Glucagon-like peptide-I Research Articles

Effects of glucagon-like peptide-I on glucose turnover in rats.

The influences of glucagon-like peptide-I-(7-36) amide (GLP-I; 15 mumol. kg-1.min-1) on glucose turnover were studied in freely moving Wistar rats. In fed rats, GLP-1 reduced plasma glucose (from 7.3 +/- 0.2 to 5.6 +/- 0.3 mmol/l; P = 0.017), increased plasma insulin (from 20 +/- 3 to 89 +/- 11 mU/l; P = 0.002), and reduced plasma glucagon (from 44 +/- 1 to 35 +/- 2 pg/ml; P = 0.009) and glucose appearance rate (Ra; from 3.9 +/- 0.2 to 1.7 +/- 0.7 micromol.min-1. 100 g-1 after 30 min; P = 0.049) without affecting glucose disappearance rate (Rd). The glucose clearance rate (MCR) was increased (P = 0.048). In 48-h-fasted rats, GLP-I reduced plasma glucose (from 5.0 +/- 0.2 to 4.4 +/- 0.3 mmol/l; P = 0.035) and increased plasma insulin (from 4 +/- 1 to 25 +/- 10 mU/l; P = 0.042) and plasma glucagon (from 43 +/- 3 to 61 +/- 7 pg/ml; P = 0.046). Ra and Rd were not significantly affected, although Ra was lower than Rd after 15-30 min (P = 0.005) and MCR was increased (P = 0.049). Thus GLP-I reduces Ra in fed rats and increases MCR in fed and fasted rats. The reduced Ra seems mediated by an increased insulin-to-glucagon ratio; the increased glucose clearance seems dependent on insulin and a peripheral effect of GLP-I.

The Effect of Glucagon-Like Peptide I (GLP-I) on Glucose Elimination in Healthy Subjects Depends on the Pancreatic Glucoregulatory Hormones

Glucagon-like peptide I (GLP-I) decreases plasma glucose in type II diabetic patients and in healthy subjects indirectly by stimulation of insulin and inhibition of glucagon secretion, whereby the hepatic glucose production decreases. However, recent studies indicate that GLP-I may also directly influence peripheral and hepatic glucose uptake. We infused somatostatin (SS) intravenously (500 or 1,000 microgram/h) in 13 healthy subjects to suppress insulin and glucagon secretion from the endocrine pancreas, together with infusion of either GLP-I (50 pmol / kg / h) or saline intravenously. After 30 min, a 25-g intravenous glucose tolerance test (IVGTT) was carried out, and plasma concentrations of glucose, insulin, glucagon, and GLP-I were measured during the following 2 h. IVGTT together with GLP-I infusion significantly elevated insulin during 500 microgram/h SS but not during 1,000 microgram/h SS. Plasma glucagon was strongly depressed in all experiments. During 500 microgram/h SS, the glucose disappearance constant, Kg, was 0.49 +/- 0.03% per minute with GLP-I and 0.39 +/- 0.04% per minute with saline (n = 8, P = 0.004). With 1,000 microgram/h SS, Kg was 0.42 +/- 0.03% per minute with GLP-I and 0.40 +/- 0.03% per minute without (NS). In conclusion, when endogenous insulin secretion is held at a constant low level, which may be accomplished only with very large doses of SS, GLP-I has no effect on glucose elimination. Thus, an insulin-independent effect of GLP-I on glucose disposal could not be demonstrated.

The effect of glucagon-like peptide I (GLP-I) on glucose elimination in healthy subjects depends on the pancreatic glucoregulatory hormones

The effect of glucagon-like peptide I (GLP-I) on glucose elimination in healthy subjects depends on the pancreatic glucoregulatory hormones

Central glucagon-like peptide-I in the control of feeding.

Central glucagon-like peptide-I in the control of feeding.

