Richard W. Gelling

Identification of a bioactive domain in the amino-terminus of glucose-dependent insulinotropic polypeptide (GIP).

The incretins are a class of hormones released from the small bowel that act on the endocrine pancreas to potentiate insulin secretion in a glucose-dependent manner. Due to the requirement for an elevated glucose concentration for activity, the incretins, glucose-dependent insulinotropic polypeptide (GIP) and glucagon-like peptide-1, have potential in the treatment of non-insulin-dependent diabetes mellitus. A series of synthetic peptide GIP fragments was generated for the purpose of elucidating the bioactive domain of the molecule. Peptides were screened for stimulation of cyclic AMP (cAMP) accumulation in Chinese hamster ovary cells transfected with the rat islet GIP receptor. Of the GIP fragments tested, GIP(1-14) and GIP(19-30) demonstrated the greatest cAMP-stimulating ability over the range of concentrations tested (up to 20 microM). In contrast, GIP fragments corresponding to amino acids 15-42, 15-30, 16-30 and 17-30 all demonstrated weak antagonism of GIP(1-42) activity. Competitive-binding displacement studies indicated that these peptides were low-affinity ligands for the GIP receptor. To examine biological activity in vivo, a bioassay was developed in the anesthetized rat. Intravenous infusion of GIP(1-42) (1 pmol/min/100 g) with a concurrent intraperitoneal glucose load (1 g/kg) significantly reduced circulating blood glucose excursions through stimulation of insulin release. Higher doses of GIP(1-14) and GIP(19-30) (100 pmol/min/100 g) also reduced blood glucose excursions.

A new oxytocin-saporin cytotoxin for lesioning oxytocin-receptive neurons in the rat hindbrain.

Evidence suggests that release of oxytocin in the nucleus tractus solitarius (NTS) of the hindbrain from descending projections that originate in the paraventricular nucleus can inhibit food intake by amplifying the satiety response to cholecystokinin (CCK). To further evaluate this mechanism in rats, we used a novel cytotoxin, saporin conjugated to oxytocin (OXY-SAP), a compound designed to destroy cells that express oxytocin receptors (OXYr). OXY-SAP was injected directly into the NTS to lesion neurons that express OXYr and that are implicated in potentiating CCKs satiety effects. The control consisted of injection of saporin conjugated to a nonsense peptide. We found that OXY-SAP was cytotoxic to human uterine smooth muscle cells in vitro, demonstrating that OXY-SAP can lesion cells that express OXYr. Using laser capture microdissection and real-time quantitative PCR, we demonstrated that OXYr mRNA levels were reduced in the NTS after OXY-SAP administration. Moreover, we found that OXY-SAP attenuated the efficacy of CCK-8 to reduce food intake and blocked the actions of an OXYr antagonist to stimulate food intake. The findings suggest that OXY-SAP is an effective neurotoxin for in vivo elimination of cells that express OXYr and is potentially useful for studies to analyze central nervous system mechanisms that involve the action of oxytocin on food intake and other physiological processes.

GIP6–30amide contains the high affinity binding region of GIP and is a potent inhibitor of GIP1–42action in vitro

Abstract GIP (Glucose-dependent Insulinotropic Polypeptide) is an important regulator of insulin secretion. The effects of truncated forms of the peptide, GIP 10–30 , GIP 6–30amide and GIP 7–30 , on binding of 125 I-GIP 1–42 to GIP receptors in transfected CHO-KI cells, and on cyclic AMP responses to GIP 1–42 , have been studied with a view to defining further the receptor binding region of GIP, and to establish whether such truncated peptides exhibit agonist or antagonist activity. All three peptides were found to be receptor antagonists, however GIP 6–30amide exhibited receptor binding affinity equivalent to that of GIP 1–42 in competitive binding studies (IC 50 =3.08±0.57 nM). GIP 6–30amide inhibited GIP 1–42 -induced cAMP production by 58% at a concentration of 100 nM, whereas GIP 10–30 and GIP 7–30 , inhibited only in the μM range. GIP 6–30amide therefore contains the high affinity binding region of GIP and is a potent inhibitor of G1P 1–42 action in vitro.

