Your search keyword '"Glucagon physiology"' showing total 300 results

1. Paracrine regulation of somatostatin secretion by insulin and glucagon in mouse pancreatic islets.

Author

Svendsen B and Holst JJ

Subjects

Animals, Arginine administration & dosage, Cell Communication, Diphtheria Toxin pharmacology, Gene Knockdown Techniques, Glucagon administration & dosage, Glucagon-Like Peptide-1 Receptor drug effects, Glucagon-Like Peptide-1 Receptor physiology, Glucagon-Secreting Cells drug effects, Glucagon-Secreting Cells physiology, Glucose administration & dosage, Insulin administration & dosage, Insulin Secretion drug effects, Islets of Langerhans drug effects, Islets of Langerhans metabolism, Mice, Mice, Inbred C57BL, Mice, Knockout, Receptors, Glucagon deficiency, Receptors, Glucagon genetics, Receptors, Glucagon physiology, Receptors, Somatostatin antagonists & inhibitors, Signal Transduction physiology, Somatostatin administration & dosage, Glucagon physiology, Insulin physiology, Somatostatin metabolism

Abstract

Aims/hypothesis: The endocrine pancreas comprises the islets of Langerhans, primarily consisting of beta cells, alpha cells and delta cells responsible for secretion of insulin, glucagon and somatostatin, respectively. A certain level of intra-islet communication is thought to exist, where the individual hormones may reach the other islet cells and regulate their secretion. Glucagon has been demonstrated to importantly regulate insulin secretion, while somatostatin powerfully inhibits both insulin and glucagon secretion. In this study we investigated how secretion of somatostatin is regulated by paracrine signalling from glucagon and insulin., Methods: Somatostatin secretion was measured from perfused mouse pancreases isolated from wild-type as well as diphtheria toxin-induced alpha cell knockdown, and global glucagon receptor knockout (Gcgr -/- ) mice. We studied the effects of varying glucose concentrations together with infusions of arginine, glucagon, insulin and somatostatin, as well as infusions of antagonists of insulin, somatostatin and glucagon-like peptide 1 (GLP-1) receptors., Results: A tonic inhibitory role of somatostatin was demonstrated with infusion of somatostatin receptor antagonists, which significantly increased glucagon secretion at low and high glucose, whereas insulin secretion was only increased at high glucose levels. Infusion of glucagon dose-dependently increased somatostatin secretion approximately twofold in control mice. Exogenous glucagon had no effect on somatostatin secretion in Gcgr -/- mice, and a reduced effect when combined with the GLP-1 receptor antagonist exendin 9-39. Diphtheria toxin-induced knockdown of glucagon producing cells led to reduced somatostatin secretion in response to 12 mmol/l glucose and arginine infusions. In Gcgr -/- mice (where glucagon levels are dramatically increased) overall somatostatin secretion was increased. However, infusion of exendin 9-39 in Gcgr -/- mice completely abolished somatostatin secretion in response to glucose and arginine. Neither insulin nor an insulin receptor antagonist (S961) had any effect on somatostatin secretion., Conclusions/interpretation: Our findings demonstrate that somatostatin and glucagon secretion are linked in a reciprocal feedback cycle with somatostatin inhibiting glucagon secretion at low and high glucose levels, and glucagon stimulating somatostatin secretion via the glucagon and GLP-1 receptors. Graphical abstract.

Published

2021

2. Role of Glucagon in Automated Insulin Delivery.

Author

Wilson LM, Jacobs PG, and Castle JR

Subjects

Automation instrumentation, Diabetes Mellitus, Type 1 blood, Drug Therapy, Combination instrumentation, Drug Therapy, Combination methods, Glucagon administration & dosage, Glycemic Control instrumentation, Glycemic Control methods, Humans, Hypoglycemia chemically induced, Hypoglycemia prevention & control, Pancreas, Artificial, Diabetes Mellitus, Type 1 drug therapy, Glucagon physiology, Insulin administration & dosage, Insulin Infusion Systems

Abstract

Treatment of type 1 diabetes with exogenous insulin often results in unpredictable daily glucose variability and hypoglycemia, which can be dangerous. Automated insulin delivery systems can improve glucose control while reducing burden for people with diabetes. One approach to improve treatment outcomes is to incorporate the counter-regulatory hormone glucagon into the automated delivery system to help prevent the hypoglycemia that can be induced by the slow pharmacodynamics of insulin action. This article explores the advantages and disadvantages of incorporating glucagon into dual-hormone automated hormone delivery systems., Competing Interests: Disclosure L.M. Wilson has nothing to disclose. P.G. Jacobs and J.R. Castle have a financial interest in Pacific Diabetes Technologies, Inc, a company that may have a commercial interest in the results of this type of research and technology. This potential conflict of interest has been reviewed and managed by OHSU. In addition, P.G. Jacobs and J.R. Castle report research support from Xeris, Dexcom, and Tandem Diabetes Care. J.R. Castle reports advisory board participation for Zealand Pharma and Novo Nordisk, consulting for Dexcom, and a United States patent on the use of ferulic acid to stabilize glucagon., (Copyright © 2019 Elsevier Inc. All rights reserved.)

Published

2020

3. Glucagon and Insulin Cooperatively Stimulate Fibroblast Growth Factor 21 Gene Transcription by Increasing the Expression of Activating Transcription Factor 4.

Author

Alonge KM, Meares GP, and Hillgartner FB

Subjects

Animals, Cells, Cultured, Chenodeoxycholic Acid pharmacology, Drug Synergism, Eukaryotic Initiation Factor-2 pharmacology, Gene Expression Regulation drug effects, Glucagon pharmacology, Hepatocytes cytology, Rats, Transcription, Genetic drug effects, Activating Transcription Factor 4 metabolism, Fibroblast Growth Factors genetics, Glucagon physiology, Insulin physiology

Abstract

Previous studies have shown that glucagon cooperatively interacts with insulin to stimulate hepatic FGF21 gene expression. Here we investigated the mechanism by which glucagon and insulin increased FGF21 gene transcription in primary hepatocyte cultures. Transfection analyses demonstrated that glucagon plus insulin induction of FGF21 transcription was conferred by two activating transcription factor 4 (ATF4) binding sites in the FGF21 gene. Glucagon plus insulin stimulated a 5-fold increase in ATF4 protein abundance, and knockdown of ATF4 expression suppressed the ability of glucagon plus insulin to increase FGF21 expression. In hepatocytes incubated in the presence of insulin, treatment with a PKA-selective agonist mimicked the ability of glucagon to stimulate ATF4 and FGF21 expression. Inhibition of PKA, PI3K, Akt, and mammalian target of rapamycin complex 1 (mTORC1) suppressed the ability of glucagon plus insulin to stimulate ATF4 and FGF21 expression. Additional analyses demonstrated that chenodeoxycholic acid (CDCA) induced a 6-fold increase in ATF4 expression and that knockdown of ATF4 expression suppressed the ability of CDCA to increase FGF21 gene expression. CDCA increased the phosphorylation of eIF2α, and inhibition of eIF2α signaling activity suppressed CDCA regulation of ATF4 and FGF21 expression. These results demonstrate that glucagon plus insulin increases FGF21 transcription by stimulating ATF4 expression and that activation of cAMP/PKA and PI3K/Akt/mTORC1 mediates the effect of glucagon plus insulin on ATF4 expression. These results also demonstrate that CDCA regulation of FGF21 transcription is mediated at least partially by an eIF2α-dependent increase in ATF4 expression., (© 2017 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2017

4. Acute disruption of glucagon secretion or action does not improve glucose tolerance in an insulin-deficient mouse model of diabetes.

Author

Steenberg VR, Jensen SM, Pedersen J, Madsen AN, Windeløv JA, Holst B, Quistorff B, Poulsen SS, and Holst JJ

Subjects

Animals, Blood Glucose drug effects, Blood Glucose metabolism, Diphtheria Toxin, Glucagon-Like Peptide 1 metabolism, Glucagon-Secreting Cells drug effects, Glucagon-Secreting Cells pathology, Glucose Tolerance Test, Insulin metabolism, Insulin-Secreting Cells drug effects, Insulin-Secreting Cells metabolism, Insulin-Secreting Cells pathology, Male, Mice, Mice, Inbred C57BL, Mice, Knockout, Receptors, Glucagon antagonists & inhibitors, Receptors, Glucagon genetics, Streptozocin, Diabetes Mellitus, Experimental chemically induced, Diabetes Mellitus, Experimental genetics, Diabetes Mellitus, Experimental metabolism, Diabetes Mellitus, Experimental pathology, Glucagon antagonists & inhibitors, Glucagon metabolism, Glucagon physiology, Glucose Intolerance blood, Glucose Intolerance drug therapy, Glucose Intolerance genetics, Insulin deficiency

Abstract

Aims/hypothesis: Normal glucose metabolism depends on pancreatic secretion of insulin and glucagon. The bihormonal hypothesis states that while lack of insulin leads to glucose underutilisation, glucagon excess is the principal factor in diabetic glucose overproduction. A recent study reported that streptozotocin-treated glucagon receptor knockout mice have normal glucose tolerance. We investigated the impact of acute disruption of glucagon secretin or action in a mouse model of severe diabetes by three different approaches: (1) alpha cell elimination; (2) glucagon immunoneutralisation; and (3) glucagon receptor antagonism, in order to evaluate the effect of these on glucose tolerance., Methods: Severe diabetes was induced in transgenic and wild-type mice by streptozotocin. Glucose metabolism was investigated using OGTT in transgenic mice with the human diphtheria toxin receptor expressed in proglucagon producing cells allowing for diphtheria toxin (DT)-induced alpha cell ablation and in mice treated with either a specific high affinity glucagon antibody or a specific glucagon receptor antagonist., Results: Near-total alpha cell elimination was induced in transgenic mice upon DT administration and resulted in a massive decrease in pancreatic glucagon content. Oral glucose tolerance in diabetic mice was neither affected by glucagon immunoneutralisation, glucagon receptor antagonism, nor alpha cell removal, but did not deteriorate further compared with mice with intact alpha cell mass., Conclusions/interpretation: Disruption of glucagon action/secretion did not improve glucose tolerance in diabetic mice. Near-total alpha cell elimination may have prevented further deterioration. Our findings support insulin lack as the major factor underlying hyperglycaemia in beta cell-deficient diabetes.

