The RPE65 gene encodes the isomerase of the retinoid cycle, the enzymatic pathway that underlies mammalian vision. Mutations in RPE65 disrupt the retinoid cycle and cause a congenital human blindness known as Leber congenital amaurosis (LCA). We used adeno-associated virus-2-based RPE65 gene replacement therapy to treat three young adults with RPE65-LCA and measured their vision before and up to 90 days after the intervention. All three patients showed a statistically significant increase in visual sensitivity at 30 days after treatment localized to retinal areas that had received the vector. There were no changes in the effect between 30 and 90 days. Both cone-and rod-photoreceptor-based vision could be demonstrated in treated areas. For cones, there were increases of up to 1.7 log units (i.e., 50 fold); and for rods, there were gains of up to 4.8 log units (i.e., 63,000 fold). To assess what fraction of full vision potential was restored by gene therapy, we related the degree of light sensitivity to the level of remaining photoreceptors within the treatment area. We found that the intervention could overcome nearly all of the loss of light sensitivity resulting from the biochemical blockade. However, this reconstituted retinoid cycle was not completely normal. Resensitization kinetics of the newly treated rods were remarkably slow and required 8 h or more for the attainment of full sensitivity, compared with <1 h in normal eyes. Cone-sensitivity recovery time was rapid. These results demonstrate dramatic, albeit imperfect, recovery of rod-and cone-photoreceptor-based vision after RPE65 gene therapy. dark adaptation ͉ photoreceptor ͉ retinal degeneration ͉ retinoid cycle T he enzymatic pathway in the human eye that regenerates light-altered vitamin A molecules is known as the retinoid cycle of vision. Molecular defects in retinoid cycle genes can lead to inherited retinal diseases in man (1). The severity of visual disturbance in these diseases is thought to be related to how the mutation alters the biochemical activity and whether there is redundancy at the multiple biochemical steps of the cycle. A severe form of incurable childhood blindness, Leber congenital amaurosis (LCA), is caused by mutations in RPE65 (retinal pigment epithelium-specific protein, 65 kDa), the gene in the retinal pigment epithelium (RPE) that encodes the isomerase. This is the only known enzyme that catalyzes isomerization of all-trans-retinyl esters to 11-cis-vitamin A. In RPE65 deficiency, photoreceptor cells do not regenerate their visual pigment and vision is not sustained. Retinal anatomy also degenerates, but not entirely (2, 3).RPE65-deficient animals have been characterized, and proofof-principle studies using recombinant adeno-associated virus (AAV) vector delivery of RPE65 to RPE cells have described restoration of vision (2,(4)(5)(6)(7)(8)(9)(10)(11)(12)(13)(14). These studies provided the impetus for human safety studies of RPE65 gene replacement (trials NCT00481546, NCT00643747, NCT00516477, and NCT00422721, www.clinicaltri...
Rhodopsin, the visual pigment mediating vision under dim light, is composed of the apoprotein opsin and the chromophore ligand 11-cis-retinal. A P23H mutation in the opsin gene is one of the most prevalent causes of the human blinding disease, autosomal dominant retinitis pigmentosa. Although P23H cultured cell and transgenic animal models have been developed, there remains controversy over whether they fully mimic the human phenotype; and the exact mechanism by which this mutation leads to photoreceptor cell degeneration remains unknown. By generating P23H opsin knock-in mice, we found that the P23H protein was inadequately glycosylated with levels 1-10% that of wild type opsin. Moreover, the P23H protein failed to accumulate in rod photoreceptor cell endoplasmic reticulum but instead disrupted rod photoreceptor disks. Genetically engineered P23H mice lacking the chromophore showed accelerated photoreceptor cell degeneration. These results indicate that most synthesized P23H protein is degraded, and its retinal cytotoxicity is enhanced by lack of the 11-cisretinal chromophore during rod outer segment development.Greater understanding of a genetically heterogeneous group of retinal disorders is now possible due to the results of studies that have revealed their causative genes. Many genetic loci can cause such retinopathies (RetNet) (1). Mutations in phototransduction genes, including those in opsin genes (2), constitute one of the major known causes of inherited blinding diseases (3). Among them, retinitis pigmentosa (RP) 2 refers to a group that displays genetic heterogeneity and a range of clinical phenotypes (4). RP manifested predominantly by death of rod photoreceptor cells is a progressive disease characterized by night blindness that progresses to loss of peripheral vision and eventually all useful vision over decades (5). Of more than 100 mutant opsins associated with autosomal dominant RP (adRP), the most frequent mutation is P23H (6), accounting for ϳ10% of human cases (7,8).In vitro studies have shown that the P23H opsin associated with adRP is misfolded and retained in the ER (9 -12). Consequently, this protein is not transported to the cell membrane (12) but instead was degraded by the ubiquitin-proteosome system (13). Co-expression of adRP-linked opsin folding-deficient mutants and wild type (WT) opsin resulted in enhanced proteosome-mediated degradation and steady-state ubiquitination of both mutant and WT opsin in an experimental cell line (14). These results imply that in vivo, a misfolded monomer of P23H opsin can also induce co-aggregation with WT rhodopsin preventing rod outer segment (ROS) formation. This dominant negative effect on ROS formation has been considered as the underlying reason for the adRP inheritance of P23H in humans.The retinal structure in heterozygous transgenic mice and rats expressing the P23H opsin partially mimics that of adRP in humans carrying this mutation (15)(16)(17)(18)(19). Mislocalization of the P23H opsin in the retina also has been reported in transgenic ani...
Leber congenital amaurosis (LCA) associated with retinal pigment epithelium-specific protein 65 kDa (RPE65) mutations is a severe hereditary blindness resulting from both dysfunction and degeneration of photoreceptors. Clinical trials with gene augmentation therapy have shown partial reversal of the dysfunction, but the effects on the degeneration are not known. We evaluated the consequences of gene therapy on retinal degeneration in patients with RPE65-LCA and its canine model. In untreated RPE65-LCA patients, there was dysfunction and degeneration of photoreceptors, even at the earliest ages. Examined serially over years, the outer photoreceptor nuclear layer showed progressive thinning. Treated RPE65-LCA showed substantial visual improvement in the short term and no detectable decline from this new level over the long term. However, retinal degeneration continued to progress unabated. In RPE65-mutant dogs, the first one-quarter of their lifespan showed only dysfunction, and there was normal outer photoreceptor nuclear layer thickness retina-wide. Dogs treated during the earlier dysfunction-only stage showed improved visual function and dramatic protection of treated photoreceptors from degeneration when measured 5-11 y later. Dogs treated later during the combined dysfunction and degeneration stage also showed visual function improvement, but photoreceptor loss continued unabated, the same as in human RPE65-LCA. The results suggest that, in RPE65 disease treatment, protection from visual function deterioration cannot be assumed to imply protection from degeneration. The effects of gene augmentation therapy are complex and suggest a need for a combinatorial strategy in RPE65-LCA to not only improve function in the short term but also slow retinal degeneration in the long term.neurodegeneration | outer nuclear layer | retinal structure
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