Increased ileal proglucagon expression after jejunectomy is not suppressed by inhibition of bowel growth

After jejunectomy, a rapid and sustained increase in the abundance of proglucagon mRNA occurs in residual ileum and is accompanied by increases in plasma intestinal proglucagon-derived peptides. This response may be a component of adaptive growth, or proglucagon-derived peptides may regulate adaptive growth. To distinguish these possibilities, rats were treated with difluoromethylornithine, blocking ornithine decarboxylase activity and thereby adaptive bowel growth. Three groups fed ad libitum were compared: (1) resect: rats with 80% proximal small bowel resection; (2) resect + difluoromethylornithine: resected rats given difluoromethylornithine in drinking water; and (3) transect: transected controls. Six days after surgery, the resect + difluoromethylornithine group demonstrated inhibition of adaptive bowel growth. Abundance of ileal proglucagon mRNA in resect and resect + difluoromethylornithine groups was double that in the transect group (P < 0.02), whereas ornithine decarboxylase mRNA levels did not differ. Plasma enteroglucagon and glucagon-like peptide-I levels were greater in resect than transect groups (P < 0.002) and did not differ between resect and resect + difluoromethylornithine groups. The rise in ileal proglucagon mRNA after proximal small bowel resection is not inhibited by difluoromethylornithine despite blocking bowel growth and, therefore, is not merely a component of adaptive growth. Proglucagon-derived peptides are possible modulators of adaptive bowel but cannot stimulate growth when ornithine decarboxylase activity is inhibited.

Regulation of glucagon-like peptide-I receptor expression and transcription by the protein kinase C pathway

Regulation of glucagon-like peptide-I receptor expression and transcription by the protein kinase C pathway

Studies on the viability of the isolated vascularly perfused rat colon.

The colon contains large numbers of endocrine cells. Insight into their physiological function is limited. This is due to the fact that no sufficient model of isolated endocrine colon cells is available. In the present study we introduce an isolated vascularly perfused colon model for in vitro studies. This model offers the advantage that it keeps the endocrine cells in their physiological orientation and environment. The gut mucosa is highly sensitive to ischemia. Therefore, a careful validation of its viability is crucial in gut organ preparations. This study demonstrates that, by utilizing an oxygenated vascular medium supplemented with 25% washed bovine erythrocytes, a perfusion of the colon is achieved for at least 1 h without obvious tissue injuries. During this time parameters such as perfusion pressure, venous lactate dehydrogenase release, glucose consumption, lactate output, oxygen consumption, perfusate loss by the preparation and morphology were analyzed. Dependent on stimulation, the endocrine L cells of the colon released glucagon-like peptide-I upon arterial perfusion of methacholine or gastrin-releasing peptide. In conclusion, a model for the isolated perfusion of the colon is introduced which is suitable for studies of endocrine colon cells.

Enteral enhancement of glucose disposition by both insulin-dependent and insulin-independent processes. A physiological role of glucagon-like peptide I.

Glucagon-like peptide I (GLP-I)(7-36) amide is secreted by intestinal L-cells in response to food ingestion. GLP-I is a potent insulin secretagogue and also inhibits glucagon release. In addition, when given to humans in pharmacological amounts, GLP-I increases glucose disposal independent of its effects on islet hormone secretion. To test the hypothesis that this extrapancreatic effect of GLP-I on glucose disposition is present at physiological levels of GLP-I, we performed intravenous glucose tolerance tests (IVGTTs) 1 h after the following interventions: 1) the ingestion of 50 g fat to stimulate GLP-I secretion or the ingestion of water as a control and 2) infusion of GLP-I to attain physiological levels or a control infusion of saline. The results of the IVGTTs were analyzed using the minimal model technique to determine the insulin sensitivity index (SI) and indexes of insulin-independent glucose disposition, glucose effectiveness at basal insulin (SG), and glucose effectiveness at zero insulin (GEZI), as well as the glucose disappearance constant (k(g)) and the acute insulin response to glucose (AIRg). These parameters were compared between conditions of elevated circulating GLP-I and control conditions. After ingestion of fat and infusion of synthetic hormone, plasma GLP-I increased to similar levels; GLP-I did not change with water ingestion or saline infusion.(ABSTRACT TRUNCATED AT 250 WORDS)

The effects of glucagon-like peptide-I (GLP-I) on hormone secretion from isolated human pancreatic islets.