Published

2016

5. Insulin's sidekicks. Developing alternative medications for type 1 diabetes.

Author

Berg EG

Subjects

Administration, Oral, Blood Glucose metabolism, Glucagon antagonists & inhibitors, Glucagon physiology, Humans, Hypoglycemic Agents administration & dosage, Diabetes Mellitus, Type 1 drug therapy, Hypoglycemic Agents therapeutic use, Insulin therapeutic use, Islet Amyloid Polypeptide therapeutic use

Published

2013

6. [Regulation of adenylyl cyclase signaling system by insulin, biogenic amines, and glucagon at their separate and combined action in the muscle membranes of the mollusc Anodonta cygnea].

Author

Kuznetsova LA, Plesneva SA, Sharova TS, Pertseva MN, and Shpakov AO

Subjects

Adenylyl Cyclase Inhibitors, Adrenergic beta-Antagonists pharmacology, Animals, Anodonta enzymology, Anodonta physiology, Biogenic Amines administration & dosage, Biogenic Amines physiology, Cell Membrane drug effects, Cell Membrane enzymology, Drug Interactions, Glucagon administration & dosage, Glucagon physiology, In Vitro Techniques, Insulin administration & dosage, Insulin physiology, Muscle, Smooth drug effects, Muscle, Smooth enzymology, Muscle, Smooth physiology, Signal Transduction physiology, Adenylyl Cyclases metabolism, Anodonta drug effects, Biogenic Amines pharmacology, Glucagon pharmacology, Insulin pharmacology, Signal Transduction drug effects

Abstract

In smooth muscles of mollusc Anodonta cygnea, hormones produce regulatory effects on the adenylyl cyclase (AC) signaling system via receptors of the serpentine (biogenic amine, isoproterenol, glucagon) and of tyrosine kinase (insulin) types. Intracellular mechanisms of their action are interconnected. Use of hormones, their antagonists, and pertussis toxin at the combined action of insulin and biogenic amines or of glucagon on the AC activity allows revealing possible intersection points in mechanisms of their action. The combined effect of insulin and serotonin or of glucagon leads to a decrease of stimulation of AC by these hormones, whereas at action of insulin and isoproterenol the AC-stimulatory effect of insulin is blocked, while the AC-inhibitory effect of isoproterenol is preserved both in the presence and in the absence of the non-hydrolyzed GTP analog - guanylylimidodiphosphate (GppNHp). Specific blocking of the AC-stimulatory serotonin effect by cyproheptadine - an antagonist of serotonin receptors - did not affect stimulation of AC by insulin. Beta-adrenoblockers (propranolol and alprenolol) interfered with inhibition of the AC activity by isoproterenol, but did not change the AC stimulation by insulin. Pertussis toxin blocked the AC-inhibitory effect of isoproterenol and attenuated the AC-stimulatory effect of insulin. Thus, in muscles of the mollusc Anodonta cygnea there have been revealed negative interrelations between the AC system, which are realized at the combined effect of insulin and serotonin or of glucagon, probably at the level of receptor of the serpentine type (serotonin, glucagon), while at action of insulin and isoproterenol - at the level of interaction of G1 protein and AC.

Published

2013

7. Kinetic modeling of human hepatic glucose metabolism in type 2 diabetes mellitus predicts higher risk of hypoglycemic events in rigorous insulin therapy.

Author

König M and Holzhütter HG

Subjects

Algorithms, Blood Glucose, Computer Simulation, Diabetes Mellitus, Type 2 blood, Diabetes Mellitus, Type 2 drug therapy, Epinephrine blood, Epinephrine physiology, Glucagon blood, Glucagon physiology, Glucose metabolism, Glucose physiology, Glycogen metabolism, Hepatocytes metabolism, Humans, Hypoglycemia blood, Hypoglycemia drug therapy, Hypoglycemic Agents adverse effects, Insulin adverse effects, Insulin blood, Insulin Resistance, Kinetics, Liver cytology, Phosphorylation, Postprandial Period, Protein Processing, Post-Translational, Carbohydrate Metabolism, Diabetes Mellitus, Type 2 metabolism, Hypoglycemia metabolism, Hypoglycemic Agents therapeutic use, Insulin therapeutic use, Liver metabolism, Models, Biological

Abstract

A major problem in the insulin therapy of patients with diabetes type 2 (T2DM) is the increased occurrence of hypoglycemic events which, if left untreated, may cause confusion or fainting and in severe cases seizures, coma, and even death. To elucidate the potential contribution of the liver to hypoglycemia in T2DM we applied a detailed kinetic model of human hepatic glucose metabolism to simulate changes in glycolysis, gluconeogenesis, and glycogen metabolism induced by deviations of the hormones insulin, glucagon, and epinephrine from their normal plasma profiles. Our simulations reveal in line with experimental and clinical data from a multitude of studies in T2DM, (i) significant changes in the relative contribution of glycolysis, gluconeogenesis, and glycogen metabolism to hepatic glucose production and hepatic glucose utilization; (ii) decreased postprandial glycogen storage as well as increased glycogen depletion in overnight fasting and short term fasting; and (iii) a shift of the set point defining the switch between hepatic glucose production and hepatic glucose utilization to elevated plasma glucose levels, respectively, in T2DM relative to normal, healthy subjects. Intriguingly, our model simulations predict a restricted gluconeogenic response of the liver under impaired hormonal signals observed in T2DM, resulting in an increased risk of hypoglycemia. The inability of hepatic glucose metabolism to effectively counterbalance a decline of the blood glucose level becomes even more pronounced in case of tightly controlled insulin treatment. Given this Janus face mode of action of insulin, our model simulations underline the great potential that normalization of the plasma glucagon profile may have for the treatment of T2DM.

Published

2012

8. Hyperglucagonemia precedes a decline in insulin secretion and causes hyperglycemia in chronically glucose-infused rats.

Author

Jamison RA, Stark R, Dong J, Yonemitsu S, Zhang D, Shulman GI, and Kibbey RG

Subjects

Animals, Down-Regulation, Drug Administration Schedule, Glucagon physiology, Gluconeogenesis drug effects, Gluconeogenesis physiology, Glucose pharmacology, Glucose Tolerance Test methods, Hyperglycemia blood, Hyperglycemia chemically induced, Infusion Pumps, Insulin Secretion, Male, Models, Animal, Rats, Rats, Sprague-Dawley, Time Factors, Up-Regulation, Glucagon blood, Glucose administration & dosage, Hyperglycemia etiology, Insulin metabolism

Abstract

Islet damage from glucose toxicity is implicated in the pathogenesis of type 2 diabetes, but the sequence of events leading to islet cell dysfunction and hyperglycemia remains unclear. To examine the early stages of islet pathology resulting from increased basal glucose loads, normal awake rats were infused with glucose continuously for 10 days. Plasma glucose and markers of islet and liver function were monitored throughout the infusion. After initial hyperglycemia, rats adapted to the infusion and maintained euglycemia for approximately 4 days. Continued infusion led to worsening hyperglycemia in just 5% of rats after 6 days, but 69% after 8 days and 89% after 10 days, despite unchanged basal and stimulated plasma insulin and C-peptide concentrations. In contrast, plasma glucagon concentrations increased fivefold. Endogenous glucose production (EGP) was appropriately suppressed after 4 days (2.8 ± 0.7 vs. 6.1 ± 0.4 mg·kg(-1)·min(-1) on day 0, P < 0.001) but tripled between days 4 and 8 (9.9 ± 1.7 mg·kg(-1)·min(-1), P < 0.01). Surprisingly, the increase in EGP was accompanied by increased mitochondrial phosphoenolpyruvate carboxykinase expression with appropriate suppression of the cytosolic isoform. Infusion of anti-glucagon antibodies normalized plasma glucose to levels identical to those on day 4 and ∼300 mg/dl lower than controls. This improved glycemia was associated with a 60% reduction in EGP. These data support the novel concept that glucose toxicity may first manifest as α-cell dysfunction prior to any measurable deficit in insulin secretion. Such hyperglucagonemia could lead to excessive glucose production overwhelming the capacity of the β-cell to maintain glucose homeostasis.

Published

2011

9. Insulin and glucagon regulate pancreatic α-cell proliferation.

Author

Liu Z, Kim W, Chen Z, Shin YK, Carlson OD, Fiori JL, Xin L, Napora JK, Short R, Odetunde JO, Lao Q, and Egan JM

Subjects

Animals, Diabetes Mellitus, Type 2 pathology, Dose-Response Relationship, Drug, Glucagon blood, Hypertrophy etiology, Insulin therapeutic use, Mice, Mice, Inbred Strains, Cell Proliferation, Glucagon physiology, Glucagon-Secreting Cells cytology, Insulin pharmacology

Abstract

Type 2 diabetes mellitus (T2DM) results from insulin resistance and β-cell dysfunction, in the setting of hyperglucagonemia. Glucagon is a 29 amino acid peptide hormone, which is secreted from pancreatic α cells: excessively high circulating levels of glucagon lead to excessive hepatic glucose output. We investigated if α-cell numbers increase in T2DM and what factor (s) regulate α-cell turnover. Lepr(db)/Lepr(db) (db/db) mice were used as a T2DM model and αTC1 cells were used to study potential α-cell trophic factors. Here, we demonstrate that in db/db mice α-cell number and plasma glucagon levels increased as diabetes progressed. Insulin treatment (EC50 = 2 nM) of α cells significantly increased α-cell proliferation in a concentration-dependent manner compared to non-insulin-treated α cells. Insulin up-regulated α-cell proliferation through the IR/IRS2/AKT/mTOR signaling pathway, and increased insulin-mediated proliferation was prevented by pretreatment with rapamycin, a specific mTOR inhibitor. GcgR antagonism resulted in reduced rates of cell proliferation in αTC1 cells. In addition, blockade of GcgRs in db/db mice improved glucose homeostasis, lessened α-cell proliferation, and increased intra-islet insulin content in β cells in db/db mice. These studies illustrate that pancreatic α-cell proliferation increases as diabetes develops, resulting in elevated plasma glucagon levels, and both insulin and glucagon are trophic factors to α-cells. Our current findings suggest that new therapeutic strategies for the treatment of T2DM may include targeting α cells and glucagon.

