Dissecting the roles of type 2 diabetes-associated variants and effector genes in islet endoplasmic reticulum stress response

PROJECT SUMMARY Type 2 Diabetes (T2D) is a complex disease caused by both genetic and environmental factors. Genome-wide association studies (GWAS) have identified 403 association signals at 243 loci (T2D variants) that increase T2D genetic risk. Functional (epi)genomic analyses strongly suggest that non-coding T2D variants alter transcriptional

regulation and target gene expression in pancreatic islets, but only ~20% of T2D variants elicit changes in islet cis-regulatory element (CRE) use or gene expression under steady state conditions. Environmental factors such as endoplasmic reticulum (ER) stress have been implicated in islet dysfunction. However, studies to date have

not assessed if or how T2D variants modulate the response of islets to ER stress. I hypothesize that these T2D variants alter islet ER stress-responsive CRE use or activity and target gene expression to contribute to islet β cell dysfunction or death in T2D. In my preliminary data analysis, I have identified ER stress-responsive

CREs that overlap 407 T2D variants in islets and connected these CREs to 22 putative target gene promoters using islet promoter capture Hi-C maps. In Aim 1, I will comprehensively assess the effects of T2D variants on the use or activity of ER stress-responsive CREs using chromatin accessibility quantitative trait locus (caQTL)

and massively parallel reporter assays (MPRA), respectively. In Aim 2, I will determine if the putative CRE- targeted genes are required in human islet cells for their ER stress response and survival by altering their expression using CRISPR/Cas9 epigenomic editing platforms. Successful completion of these Aims will yield a

functionally characterized set of T2D variants and a validated set of downstream 'T2D target genes’ that modulate islet function and survival in response to a central (patho)physiologic stressor. More broadly, I anticipate that the principles and framework I employ in this mechanistic variant-to-function project could be

applied to characterize the effects of T2D variants in the context of other environmental stressors and metabolic tissues. Importantly, completion of this project will help me master current concepts and state-of-the-art techniques in genetics and functional genomics and increase my scientific communication skills through

extensive opportunities to present and publish my studies. Finally, my position as an MD/PhD student at UConn Health and The Jackson Laboratory for Genomic Medicine will not only allow me to be mentored in a world- class, highly collaborative environment, but it will provide me with opportunities to continue honing my clinical

skills and gain specialized experience during and after my research phase. Fulfilling my training and development plan will be a crucial step toward my future career as a physician-scientist studying the genetic and (epi)genomic mechanisms of disease-associated variants in patients.