GLP-2 is a potent intestinotrophic peptide that can increase mucosal growth, intestinal blood flow, and nutrient absorption when administered exogenously. We aimed to delineate the effects of endogenous GLP-2R signalling in conditions of nutrient deprivation and excess. Using a mouse with a targeted genetic deletion of the Glp2r gene (Glp2r-/-), we addressed the hypothesis that the known GLP-2R is required for intestinal adaptation to nutrient deprivation and excess. In Chapter 2, we demonstrate that Glp2r−/− mice fasted for 24 hours and re-fed for 24 hours failed to increase intestinal growth and jejunal crypt cell proliferation compared to littermate Glp2r+/+ mice. Administration of EGF to Glp2r−/− during the re-feeding period rescued this re-feeding defect. Wildtype mice re-fed for 30, 90, and 180 minutes following a 24 hour fast displayed increased jejunal mRNA levels of the ErbB ligands amphiregulin, epiregulin and HB-EGF. Treatment with the pan ErbB inhibitor CI-1033 inhibited induction of these ErbB ligands in jejunum of mice in association with prevention of crypt cell proliferation. Re-feeding also caused an increase in jejunal p-Akt levels and treatment with CI-1033 prevented increased p-Akt levels. Moreover, re-fed Glp2r−/− mice failed to increase ErbB ligands or p-Akt levels 90 minutes following re-feeding when compared to Glp2r+/+ littermates. Therefore, the GLP-2R is essential for re-feeding induced intestinal adaptation by activating the ErbB network and p-Akt to increase crypt cell proliferation. In Chapter 3, we show that the known GLP-2R is not required for intestinal adaptation to a perceived nutrient deprivation challenge (STZ-induced diabetes) or chronic nutrient excess (high-fat diet induced glucose intolerance). Although exogenous GLP-2 administration has been previously shown to stimulate glucagon secretion, glucose homeostasis was normal in STZ-diabetic and high fat fed Glp2r−/− mice. We also developed a third model of diabetes and glucose intolerance: ob/ob: Glp2r−/−. In the absence of GLP-2R signalling, ob/ob mice display improved oral but impaired intraperitoneal glucose tolerance, elevated fed and fasted glucose levels, increased circulating glucagon, decreased beta cell and increased alpha cell mass. Taken together, these results suggest that endogenous GLP-2R signalling is essential for intestinal and islet adaptation to conditions of nutrient deprivation and excess.
Identifer | oai:union.ndltd.org:TORONTO/oai:tspace.library.utoronto.ca:1807/26499 |
Date | 16 March 2011 |
Creators | Bahrami, Jasmine |
Contributors | Drucker, Daniel J. |
Source Sets | University of Toronto |
Language | en_ca |
Detected Language | English |
Type | Thesis |
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