AAV-mediated Gene Therapy Halts Retinal Degeneration in PDE6ß-deficient Dogs.

We previously reported that subretinal injection of AAV2/5 RK.cpde6ß allowed long-term preservation of photoreceptor function and vision in the rod-cone dysplasia type 1 (rcd1) dog, a large animal model of naturally occurring PDE6ß deficiency. The present study builds on these earlier findings to provide a detailed assessment of the long-term effects of gene therapy on the spatiotemporal pattern of retinal degeneration in rcd1 dogs treated at 20 days of age. We analyzed the density distribution of the retinal layers and of particular photoreceptor cells in 3.5-year-old treated and untreated rcd1 dogs. Whereas no rods were observed outside the bleb or in untreated eyes, gene transfer halted rod degeneration in all vector-exposed regions. Moreover, while gene therapy resulted in the preservation of cones, glial cells and both the inner nuclear and ganglion cell layers, no cells remained in vector-unexposed retinas, except in the visual streak. Finally, the retinal structure of treated 3.5-year-old rcd1 dogs was identical to that of unaffected 4-month-old rcd1 dogs, indicating near complete preservation. Our findings indicate that gene therapy arrests the degenerative process even if intervention is initiated after the onset of photoreceptor degeneration, and point to significant potential of this therapeutic approach in future clinical trials.

Successful gene therapy in the RPGRIP1-deficient dog: a large model of cone-rod dystrophy.

For the development of new therapies, proof-of-concept studies in large animal models that share clinical features with their human counterparts represent a pivotal step. For inherited retinal dystrophies primarily involving photoreceptor cells, the efficacy of gene therapy has been demonstrated in canine models of stationary cone dystrophies and progressive rod-cone dystrophies but not in large models of progressive cone-rod dystrophies, another important cause of blindness. To address the last issue, we evaluated gene therapy in the retinitis pigmentosa GTPase regulator interacting protein 1 (RPGRIP1)-deficient dog, a model exhibiting a severe cone-rod dystrophy similar to that seen in humans. Subretinal injection of AAV5 (n = 5) or AAV8 (n = 2) encoding the canine Rpgrip1 improved photoreceptor survival in transduced areas of treated retinas. Cone function was significantly and stably rescued in all treated eyes (18-72% of those recorded in normal eyes) up to 24 months postinjection. Rod function was also preserved (22-29% of baseline function) in four of the five treated dogs up to 24 months postinjection. No detectable rod function remained in untreated contralateral eyes. More importantly, treatment preserved bright- and dim-light vision. Efficacy of gene therapy in this large animal model of cone-rod dystrophy provides great promise for human treatment.

Restoration of vision in the pde6ß-deficient dog, a large animal model of rod-cone dystrophy.

Defects in the ß subunit of rod cGMP phosphodiesterase 6 (PDE6ß) are associated with autosomal recessive retinitis pigmentosa (RP), a childhood blinding disease with early retinal degeneration and vision loss. To date, there is no treatment for this pathology. The aim of this preclinical study was to test recombinant adeno-associated virus (AAV)-mediated gene addition therapy in the rod-cone dysplasia type 1 (rcd1) dog, a large animal model of naturally occurring PDE6ß deficiency that strongly resembles the human pathology. A total of eight rcd1 dogs were injected subretinally with AAV2/5RK.cpde6ß (n = 4) or AAV2/8RK.cpde6ß (n = 4). In vivo and post-mortem morphological analysis showed a significant preservation of the retinal structure in transduced areas of both AAV2/5RK.cpde6ß- and AAV2/8RK.cpde6ß-treated retinas. Moreover, substantial rod-derived electroretinography (ERG) signals were recorded as soon as 1 month postinjection (35% of normal eyes) and remained stable for at least 18 months (the duration of the study) in treated eyes. Rod-responses were undetectable in untreated contralateral eyes. Most importantly, dim-light vision was restored in all treated rcd1 dogs. These results demonstrate for the first time that gene therapy effectively restores long-term retinal function and vision in a large animal model of autosomal recessive rod-cone dystrophy, and provide great promise for human treatment.

Intravitreal air tamponade after AAV2 subretinal injection modifies retinal EGFP distribution.