Published

2011

10. Glucagon supports postabsorptive plasma glucose concentrations in humans with biologically optimal insulin levels.

Author

Cooperberg BA and Cryer PE

Subjects

Adult, Blood Glucose drug effects, Diabetes Mellitus, Type 1 drug therapy, Female, Glucagon physiology, Humans, Infusions, Intravenous, Insulin administration & dosage, Insulin blood, Intestinal Absorption, Male, Reference Values, Blood Glucose metabolism, Diabetes Mellitus, Type 1 blood, Glucagon blood, Insulin therapeutic use

Abstract

Objective: Based on the premise that postabsorptive patients with type 1 diabetes receiving intravenous insulin in a dose that maintains stable euglycemia are receiving biologically optimal insulin replacement, we tested the hypothesis that glucagon supports postabsorptive plasma glucose concentrations in humans., Research Design and Methods: Fourteen patients with type 1 diabetes were studied after an overnight fast on up to five occasions. Insulin was infused intravenously to hold plasma glucose concentrations at ∼100 mg/dl (5.6 mmol/l) overnight and fixed from -60 to 240 min the following morning. From 0 through 180 min the patients also received 1) saline, 2) octreotide 30 ng · kg(-1) · min(-1) with growth hormone replacement or octreotide with growth hormone, plus 3) glucagon in doses of 0.5 ng · kg(-1) · min(-1), 4) 1.0 ng · kg(-1) · min(-1), and 5) 2.0 ng · kg(-1) · min(-1)., Results: Compared with a mean ± SE of 98 ± 5 mg/dl (5.4 ± 0.3 mmol/l) at 180 min during saline, mean plasma glucose concentrations declined to 58 ± 1 mg/dl (3.2 ± 0.1 mmol/l) (P < 0.001) at 180 min during octreotide plus saline and were 104 ± 16 mg/dl (5.8 ± 0.9 mmol/l) (NS), 143 ± 13 mg/dl (7.9 ± 0.7 mmol/l) (P = 0.004), and 160 ± 15 mg/dl (8.9 ± 0.8 mmol/l) (P < 0.001) at 180 min during octreotide plus glucagon in doses of 0.5, 1.0, and 2.0 ng · kg(-1) · min(-1), respectively., Conclusions: In the setting of biologically optimal insulin replacement, suppression of glucagon secretion with octreotide caused a progressive fall in plasma glucose concentrations that was prevented by glucagon replacement. These data document that glucagon supports postabsorptive glucose concentrations in humans.

Published

2010

11. What is known, new and controversial about GLP-1? Minutes of the 1st European GLP-1 Club Meeting, Marseille, 28-29 May 2008.

Author

Burcelin R

Subjects

Animals, Cell Differentiation, Diabetes Mellitus, Type 1 physiopathology, Diabetes Mellitus, Type 2 physiopathology, France, Glucagon physiology, Glucagon-Like Peptide 1 blood, Glucagon-Like Peptide 1 therapeutic use, Humans, Insulin Secretion, Insulin-Secreting Cells cytology, L Cells physiology, Mice, Glucagon-Like Peptide 1 physiology, Insulin metabolism

Abstract

The first antidiabetic agent was a hormone--insulin--and ever since, all therapeutic strategies have been based on the synthesis of chemical compounds to bind its receptors or transcription factors, or to trigger its intracellular mechanisms. Eighty years on, new therapeutic molecules are available for the treatment of diabetes and, again, are based on a hormone--glucagon-like peptide-1 (GLP-1). Whereas the theoretical benefit of insulin is based on normalization of functional physiology, therapeutic strategies based on GLP-1 aim to increase the circulating concentration of a natural component--the hormone GLP-1. There are two strategies for increasing GLP-1 plasma concentrations: replace the hormone with a long-acting analogue or molecule with a longer half-life; and prevent its degradation by inhibiting its natural protease, dipeptidyl peptidase IV (DPPIV). Although numerous clinical trials have been carried out and vast amounts of data are available, the mechanisms through which GLP-1-based therapy reduces blood glucose in diabetic patients remain unclear. Thus, it is essential to ask the right questions and to design appropriate clinical trials and experiments to increase our understanding of the mode of action of GLP-1-based therapy. For this reason, in the spring of 2008, expert scientists and clinicians in the field of GLP-1 got together for an intensive debate on the subject at the first meeting of the European Club for the study of GLP-1, held in Marseille. The subject of the round table discussions was: what is known, new and controversial about GLP-1? During these discussions, numerous facts and controversies were reevaluated, and revealed that several long-held, dogmatic beliefs have never been fully and scientifically established. These points are detailed here in these minutes of the landmark meeting.

Published

2008

12. Insulin as a physiological modulator of glucagon secretion.

Author

Bansal P and Wang Q

Subjects

Animals, Glucagon biosynthesis, Glucagon physiology, Humans, Hyperglycemia physiopathology, Islets of Langerhans physiology, Glucagon metabolism, Insulin physiology

Abstract

Glucose homeostasis is regulated primarily by the opposing actions of insulin and glucagon, hormones that are secreted by pancreatic islets from beta-cells and alpha-cells, respectively. Insulin secretion is increased in response to elevated blood glucose to maintain normoglycemia by stimulating glucose transport in muscle and adipocytes and reducing glucose production by inhibiting gluconeogenesis in the liver. Whereas glucagon secretion is suppressed by hyperglycemia, it is stimulated during hypoglycemia, promoting hepatic glucose production and ultimately raising blood glucose levels. Diabetic hyperglycemia occurs as the result of insufficient insulin secretion from the beta-cells and/or lack of insulin action due to peripheral insulin resistance. Remarkably, excessive secretion of glucagon from the alpha-cells is also a major contributor to the development of diabetic hyperglycemia. Insulin is a physiological suppressor of glucagon secretion; however, at the cellular and molecular levels, how intraislet insulin exerts its suppressive effect on the alpha-cells is not very clear. Although the inhibitory effect of insulin on glucagon gene expression is an important means to regulate glucagon secretion, recent studies suggest that the underlying mechanisms of the intraislet insulin on suppression of glucagon secretion involve the modulation of K(ATP) channel activity and the activation of the GABA-GABA(A) receptor system. Nevertheless, regulation of glucagon secretion is multifactorial and yet to be fully understood.

Published

2008

13. Reactive oxygen species facilitate the insulin-dependent inhibition of glucagon-induced glucose production in the isolated perfused rat liver.

Author

Messner J and Graf J

Subjects

Animals, Male, Melatonin physiology, NADPH Oxidases physiology, Organ Culture Techniques, Phosphoproteins physiology, Protein-Tyrosine Kinases antagonists & inhibitors, Rats, Rats, Sprague-Dawley, Signal Transduction physiology, Blood Glucose metabolism, Glucagon physiology, Insulin physiology, Reactive Oxygen Species metabolism

Abstract

Recent studies indicate that intracellular insulin signalling involves the formation of reactive oxygen species (ROS) by NADPH oxidases (NOX). ROS inhibit intracellular protein tyrosin phosphatases whereby phosphoprotein signalling is enhanced and prolonged. We used the isolated perfused rat liver and detected ROS formation by measuring the surface fluorescence at wavelengths specific for the intracellular ROS sensor carboxydihydrodichlorofluorescein. Insulin (2, 5, 20 nM) induced low level ROS formation that was abolished by the NOX inhibitor diphenyleneiodonium chloride (4 microM). Studying insulin-dependent inhibition of glucagon-activated glucose production showed that melatonin (50 microM), used as ROS scavenger, inhibited ROS formation and blunted the effect of insulin on glucose production. The data support the general notion that hormone-dependent ROS formation modifies intracellular signal transduction.

Published

2008

14. The role of gut hormones in glucose homeostasis.

Author

Drucker DJ

Subjects

Adenosine Deaminase physiology, Dipeptidyl Peptidase 4 physiology, Glucagon physiology, Glycoproteins physiology, Homeostasis, Humans, Proglucagon physiology, Gastrointestinal Diseases physiopathology, Gastrointestinal Tract physiology, Insulin physiology

Abstract

The gastrointestinal tract has a crucial role in the control of energy homeostasis through its role in the digestion, absorption, and assimilation of ingested nutrients. Furthermore, signals from the gastrointestinal tract are important regulators of gut motility and satiety, both of which have implications for the long-term control of body weight. Among the specialized cell types in the gastrointestinal mucosa, enteroendocrine cells have important roles in regulating energy intake and glucose homeostasis through their actions on peripheral target organs, including the endocrine pancreas. This article reviews the biological actions of gut hormones regulating glucose homeostasis, with an emphasis on mechanisms of action and the emerging therapeutic roles of gut hormones for the treatment of type 2 diabetes mellitus.

Published

2007

15. Glucagon receptor knockout mice display increased insulin sensitivity and impaired beta-cell function.

Author

Sørensen H, Winzell MS, Brand CL, Fosgerau K, Gelling RW, Nishimura E, and Ahren B

Subjects

Animals, Arginine pharmacology, Blood Glucose metabolism, Carbachol pharmacology, Glucagon physiology, Glucose metabolism, Glucose Clamp Technique, Glucose Tolerance Test, Hyperinsulinism, Insulin metabolism, Insulin Secretion, Kinetics, Mice, Mice, Knockout, Insulin pharmacology, Insulin-Secreting Cells metabolism, Receptors, Glucagon deficiency, Receptors, Glucagon genetics

Abstract

In previous studies, glucagon receptor knockout mice (Gcgr(-/-)) display reduced blood glucose and increased glucose tolerance, with hyperglucagonemia and increased levels of glucagon-like peptide (GLP)-1. However, the role of glucagon receptor signaling for the regulation of islet function and insulin sensitivity is unknown. We therefore explored beta-cell function and insulin sensitivity in Gcgr(-/-) and wild-type mice. The steady-state glucose infusion rate during hyperinsulinemic-euglycemic clamp was elevated in Gcgr(-/-) mice, indicating enhanced insulin sensitivity. Furthermore, the acute insulin response (AIR) to intravenous glucose was higher in Gcgr(-/-) mice. The augmented AIR to glucose was blunted by the GLP-1 receptor antagonist, exendin-3. In contrast, AIR to intravenous administration of other secretagogues was either not affected (carbachol) or significantly reduced (arginine, cholecystokinin octapeptide) in Gcgr(-/-) mice. In islets isolated from Gcgr(-/-) mice, the insulin responses to glucose and several insulin secretagogues were all significantly blunted compared with wild-type mice. Furthermore, glucose oxidation was reduced in islets from Gcgr(-/-) mice. In conclusion, the present study shows that glucagon signaling is required for normal beta-cell function and that insulin action is improved when disrupting the signal. In vivo, augmented GLP-1 levels compensate for the impaired beta-cell function in Gcgr(-/-) mice.