Glucose-dependent insulinotropic polypeptide stimulation of lipolysis in differentiated 3T3-L1 cells: wortmannin-sensitive inhibition by insulin.

GIP is an important insulinotropic hormone (incretin) that has also been implicated in fat metabolism. There is controversy regarding the actions of GIP on adipocytes. In the current study, the existence of GIP receptors and effects of GIP on lipolysis were studied in differentiated 3T3-L1 cells. GIP receptor messenger RNA was detected by RT-PCR and RNase protection assay. Receptors were detected in binding studies (IC50 26.7 ± 0.7 nm). GIP stimulated glycerol release with an EC50 of 3.28 ± 0.63 nm. GIP (10−9–10−7 m) + IBMX increased cAMP production by 1180–2246%. The adenylyl cyclase inhibitor MDL 12330A (10−4 m) inhibited GIP-induced glycerol production by >90%, and reduced cAMP responses to basal. Preincubation of 3T3-L1 cells with insulin inhibited glycerol responses to GIP, and the inhibitory effect of insulin was blocked by the phosphatidylinositol 3′-kinase inhibitor, wortmannin. It is concluded that GIP stimulates glycerol release in 3T3-L1 cells primarily via stimulation of cAMP production, and t...

Pancreatic β-cell overexpression of the glucagon receptor gene results in enhanced β-cell function and mass

In addition to its primary role in regulating glucose production from the liver, glucagon has many other actions, reflected by the wide tissue distribution of the glucagon receptor (Gcgr). To investigate the role of glucagon in the regulation of insulin secretion and whole body glucose homeostasis in vivo, we generated mice overexpressing the Gcgr specifically on pancreatic beta-cells (RIP-Gcgr). In vivo and in vitro insulin secretion in response to glucagon and glucose was increased 1.7- to 3.9-fold in RIP-Gcgr mice compared with controls. Consistent with the observed increase in insulin release in response to glucagon and glucose, the glucose excursion resulting from both a glucagon challenge and intraperitoneal glucose tolerance test (IPGTT) was significantly reduced in RIP-Gcgr mice compared with controls. However, RIP-Gcgr mice display similar glucose responses to an insulin challenge. beta-Cell mass and pancreatic insulin content were also increased (20 and 50%, respectively) in RIP-Gcgr mice compared with controls. When fed a high-fat diet (HFD), both control and RIP-Gcgr mice developed similar degrees of obesity and insulin resistance. However, the severity of both fasting hyperglycemia and impaired glucose tolerance (IGT) were reduced in RIP-Gcgr mice compared with controls. Furthermore, the insulin response of RIP-Gcgr mice to an IPGTT was twice that of controls when fed the HFD. These data indicate that increased pancreatic beta-cell expression of the Gcgr increased insulin secretion, pancreatic insulin content, beta-cell mass, and, when mice were fed a HFD, partially protected against hyperglycemia and IGT.

Characterization of the Carboxyl-terminal Domain of the Rat Glucose-dependent Insulinotropic Polypeptide (GIP) Receptor A ROLE FOR SERINES 426 AND 427 IN REGULATING THE RATE OF INTERNALIZATION

Glucose-dependent insulinotropic polypeptide (GIP) is a gastrointestinal hormone involved in the regulation of insulin secretion. In non-insulin-dependent diabetes mellitus insulin responses to GIP are blunted, possibly due to altered signal transduction or reduced receptor number. Site-directed mutagenesis was used to construct truncated GIP receptors to study the importance of the carboxyl-terminal tail (CT) in binding, signaling, and receptor internalization. Receptors truncated at amino acids 425, 418, and 405, expressed in COS-7 or CHO-K1 cells, exhibited similar binding to wild type receptors. GIP-dependent cAMP production with the 405 mutant was decreased in COS-7 cells. Maximal cAMP production in CHO-K1 cells was reduced with all truncated forms. Binding was undetectable with a receptor truncated at amino acid 400; increasing tail length by adding 5 alanines restored binding and signaling. Mutants produced by alanine scanning of residues 394–401, adjacent to transmembrane domain 7, were all functional. CT truncation by 30 or more amino acids, mutation of serines 426/427, singly or combined, or complete CT serine knockout all reduced receptor internalization rate. The majority of the GIP receptor CT is therefore not required for signaling, a minimum chain length of ∼405 amino acids is needed for receptor expression, and serines 426 and 427 are important for regulating rate of receptor internalization.

