Optogenetic therapy for retinal degeneration shows potential of gene-independent therapeutic strategies
During a presentation at the EURETINA 2021 Virtual Congress, Dr José-Alain Sahel explains that optogenetics involves the use of artificial photoreceptors from specific retinal cells to restore vision by transferring a gene that encodes for a light-sensitive protein that causes neuronal cells to respond to light stimulation.
Reviewed by Dr José-Alain Sahel.
Gene replacement therapies for inherited retinal degenerations have shown promise in experimental disease models and are being tested in RPE65-associated Leber congenital amaurosis (approved in 2017) and Leber hereditary optic neuropathy, among others.
In addition to this research, Dr José-Alain Sahel and colleagues are involved in another line of research to benefit patients with inherited retinal degenerations with the hope of avoiding the challenges posed by gene replacement therapies, i.e., extensive genetic heterogeneity and dominant transmission.
“Gene-independent strategies could offer promising treatment avenues for these blinding diseases,” Sahel, chairman of the Department of Ophthalmology, and director of the University of Pittsburgh Medical Center Eye Center University of Pittsburgh, said during a presentation at the EURETINA 2021 Virtual Congress.
According to Sahel, cones are critical to vision and preserving them may save vision in patients with inherited retinal degenerative diseases. The focus of his team’s work, rod-derived cone viability factor, promotes cone survival by stimulating aerobic glycolysis.
In previous work, Sahel, with Saddek Mohand-Said, MD, and Thierry Léveillard from the Institut de la Vision, Paris, demonstrated in a murine model of retinitis pigmentosa that rod transplantation delayed cone loss, which depends on functioning rod photoreceptor cells. These finding could benefit patients with retinitis pigmentosa and other inherited retinal diseases (trial in preparation by SparingVision).
Optogenetics involves use of artificial photoreceptors from specific retinal cells to restore vision by transferring a gene that encodes for a light-sensitive protein that causes neuronal cells to respond to light stimulation (GS030, GenSight Biologics). This technology combines gene therapy and a medical device to restore retinal light sensitivity by modifying and training retinal ganglion cells to act as photoreceptor, Sahel explained.
The PIONEER Study is the first trial to test how GS030 optogenetic therapy works in 9 patients with end-stage retinitis pigmentosa. Patients received 1 intravitreal injection in the eye with the worse vision. The primary endpoint was the safety and tolerability of the treatment at the 1-year timepoint.
The study also is evaluating he effects of 3 doses of the treatment. Three patients were injected with the lowest dose in March 2019, 3 with the medium dose in February 2020, and 3 with the highest dose in June 2020 and June 2021.
The injections are part of the combined therapy that includes the use of goggles that project light onto the retina. An extension cohort is planned for the end of 2021. Thus far, the therapy has been well tolerated up to 2.5 years after the intravitreal therapy. The most frequent adverse event was anterior chamber or intermediate intraocular inflammation that responded to steroids in 5 of the 9 patients.
Sahel reported that 1 patient had partial recovery of visual function after this treatment.1 He was the only one who could perform training during the COVID-19 pandemic. Others are now training. There is some hope that this treatment can benefit patients with many types of retinal degenerations included age-related macular degeneration.
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Reference
1. Sahel J-A, Boulanger-Scemama E, Pagot C, et al. Partial recovery of visual function in a blind patient after optogenetic therapy. Nature Med 2021;27:1223-9; https://doi.org/10.1038/s41591-021-01351-4