The subretinal injection protocol for the only approved retinal gene therapy (voretigene neparvovec-rzyl) includes air tamponade at the end of the procedure, but its effects on the subretinal bleb have not been described. In the present study, we evaluated the distribution of enhanced green fluorescent protein (EGFP) after subretinal injection of AAV2 in non-human primates (NHP) without (group A = 3 eyes) or with (group B = 3 eyes) air tamponade. The retinal expression of EGFP was assessed 1 month after subretinal injection with in vivo fundus photographs and fundus autofluorescence. In group A (without air), EGFP expression was limited to the area of the initial subretinal bleb. In group B (with air), EGFP was expressed in a much wider area. These data show that the buoyant force of air on the retina causes a wide subretinal diffusion of vector, away from the injection site. In the present paper, we discuss the beneficial and deleterious clinical effects of this finding. Whereas subretinal injection is likely to become more common with the coming of new gene therapies, the effects of air tamponade should be explored further to improve efficacy, reproducibility, and safety of the protocol.

Neonatal systemic delivery of scAAV9 in rodents and large animals results in gene transfer to RPE cells in the retina.

Systemic delivery of recombinant adeno-associated virus (rAAV) vectors has recently been shown to cross the blood brain barrier in rodents and large animals and to efficiently target cells of the central nervous system. Such approach could be particularly interesting to treat lysosomal storage diseases or neurodegenerative disorders characterized by multiple organs injuries especially neuronal and retinal dysfunctions. However, the ability of rAAV vector to cross the blood retina barrier and to transduce retinal cells after systemic injection has not been precisely determined. In this study, gene transfer was investigated in the retina of neonatal and adult rats after intravenous injection of self-complementary (sc) rAAV serotype 1, 5, 6, 8, and 9 carrying a CMV-driven green fluorescent protein (GFP), by fluorescence fundus photography and histological examination. Neonatal rats injected with scAAV2/9 vector displayed the strongest GFP expression in the retina, within the retinal pigment epithelium (RPE) cells. Retinal tropism of scAAV2/9 vector was further assessed after systemic delivery in large animal models, i.e., dogs and cats. Interestingly, efficient gene transfer was observed in the RPE cells of these two large animal models following neonatal intravenous injection of the vector. The ability of scAAV2/9 to transduce simultaneously neurons in the central nervous system, and RPE cells in the retina, after neonatal systemic delivery, makes this approach potentially interesting for the treatment of infantile neurodegenerative diseases characterized by both neuronal and retinal damages.

Regulation of retinal function but nonrescue of vision in RPE65-deficient dogs treated with doxycycline-regulatable AAV vectors.

In previous studies, we demonstrated that recombinant adeno-associated virus (rAAV)-mediated gene transfer of the doxycycline (Dox)-regulatable system allows for the regulation of erythropoietin (EPO) expression in the retina of nonhuman primates after intravenous or oral administration of Dox. In addition, it was shown that administrating different amounts of Dox resulted in a dose-response dynamic of transgene expression. Adeno-associated viral gene therapy has raised hope for the treatment of patients with Leber congenital amaurosis, caused by mutations in the retinal pigment epithelium (RPE)-specific gene RPE65. The preliminary results of three clinical trials suggest some improvement in visual function. However, further improvements might be necessary to optimize vision recovery and this means developing vectors able to generate transgene expression at physiological levels. The purpose of this study was to investigate the ability of the Dox-regulatable system to regulate retinal function in RPE65(-/-) Briard dogs. rAAV vectors expressing RPE65 under the control of either the TetOff and TetOn Dox-regulated promoters or the cytomegalovirus (CMV) constitutive promoter were generated and administered subretinally to seven RPE65-deficient dogs. We demonstrate that the induction and deinduction of retinal function, as assessed by electroretinography (ERG), can be achieved using a Dox-regulatable system, but do not lead to any recovery of vision.

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.

The RPGRIP1-deficient dog, a promising canine model for gene therapy.

PURPOSE: To evaluate the RPGRIP1-deficient miniature longhaired dachshund (MLHD) dog as a potential candidate for gene therapy. METHODS: Six RPGRIP1-deficient MLHD dogs from our dog colony have been observed for two years using a variety of noninvasive procedures. These included bilateral full-field electroretinograms (ERG) to evaluate retinal function, fundus photographs to evaluate retinal vascularization, and optical coherence tomographs (OCT) to evaluate retinal thickness. We also performed histological examination of hematoxylin- and eosin-stained retinal sections as well as sections labeled in situ by the terminal dUTP nick end labeling (TUNEL) method. RESULTS: ERG findings showed that as early as 2 months of age, cone function was lost while rod function was preserved. However, by 9 months of age, both cone and rod functions could not be detected. Functional visual assessment based on the ability to avoid obstacles showed that vision was retained up to the age of 11 months. Both OCT and histopathology studies revealed a progressive thinning of the outer nuclear layer (ONL) over the first 2 years of age. TUNEL labeling identified apoptotic photoreceptor cell death as the cause of this thinning of the ONL. CONCLUSIONS: A treatment strategy should consist in initiating gene therapy as early as possible after birth to prevent or delay the loss of rod function. In the MLHD, successful subretinal delivery of a therapeutic vector is feasible at 2 months of age and may prevent or delay the loss of rod function.

