DESCRIPTION (provided by applicant): Insulin resistance is defined as the decreased ability of insulin to perform its biological function in fat liver and muscle. The insulin resistance observed in skeletal muscle is particularly important as this tissue under normal physiological conditions is the main site of insulin-stimulated glucose disposal. Both genetic and environmental factors contribute to the pathogenesis of insulin resistance which is an underlying feature of a number of diseases including obesity and type 2 diabetes. However the role of epigenetic factors in the pathogenesis of insulin resistance is less understood. Epigenetic modifications encompass both DNA methylation and histone modifications and can be described as heritable changes in gene function that occur without a change in nucleotide sequence. DNA methylation (and histone modifications) of the genome may provide a potential link between the genetic and environmental factors observed in insulin resistance. While epigenetics refers to the study of single genes or sets of genes epigenomics which simply means 'above the genome' refers to more global analyses of epigenetic changes across the entire genome. The overall goal of the experiments included in this proposal is to determine global patterns of changes in DNA methylation in metabolically well-characterized insulin sensitive and resistant volunteers and to determine whether these changes can explain alterations in gene expression and protein abundance in the insulin resistance associated with obesity and type 2 diabetes. Specifically we will use these findings to determine whether changes in DNA methylation could explain a reduced response to muscle contraction in insulin resistant individuals. These findings will allow us to determine whether changes in protein abundance we have observed in insulin resistance occur in conjunction with changes in methylation of the promoters of the genes coding for these proteins. This study brings a transdisciplinary team of investigators together to address critical gaps in our understanding of global epigenetic markers specifically DNA methylation in understanding the pathophysiology of insulin resistance in both skeletal muscle and whole blood tissues.