Published

2006

16. Pancreatic signals controlling food intake; insulin, glucagon and amylin.

Author

Woods SC, Lutz TA, Geary N, and Langhans W

Subjects

Animals, Body Weight physiology, Islet Amyloid Polypeptide, Amyloid physiology, Eating physiology, Glucagon physiology, Insulin physiology, Pancreas metabolism

Abstract

The control of food intake and body weight by the brain relies upon the detection and integration of signals reflecting energy stores and fluxes, and their interaction with many different inputs related to food palatability and gastrointestinal handling as well as social, emotional, circadian, habitual and other situational factors. This review focuses upon the role of hormones secreted by the endocrine pancreas: hormones, which individually and collectively influence food intake, with an emphasis upon insulin, glucagon and amylin. Insulin and amylin are co-secreted by B-cells and provide a signal that reflects both circulating energy in the form of glucose and stored energy in the form of visceral adipose tissue. Insulin acts directly at the liver to suppress the synthesis and secretion of glucose, and some plasma insulin is transported into the brain and especially the mediobasal hypothalamus where it elicits a net catabolic response, particularly reduced food intake and loss of body weight. Amylin reduces meal size by stimulating neurons in the hindbrain, and there is evidence that amylin additionally functions as an adiposity signal controlling body weight as well as meal size. Glucagon is secreted from A-cells and increases glucose secretion from the liver. Glucagon acts in the liver to reduce meal size, the signal being relayed to the brain via the vagus nerves. To summarize, hormones of the endocrine pancreas are collectively at the crossroads of many aspects of energy homeostasis. Glucagon and amylin act in the short term to reduce meal size, and insulin sensitizes the brain to short-term meal-generated satiety signals; and insulin and perhaps amylin as well act over longer intervals to modulate the amount of fat maintained and defended by the brain. Hormones of the endocrine pancreas interact with receptors at many points along the gut-brain axis, from the liver to the sensory vagus nerve to the hindbrain to the hypothalamus; and their signals are conveyed both neurally and humorally. Finally, their actions include gastrointestinal and metabolic as well as behavioural effects.

Published

2006

17. The physiology of amylin and insulin: maintaining the balance between glucose secretion and glucose uptake.

Author

Martin C

Subjects

Homeostasis, Humans, Islet Amyloid Polypeptide, Models, Biological, Amyloid physiology, Glucagon physiology, Glucose metabolism, Insulin physiology

Abstract

Glucose homeostasis is accomplished through intricate, and arguably, elegant interactions among several organs and hormones. Historically, glucose homeostasis has been viewed somewhat narrowly--insulin from pancreatic beta cells regulated glucose disposal, while glucagon from pancreatic alpha [corrected] cells regulated glucose appearance during fasting states. But more recent characterization and understanding of the role of incretin hormones from the gut--notably, glucagon-like peptide 1 and gastric inhibitory polypeptide--and amylin from pancreatic beta cells has led to a more complete model of glucose homeostasis. Furthermore, availability of pharmacologic agents to replace, mimic, or enhance the actions of these hormones allows application of this more complete model of glucose homeostasis to the treatment of type 1 and type 2 diabetes. This article provides an overview of the role of the pancreatic hormone amylin in glucose homeostasis and of Pramlintide, a analogue of native amylin, recently approved as adjunct therapy to insulin in people with type 1 and type 2 diabetes.

Published

2006

18. [Molecular biology of regulation in renal functions; biosynthesis, metabolism, and action of insulin and glucagon].

Author

Nakatsuka A, Wada J, and Makino H

Subjects

C-Peptide physiology, Glomerular Filtration Rate drug effects, Glucagon biosynthesis, Glucagon metabolism, Glucagon pharmacology, Humans, Insulin biosynthesis, Insulin metabolism, Insulin pharmacology, Kidney Glomerulus pathology, Kidney Tubules metabolism, Renal Circulation drug effects, Sclerosis etiology, Sodium metabolism, Glucagon physiology, Insulin physiology, Kidney physiology

Published

2006

19. [Gluco-incretin hormones in insulin secretion].

Author

Thorens B

Subjects

Animals, Diabetes Mellitus, Type 2 physiopathology, Humans, Insulin metabolism, Insulin Secretion, Islets of Langerhans metabolism, Glucagon physiology, Glucagon-Like Peptide 1 physiology, Insulin physiology

Abstract

Nutrient ingestion triggers a complex hormonal response aimed at stimulating glucose utilization in liver, muscle and adipose tissue to minimize the raise in blood glucose levels. Insulin secretion by pancreatic beta cells plays a major role in this response. Although the beta cell secretary response is mainly controlled by blood glucose levels, gut hormones secreted in response to food intake have an important role in potentiating glucose-stimulated insulin secretion. These gluco-incretin hormones are GLP-1 (glucagon-like peptide-1) and GIP (gluco-dependent insulinotropic polypeptide). Their action on pancreatic beta cells depends on binding to specific G-coupled receptors linked to activation of the adenylyl cyclase pathway. In addition to their effect on insulin secretion both hormones also stimulate insulin production at the transcriptional and translational level and positively regulate beta cell mass. Because the glucose-dependent insulinotropic action of GLP-1 is preserved in type 2 diabetic patients, this peptide is now developed as a novel therapeutic drug for this disease.

Published

2005

20. Maintenance of the postabsorptive plasma glucose concentration: insulin or insulin plus glucagon?

Author

Raju B and Cryer PE

Subjects

Animals, Dietary Carbohydrates metabolism, Dietary Fats metabolism, Humans, Hypoglycemia physiopathology, Somatostatin physiology, Blood Glucose metabolism, Glucagon physiology, Insulin physiology, Intestinal Absorption physiology, Postprandial Period physiology

Abstract

The prevalent view is that the postabsorptive plasma glucose concentration is maintained within the physiological range by the interplay of the glucose-lowering action of insulin and the glucose-raising action of glucagon. It is supported by a body of evidence derived from studies of suppression of glucagon (and insulin, among other effects) with somatostatin in animals and humans, immunoneutralization of glucagon, defective glucagon synthesis, diverse mutations, and absent or reduced glucagon receptors in animals and glucagon antagonists in cells, animals, and humans. Many of these studies are open to alternative interpretations, and some lead to seemingly contradictory conclusions. For example, immunoneutralization of glucagon lowered plasma glucose concentrations in rabbits, but administration of a glucagon antagonist did not lower plasma glucose concentrations in healthy humans. Evidence that the glycemic threshold for glucagon secretion, unlike that for insulin secretion, lies below the physiological range, and the finding that selective suppression of insulin secretion without stimulation of glucagon secretion raises fasting plasma glucose concentrations in humans underscore the primacy of insulin in the regulation of the postabsorptive plasma glucose concentration and challenge the prevalent view. The alternative view is that the postabsorptive plasma glucose concentration is maintained within the physiological range by insulin alone, specifically regulated increments and decrements in insulin, and the resulting decrements and increments in endogenous glucose production, respectively, and glucagon becomes relevant only when glucose levels drift below the physiological range. Although the balance of evidence suggests that glucagon is involved in the maintenance of euglycemia, more definitive evidence is needed, particularly in humans.

Published

2005

21. Distinct effects of glucose-dependent insulinotropic polypeptide and glucagon-like peptide-1 on insulin secretion and gut motility.

Author

Miki T, Minami K, Shinozaki H, Matsumura K, Saraya A, Ikeda H, Yamada Y, Holst JJ, and Seino S

Subjects

Animals, Arginine pharmacology, Blood Glucose physiology, Food, Glucagon-Like Peptide 1, Insulin Secretion, Islets of Langerhans drug effects, Mice, Mice, Knockout, Pancreas physiology, Potassium Channels physiology, Potassium Channels, Inwardly Rectifying physiology, Time Factors, Gastric Inhibitory Polypeptide physiology, Gastrointestinal Motility physiology, Glucagon physiology, Insulin metabolism, Islets of Langerhans metabolism, Peptide Fragments physiology, Protein Precursors physiology

Abstract

Glucose-induced insulin secretion from pancreatic beta-cells depends critically on ATP-sensitive K(+) channel (K(ATP) channel) activity, but it is not known whether K(ATP) channels are involved in the potentiation of insulin secretion by glucose-dependent insulinotropic polypeptide (GIP). In mice lacking K(ATP) channels (Kir6.2(-/-) mice), we found that pretreatment with GIP in vivo failed to blunt the rise in blood glucose levels after oral glucose load. In Kir6.2(-/-) mice, potentiation of insulin secretion by GIP in vivo was markedly attenuated, indicating that K(ATP) channels are essential in the insulinotropic effect of GIP. In contrast, pretreatment with glucagon-like peptide-1 (GLP-1) in Kir6.2(-/-) mice potentiated insulin secretion and blunted the rise in blood glucose levels. We also found that GLP-1 inhibited gut motility whereas GIP did not. Perfusion experiments of Kir6.2(-/-) mice revealed severely impaired potentiation of insulin secretion by 1 nmol/l GIP and substantial potentiation by 1 nmol/l GLP-1. Although both GIP and GLP-1 increase the intracellular cAMP concentration and potentiate insulin secretion, these results demonstrate that the GLP-1 and GIP signaling pathways involve the K(ATP) channel differently.

Published

2005

22. Loss of the decrement in intraislet insulin plausibly explains loss of the glucagon response to hypoglycemia in insulin-deficient diabetes: documentation of the intraislet insulin hypothesis in humans.

Author

Raju B and Cryer PE

Subjects

Adult, Diazoxide pharmacology, Female, Glucagon metabolism, Growth Hormone blood, Humans, Hydrocortisone blood, Hypoglycemia blood, Hypoglycemia physiopathology, Insulin metabolism, Insulin Secretion, Islets of Langerhans drug effects, Male, Signal Transduction, Glucagon physiology, Insulin physiology, Islets of Langerhans physiology

Abstract

The intraislet insulin hypothesis for the signaling of the glucagon secretory response to hypoglycemia states that a decrease in arterial glucose --> a decrease in beta-cell insulin secretion --> a decrease in tonic alpha-cell inhibition by insulin --> an increase in alpha-cell glucagon secretion. To test this hypothesis in humans, a hyperinsulinemic- euglycemic ( approximately 5.0 mmol/l [90 mg/dl] x 2 h) and then a hypoglycemic ( approximately 3.0 mmol/l [55 mg/dl] x 2 h) clamp was performed in 14 healthy young adults on two occasions, once with oral administration of the ATP-sensitive potassium channel agonist diazoxide to selectively suppress baseline insulin secretion and once with the administration of a placebo. The decrement in plasma C-peptide during the induction of hypoglycemia was reduced by approximately 50% in the diazoxide clamps (from 0.3 +/- 0.0 to 0.1 +/- 0.0 nmol/l [0.8 +/- 0.1 to 0.4 +/- 0.1 ng/ml]) compared with the placebo clamps (from 0.4 +/- 0.0 to 0.1 +/- 0.0 nmol/l [1.2 +/- 0.1 to 0.4 +/- 0.1 ng/ml]) (P = 0.0015). This reduction of the decrement in intraislet insulin during induction of hypoglycemia caused an approximately 50% reduction (P = 0.0010) of the increase in plasma glucagon in the diazoxide clamps (from 29 +/- 3 to 35 +/- 2 pmol/l [102 +/- 9 to 123 +/- 8 pg/ml]) compared with the placebo clamps (from 28 +/- 2 to 43 +/- 5 pmol/l [98 +/- 7 to 151 +/- 16 pg/ml]). Baseline glucagon levels, the glucagon response to intravenous arginine, and the autonomic (adrenomedullary, sympathetic neural, and parasympathetic neural) responses to hypoglycemia were not altered by diazoxide. These data indicate that a decrease in intraislet insulin is a signal for the glucagon secretory response to hypoglycemia in healthy humans. The absence of that signal plausibly explains the loss of the glucagon response to falling plasma glucose concentrations, a key feature of the pathogenesis of iatrogenic hypoglycemia, in insulin-deficient (type 1 and advanced type 2) diabetes.

