Transient suppression of hepatocellular replication in the mouse liver following transduction with recombinant adeno-associated virus.

Recombinant vectors based on adeno-associated virus (AAV) are proving to be powerful tools for genetic manipulation of the liver, for both discovery and therapeutic purposes. The system can be used to deliver transgene cassettes for expression or, alternatively, DNA templates for genome editing via homologous recombination. The replicative state of target cells is known to influence the efficiency of these processes and knowledge of the host-vector interactions involved is required for optimally effective vector deployment. Here we show, for the first time in vivo, that in addition to the known effects of hepatocellular replication on AAV-mediated gene transfer, the vector itself exerts a potent, albeit transient suppressive effect on cell cycle progression that is relieved on a time course that correlates with the known rate of clearance of input single-stranded vector DNA. This finding requires further mechanistic investigation, delineates an excellent model system for such studies and further deepens our insight into the complexity of interactions between AAV vectors and the cell cycle in a clinically promising target tissue.

AAV-encoded OTC activity persisting to adulthood following delivery to newborn spf(ash) mice is insufficient to prevent shRNA-induced hyperammonaemia.

Urea cycle defects presenting in the neonatal period with hyperammonaemia are associated with high morbidity and mortality, and necessitate liver transplantation for long-term management. Gene therapy is therefore an attractive possibility, with vectors based on adeno-associated virus (rAAV) currently showing exciting promise in liver-targeted clinical trials in adults. Successful use of rAAV vectors in infants, however, is more challenging as episomal rAAV genomes will be lost from proliferating hepatocytes during liver growth, leaving stable transgene expression dependent on the subset of vector genomes that undergo genomic integration. To explore this challenge, we exploited the partially ornithine transcarbamylase (OTC)-deficient spf(ash) mouse model and small hairpin RNA-mediated knockdown of residual endogenous OTC enzyme activity in adult mice that had received neonatal treatment with an OTC-encoding rAAV. This leaves mice reliant on vector-encoded OTC activity that has persisted from the newborn period. Despite stable transduction in approximately 8% of hepatocytes and residual vector-encoded OTC activity of up to 33% of wild-type, well above endogenous spf(ash) levels (5-7%), mice were not protected from hyperammonaemia. These data show that the distribution of OTC activity within the liver is critical and that rAAV vector re-delivery after early neonatal treatment is likely to be necessary for stable control of hyperammonaemia into adulthood.