vigorous investigation of alternate therapies. Clinical evidence suggests that as little as 3% normal enzyme activity is sufficient to ameliorate the severe neonatal phenotype, making OTC deficiency an ideal model for the development of liver-targeted gene therapy. In this study, we investigated metabolic correction in neonatal and adult male OTC-deficient Spf(ash) mice following adeno-associated virus (AAV)2/8-mediated delivery of the murine OTC complementary DNA under the transcriptional control of a liver-specific promoter. Substantially supraphysiological levels of OTC enzymatic activity were readily achieved in both adult and neonatal mice following a single intraperitoneal (i.p.) injection, with metabolic correction in adults being robust and life-long. In the neonates, however, full metabolic correction was transient, although modest levels of OTC expression persisted into adulthood. Although not directly testable in Spf(ash) mice, these levels were theoretically sufficient to prevent hyperammonemia in a null phenotype. This loss of expression in the neonatal liver is the consequence of hepatocellular proliferation and presents an added challenge to human therapy.
Peripheral nervous system (PNS) sensory neurons are directly involved in the pathophysiology of a number of debilitating inherited and acquired neurological conditions. The lack of effective treatments for many such conditions provides a strong rationale for exploring novel therapeutic approaches, including gene therapy. Friedreich ataxia (FRDA), a sensory neuropathy, is a progressive neurodegenerative disease associated with a loss of large sensory neurons from the dorsal root ganglia. Because a mouse model for this well-characterized disease has been generated, we elected to use FRDA as a model disease. In previous studies we achieved efficient and sustained delivery of a reporter gene to PNS sensory neurons, using recombinant adeno-associated viral (AAV) and lentiviral (LV) vectors. In the current study, AAV and LV vectors encoding the human frataxin cDNA were constructed and assessed for frataxin expression and function in primary FRDA patient fibroblast cell lines. FRDA fibroblasts have been shown to exhibit subtle biochemical changes, including increased mitochondrial iron and sensitivity to oxidant stress. Despite the inherent difficulty in working with primary cells, transduction of patient fibroblasts with either vector resulted in the expression of appropriately localized frataxin and partial reversal of phenotype.
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