Published

2005

23. Glucagon-like peptide-1: regulation of insulin secretion and therapeutic potential.

Author

Gromada J, Brock B, Schmitz O, and Rorsman P

Subjects

Adenosine Triphosphate metabolism, Animals, Calcium metabolism, Diabetes Mellitus, Type 2 metabolism, Dipeptidyl Peptidase 4 metabolism, Glucagon physiology, Glucagon-Like Peptide 1, Glucagon-Like Peptide-1 Receptor, Glucose metabolism, Humans, Insulin Secretion, Ion Channels antagonists & inhibitors, Ion Channels metabolism, Islets of Langerhans drug effects, Islets of Langerhans metabolism, Peptide Fragments physiology, Protein Precursors physiology, Receptors, Glucagon metabolism, Diabetes Mellitus, Type 2 drug therapy, Glucagon pharmacology, Glucagon therapeutic use, Insulin metabolism, Peptide Fragments pharmacology, Peptide Fragments therapeutic use, Protein Precursors pharmacology, Protein Precursors therapeutic use

Abstract

Glucagon-like peptide-1 (GLP-1) is an intestinally derived insulinotropic hormone currently under investigation for use as a novel therapeutic agent in the treatment of type 2 diabetes. One of several important effects of GLP-1 is on nutrient-induced pancreatic hormone release and is mediated by binding to a specific G-protein coupled receptor resulting in the activation of adenylate cyclase and an increase in cAMP generation. In the beta-cell, cAMP binds and modulates activities of both protein kinase A and cAMP-regulated guanine nucleotide exchange factor II, thereby enhancing glucose-dependent insulin secretion. The stimulatory action of GLP-1 on insulin secretion involves interaction with a plethora of signal transduction processes including ion channel activity, intracellular Ca(2+) handling and exocytosis of the insulin-containing granules. In this review we focus principally on recent advances in our understanding on the cellular mechanisms proposed to underlie GLP-1's insulinotropic effect and attempt to incorporate this knowledge into a working model for the control of insulin secretion. Lastly, this review discusses the applicability of GLP-1 as a therapeutic agent for the treatment of type 2 diabetes.

Published

2004

24. Incretin hormones and insulin secretion.

Author

Ahrén B, Gromada J, and Schmitz O

Subjects

Diabetes Mellitus metabolism, Gastric Inhibitory Polypeptide agonists, Gastric Inhibitory Polypeptide antagonists & inhibitors, Glucagon agonists, Glucagon antagonists & inhibitors, Glucagon-Like Peptide 1, Humans, Insulin Secretion, Peptide Fragments agonists, Peptide Fragments antagonists & inhibitors, Protein Precursors agonists, Protein Precursors antagonists & inhibitors, Diabetes Mellitus drug therapy, Gastric Inhibitory Polypeptide physiology, Glucagon physiology, Insulin metabolism, Peptide Fragments physiology, Protein Precursors physiology

Published

2004

25. Interplay of glucagon-like peptide-1 and transforming growth factor-beta signaling in insulin-positive differentiation of AR42J cells.

Author

Yew KH, Prasadan KL, Preuett BL, Hembree MJ, McFall CR, Benjes CL, Crowley AR, Sharp SL, Li Z, Tulachan SS, Mehta SS, and Gittes GK

Subjects

Animals, Cell Differentiation drug effects, Cell Line, DNA Primers, Equidae, Exenatide, Glucagon-Like Peptide 1, Oligonucleotides, Antisense pharmacology, Peptides pharmacology, Polymerase Chain Reaction, Venoms pharmacology, Cell Differentiation physiology, Glucagon physiology, Insulin pharmacology, Peptide Fragments physiology, Protein Precursors physiology, Signal Transduction drug effects, Transforming Growth Factor beta physiology

Abstract

The differentiation of pancreatic exocrine AR42J cells into insulin-expressing endocrine cells has served as an important model for both endogenous in vivo beta-cell differentiation as well as potential application to beta-cell engineering of progenitor cells. Exogenous activin, possibly working through intracellular smad 2 and/or smad 3, as well as exogenous exendin-4 (a long-acting glucagon-like peptide-1 agonist) have both been shown to induce insulin-positive/endocrine differentiation in AR42J cells. In this study, we present evidence of significant interplay and interdependence of these two pathways as well as potential synergy between the pathways. In particular, insulin-positive differentiation seems to entail an exendin-4-induced drop in smad 2 and elevation in smad 3 in RNA levels. The latter appears to be dependent on endogenous transforming growth factor (TGF)-beta isoform release by the AR42J cells and may serve as a mechanism to promote beta-cell maturation. The drop in smad 2 may mediate early endocrine commitment. The coapplication of exogenous exendin-4 and, specifically, low-dose exogenous TGF-beta1 led to a dramatic 20-fold increase in insulin mRNA levels, supporting a novel synergistic and codependent relationship between exendin-4 signaling and TGF-beta isoform signaling.

Published

2004

26. New insights concerning the glucose-dependent insulin secretagogue action of glucagon-like peptide-1 in pancreatic beta-cells.

Author

Holz GG

Subjects

Animals, Calcium metabolism, Cyclic AMP-Dependent Protein Kinases metabolism, Glucagon-Like Peptide 1, Guanine Nucleotide Exchange Factors metabolism, Humans, Insulin Secretion, Mitochondria metabolism, Potassium Channels metabolism, Glucagon physiology, Insulin metabolism, Islets of Langerhans metabolism, Peptide Fragments physiology, Protein Precursors physiology, Receptors, Glucagon physiology

Abstract

The GLP-1 receptor is a Class B heptahelical G-protein-coupled receptor that stimulates cAMP production in pancreatic beta-cells. GLP-1 utilizes this receptor to activate two distinct classes of cAMP-binding proteins: protein kinase A (PKA) and the Epac family of cAMP-regulated guanine nucleotide exchange factors (cAMPGEFs). Actions of GLP-1 mediated by PKA and Epac include the recruitment and priming of secretory granules, thereby increasing the number of granules available for Ca(2+)-dependent exocytosis. Simultaneously, GLP-1 promotes Ca(2+) influx and mobilizes an intracellular source of Ca(2+). GLP-1 sensitizes intracellular Ca(2+) release channels (ryanodine and IP (3) receptors) to stimulatory effects of Ca(2+), thereby promoting Ca(2+)-induced Ca(2+) release (CICR). In the model presented here, CICR activates mitochondrial dehydrogenases, thereby upregulating glucose-dependent production of ATP. The resultant increase in cytosolic [ATP]/[ADP] concentration ratio leads to closure of ATP-sensitive K(+) channels (K-ATP), membrane depolarization, and influx of Ca(2+) through voltage-dependent Ca(2+) channels (VDCCs). Ca(2+) influx stimulates exocytosis of secretory granules by promoting their fusion with the plasma membrane. Under conditions where Ca(2+) release channels are sensitized by GLP-1, Ca(2+) influx also stimulates CICR, generating an additional round of ATP production and K-ATP channel closure. In the absence of glucose, no "fuel" is available to support ATP production, and GLP-1 fails to stimulate insulin secretion. This new "feed-forward" hypothesis of beta-cell stimulus-secretion coupling may provide a mechanistic explanation as to how GLP-1 exerts a beneficial blood glucose-lowering effect in type 2 diabetic subjects.

Published

2004

27. The role of insulin, glucagon, dexamethasone, and leptin in the regulation of ketogenesis and glycogen storage in primary cultures of porcine hepatocytes prepared from 60 kg pigs.

Author

Fernández-Fígares I, Shannon AE, Wray-Cahen D, and Caperna TJ

Subjects

Animals, Body Weight, Carnitine administration & dosage, Cells, Cultured, Culture Media, Serum-Free, Dexamethasone administration & dosage, Glucagon administration & dosage, Glucocorticoids administration & dosage, Glucocorticoids physiology, Hepatocytes drug effects, Humans, Insulin administration & dosage, Leptin administration & dosage, Leptin physiology, Linoleic Acid administration & dosage, Recombinant Proteins administration & dosage, Glucagon physiology, Glycogen metabolism, Hepatocytes metabolism, Insulin physiology, Ketone Bodies biosynthesis, Swine

Abstract

A study was conducted to elucidate hormonal control of ketogenesis and glycogen deposition in primary cultures of porcine hepatocytes. Hepatocytes were isolated from pigs (54-68 kg) by collagenase perfusion and seeded into collagen-coated T-25 flasks. Monolayers were established in medium containing fetal bovine serum for 1 day and switched to a serum-free medium for the remainder of the culture period. Hepatocytes were maintained in DMEM/M199 containing 1% DMSO, dexamethasone (10(-6) or 10(-7) M), linoleic acid (3.4 x 10(-5) M), and carnitine (10(-3) M) for 3 days. On the first day of serum-free culture, insulin was added at 1 or 100 ng/ml and glucagon was added at 0, 1, or 100 ng/ml. Recombinant human leptin (200 ng/ml) was added during the final 24 h; medium and all cells were harvested on the third day. Concentrations of acetoacetate and beta-hydroxybutyrate (ketone bodies) in media and glycogen deposition in the cellular compartment were determined. Ketogenesis was highly stimulated by glucagon (1 and 100 ng/ml) and inhibited by insulin. In contrast, glycogen deposition was stimulated by insulin and attenuated by glucagon; high insulin was also associated with a reduction in the ketone body ratio (acetoacetate:beta-hydroxybutyrate). High levels of dexamethasone stimulated ketogenesis, but inhibited glycogen deposition at low insulin. Culture of cells with leptin for 24 h, over the range of insulin, glucagon, and dexamethasone concentrations had no effect on either glycogen deposition or ketogenesis. These data suggest that while adult porcine hepatocytes are indeed sensitive to hormonal manipulation, leptin has no direct influence on hepatic energy metabolism in swine.

