👤 Chuen-Den Tseng

The glucose-dependent insulinotropic peptide receptor (GIP-R) is a member of the G protein-coupled receptors. Recent studies have indicated that elevated serum GIP concentrations in type II diabetic patients might induce desensitization of the GIP-R, and this mechanism could contribute to impaired insulin secretion. The cellular and molecular mechanisms governing GIP desensitization are unknown. Here, we report the results of studies on a new family of proteins known as regulators of G protein signaling (RGS) that have been shown to mediate the desensitization process of other receptors. GIP-R and RGS1, -2, -3, and -4 complementary DNAs were cotransfected into human embryonic kidney cells (L293). GIP-stimulated cAMP generation in control cells and in those coexpressing RGS1, -3, and -4 displayed a dose-dependent increase 10 min after GIP treatment. In contrast, RGS2 expression inhibited the GIP-induced cAMP response by 50%, a response similar to that of cells desensitized by preincubation with 10(-7) M GIP. In betaTC3 cells, preincubation of GIP attenuated GIP-induced insulin release by 45% at 15 min and by 55% at 30 min. Expression of RGS2 in the betaTC3 cells significantly decreased GIP-stimulated insulin secretion, whereas glucose-induced insulin release was not affected. RGS2 messenger RNA was identified by Northern blot analysis to be expressed endogenously in betaTC3 and L293 cells, and its level was significantly induced by GIP treatment in betaTC3 cells. Moreover, RGS2 bound Gs alpha protein in an in vitro system, suggesting that RGS2 attenuated the Gs-adenylate cyclase signaling pathway. These results suggest a potential role for RGS2 in modulating GIP-mediated insulin secretion in pancreatic islet cells. Show less

The glucose-dependent insulinotropic peptide receptor (GIP-R) is a member of G-protein-coupled, seven transmembrane-spanning receptors. Recent studies have shown that elevated serum GIP level in diabetic patients may induce chronic desensitization of the GIP-R, and that this mechanism could contribute to impaired insulin secretion. The cellular basis of down-regulation and chronic desensitization of GIP-R is unclear. To explore the role of the carboxyl terminus of the GIP-R in mediating these processes, five truncated GIP-Rs (T395, T399, T420, T431, T455) were created to delete consecutive serines from the carboxyl end. All mutants except T395 exhibit an identical ligand-binding affinity to the WT receptor. The T395 mutant, which had the entire carboxyl tail removed, does not bind to ligand. Down-regulation and desensitization was assessed by measuring the receptor number and the ability of agonist-induced cAMP or [Ca2+] generation after pre-exposure to 10(-7) M GIP for 24 h. The wild-type (WT) and T421, T431, T455 mutant GIP-Rs are maximally down-regulated by GIP preincubation, whereas T399 mutant does not, indicating that the sequence between amino acids 399 and 420 is critical for this process. Mutation analysis of this area by alanine scanning mutagenesis reveals two critical residues: serine 406 and cysteine 411. Replacement of serine 406 with arginine (S406R) or alanine (S406A) partly attenuates agonist-induced down-regulation and desensitization. In contrast, mutation of the cysteine 411 to glycine (C411G) or alanine (C411A) markedly attenuates both processes. Mutant SCRG, in which both serine 406 and cysteine 411 are mutated, behaves similar to C411G or C4111A. The data suggest that chronic desensitization and down-regulation of the GIP-R may be mediated by similar mechanisms, and that the cysteine in the carboxyl terminus plays an essential role in regulating both processes. Show less

The glucose-dependent insulinotropic peptide receptor (GIP-R) is a member of the secretin and parathyroid hormone (PTH) family of seven transmembrane-spanning receptors. Point mutations of a histidine at the junction between the first intracellular loop and the second membrane-spanning domain and a threonine in the sixth membrane-spanning domain of the human PTH-receptor have been reported to be associated with constitutive activation of the PTH receptor in Jansen-type metaphyseal chondrodysplasia. In this study, we explored whether such mutations in the GIP-R might similarly induce constitutive, ligand-independent activation of the receptor. Single amino acid substitutions in the GIP receptor were made by site-directed mutagenesis and receptor binding and cAMP levels were measured in transfected human embryonal kidney cell line (L293). Mutation of the threonine at position 340 in the sixth transmembrane spanning domain to proline (T340P) led to agonist-independent constitutive activity and exhibited a four-fold increase in basal cAMP level as compared to the wild-type GIP-R. The increase in cAMP level in T340P mutant was proportional to the amount of transfected plasmid and corresponded to the receptor number on the cell surface. Despite its high basal cAMP level, the T340P mutant could be further stimulated by GIP, with maximal cAMP generation comparable to the wild-type receptor. The change of amino acid histidine at position 169 to arginine (H169R), however, behaved like the wild type receptor and did not possess constitutive activity. These results illustrate that a point mutation of threonine to proline at position 340 results in constitutive activation of the GIP receptor, without affecting its sensitivity to agonist stimulation. Show less