of Work Incretins, glucose-dependent insulinotropic polypeptide (GIP) and glucagon-like peptide 1 (GLP-1), are intestinally derived hormones that regulate postprandial metabolism. The incretin system accounts for up to 70% of postprandial insulin secretion in healthy individuals and diminishes to ~30% in people with type 2 diabetes (T2D). Understanding the mechanisms that regulate incretin control of insulin secretion, and how this becomes dysfunctional with metabolic stress, is central to understanding the pathophysiology of T2D. We have recently discovered that proglucagon products from alpha-cells are essential for normal beta-cell function ? a phenomenon termed alpha-to-beta cell communication. Specifically, we found that intra-?-cell tone is dictated by the level of cAMP generated by input from proglucagon peptides. Impairing alpha-to-beta cell communication greatly diminishes insulin secretion and results in glucose intolerance in the context of metabolic stress. The GIP receptor (GIPR) and GLP-1 receptor (GLP-1R) are expressed on beta-cells and potentiate glucose-stimulated insulin secretion. On the other hand, alpha cells only express the GIPR and not the GLP-1R. Indeed, GIP stimulates glucagon secretion, while GLP-1R decreases it. The goal of this project is to understand the importance of GIPR activity in alpha cells and the potential contribution to metabolic regulation in both healthy and diseased states. Our recent discovery that glucagon production from alpha cells is necessary for nutrient stimulated insulin secretion, support the hypothesis that GIPR activity in alpha cells enhances alpha-to-beta cell communication. A corollary to this hypothesis is that GIPR activity in alpha cells contribute meaningfully to the incretin effect in a postprandial situation by enhancing insulin secretion. Moreover, interventions that limit GIPR activity in alpha cells would be expected to decrease insulin secretion and impair glucose tolerance. Testing this hypothesis has the potential to extend our concept of the incretin effect beyond beta cell activity to incorporate the alpha cell as a vital component. Furthermore, clarification of GIPR activity in alpha cells can provide insight into the new generation of anti-diabetic medications that incorporate GIPR activity, potentially explaining the increased efficacy achieved by these compounds above and beyond GLP-1R monoagonism.
Novel Metabolic Actions of GIP Project Narrative: The incretin system is strategically positioned to control metabolism in the postprandial state and people with type 2 diabetes have severe impairments in the incretin axis. Heretofore, the incretin system has been viewed primarily within a glucose context and incretin action has been studied almost exclusively in b-cells. Our preliminary data demonstrates that a-cells and glucagon are significant contributors to the incretin axis and that GIP is a crucial determinant of this novel mechanism.