Analogs of Glucose-Dependent Insulinotropic Polypeptide With Increased Dipeptidyl Peptidase IV Resistance

Fully and partially DPIV-resistant analogs of GIP1–30 could be synthesized. The introduction of D-amino acids in P1- and P1’-position resulted in a slight reduction in binding and bioactivity. The examined C-terminal truncated fragments (with exception of the GIP1–30 fragment) showed no binding affinity, whereas the antagonistic N-terminal truncated fragments were able to bind to transfected rat GIP receptor. These results emphasize the hypothesis of an existing one-receptor-two-interaction-sites-model which was shown for peptides of the GRF-family.

Isolation of a murine glucose-dependent insulinotropic polypeptide (GIP) cDNA from a tumor cell line (STC6–14) and quantification of glucose-induced increases in GIP mRNA

A 537 base pair cDNA clone for murine GIP has been isolated. The elucidated sequence encodes an open reading frame of 432 base pairs which codes for a 144 amino acid precursor. Murine GIP is predicted to differ from the human hormone by three amino acid substitutions: arginine for histidine at position 18, arginine for lysine at position 30 and serine for lysine at position 34. GIP mRNA levels in STC6-14 cells incubated in the presence of varying glucose concentrations was investigated using a competitive-PCR method. In the presence of a 5-mM glucose stimulus, 1 x 10(5) GIP cells were found to contain 3.9 +/- 0.59 amol of GIP mRNA while the same number of cells contained 11.6 +/- 1.4 amol when subjected to a high (25 mM) glucose stimulus.

Pancreatic α-cell hyperplasia and hyperglucagonemia due to a glucagon receptor splice mutation.

Summary Glucagon stimulates hepatic glucose production by activating specific glucagon receptors in the liver, which in turn increase hepatic glycogenolysis as well as gluconeogenesis and ureagenesis from amino acids. Conversely, glucagon secretion is regulated by concentrations of glucose and amino acids. Disruption of glucagon signaling in rodents results in grossly elevated circulating glucagon levels but no hypoglycemia. Here, we describe a patient carrying a homozygous G to A substitution in the invariant AG dinucleotide found in a 3′ mRNA splice junction of the glucagon receptor gene. Loss of the splice site acceptor consensus sequence results in the deletion of 70 nucleotides encoded by exon 9, which introduces a frame shift and an early termination signal in the receptor mRNA sequence. The mutated receptor neither bound 125I-labeled glucagon nor induced cAMP production upon stimulation with up to 1 µM glucagon. Despite the mutation, the only obvious pathophysiological trait was hyperglucagonemia, hyperaminoacidemia and massive hyperplasia of the pancreatic α-cells assessed by histology. Our case supports the notion of a hepato–pancreatic feedback system, which upon disruption leads to hyperglucagonemia and α-cell hyperplasia, as well as elevated plasma amino acid levels. Together with the glucagon-induced hypoaminoacidemia in glucagonoma patients, our case supports recent suggestions that amino acids may provide the feedback link between the liver and the pancreatic α-cells. Learning points: Loss of function of the glucagon receptor may not necessarily lead to the dysregulation of glucose homeostasis. Loss of function of the glucagon receptor causes hyperaminoacidemia, hyperglucagonemia and α-cell hyperplasia and sometimes other pancreatic abnormalities. A hepato–pancreatic feedback regulation of the α-cells, possibly involving amino acids, may exist in humans.