Systemic administration of AAV8-α-galactosidase A induces humoral tolerance in nonhuman primates despite low hepatic expression.

In mice, liver-restricted expression of lysosomal enzymes from adeno-associated viral serotype 8 (AAV8) vectors results in reduced antibodies to the expressed proteins. To ask whether this result might translate to patients, nonhuman primates (NHPs) were injected systemically with AAV8 encoding α-galactosidase A (α-gal). As in mice, sustained expression in monkeys attenuated antibody responses to α-gal. However, this effect was not robust, and sustained α-gal levels were 1-2 logs lower than those achieved in male mice at the same vector dose. Because our mouse studies had shown that antibody levels were directly related to expression levels, several strategies were evaluated to increase expression in monkeys. Unlike mice, expression in monkeys did not respond to androgens. Local delivery to the liver, immune suppression, a self-complementary vector and pharmacologic approaches similarly failed to increase expression. While equivalent vector copies reached mouse and primate liver and there were no apparent differences in vector form, methylation or deamination, transgene expression was limited at the mRNA level in monkeys. These results suggest that compared to mice, transcription from an AAV8 vector in monkeys can be significantly reduced. They also suggest some current limits on achieving clinically useful antibody reduction and therapeutic benefit for lysosomal storage diseases using a systemic AAV8-based approach.

Induction of immune tolerance to a therapeutic protein by intrathymic gene delivery.

The efficacy of recombinant enzyme therapy for genetic diseases is limited in some patients by the generation of a humoral immune response to the therapeutic protein. Inducing immune tolerance to the protein prior to treatment has the potential to increase therapeutic efficacy. Using an AAV8 vector encoding human acid α-glucosidase (hGAA), we have evaluated direct intrathymic injection for inducing tolerance. We have also compared the final tolerogenic states achieved by intrathymic and intravenous injection. Intrathymic vector delivery induced tolerance equivalent to that generated by intravenous delivery, but at a 25-fold lower dose, the thymic hGAA expression level was 10,000-fold lower than the liver expression necessary for systemic tolerance induction. Splenic regulatory T cells (Tregs) were apparent after delivery by both routes, but with different phenotypes. Intrathymic delivery resulted in Tregs with higher FoxP3, TGFß, and IL-10 mRNA levels. These differences may account for the differences noted in splenic T cells, where only intravenous delivery appeared to inhibit their activation. Our results imply that different mechanisms may be operating to generate immune tolerance by intrathymic and intravenous delivery of an AAV vector, and suggest that the intrathymic route may hold promise for decreasing the humoral immune response to therapeutic proteins in genetic disease indications.

Inhibition of glycogen biosynthesis via mTORC1 suppression as an adjunct therapy for Pompe disease.

Pompe disease, also known as glycogen storage disease (GSD) type II, is caused by deficiency of lysosomal acid alpha-glucosidase (GAA). The resulting glycogen accumulation causes a spectrum of disease severity ranging from a rapidly progressive course that is typically fatal by 1-2years of age to a more slowly progressive course that causes significant morbidity and early mortality in children and adults. Recombinant human GAA (rhGAA) improves clinical outcomes with variable results. Adjunct therapy that increases the effectiveness of rhGAA may benefit some Pompe patients. Co-administration of the mTORC1 inhibitor rapamycin with rhGAA in a GAA knockout mouse reduced muscle glycogen content more than rhGAA or rapamycin alone. These results suggest mTORC1 inhibition may benefit GSDs that involve glycogen accumulation in muscle.

Systemic Insulin-like growth factor-1 reverses hypoalgesia and improves mobility in a mouse model of diabetic peripheral neuropathy.

Peripheral neuropathy is a particularly debilitating complication of both type 1 and type 2 diabetes characterized by sensory and motor neuron damage and decreased circulating levels of insulin-like growth factor 1 (IGF-1). Quite often, an early hyperalgesia is followed by hypoalgesia and muscle weakness. Hypoalgesia can lead to significant morbidity for which there is no current treatment. Hyperglycemic, streptozotocin (STZ)-induced rodent models reproduce these symptoms. We investigated whether increasing systemic IGF-1 could improve neuronal function in hyper- and hypoalgesic STZ-treated mice. Increased circulating levels of IGF-1 were achieved by delivering a plasmid or adeno-associated viral (AAV) vector bearing mouse IGF-1 to the liver. Treating mice in the hyperalgesia stage prevented later hypoalgesia. Treating mice in the hypoalgesia stage reversed existing hypoalgesia. This latter effect could be seen by merely restoring IGF-1 serum levels to normalcy, which was possible to achieve by IGF-1 gene therapy or insulin treatment. Sensory nerve functional correction was seen to be correlated with attenuated Schwann cell vacuolization and demyelination in peripheral sensory nerve fibers. A further increase in serum IGF-1 levels with gene therapy also improved motor function, consistent with the observed prevention of both muscle atrophy and peripheral motor nerve fiber demyelination. These results suggest that the restoration of systemic levels of IGF-1 may prove to be a highly effective therapeutic modality for treating diabetic peripheral neuropathy.