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.

Outer Plexiform Layer Structures Are Not Altered Following AAV-Mediated Gene Transfer in Healthy Rat Retina.

Ocular gene therapy approaches have been developed for a variety of different diseases. In particular, clinical gene therapy trials for RPE65 mutations, X-linked retinoschisis, and choroideremia have been conducted at different centers in recent years, showing that adeno-associated virus (AAV)-mediated gene therapy is safe, but limitations exist as to the therapeutic benefit and long-term duration of the treatment. The technique of vector delivery to retinal cells relies on subretinal injection of the vector solution, causing a transient retinal detachment. Although retinal detachments are known to cause remodeling of retinal neuronal structures as well as significant cell loss, the possible effects of this short-term therapeutic retinal detachment on retinal structure and circuitry have not yet been studied in detail. In this study, retinal morphology and apoptotic status were examined in healthy rat retinas following AAV-mediated gene transfer via subretinal injection with AAV2/5.CMV.d2GFP or sham injection with fluorescein. Outer plexiform layer (OPL) morphology was assessed by immunohistochemical labeling, laser scanning confocal microscopy, and electron microscopy. The number of synaptic contacts in the OPL was quantified after labeling with structural markers. To assess the apoptotic status, inflammatory and pro-apoptotic markers were tested and TUNEL assay for the detection of apoptotic nuclei was performed. Pre- and postsynaptic structures in the OPL, such as synaptic ribbons or horizontal and bipolar cell processes, did not differ in size or shape in injected versus non-injected areas and control retinas. Absolute numbers of synaptic ribbons were not altered. No signs of relevant gliosis were detected. TUNEL labeling of retinal cells did not vary between injected and non-injected areas, and apoptosis-inducing factor was not delocalized to the nucleus in transduced areas. The neuronal circuits in the OPL of healthy rat retinas undergoing AAV-mediated gene transfer were not altered by the temporary retinal detachment caused by subretinal injection, the presence of viral particles, or the expression of green fluorescent protein as a transgene. This observation likely requires further investigations in the dog model for RPE65 deficiency in order to determine the impact of RPE65 transgene expression on diseased retinas in animals and men.

Gene therapeutic prospects in early onset of severe retinal dystrophy: restoration of vision in RPE65 Briard dogs using an AAV serotype 4 vector that specifically targets the retinal pigmented epithelium.

Previous studies have tested gene replacement therapy in RPE65 deficient dogs using recombinant adeno-associated virus 2/2 (rAAV2/2), -2/1 or -2/5 mediated delivery of the RPE65 gene. They all documented restoration of dark- and light-adapted ERG responses and improved psychophysical outcomes. Use of a specific RPE65 promoter and a rAAV vector that targets transgene expression specifically to the retinal pigmented epithelium (RPE) may, however, provide a safer setting for the long-term therapeutic expression of RPE65. Subretinal injection of rAAV2 pseudotyped with serotype 4 (rAAV2/4) specifically targets the RPE. The purpose of our study was to evaluate a rAAV2/4 vector carrying a human RPE65cDNA driven by a human RPE65 promoter, for the ability to restore vision in RPE65-/- purebred Briard dogs. Recombinant rAAV2/4 and rAAV2/2 vectors containing similar human RPE65 promoter and cDNA cassettes were generated and administered subretinally in 8 affected dogs, ages 8 to 30 months (n = 6 with rAAV2/4, n = 2 with rAAV2/2). Although fluorescein angiography and OCT examinations displayed retinal abnormalities in treated retinas, electrophysiological analysis demonstrated that restoration of rod and cone photoreceptor function started as soon as 15 days post-injection, reaching maximal function at 3 months post-injection, and remaining stable thereafter in all animals treated at 8 to 11 months of age. As assessed by the ability of these animals to avoid obstacles in both dim and normal light, functional vision was restored in the treated eye, while the untreated contralateral eye served as an internal control. The dog treated at a later age (30 months) did not recover retinal function or vision, suggesting that there might be a therapeutic window for the successful treatment of RPE65 -/- dogs by gene replacement therapy.