Published

2004

28. The enteroinsular axis and the recovery from type 2 diabetes after bariatric surgery.

Author

Patriti A, Facchiano E, Sanna A, Gullà N, and Donini A

Subjects

Down-Regulation physiology, Gastric Inhibitory Polypeptide metabolism, Glucagon metabolism, Glucagon-Like Peptide 1, Humans, Ileum physiopathology, Insulin Resistance physiology, Obesity, Morbid physiopathology, Obesity, Morbid surgery, Pancreas physiopathology, Peptide Fragments metabolism, Postprandial Period physiology, Protein Precursors metabolism, Blood Glucose metabolism, Diabetes Mellitus physiopathology, Diabetes Mellitus surgery, Diabetes Mellitus, Type 2 physiopathology, Gastric Bypass, Gastric Inhibitory Polypeptide physiology, Glucagon physiology, Insulin blood, Obesity, Peptide Fragments physiology, Protein Precursors physiology

Abstract

The Roux-en-Y gastric bypass (RYGBP) and the biliopancreatic diversion (BPD) induce long-term control of type 2 diabetes in morbidly obese individuals. The reasons for such an effect on glycemic metabolism are thought to be secondary to reduced food intake, weight loss and modifications of the enteroinsular axis which is impaired in type 2 diabetic patients. Both GLP-1 and GIP have an impaired secretin effect in type 2 diabetics, and surgery can restore this function. GIP is a peptide secreted by the duodenal K-cells in response to ingested fat and carbohydrate. In obese type 2 diabetes patients, its receptor on beta-cells is down-regulated. GLP-1 is a peptide secreted by the gut L-cells, and, in type 2 diabetes, its secretion is impaired. Both RYGBP and BPD provide durable GLP-1 delivery, both during fasting and after meal ingestion, inducing L-cell stimulation by early arrival of nutrients in the distal ileum. The secretion of GLP-1 influences glucose metabolism by inhibiting glucagon secretion, stimulating insulin secretion, delaying gastric emptying and stimulating glycogenogenesis. In conclusion, the early arrival of a meal in the terminal ileum seems to be the common feature of both operations that leads to an improvement in glycemic metabolism and to resolution of type 2 diabetes.

Published

2004

29. Restitution of defective glucose-stimulated insulin release of sulfonylurea type 1 receptor knockout mice by acetylcholine.

Author

Doliba NM, Qin W, Vatamaniuk MZ, Li C, Zelent D, Najafi H, Buettger CW, Collins HW, Carr RD, Magnuson MA, and Matschinsky FM

Subjects

1-Methyl-3-isobutylxanthine pharmacology, Animals, Calcium metabolism, Glucagon physiology, Glucagon-Like Peptide 1, In Vitro Techniques, Insulin metabolism, Insulin Secretion, Intracellular Fluid metabolism, Islets of Langerhans drug effects, Membrane Potentials physiology, Mice, Mice, Inbred Strains, Mice, Knockout, Multidrug Resistance-Associated Proteins deficiency, Peptide Fragments physiology, Phosphodiesterase Inhibitors pharmacology, Potassium Channels, Inwardly Rectifying, Protein Precursors physiology, Receptors, Drug, Second Messenger Systems physiology, Signal Transduction physiology, Sulfonylurea Receptors, ATP-Binding Cassette Transporters, Acetylcholine physiology, Blood Glucose metabolism, Insulin physiology, Islets of Langerhans metabolism, Multidrug Resistance-Associated Proteins physiology

Abstract

Inhibition of ATP-sensitive K+ (K(ATP)) channels by an increase in the ATP/ADP ratio and the resultant membrane depolarization are considered essential in the process leading to insulin release (IR) from pancreatic beta-cells stimulated by glucose. It is therefore surprising that mice lacking the sulfonylurea type 1 receptor (SUR1-/-) in beta-cells remain euglycemic even though the knockout is expected to cause hypoglycemia. To complicate matters, isolated islets of SUR1-/- mice secrete little insulin in response to high glucose, which extrapolates to hyperglycemia in the intact animal. It remains thus unexplained how euglycemia is maintained. In recognition of the essential role of neural and endocrine regulation of IR, we evaluated the effects of acetylcholine (ACh) and glucagon-like peptide-1 (GLP-1) on IR and free intracellular Ca2+ concentration ([Ca2+]i) of freshly isolated or cultured islets of SUR1-/- mice and B6D2F1 controls (SUR1+/+). IBMX, a phosphodiesterase inhibitor, was also used to explore cAMP-dependent signaling in IR. Most striking, and in contrast to controls, SUR1-/-) islets are hypersensitive to ACh and IBMX, as demonstrated by a marked increase of IR even in the absence of glucose. The hypersensitivity to ACh was reproduced in control islets by depolarization with the SUR1 inhibitor glyburide. Pretreatment of perifused SUR1-/- islets with ACh or IBMX restored glucose stimulation of IR, an effect expectedly insensitive to diazoxide. The calcium channel blocker verapamil reduced but did not abolish ACh-stimulated IR, supporting a role for intracellular Ca2+ stores in stimulus-secretion coupling. The effect of ACh on IR was greatly potentiated by GLP-1 (10 nM). ACh caused a dose-dependent increase in [Ca2+]i at 0.1-1 microM or biphasic changes (an initial sharp increase in [Ca2+]i followed by a sustained phase of low [Ca2+]i) at 1-100 microM. The latter effects were observed in substrate-free medium or in the presence of 16.7 mM glucose. We conclude that SUR1 deletion depolarizes the beta-cells and markedly elevates basal [Ca2+]i. Elevated [Ca2+]i in turn sensitizes the beta-cells to the secretory effects of ACh and IBMX. Priming by the combination of high [Ca2+]i, ACh, and GLP-1 restores the defective glucose responsiveness, precluding the development of diabetes but not effectively enough to cause hyperinsulinemic hypoglycemia.

Published

2004

30. Incretins, insulin secretion and Type 2 diabetes mellitus.

Author

Vilsbøll T and Holst JJ

Subjects

Animals, Diabetes Mellitus, Type 2 blood, Glucagon-Like Peptide 1, Humans, Insulin Secretion, Diabetes Mellitus, Type 2 physiopathology, Gastric Inhibitory Polypeptide physiology, Glucagon physiology, Insulin metabolism, Peptide Fragments physiology, Protein Precursors physiology

Abstract

When glucose is taken orally, insulin secretion is stimulated much more than it is when glucose is infused intravenously so as to result in similar glucose concentrations. This effect, which is called the incretin effect and is estimated to be responsible for 50 to 70% of the insulin response to glucose, is caused mainly by the two intestinal insulin-stimulating hormones, glucagon-like peptide-1 (GLP-1) and glucose-dependent insulinotropic polypeptide (GIP). Their contributions have been confirmed in mimicry experiments, in experiments with antagonists of their actions, and in experiments where the genes encoding their receptors have been deleted. In patients with Type 2 diabetes, the incretin effect is either greatly impaired or absent, and it is assumed that this could contribute to the inability of these patients to adjust their insulin secretion to their needs. In studies of the mechanism of the impaired incretin effect in Type 2 diabetic patients, it has been found that the secretion of GIP is generally normal, whereas the secretion of GLP-1 is reduced, presumably as a consequence of the diabetic state. It might be of even greater importance that the effect of GLP-1 is preserved whereas the effect of GIP is severely impaired. The impaired GIP effect seems to have a genetic background, but could be aggravated by the diabetic state. The preserved effect of GLP-1 has inspired attempts to treat Type 2 diabetes with GLP-1 or analogues thereof, and intravenous GLP-1 administration has been shown to be able to near-normalize both fasting and postprandial glycaemic concentrations in the patients, perhaps because the treatment compensates for both the impaired secretion of GLP-1 and the impaired action of GIP. Several GLP-1 analogues are currently in clinical development and the reported results are, so far, encouraging.

Published

2004

31. Novel strategies for the pharmacological management of type 2 diabetes.

Author

Nourparvar A, Bulotta A, Di Mario U, and Perfetti R

Subjects

Glucagon physiology, Glucagon therapeutic use, Glucagon-Like Peptide 1, Humans, Peptide Fragments physiology, Peptide Fragments therapeutic use, Protein Precursors physiology, Protein Precursors therapeutic use, Diabetes Mellitus, Type 2 drug therapy, Hypoglycemic Agents therapeutic use, Insulin therapeutic use, Receptors, Cytoplasmic and Nuclear agonists, Sulfonylurea Compounds therapeutic use, Transcription Factors agonists

Abstract

Type 2 diabetes is characterized by high concentrations of glucose in the blood, which is caused by decreased secretion of insulin from the pancreas and decreased insulin action. This condition is prevalent worldwide and is associated with morbidity and mortality secondary to complications such as myocardial infarction, stroke and end-stage renal disease. The importance of tight control of blood glucose in either preventing or delaying the progression of complications is recognized. Currently, there are many therapeutic options to treat hyperglycemia in type 2 diabetes. However, tight control is difficult to achieve and is often associated with side-effects. Recent advances in understanding insulin secretion, action and signaling have led to the development of new pharmacological agents. In this article, we review new molecules that are promising candidates for the future management of diabetes, focusing on their mechanism of action, efficacy, safety profile and potential benefits compared with pharmacological agents that are available currently.

Published

2004

32. Gastro-intestinal hormones GIP and GLP-1.

Author

Kieffer TJ

Subjects

Animals, Diabetes Mellitus physiopathology, Dipeptidyl Peptidase 4 metabolism, Gastric Inhibitory Polypeptide metabolism, Glucagon metabolism, Glucagon-Like Peptide 1, Homeostasis, Humans, Insulin metabolism, Insulin Secretion, Digestive System Physiological Phenomena, Gastric Inhibitory Polypeptide physiology, Glucagon physiology, Glucose physiology, Insulin physiology, Peptide Fragments physiology, Protein Precursors physiology

Published

2004

33. [GIP and GLP-1: multiplicity of regulator mechanisms for insulin secretion].

Author

Thorens B

Subjects

Animals, Cell Differentiation, Diabetes Mellitus, Type 2 drug therapy, Gene Expression Regulation, Glucagon therapeutic use, Glucagon-Like Peptide 1, Glucagon-Like Peptide-1 Receptor, Glucose pharmacology, Humans, Insulin Secretion, Islets of Langerhans physiology, Mice, Mice, Knockout, Peptide Fragments therapeutic use, Protein Precursors therapeutic use, Receptors, Gastrointestinal Hormone deficiency, Receptors, Gastrointestinal Hormone physiology, Receptors, Glucagon deficiency, Receptors, Glucagon physiology, Signal Transduction, Gastric Inhibitory Polypeptide physiology, Glucagon physiology, Insulin metabolism, Peptide Fragments physiology, Protein Precursors physiology

Published

2004

34. Insulin and glucagon signaling in regulation of microsomal epoxide hydrolase expression in primary cultured rat hepatocytes.