Glucagon-like peptide-I (GLP-I) is a potent incretin hormone that is now considered as a new therapeutic tool in the treatment of diabetes mellitus. In this study we characterized the effects of GLP-I on peptide hormone release from isolated human pancreatic islets. GLP-I stimulated insulin release in the presence of 10 mM glucose (2.8 mM glucose, 100%; 10 mM glucose, 166%; 10 mM glucose + 10 nM GLP-I, 222%) but had only a weak insulinotropic effect (128%) at 2.8 mM glucose. Glucagon release was inhibited by 10 mM glucose (2.8 mM glucose, 100%; 10 mM glucose, 72%) and by 10 nM GLP-I at 2.8 mM glucose (67%). Somatostatin secretion was increased by 10 mM glucose (2.8 mM glucose, 100%; 10 mM glucose, 166%). GLP-I stimulated somatostatin release in the presence of 2.8 mM glucose (172%). Pancreatic polypeptide (PP) secretion was enhanced by 10 mM glucose (2.8 mM glucose, 100%; 10 mM glucose, 236%). GLP-I induced PP release only in the presence of 2.8 mM glucose (184%).

Glucagon-Like Peptide I Increases Cytoplasmic Calcium in Insulin-Secreting βTC3-Cells by Enhancement of Intracellular Calcium Mobilization

In the insulin-secreting beta-cell line beta TC3, stimulation with 11.2 mmol/l glucose caused a rise in the intracellular free Ca2+ concentration ([Ca2+]i) in only 18% of the tested cells. The number of glucose-responsive cells increased after pretreatment of the cells with glucagon-like peptide I (GLP-I)(7-36)amide and at 10(-11) mol/l; 84% of the cells responded to glucose with a rise in [Ca2+]i. GLP-I(7-36)amide induces a rapid increase in [Ca2+]i only in cells exposed to elevated glucose concentrations (> or = 5.6 mmol/l). The action of GLP-I(7-36)amide and forskolin involved a 10-fold increase in cytoplasmic cAMP concentration and was mediated by activation of protein kinase A. It was not associated with an effect on the membrane potential but required some (small) initial entry of Ca2+ through voltage-dependent L-type Ca2+ channels, which then produced a further increase in [Ca2+]i by mobilization from intracellular stores. The latter effect reflected Ca(2+)-induced Ca2+ release and was blocked by ryanodine. Similar increases in [Ca2+]i were also observed in voltage-clamped cells, although there was neither activation of a background (Ca(2+)-permeable) inward current nor enhancement of the voltage-dependent L-type Ca2+ current. These observations are consistent with GLP-I(7-36) amide inducing glucose sensitivity by promoting mobilization of Ca2+ from intracellular stores. We propose that this novel action of GLP-I(7-36)amide represents an important factor contributing to its insulinotropic action.

