Project Summary/Abstract Age-related macular degeneration (AMD), is the leading cause of blindness in adults over 50 with no effective treatments available. AMD is caused by multiple genetic and environmental factors making it difficult to replicate and study in the laboratory. In contrast, Sorby’s Fundus Dystrophy (SFD) is a rare monogenetic disease caused by mutations in Tissue inhibitor of metalloproteinase 3 (TIMP3) that has significant phenotypic similarities to AMD. Using animal and cell culture models of SFD, I hope to understand the underlying pathogenic and molecular mechanisms of RPE/retinal degeneration in SFD and possibly AMD. The retina has a uniquely high metabolic demand and all nutrients needed to power the retina must be transported across or generated by RPE. Furthermore, proper RPE metabolism is required for the retina to receive adequate nutrients. Retina utilize aerobic glycolysis to generate ATP and therefore primarily utilize glucose as their energy substrate. Based on preliminary data from the Anand-Apte laboratory, I hypothesize that aberrant energy metabolism in the RPE results in nutrient deprivation in the retina and is a significant contributor to SFD pathology. To address this hypothesis, I propose 2 specific aims; (i) to determine if SFD RPE cells are deficient in their ability to produce and/or transport essential metabolites to the retina. Using metabolomics and stable isotopic tracing within SFD mouse and human ARPE19 cell culture models. I will use gas chromatography mass spectrometry (GC/MS) to quantify nutrient transport across RPE in vivo and in vitro. The link between TIMP3 mutations and metabolism perturbations are unclear especially considering that TIMP3 has extracellular localization while metabolism is an intracellular process. (ii) to investigate if extracellular matrix changes and HA overproduction are responsible for altered energy metabolism in SFD RPE. Recently, the Anand-Apte laboratory has reported that SFD RPE expressing mutant TIMP3 S179C produce excess hyaluronan (HA), a glucosamine that is highly abundant in the extracellular matrix (ECM). I hypothesize that HA overproduction in SFD RPE cells is responsible for the metabolic phenotype we have observed. Since HA is synthesized from glycolytic intermediates, HA could impact energy metabolism through multiple mechanisms. Understanding the details of macular degeneration is the first step towards discovering effective prophylactics and will aid in the development of new therapeutics.