Vitrectomy Before Intravitreal Injection of AAV2/2 Vector Promotes Efficient Transduction of Retinal Ganglion Cells in Dogs and Nonhuman Primates.

Recombinant adeno-associated virus (AAV) has emerged as a promising vector for retinal gene delivery to restore visual function in certain forms of inherited retinal dystrophies. Several studies in rodent models have shown that intravitreal injection of the AAV2/2 vector is the optimal route for efficient retinal ganglion cell (RGC) transduction. However, translation of these findings to larger species, including humans, is complicated by anatomical differences in the eye, a key difference being the comparatively smaller volume of the vitreous chamber in rodents. Here, we address the role of the vitreous body as a potential barrier to AAV2/2 diffusion and transduction in the RGCs of dogs and macaques, two of the most relevant preclinical models. We intravitreally administered the AAV2/2 vector carrying the CMV-eGFP reporter cassette in dog and macaque eyes, either directly into the vitreous chamber or after complete vitrectomy, a surgical procedure that removes the vitreous body. Our findings suggest that the vitreous body appears to trap the injected vector, thus impairing the diffusion and transduction of AAV2/2 to inner retinal neurons. We show that vitrectomy before intravitreal vector injection is an effective means of overcoming this physical barrier, improving the transduction of RGCs in dog and macaque retinas. These findings support the use of vitrectomy in clinical trials of intravitreal gene transfer techniques targeting inner retinal neurons.

Postsurgical assessment and long-term safety of recombinant adeno-associated virus-mediated gene transfer into the retinas of dogs and primates.

OBJECTIVE: To evaluate, in dogs and primates, the short-term effects of subretinal injection and the safety of long-term recombinant adeno-associated virus (rAAV)-mediated transgene expression with respect to retinal morphology and function. METHODS: Subretinal delivery of rAAV (serotype 2, 4, or 5) was performed unilaterally in 14 beagles and 9 macaques. Postsurgical condition was evaluated during a 2-month follow-up study. Three dogs and 1 primate were examined for the long-term study. Green fluorescent protein expression was monitored by fluorescent retinal imaging. Retinal anatomy and function were assessed by angiography and electroretinography, respectively. RESULTS: Transgene expression was observed in 20 of 23 subretinally injected animals (both with and without vitrectomy). We did not detect an inflammatory response in any of the 23 treated subjects. In the long-term study, transgene expression was detected at the latest points evaluated: 36 months for the rAAV-2-injected dog, 24 months for the rAAV-4 and rAAV-5 dogs, and more than 18 months for the rAAV-4-injected primate. Angiography examinations were performed and showed no retinal abnormalities. Functional evaluation showed normal electroretinographic amplitude responses that were similar to those of the noninjected contralateral eyes. CONCLUSIONS: Subretinal injection of the rAAV vector in dogs and primates is a safe procedure with no perioperative complications and a high rate of successful retinal gene transfer. The retinal anatomy and function remained unchanged, despite persistent transgene expression up to 36 months postinjection with rAAV-2, -4, or -5. Additionally, we observed no other adverse effects, such as tumor formation due to possible insertional mutagenesis. These short- and long-term studies on rAAV transgene expression using large animals are encouraging for the prospects of ocular gene therapy applications in humans. CLINICAL RELEVANCE: These short- and long-term studies on rAAV transgene expression using large animals are encouraging for the prospects of ocular gene therapy applications in humans.

Immuno-histochemical analysis of rod and cone reaction to RPE65 deficiency in the inferior and superior canine retina.

Mutations in the RPE65 gene are associated with autosomal recessive early onset severe retinal dystrophy. Morphological and functional studies indicate early and dramatic loss of rod photoreceptors and early loss of S-cone function, while L and M cones remain initially functional. The Swedish Briard dog is a naturally occurring animal model for this disease. Detailed information about rod and cone reaction to RPE65 deficiency in this model with regard to their location within the retina remains limited. The aim of this study was to analyze morphological parameters of cone and rod viability in young adult RPE65 deficient dogs in different parts of the retina in order to shed light on local disparities in this disease. In retinae of affected dogs, sprouting of rod bipolar cell dendrites and horizontal cell processes was dramatically increased in the inferior peripheral part of affected retinae, while central inferior and both superior parts did not display significantly increased sprouting. This observation was correlated with photoreceptor cell layer thickness. Interestingly, while L/M cone opsin expression was uniformly reduced both in the superior and inferior part of the retina, S-cone opsin expression loss was less severe in the inferior part of the retina. In summary, in retinae of young adult RPE65 deficient dogs, the degree of rod bipolar and horizontal cell sprouting as well as of S-cone opsin expression depends on the location. As the human retinal pigment epithelium (RPE) is pigmented similar to the RPE in the inferior part of the canine retina, and the kinetics of photoreceptor degeneration in humans seems to be similar to what has been observed in the inferior peripheral retina in dogs, this area should be studied in future gene therapy experiments in this model.