Glucagon-Like Peptide I Reduces Postprandial Glycemic Excursions in IDDM

Effects of human glucagon-like peptide I (GLP-I)(7-36)amide were examined in volunteers having insulin-dependent diabetes mellitus (IDDM) with residual C-peptide (CP) secretion (n = 8, 7 men and 1 woman; age, 31 +/- 1.4 years; body mass index, 24.7 +/- 0.7 kg/m2; duration of diabetes, 3.2 +/- 0.8 years; insulin dose, 0.41 +/- 0.05 U.kg-1.day-1; meal-stimulated CP, 1.0 +/- 0.2 nmol/l [means +/- SE]). After a mixed meal (Sustacal, 30 kJ/kg body wt), intravenous injection of GLP-I, 1.2 pmol.kg-1.min-1 through 120 min, virtually abolished increments of plasma glucose, CP, pancreatic polypeptide (PP), and glucagon concentrations, with no significant effect on plasma gastrin levels during the infusions. At reduced dosage (0.75 pmol.kg-1.min-1), GLP-I had lesser effects on plasma glucose and CP levels. On cessation of intravenous GLP-I infusions after the meals, plasma glucose, CP, PP, and glucagon concentrations rebounded toward control levels by 180 min, and the response of plasma gastrin was prolonged. These rebound responses are consistent with intestinal delivery of food retained in the stomach on escape from inhibition of gastric emptying by GLP-I. Infusion of 1.2 pmol.kg-1.min-1 GLP-I with 20 g glucose (10% dextrose in water) injected intravenously over 60 min enhanced plasma responses of immunoreactive CP; the mean incremental areas under concentration curves (0-60 min) increased sixfold, but the glycemic excursion was not affected. Thus, in CP-positive IDDM, pharmacological doses of GLP-I reduce glycemic excursions after meals by a mechanism(s) not dependent on stimulation of insulin secretion, presumably involving delayed gastric emptying.(ABSTRACT TRUNCATED AT 250 WORDS)

Cell and molecular biology of the incretin hormones glucagon-like peptide-I and glucose-dependent insulin releasing polypeptide

Cell and molecular biology of the incretin hormones glucagon-like peptide-I and glucose-dependent insulin releasing polypeptide

Cell and molecular biology of the incretin hormones glucagon-like peptide-I and glucose-dependent insulin releasing polypeptide.

I. Introduction THE presence of intestinal factors regulating the function of endocrine secretion from the pancreas was first described in 1906 by Moore and colleagues (1). The idea that humoral factors secreted from the gut might act in this way arose after the recognition of “secretin” as a regulator of pancreatic secretion. Later it became evident that the hypoglycemic intestinal factor(s) is/are not “secretin” and the names “incretin” and “duodenin” were introduced in the 1920s and 1930s to describe these putative mediators (2–4). For several decades the nature of this/these factor(s) remained largely unknown (5–8) and before the first incretin hormone was chemically characterized, several other hormones produced in the gastrointestinal tract were discovered. The connection between the gastrointestinal tract and the endocrine pancreas was shown in the 1960s when insulin became measurable in plasma. In these classic studies, the insulin response to oral glucose and intravenous glucose, resulting in nea...

Altered glucose dependence of glucagon-like peptide I(7-36)-induced insulin secretion from the Zucker (fa/fa) rat pancreas.

In previous studies on the enteroinsular axis in Zucker rats, it was found that glucose-dependent insulinotropic polypeptide (GIP) levels were normal in obese animals, but the glucose threshold for the insulinotropic action of GIP in the perfused rat pancreas was reduced. Glucagon-like peptide I (GLP-I)(7-36) is also an important incretin, and in the current study, glucose, insulin, and immunoreactive (IR)-COOH-terminal GLP-I responses to oral glucose were compared in lean (Fa/?) and obese (fa/fa) rats. In addition, the concentration thresholds for stimulation and glucose dependence of perfused pancreases to GLP-I(7-36) were examined. Glucose responses to oral glucose were similar in fa/fa and Fa/? rats. Obese animals were hyperinsulinemic when fasting and after oral glucose. Significant increases in IR-GLP-I levels in response to glucose were only observed in fa/fa rats. Perfused pancreases from fa/fa rats hypersecreted insulin at all glucose concentrations. In the presence of 4.4 mmol/l glucose, GLP-I(7-36) increased insulin secretion in fa/fa pancreases approximately 25-fold, whereas there was only a 5-fold increase in Fa/? pancreases. Pancreases from fa/fa rats, perfused with a glucose gradient (2.8-11 mmol/l) in the presence of GLP-I(7-36), responded with an immediate increase in insulin secretion, i.e., at a glucose concentration of 2.8 mmol/l, whereas Fa/? pancreases required a minimum of 4.22 mmol/l glucose for stimulation. With high glucose (16.7 mmol/l), both fa/fa and Fa/? rat pancreases exhibited similar responsiveness to GLP-I(7-36), having thresholds of < 50 pmol/l.(ABSTRACT TRUNCATED AT 250 WORDS)

