Successful Arrest of Photoreceptor and Vision Loss Expands the Therapeutic Window of Retinal Gene Therapy to Later Stages of Disease

Overview

Journal Proc Natl Acad Sci U S A

Specialty Science

Date 2015 Oct 14

PMID 26460017

Citations 48

Authors

William A Beltran

Artur V Cideciyan

Simone Iwabe

Malgorzata Swider

Mychajlo S Kosyk

Kendra McDaid

Inna Martynyuk

Gui-Shuang Ying

James Shaffer

Wen-Tao Deng

Sanford L Boye

Alfred S Lewin

William W Hauswirth

Samuel G Jacobson

Gustavo D Aguirre

Affiliations

Soon will be listed here.

Abstract

Inherited retinal degenerations cause progressive loss of photoreceptor neurons with eventual blindness. Corrective or neuroprotective gene therapies under development could be delivered at a predegeneration stage to prevent the onset of disease, as well as at intermediate-degeneration stages to slow the rate of progression. Most preclinical gene therapy successes to date have been as predegeneration interventions. In many animal models, as well as in human studies, to date, retinal gene therapy administered well after the onset of degeneration was not able to modify the rate of progression even when successfully reversing dysfunction. We evaluated consequences of gene therapy delivered at intermediate stages of disease in a canine model of X-linked retinitis pigmentosa (XLRP) caused by a mutation in the Retinitis Pigmentosa GTPase Regulator (RPGR) gene. Spatiotemporal natural history of disease was defined and therapeutic dose selected based on predegeneration results. Then interventions were timed at earlier and later phases of intermediate-stage disease, and photoreceptor degeneration monitored with noninvasive imaging, electrophysiological function, and visual behavior for more than 2 y. All parameters showed substantial and significant arrest of the progressive time course of disease with treatment, which resulted in long-term improved retinal function and visual behavior compared with control eyes. Histology confirmed that the human RPGR transgene was stably expressed in photoreceptors and associated with improved structural preservation of rods, cones, and ON bipolar cells together with correction of opsin mislocalization. These findings in a clinically relevant large animal model demonstrate the long-term efficacy of RPGR gene augmentation and substantially broaden the therapeutic window for intervention in patients with RPGR-XLRP.

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