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Control of Photoreceptor Metabolism

$376,160R01FY2015EYNIH

University Of Washington, Seattle WA

Investigators

Linked publications & trials

Abstract

DESCRIPTION (provided by applicant): Metabolic demands of photoreceptors in darkness are qualitatively different than in light. In darkness their metabolism is like that of conventiona neurons. It is devoted mostly to supplying energy to ion pumps. In light their metabolism is more like that of cancer cells. Illumination lowers energy requirements for ion pumping but it increases the demand for anabolic activity to synthesize new membranes and regenerate rhodopsin. Cyclic GMP and Ca2+ play central roles in the way photoreceptors respond and adapt to light. Genetic deficiencies that alter the synthesis or degradation of cGMP cause degeneration of photoreceptor cells. We hypothesize that GMP and Ca2+ influence basic metabolic activities in photoreceptors that support their function and viability. We are investigating relationships between metabolic needs of photoreceptors and photoreceptor survival. We developed biochemical assays that evaluate photoreceptor metabolism and we found that chronic accumulation of cGMP causes massive depletion of glutamic acid, a condition that precludes synthesis of proteins and glutathione. One aim of this proposal is to test the hypothesis that depletion of glutamate is the reason photoreceptors degenerate in certain types of inherited retinal degenerative diseases. We will explore the possibility that nutritional supplements can block photoreceptor degeneration in animal models of these disease states. Metabolism and viability also depend on environment. Photoreceptors can survive for days in culture in an intact retina, but they degenerate within hours when dissociated from the retina. The second aim of this proposal is to investigate the metabolic basis for degeneration of dissociated photoreceptors by characterizing metabolic effects of small molecules that enhance photoreceptor survival. We will use this information to help identify fundamental metabolic requirements of photoreceptors.

View original record on NIH RePORTER →