Local delivery of a viral vector mitigates neutralization by antiviral antibodies and results in efficient transduction of rabbit liver.

Antiviral antibodies within the human population remain a barrier to the effective clinical use of viral gene transfer vectors. We have asked whether local, balloon catheter-mediated delivery of a viral vector to the rabbit liver using a hepatic vein might mitigate the neutralizing effects of antiviral antibodies. We have compared directly the ability of adenovirus (Ad2) encoding nuclear-localized beta-galactosidase to infect the rabbit liver after local and systemic delivery in both the presence and the absence of defined anti-Ad2 antibody titers. In naive rabbits, local delivery resulted in higher beta-galactosidase expression compared to systemic delivery. In the presence of passively administered anti-Ad2 antibodies, local delivery resulted in expression levels that were comparable to those obtained in naive rabbits by systemic delivery. Local delivery also resulted in the majority of expression originating from hepatocytes, even in passively immunized animals, a result that could not be duplicated using the systemic approach. Since systemic delivery of adenovirus in naive animal models results in transgene expression levels often regarded as therapeutic, these results predict that local hepatic vein delivery of a viral vector is a clinically practical approach to mitigate neutralizing antiviral antibodies and generate therapeutic levels of transgene expression.

Transient siRNA-mediated attenuation of liver expression from an alpha-galactosidase A plasmid reduces subsequent humoral immune responses to the transgene product in mice.

Hepatocytes are an effective depot for protein production from gene therapy vectors. However, when gene transfer vectors or their delivery induces hepatic inflammation, adaptive immune responses against the transgene product can ensue. In BALB/c mice, hydrodynamic delivery of a CMV-driven plasmid DNA (pDNA) bearing human alpha-galactosidase A (alphagal) to the liver generated antibodies against alphagal. This humoral immune response was more robust in a transgenic knockout for alphagal, the Fabry mouse. The antibody response could be attenuated in both mouse strains by using a promoter more restricted to hepatocytes. In an attempt to reduce further the humoral responses to alphagal, expression from the transgene was attenuated by using siRNA during the period of initial delivery-associated liver inflammation. In both mouse models and with both promoters, codelivering an alphagal siRNA resulted in a 2 log decrease in initial expression that then increased over the next few weeks to levels generated by the pDNA alone. This strategy led to both attenuated antibodies and an immune status approximating "tolerance" to alphagal. Importantly, in the Fabry mouse, an alphagal siRNA together with a hepatocyte-restricted promoter gave minimal anti-alphagal antibodies and profound tolerance, suggesting that such an approach might have clinical utility for genetic diseases.

Development of catheter-based procedures for transducing the isolated rabbit liver with plasmid DNA.

Rapid systemic injection of naked plasmid DNA (pDNA) in a large volume into a mouse tail vein has been shown to result in a high level of gene expression in the liver. However, the potential therapeutic benefit to humans embodied in hydrodynamic transfection of the liver cannot be realized until a clinically viable method for gene delivery is developed. In light of this fact, we have devised and evaluated several methods for delivering pDNA to the isolated rabbit liver using minimally invasive catheter-based techniques. Using a lobar technique, pDNA was delivered hydrodynamically to an isolated hepatic lobe using a balloon occlusion balloon catheter to occlude a selected hepatic vein. A whole organ technique was used wherein the entire hepatic venous system was isolated and the pDNA solution injected hydrodynamically into the vena cava between two balloons used to block hepatic venous outflow. Lobar delivery of a plasmid encoding a secreted alkaline phosphatase (SEAP) reporter gene resulted in significant levels of transgene product in the serum. A nonsecreted transgene product, chloramphenicol acetyltransferase (CAT), showed the highest levels of expression in the injected lobe distal to the injection site. Compared to lobar delivery, whole organ delivery yielded much higher serum levels of SEAP expression and a significantly broader hepatic parenchymal distribution of CAT expression. These preliminary studies suggest that catheter-mediated hydrodynamic delivery of pDNA to the isolated liver may provide a method for human gene therapy that is both therapeutically significant and clinically practicable.