Processing of Mouse Proglucagon by Recombinant Prohormone Convertase 1 and Immunopurified Prohormone Convertase 2 in Vitro

The mouse tumor cell line alpha TC1-6 was used as a model system to examine the post-translational processing of proglucagon. Determination of the mouse preproglucagon cDNA sequence and comparison with the published sequences of rat and human preproglucagons revealed nucleic acid homologies of 89.1 and 84%, respectively, and amino acid homologies of 94 and 89.4%, respectively. Immunohistochemical analyses with antibodies directed against PC2 and glucagon colocalized both the enzyme and substrate within the same secretory granules. PC1 was also immunolocalized in secretory granules. Cells were metabolically labeled with [3H]tryptophan, and extracts were analyzed by reverse-phase high pressure liquid chromatography. Radioactive peptides with retention times identical to those of synthetic peptide standards were recovered and subjected to peptide mapping to verify their identities. To determine the potential role of PC1 and PC2 in proglucagon processing, 3H-labeled proglucagon was incubated in vitro with recombinant PC1 and/or immunopurified PC2. Both enzymes cleaved proglucagon to yield the major proglucagon fragment, glicentin, and oxyntomodulin, whereas only PC1 released glucagon-like peptide-I from the major proglucagon fragment. Neither PC1 nor PC2 processed glucagon from proglucagon in vitro. These results suggest a potential role for PC1 and/or PC2 in cleaving several of the normal products, excluding glucagon, from the mouse proglucagon precursor.

Tissue-specific expression of the human receptor for glucagon-like peptide-I: brain, heart and pancreatic forms have the same deduced amino acid sequences

Glucagon-like peptide-I(GLP-I), encoded by the glucagon gene and released from the gut in response to nutrients, is a potent stimulator of glucose-induced insulin secretion. In human subjects GLP-I exerts its physiological effect as an incretin. The incretin effect of GLP-I is preserved in patients with Type II diabetes mellitus (NIDDM), suggesting that GLP-I receptor agonist can be used therapeutically in this group of patients. In these studies we addressed the question of whether GLP-I has broader actions in human physiology. To investigate this issue we examined the tissue distribution of GLP-I receptor using RNAse protection assay in order to avoid the cross-reactivities with structurally related receptors and to increase the sensitivity of detection. The riboprobe was synthetized from the human pancreatic GLP-I receptor cDNA and used in hybridization experiments with total RNA isolated from different human tissues. In addition to the pancreas, we found expression of GLP-I receptor mRNA in lung, brain, kidney, stomach and heart. Peripheral tissues which are the major sites of glucose turnover, such as liver, skeletal muscle and adipose did not express the pancreatic form of the GLP-I receptor. We also cloned and sequenced GLP-I receptor cDNA from human brain and heart. The deduced amino acid sequences are the same as the sequence found in the pancreas. These results indicate that GLP-I might have effects beyond the pancreas, including the cardiovascular and central nervous systems where a receptor with the same ligand binding specificity is found.

Interaction of glucagon-like peptide-I (GLP-I) and galanin in insulin (beta TC-1)- and somatostatin (RIN T3)-secreting cells and evidence that both peptides have no receptors on glucagon (INR1G9)-secreting cells.