Transgene regulation using the tetracycline-inducible TetR-KRAB system after AAV-mediated gene transfer in rodents and nonhuman primates.

Numerous studies have demonstrated the efficacy of the Adeno-Associated Virus (AAV)-based gene delivery platform in vivo. The control of transgene expression in many protocols is highly desirable for therapeutic applications and/or safety reasons. To date, the tetracycline and the rapamycin dependent regulatory systems have been the most widely evaluated. While the long-term regulation of the transgene has been obtained in rodent models, the translation of these studies to larger animals, especially to nonhuman primates (NHP), has often resulted in an immune response against the recombinant regulator protein involved in transgene expression regulation. These immune responses were dependent on the target tissue and vector delivery route. Here, using AAV vectors, we evaluated a doxycyclin-inducible system in rodents and macaques in which the TetR protein is fused to the human Krüppel associated box (KRAB) protein. We demonstrated long term gene regulation efficiency in rodents after subretinal and intramuscular administration of AAV5 and AAV1 vectors, respectively. However, as previously described for other chimeric transactivators, the TetR-KRAB-based system failed to achieve long term regulation in the macaque after intramuscular vector delivery because of the development of an immune response. Thus, immunity against the chimeric transactivator TetR-KRAB emerged as the primary limitation for the clinical translation of the system when targeting the skeletal muscle, as previously described for other regulatory proteins. New developments in the field of chimeric drug-sensitive transactivators with the potential to not trigger the host immune system are still needed.

Long-term doxycycline-regulated transgene expression in the retina of nonhuman primates following subretinal injection of recombinant AAV vectors.

Adeno-associated viral gene therapy has shown promise for the treatment of inherited and acquired retinal disorders. In most applications, regulation of expression is a critical concern for both safety and efficacy. The purpose of our study was to evaluate the ability of the tetracycline-regulatable system to establish long-term transgene regulation in the retina of nonhuman primates. Three rAAV vectors expressing the tetracycline-dependent transactivator (rtTA) under the control of either the ubiquitous CAG promoter or the specific RPE65 promoter (AAV2/5.CAG.TetOn.epo, AAV2/4.CAG.TetOn.epo, and AAV2/4.RPE65.TetOn.epo) were generated and administered subretinally to seven macaques. We demonstrated that repeated inductions of transgene expression in the nonhuman primate retina can be achieved using a Tet-inducible system via rAAV vector administration over a long period (2.5 years). Maximum erythropoietin (EPO) secretion in the anterior chamber depends upon the rAAV serotype and the nature of the promoter driving rtTA expression. We observed that the EPO isoforms produced in the retina differ from one another based on the transduced cell type of origin within the retina and also differ from both the physiological EPO isoforms and the isoforms produced by AAV-transduced skeletal muscle.

Biodistribution of rAAV vectors following intraocular administration: evidence for the presence and persistence of vector DNA in the optic nerve and in the brain.

The purpose of our study was to evaluate the biodistribution of rAAV vectors following subretinal or intravitreal injection. In rats, we performed subretinal or intravitreal injections of rAAV-2/2.CMV.gfp. In large animals, rAAV-2/4.CMV.gfp or rAAV-2/5.CMV.gfp was delivered into the subretinal space while rAAV-2/2.CMV.gfp was delivered either to the subretinal space or to the vitreous. In euthanized animals, we undertook a complete necropsy. In animals maintained alive, we collected blood and tissue samples from the submandibular lymph node, liver, and gonads. We analyzed total DNA, extracted from various tissue samples and peripheral blood mononuclear cells (PBMC), by PCR. Following subretinal or intravitreal injections in rats and in large animals, vector sequences were not detected in the liver or in the gonads but were occasionally found in PBMC. An unexpected result was the detection of rAAV sequences in the optic nerve following subretinal injection. The most striking finding was the detection of vector sequences in the brain, along the visual pathway, in rAAV-2/2 intravitreally injected dogs. These findings raise safety concerns regarding intraocular administration of rAAV vectors and will have an impact on the development of future gene therapy trials for retinal diseases.