Author

Kim SK, Woodcroft KJ, Kim SG, and Novak RF

Subjects

Animals, Cells, Cultured, Dose-Response Relationship, Drug, Enzyme Inhibitors pharmacology, Epoxide Hydrolases genetics, Gene Expression Regulation, Enzymologic physiology, Hepatocytes drug effects, Hepatocytes physiology, Male, Microsomes, Liver drug effects, Microsomes, Liver physiology, Rats, Rats, Sprague-Dawley, Signal Transduction drug effects, Epoxide Hydrolases biosynthesis, Gene Expression Regulation, Enzymologic drug effects, Glucagon physiology, Hepatocytes enzymology, Insulin physiology, Microsomes, Liver enzymology, Signal Transduction physiology

Abstract

Microsomal epoxide hydrolase (mEH) plays an important role in the detoxification of a broad range of epoxide intermediates and has been reported to be decreased during diabetes and fasting. The signaling pathways involved in the regulation of mEH expression in response to insulin and glucagon were examined in primary cultured rat hepatocytes. mEH protein levels were increased 2- to 6-fold in hepatocytes cultured for 1 to 4 days, respectively, in the presence of insulin. Concentration-response studies revealed that insulin concentrations >or=1 nM resulted in increased mEH protein levels. The phosphatidylinositol 3-kinase (PI3K) inhibitors wortmannin or LY294002 [2-(4-morpholinyl)-8-phenyl-4H-1-benzopyran-4-one], and rapamycin, an inhibitor of p70 S6 kinase phosphorylation, ameliorated the insulin-mediated increase in mEH protein levels. The p38 mitogen-activated protein (MAP) kinase inhibitors SB203580 and SB202190 also abrogated the insulin-mediated increase in mEH protein. Treatment of cells with glucagon, 8-bromo-cAMP, or dibutyryl-cAMP for 3 days resulted in decreased mEH protein levels. Pretreatment with the protein kinase A (PKA) inhibitor H89 (N-[2-(4-bromocinnamylamino)ethyl]-5-isoquinoline) prior to glucagon addition markedly attenuated the glucagon effect, implicating PKA signaling in the regulation of mEH expression. These data demonstrate that insulin and glucagon regulate, in an opposing manner, the expression of mEH in primary cultured rat hepatocytes. Furthermore, these data suggest that PI3K and p70 S6 kinase are active in the regulation of insulin-mediated mEH expression. We also provide data implicating p38 MAP kinase in the insulin-mediated increase in mEH levels. Moreover, cAMP and PKA are implicated in mediating the inhibitory effect of glucagon on mEH expression.

Published

2003

35. [Gluco-incretin hormones in insulin secretion and diabetes].

Author

Thorens B

Subjects

Animals, Gastric Inhibitory Polypeptide pharmacology, Gastric Inhibitory Polypeptide physiology, Glucagon pharmacology, Glucagon physiology, Glucagon-Like Peptide 1, Glucagon-Like Peptides, Humans, Insulin Secretion, Islets of Langerhans physiopathology, Mice, Peptide Fragments pharmacology, Protein Precursors pharmacology, Protein Precursors physiology, Rats, Diabetes Mellitus physiopathology, Insulin metabolism, Peptide Fragments physiology

Abstract

Nutrient ingestion triggers a complex hormonal response aimed at stimulating glucose utilization in liver, muscle and adipose tissue to minimize the raise in blood glucose levels. Insulin secretion by pancreatic beta cells plays a major role in this response. Although the beta cell secretory response is mainly controlled by blood glucose levels, gut hormones secreted in response to food intake have an important role in potentiating glucose-stimulated insulin secretion. These gluco-incretin hormones are GLP-1 (glucagon-like peptide-1) and GIP (gluco-dependent insulinotropic polypeptide). Their action on pancreatic beta cells depends on binding to specific G-coupled receptors linked to activation of the adenylyl cyclase pathway. In addition to their effect on insulin secretion both hormones also stimulate insulin production at the transcriptional and translational level and positively regulate beta cell mass. Because the glucose-dependent insulinotropic action of GLP-1 is preserved in type 2 diabetic patients, this peptide is now developed as a novel therapeutic drug for this disease.

Published

2003

36. Both GLP-1 and GIP are insulinotropic at basal and postprandial glucose levels and contribute nearly equally to the incretin effect of a meal in healthy subjects.

Author

Vilsbøll T, Krarup T, Madsbad S, and Holst JJ

Subjects

Adult, C-Peptide blood, Gastric Inhibitory Polypeptide administration & dosage, Glucagon administration & dosage, Glucagon blood, Glucagon-Like Peptide 1, Glucose administration & dosage, Humans, Insulin blood, Insulin Secretion, Male, Peptide Fragments administration & dosage, Protein Precursors administration & dosage, Reference Values, Blood Glucose metabolism, Gastric Inhibitory Polypeptide physiology, Glucagon physiology, Insulin metabolism, Peptide Fragments physiology, Postprandial Period, Protein Precursors physiology

Abstract

Glucagon-like peptide-1 (GLP-1) and glucose-dependent insulinotropic polypeptide (GIP) are both incretin hormones regulating postprandial insulin secretion. Their relative importance in this respect under normal physiological conditions is unclear, however, and the aim of the present investigation was to evaluate this. Eight healthy male volunteers (mean age: 23 (range 20-25) years; mean body mass index: 22.2 (range 19.3-25.4) kg/m2) participated in studies involving stepwise glucose clamping at fasting plasma glucose levels and at 6 and 7 mmol/l. Physiological amounts of either GIP (1.5 pmol/kg/min), GLP-1(7-36)amide (0.33 pmol/kg/min) or saline were infused for three periods of 30 min at each glucose level, with 1 h "washout" between the infusions. On a separate day, a standard meal test (566 kcal) was performed. During the meal test, peak insulin concentrations were observed after 30 min and amounted to 223+/-27 pmol/l. Glucose+saline infusions induced only minor increases in insulin concentrations. GLP-1 and GIP infusions induced significant and similar increases at fasting glucose levels and at 6 mmol/l. At 7 mmol/l, further increases were seen, with GLP-1 effects exceeding those of GIP. Insulin concentrations at the end of the three infusion periods (60, 150 and 240 min) during the GIP clamp amounted to 53+/-5, 79+/-8 and 113+/-15 pmol/l, respectively. Corresponding results were 47+/-7, 95+/-10 and 171+/-21 pmol/l, respectively, during the GLP-1 clamp. C-peptide responses were similar. Total and intact incretin hormone concentrations during the clamp studies were higher compared to the meal test, but within physiological limits. Glucose infusion alone significantly inhibited glucagon secretion, which was further inhibited by GLP-1 but not by GIP infusion. We conclude that during normal physiological plasma glucose levels, glucagon-like peptide-1 and glucose-dependent insulinotropic polypeptide contribute nearly equally to the incretin effect in humans, because their differences in concentration and potency outweigh each other.

Published

2003

37. Enteroinsular signaling: perspectives on the role of the gastrointestinal hormones glucagon-like peptide 1 and glucose-dependent insulinotropic polypeptide in normal and abnormal glucose metabolism.

Author

Vahl T and D'Alessio D

Subjects

Gastric Inhibitory Polypeptide metabolism, Glucagon metabolism, Glucagon-Like Peptide 1, Humans, Insulin Secretion, Islets of Langerhans growth & development, Peptide Fragments metabolism, Protein Precursors metabolism, Secretory Rate physiology, Signal Transduction physiology, Diabetes Mellitus, Type 2 metabolism, Gastric Inhibitory Polypeptide physiology, Glucagon physiology, Glucose metabolism, Insulin metabolism, Peptide Fragments physiology, Protein Precursors physiology

Abstract

Purpose of Review: The gastrointestinal hormones glucagon-like peptide 1 and glucose-dependent insulinotropic polypeptide are emerging as essential regulators of insulin secretion and glucose homeostasis. These peptides, termed incretins, are the key intermediaries in a system that links the absorption of nutrients in the gut with important metabolic processes in substrate assimilation. New findings indicate that the enteroinsular system mediated by the incretins is relevant to both the pathophysiology and treatment of diabetes., Recent Findings: Important advances have been made in the understanding of mechanisms fundamental to incretin function such as their release from the intestine during meals, their actions on beta-cell secretion, and extrapancreatic effects. In addition, the regulation of islet growth by glucagon-like peptide 1 and glucose-dependent insulinotropic polypeptide is a novel area with considerable support from recent studies. Abnormalities of incretin function are present in patients with diabetes and current research has implicated specific defects of both glucagon-like peptide 1 and glucose-dependent insulinotropic polypeptide action in diabetes. Finally, several pharmacological applications of the incretin signaling pathways are under active investigation for the treatment of diabetes., Summary: With the intensified research of the last several years the physiologic importance of the incretins has been clarified. Enteroinsular signaling is an essential component of the metabolic processes that govern carbohydrate, and likely other nutrient metabolism. As a pathophysiology of the incretins emerges, glucagon-like peptide 1 and glucose-dependent insulinotropic polypeptide will have increasing clinical relevance. This is currently exemplified by the development of therapeutics for diabetes that work through the incretin signaling pathways.

Published

2003

38. The influence of GLP-1 on glucose-stimulated insulin secretion: effects on beta-cell sensitivity in type 2 and nondiabetic subjects.

