PROJECT SUMMARY Pacific Islanders (PIs) have among the world’s highest burden of metabolic disease and are at increased risk for other associated comorbidities, such as cardiovascular disease, kidney disease, and cancer. Despite high rates of these complex diseases, PIs have largely been underrepresented in studies designed to identify the underlying factors that contribute to their increased risk. Ceramides are lipotoxic sphingolipids that contribute to cellular dysfunction that cause metabolic disease. While much of the literature implicating ceramides in metabolic disease has centered on genetic modification or pharmacological inhibition of genes involved in ceramide synthesis pathways in various model systems, accumulation of ceramides has also been demonstrated in human disease. The underlying mechanisms leading to increased ceramides in human disease, however, are unknown. As part of our studies leveraging unique resources at the University of Utah, including the Utah Diabetes Database and the Utah Population Database, we recently identified rare mutations that alter ceramide levels in 2 families enriched for obesity, diabetes, and end-stage renal disease, causing familial dysceramidemia, including the first family from the Pacific Islands with a rare genetic variant associated with elevated ceramides. Given this novel and important finding, we hypothesize that aberrant sphingolipid levels and genetic variants that alter their biosynthesis are key contributors to metabolic disease and related comorbidities in PIs. Building on this evidence, the goal of this developmental research project is to expand this research and investigate the role of sphingolipid levels in metabolic disease in PIs using a multi-omics approach that includes lipidomic and genomic analysis of large, multi-generational PI pedigrees. To accomplish this goal, we will 1) determine sphingolipid levels in members of 25 large, multi-generational PI pedigrees with metabolic disease by i) expanding recruitment of PI families currently enrolled in the Utah Diabetes and Diabetic Complications Study to include at least 10-15 members per family and ii) use liquid chromatography with tandem mass spectrometry to establish lipid profiles of sphingolipid species in all recruited PI family members and 2) evaluate the contribution of genetic variation on sphingolipid levels in members of large, multi-generational PI pedigrees by i) screening for genetic variants in members of PI families with aberrant sphingolipid profiles using whole exome sequencing and ii) performing unified linkage analysis and rare variant association testing to identify variants influencing sphingolipid species. We anticipate that this research will build on exciting preliminary data and provide key insights on the role of this pathway in metabolic disease in PIs. This research will provide a solid foundation for future efforts aimed at elucidating the mechanisms behind the disparity of metabolic disease in PIs an...