The interaction of glucagon-like peptide-I (GLP-I) and galanin in clonal endocrine pancreatic cells was characterized. By Northern blot analysis the presence of GLP-I receptor mRNA was shown in B (beta TC-1 cells) and D (RIN 1048-38) cells but not in A (INR1 G9) cells, thus confirming functional data demonstrating the absence of active GLP-I receptors on glucagon-producing cells. Galanin receptors were detected on B and D cells but not on A cells. In B and D cells galanin inhibited the GLP-I stimulated adenylate cyclase activity. Treatment of insulin- and somatostatin-producing cells with GLP-I increased intracellular cAMP levels, and this was dampened by galanin, GLP-I stimulated the activity of protein kinase A in B and D cells, which was also inhibited by galanin. Galanin alone did not influence B- and D-cell function. These data show that in the endocrine pancreas B and D cells but not A cells express GLP-I and galanin receptors. The interaction of GLP-I and galanin might act in the endocrine pancreas as a physiological inhibitor of the potent incretin hormone GLP-I. Therefore, we suggest galanin is a 'decretin'.

A novel insulin secretagogue is a phosphodiesterase inhibitor.

The arylpiperazine L-686,398 was described as an oral hypoglycemic agent and is shown to be an insulin secretagogue in vitro. The characteristics of its activity were similar to those of the incretin glucagon-like peptide I (GLP-I). We demonstrate that both the peptide and L-686,398 increase the accumulation of cAMP in isolated ob/ob mouse pancreatic islet cells, but by different mechanisms. Although GLP-I activates adenylate cyclase, the arylpiperazine has no effect on this enzyme or on the binding of 125I-labeled GLP-I to its receptor on RINm5F rat insulinoma cell membranes. However, L-686,398 inhibits the total cAMP phosphodiesterase (PDE) activity in homogenates of ob/ob mouse pancreatic islets with an EC50 of approximately 50 mumol/l. To determine the mechanism of PDE inhibition by the arylpiperazine and to examine its specificity, we studied the kinetics of arylpiperazine inhibition of two recombinant PDEs. The arylpiperazine is a competitive inhibitor of both a human heart type III PDE and a rat type IV-D PDE. Inhibition of the type III and IV isozymes are characterized by Ki values of 27 and 5 mumol/l, respectively. Although not extremely potent, the arylpiperazine does exhibit modest selectivity between these PDEs. The observation that L-686,398 acts as a PDE inhibitor suggests that exploration for beta-cell-specific PDE isoforms may reveal novel PDEs as targets for the development of therapeutically useful glucose-dependent insulin secretagogues.

Pituitary adenylate cyclase-activating polypeptide receptors of types I and II and glucagon-like peptide-I receptors are expressed in the rat medullary carcinoma of the thyroid cell line 6/23.

The expression of the messenger RNAs coding for glucagon-like peptide-I (GLP-I) receptor, VIP receptor, and pituitary adenylate cyclase-activating polypeptide (PACAP) receptor as well as the expression of the receptor proteins were demonstrated in the rat medullary carcinoma of thyroid cell line 6/23 by the following experiments: 1) RNA extraction, reverse transcriptase, and polymerase chain reaction with specific primers; 2) binding of the radiolabeled ligands [125I]GLP-I-(7-36)-NH2, [125I]PACAP-(1-27), and [125I]VIP and inhibition by, respectively, unlabeled GLP-I-(7-36)-NH2, PACAP-(1-27), and VIP; and 3) study of adenylate cyclase activation by the peptides and selective inhibition of the VIP/PACAP response by the antagonist [D-Phe2]VIP. Besides the highly selective GLP-I receptor, PACAP receptors of types I and II were present on the cell line and coupled to adenylate cyclase. PACAP stimulated the adenylate cyclase through type I and II receptors, whereas VIP interacted with type II receptors only. Messenger RNA analysis indicated that at least three splice variants of the PACAP type I receptor may be expressed in 6/23 cells.

Pituitary adenylate cyclase-activating polypeptide receptors of types I and II and glucagon-like peptide-I receptors are expressed in the rat medullary carcinoma of the thyroid cell line 6/23

Pituitary adenylate cyclase-activating polypeptide receptors of types I and II and glucagon-like peptide-I receptors are expressed in the rat medullary carcinoma of the thyroid cell line 6/23