Nathalie Provost

Recombinant adeno-associated virus serotype 4 mediates unique and exclusive long-term transduction of retinal pigmented epithelium in rat, dog, and nonhuman primate after subretinal delivery

We previously described chimeric recombinant adeno-associated virus (rAAV) vectors 2/4 and 2/5 as the most efficient vectors in rat retina. We now characterize these two vectors carrying the CMV.gfp genome following subretinal injection in the Wistar rat, beagle dog, and cynomolgus macaque. Both serotypes displayed stable GFP expression for the duration of the experiment (6 months) in all three animal models. Similar to the AAV-2 serotype, AAV-2/5 transduced both RPE and photoreceptor cells, with higher level of transduction in photoreceptors, whereas rAAV-2/4 transduction was unambiguously restricted to RPE cells. This unique specificity found conserved among all three species makes AAV-2/4-derived vectors attractive for retinal diseases originating in RPE such as Leber congenital amaurosis (RPE65) or retinitis pigmentosa due to a mutated mertk gene. To provide further important preclinical data, vector shedding was monitored by PCR in various biological fluids for 2 months post-rAAV administration. Following rAAV-2/4 and -5 subretinal delivery in dogs (n = 6) and in nonhuman primates (n = 2), vector genome was found in lacrymal and nasal fluids for up to 3-4 days and in the serum for up to 15-20 days. Overall, these findings will have a practical impact on the development of future gene therapy trials of retinal diseases.

Lack of an Immune Response against the Tetracycline-Dependent Transactivator Correlates with Long-Term Doxycycline-Regulated Transgene Expression in Nonhuman Primates after Intramuscular Injection of Recombinant Adeno-Associated Virus

ABSTRACT We previously documented persistent regulation of erythropoietin (Epo) secretion in mice after a single intramuscular (i.m.) injection of a recombinant adeno-associated virus (rAAV) vector harboring both the tetracycline-dependent transactivator (rtTA) and the Epo cDNA (D. Bohl, A. Salvetti, P. Moullier, and J. M. Heard, Blood 92:1512-1517, 1998). Using the same vector harboring the cynomolgus macaque Epo cDNA instead, the present study evaluated the ability of the tetracycline-regulatable (tetR) system to establish long-term transgene regulation in nonhuman primates. The vector was administered i.m., after which 5-day induction pulses were performed monthly for up to 13 months by using doxycycline (DOX), a tetracycline analog. We show that initial inductions were successful in all individuals and that there was a tight regulation and a rapid deinduction pattern upon DOX withdrawal. For one macaque, regulation of Epo secretion was maintained during the entire experimental period; for the five remaining macaques, secreted Epo became indistinguishable from endogenous Epo upon repeated DOX inductions. We investigated the mechanism involved and showed that, except in the animal in which secretion persisted, delayed humoral and cellular immune responses were directed against the rtTA transactivator protein associated with the reduction of vector DNA in transduced muscles. This study provides some evidence that, when the immune system is not mobilized against the rtTA transactivator, the tetR-regulatable system is able to support long-term transgene regulation in the context of an rAAV in nonhuman primates. In addition, our results suggest potential improvements for vector design.

Efficient recombinant adeno-associated virus production by a stable rep-cap HeLa cell line correlates with adenovirus-induced amplification of the integrated rep-cap genome

A possible procedure for the production of clinical grade recombinant adeno‐associated virus type 2 (rAAV) would include the use of packaging cell lines, harboring the rep‐cap genes and the vector, combined with a replication defective adenoviral plasmid to provide the helper activities. Several studies have already shown that rAAV can be efficiently assembled by infecting the stable packaging cell line with adenovirus. However, the direct comparison with an adenoviral plasmid has never been reported.

Subretinal Delivery of Recombinant AAV Serotype 8 Vector in Dogs Results in Gene Transfer to Neurons in the Brain

Recombinant adeno-associated virus (rAAV) vectors are among the most efficient gene delivery vehicles for gene transfer to the retina. This study evaluates the behavior of the rAAV8 serotype vector with regard to intraocular delivery in rats and dogs. Subretinal delivery of an AAV2/8.gfp vector results in efficient gene transfer in the retinal pigment epithelium (RPE), the photoreceptors and, surprisingly, in the cells of the inner nuclear layer as well as in ganglion cells. Most importantly, in dogs, gene transfer also occurred distal to the injection site in neurons of the lateral geniculate nucleus of the brain. Because green fluorescent protein (GFP) was detected along the visual pathway within the brain, we analyzed total DNA extracted from various brain slices using PCR. Vector sequences were detected in many parts of the brain, but chiefly in the contralateral hemisphere.

Sustained tetracycline-regulated transgene expression in vivo in rat retinal ganglion cells using a single type 2 adeno-associated viral vector

Viral vector delivery of neurotrophic‐expressing transgenes in the retina may retard or prevent the onset of blindness associated with photoreceptor degeneration. A key safety issue is to achieve regulated expression of these genes in the retina. The purpose of our study was to evaluate whether a single recombinant AAV‐2 (rAAV) encoding for a tetracycline (Tet)‐regulated destabilized reporter gene could provide quantitative profiles of gene regulation targeted to the rat neuroretina.

Detection of Intact rAAV Particles up to 6 Years After Successful Gene Transfer in the Retina of Dogs and Primates

Gene transfer to the retina using recombinant adeno-associated viral (rAAV) vectors has proven to be an effective option for the treatment of retinal degenerative diseases in several animal models and has recently advanced into clinical trials in humans. To date, intracellular trafficking of AAV vectors and subsequent capsid degradation has been studied only in vitro, but the fate of AAV particles in transduced cells following subretinal injection has yet to be elucidated. Using electron microscopy and western blot, we analyzed retinas of one primate and four dogs that had been subretinally injected with AAV2/4, -2/5, or -2/2 serotypes and that displayed efficient gene transfer over several years. We show that intact AAV particles are still present in retinal cells, for up to 6 years after successful gene transfer in these large animals. The persistence of intact vector particles in the target organ, several years postadministration, is totally unexpected and, therefore, represents a new and unanticipated safety issue to consider at a time when gene therapy clinical trials raise new immunological concerns.Gene transfer to the retina using recombinant adeno-associated viral (rAAV) vectors has proven to be an effective option for the treatment of retinal degenerative diseases in several animal models and has recently advanced into clinical trials in humans. To date, intracellular trafficking of AAV vectors and subsequent capsid degradation has been studied only in vitro, but the fate of AAV particles in transduced cells following subretinal injection has yet to be elucidated. Using electron microscopy and western blot, we analyzed retinas of one primate and four dogs that had been subretinally injected with AAV2/4, -2/5, or -2/2 serotypes and that displayed efficient gene transfer over several years. We show that intact AAV particles are still present in retinal cells, for up to 6 years after successful gene transfer in these large animals. The persistence of intact vector particles in the target organ, several years postadministration, is totally unexpected and, therefore, represents a new and unanticipated safety issue to consider at a time when gene therapy clinical trials raise new immunological concerns.