Abstract

Glucose-dependent insulinotropic polypeptide (GIP) and glucagon-like peptide-1 (GLP-1) are secreted by specific cell types in the intestine and are responsible for the so-called incretin effect, the phenomenon that an oral glucose load elicits a higher insulin response than does an intravenous glucose load. In patients with type 2 diabetes mellitus the overall incretin effect is reduced. This fact is mostly attributed to a lowered insulinotropic effect of GIP, while the effect of GLP-1 is preserved. In order to better understand the consequences of impaired function of GIP, knockout mice lacking a functional GIP receptor (GIPR^–/–) as well as transgenic mice expressing a dominant negative GIPR (GIPR^dn) were established. While GIPR^–/– mice show only relatively mild changes in glucose homeostasis, GIPR^dn mice display a distinct diabetic phenotype due to disturbed development of the endocrine pancreas (Herbach et al. 2005 Regul. Pept. 125, 103–117). To further clarify the underlying mechanisms, we used a novel, highly efficient gene transfer technology based on lentiviral vectors (Hofmann et al. 2003 EMBO Rep. 4, 1054–1060; Hofmann et al. 2006 Mol. Ther. 13, 59–66) to generate transgenic pigs expressing a GIPR^dn under the control of the rat Ins2 promoter (RIP). RIP-GIPR^dn transgenic pigs develop normally and do not display diabetes mellitus up to at least one year of age. Weekly measured fasting blood glucose levels in transgenic animals did not show a significant difference compared to control pigs. The same was true for monthly determined fructosamine levels. However, RIP-GIPR^dn transgenic pigs exhibited reduced insulin release and higher glucose levels than non-transgenic littermate controls in an oral glucose tolerance test. The area under the curve (AUC) for insulin was 49% smaller (P < 0.01) and the AUC for glucose 26% larger (P < 0.05) in RIP-GIPR^dn transgenic pigs (n = 5) than in their non-transgenic littermate controls (n = 5). These findings demonstrate that expression of a GIPR^dn, which was shown by RT-PCR in isolated pancreatic islets, disturbs the function of GIP in transgenic pigs. Thus we have created a novel, clinically relevant animal model for studying the roles of the GIP/GIPR system. Quantitative morphological studies of the pancreas are being performed to clarify whether GIPR function is essential for pancreatic islet development and maintenance.