Author

Kjems LL, Holst JJ, Vølund A, and Madsbad S

Subjects

Area Under Curve, Blood Glucose drug effects, C-Peptide blood, Diabetes Mellitus, Type 2 blood, Female, Glucagon administration & dosage, Glucagon physiology, Glucagon-Like Peptide 1, Glucose Clamp Technique, Humans, Infusions, Intravenous, Insulin Secretion, Islets of Langerhans drug effects, Kinetics, Male, Peptide Fragments administration & dosage, Peptide Fragments physiology, Protein Precursors administration & dosage, Protein Precursors physiology, Reference Values, Blood Glucose metabolism, Diabetes Mellitus, Type 2 physiopathology, Glucagon pharmacology, Insulin metabolism, Islets of Langerhans metabolism, Peptide Fragments pharmacology, Protein Precursors pharmacology

Abstract

The intestinally derived hormone glucagon-like peptide 1 (GLP-1) (7-36 amide) has potent effects on glucose-mediated insulin secretion, insulin gene expression, and beta-cell growth and differentiation. It is, therefore, considered a potential therapeutic agent for the treatment of type 2 diabetes. However, the dose-response relationship between GLP-1 and basal and glucose-stimulated prehepatic insulin secretion rate (ISR) is currently not known. Seven patients with type 2 diabetes and seven matched nondiabetic control subjects were studied. ISR was determined during a graded glucose infusion of 2, 4, 6, 8, and 12 mg x kg(-1) x min(-1) over 150 min on four occasions with infusion of saline or GLP-1 at 0.5, 1.0, and 2.0 pmol x kg(-1) x min(-1). GLP-1 enhanced ISR in a dose-dependent manner during the graded glucose infusion from 332 +/- 51 to 975 +/- 198 pmol/kg in the patients with type 2 diabetes and from 711 +/- 123 to 2,415 +/- 243 pmol/kg in the control subjects. The beta-cell responsiveness to glucose, expressed as the slope of the linear relation between ISR and the glucose concentration, increased in proportion to the GLP-1 dose to 6 times relative to saline at the highest GLP-1 dose in the patients and 11 times in the control subjects, but it was 3 to 5 times lower in the patients with type 2 diabetes compared with healthy subjects at the same GLP-1 dose. During infusion of GLP-1 at 0.5 pmol x kg(-1) x min(-1) in the patients, the slope of ISR versus glucose became indistinguishable from that of the control subjects without GLP-1. Our results show that GLP-1 increases insulin secretion in patients with type 2 diabetes and control subjects in a dose-dependent manner and that the beta-cell responsiveness to glucose may be increased to normal levels with a low dose of GLP-1 infusion. Nevertheless, the results also indicate that the dose-response relation between beta-cell responsiveness to glucose and GLP-1 is severely impaired in patients with type 2 diabetes.

Published

2003

39. The multiple actions of GLP-1 on the process of glucose-stimulated insulin secretion.

Author

MacDonald PE, El-Kholy W, Riedel MJ, Salapatek AM, Light PE, and Wheeler MB

Subjects

Animals, Glucagon-Like Peptide 1, Humans, Insulin Secretion, Pancreas metabolism, Glucagon physiology, Glucose physiology, Insulin metabolism, Peptide Fragments physiology, Protein Precursors physiology

Abstract

The physiological effects of glucagon-like peptide-1 (GLP-1) are of immense interest because of the potential clinical relevance of this peptide. Produced in intestinal L-cells through posttranslational processing of the proglucagon gene, GLP-1 is released from the gut in response to nutrient ingestion. Peripherally, GLP-1 is known to affect gut motility, inhibit gastric acid secretion, and inhibit glucagon secretion. In the central nervous system, GLP-1 induces satiety, leading to reduced weight gain. In the pancreas, GLP-1 is now known to induce expansion of insulin-secreting beta-cell mass, in addition to its most well-characterized effect: the augmentation of glucose-stimulated insulin secretion. GLP-1 is believed to enhance insulin secretion through mechanisms involving the regulation of ion channels (including ATP-sensitive K(+) channels, voltage-dependent Ca(2+) channels, voltage-dependent K(+) channels, and nonselective cation channels) and by the regulation of intracellular energy homeostasis and exocytosis. The present article will focus principally on the mechanisms proposed to underlie the glucose dependence of GLP-1's insulinotropic effect.

Published

2002

40. [Role of glucagon-like peptide 1 (GLP-1) in regulation of insulin secretion].

Author

Radosavljević T, Todorović V, and Sikić B

Subjects

Diabetes Mellitus physiopathology, Glucagon-Like Peptide 1, Humans, Insulin Secretion, Glucagon physiology, Insulin metabolism, Peptide Fragments physiology, Protein Precursors physiology

Published

2002

41. Transfection of pancreatic-derived beta-cells with a minigene encoding for human glucagon-like peptide-1 regulates glucose-dependent insulin synthesis and secretion.

Author

Hui H, Yu R, Bousquet C, and Perfetti R

Subjects

Animals, Blotting, Northern, Blotting, Western, Cyclic AMP pharmacology, Cytomegalovirus genetics, Fluorescent Antibody Technique, Glucagon metabolism, Glucagon physiology, Glucagon-Like Peptide 1, Glucose pharmacology, Humans, Insulin genetics, Insulin Secretion, Insulinoma, Islets of Langerhans drug effects, Mice, Microscopy, Fluorescence, Pancreatic Neoplasms, Peptide Fragments metabolism, Peptide Fragments physiology, Proglucagon, Promoter Regions, Genetic, Protein Precursors metabolism, Protein Precursors physiology, RNA, Messenger analysis, Signal Transduction, Tumor Cells, Cultured, Glucagon genetics, Insulin biosynthesis, Insulin metabolism, Islets of Langerhans metabolism, Peptide Fragments genetics, Protein Precursors genetics, Transfection

Abstract

Glucagon-like peptide-1 (GLP-1) is an incretin hormone derived from the proglucagon gene, capable of regulating the transcription of the three major genes that determine the pancreatic beta-cell-specific phenotype: insulin, GLUT-2, and glucokinase. The aim of this study was to investigate the potential role of GLP-1 for the gene therapy of glucose-insensitive pancreatic beta-cells. We transfected mouse insulinoma cells with a DNA fragment of the human proglucagon gene containing the nucleotide sequence encoding for human GLP-1 but lacking the coding region for glucagon. Two constructs were generated: In one, the expression of GLP-1 was under the control of the cytomegalovirus (CMV) promoter (CMV/GLP-1), and the second was regulated by the rat insulin II promoter (RIP)/GLP-1). Northern blot, HPLC, and RIA analyses confirmed that the minigene was transcribed and the protein appropriately translated, processed, and secreted in the extracellular environment. Gene expression studies revealed that although CMV/GLP-1 cells did not gain a greater glucose sensitivity as a result of the transfection with GLP-1, compared with cells transfected with the plasmid alone, RIP/GLP-1 was capable of regulating the gene expression of insulin and GLP-1 based on the concentration of glucose in the culture medium. Detection of the counterpart proteins (insulin and GLP-1) in the culture medium paralleled the observation derived from the Northern blot analysis. GLP-1 action was mediated by an IDX-1 (islet/duodenum homeobox-1) dependent transactivation of the endogenous insulin promoter, as demonstrated by gel shift analysis. This was further suggested by a significant increase of the glucose-dependent binding of IDX-1 to the insulin promoter in RIP/GLP-1 cells but not in CMV/GLP-1 cells or control cells. Finally, we observed that although the GLP-1-dependent secretion of insulin was mediated by an increase in cAMP levels, the transcription of the insulin gene, in response to GLP-1, was in large part cAMP independent. The present study lays the research foundation to investigate the potential use of GLP-1 for the gene or cell therapy of diabetes.

Published

2002

42. Critical role of cAMP-GEFII--Rim2 complex in incretin-potentiated insulin secretion.

Author

Kashima Y, Miki T, Shibasaki T, Ozaki N, Miyazaki M, Yano H, and Seino S

Subjects

Animals, Base Sequence, Cyclic AMP biosynthesis, Cyclic AMP-Dependent Protein Kinases metabolism, DNA Primers, Gastric Inhibitory Polypeptide physiology, Glucagon physiology, Glucagon-Like Peptide 1, Glucagon-Like Peptides, Imines pharmacology, Insulin Secretion, Islets of Langerhans drug effects, Islets of Langerhans metabolism, Mice, Protein Precursors physiology, Carrier Proteins metabolism, Cyclic AMP metabolism, GTP-Binding Proteins, Guanine Nucleotide Exchange Factors metabolism, Insulin metabolism, Nerve Tissue Proteins, Nuclear Proteins metabolism, Peptide Fragments physiology

Abstract

Incretins such as glucagon-like peptide-1 and gastric inhibitory polypeptide/glucose-dependent insulinotropic peptide are known to potentiate insulin secretion mainly through a cAMP/protein kinase A (PKA) signaling pathway in pancreatic beta-cells, but the mechanism is not clear. We recently found that the cAMP-binding protein cAMP-GEFII (or Epac 2), interacting with Rim2, a target of the small G protein Rab3, mediates cAMP-dependent, PKA-independent exocytosis in a reconstituted system. In the present study, we investigated the role of the cAMP-GEFII--Rim2 pathway in incretin-potentiated insulin secretion in native pancreatic beta-cells. Treatment of pancreatic islets with antisense oligodeoxynucleotides (ODNs) against cAMP-GEFII alone or with the PKA inhibitor H-89 alone inhibited incretin-potentiated insulin secretion approximately 50%, while a combination of antisense ODNs and H-89 inhibited the secretion approximately 80-90%. The effect of cAMP-GEFII on insulin secretion is mediated by Rim2 and depends on intracellular calcium as well as on cAMP. Treatment of the islets with antisense ODNs attenuated both the first and second phases of insulin secretion potentiated by the cAMP analog 8-bromo-cAMP. These results indicate that the PKA-independent mechanism involving the cAMP-GEFII--Rim2 pathway is critical in the potentiation of insulin secretion by incretins.

Published

2001

43. Diabetogenic role of insulin's counterregulatory hormones in the isletectomized, diabetic goby.

Author

Haigwood JT, Flores RM, Mazloumi R, Ngan G, and Kelley KM

Subjects

Ammonia blood, Animals, Diabetes Mellitus, Experimental blood, Diabetes Mellitus, Type 1 blood, Disease Models, Animal, Glucagon pharmacology, Hydrocortisone blood, Hydrocortisone pharmacology, Hyperglycemia blood, Hyperglycemia etiology, Kinetics, Nitrogen metabolism, Rats, Diabetes Mellitus, Experimental etiology, Fishes, Glucagon physiology, Hydrocortisone physiology, Insulin physiology, Islets of Langerhans surgery

Abstract

In an experimental model of insulin-dependent diabetes mellitus (IDDM) in the teleost fish, the goby Gillichthys mirabilis, an isletectomy procedure completely removes the pancreatic endocrine tissue without affecting the exocrine acini or other essential tissues. Interestingly, isletectomized (Ix) gobies do not exhibit a significant hyperglycemia until 10-15 d after this procedure, suggesting a lack of initial diabetogenic actions of a pancreatic factor(s). Administering exogenous glucagon in otherwise nonsymptomatic 7-d Ix gobies, however, induces a hyperglycemic state comparable to that in severely diabetic rats or gobies (after 20 d post-Ix). The spontaneously arising hyperglycemia observed between 10 and 15d post-Ix, on the other hand, is significantly correlated with increasing serum cortisol concentrations, with both exhibiting sustained elevated levels (approx 23 mmol/L and >100 ng/mL, respectively) at 20- and 25-d post-Ix. Exogenous cortisol treatment also significantly induced hyperglycemia in nonsymptomatic, 7-d Ix gobies. By contrast, growth hormone (GH) had no detectable diabetogenic effect in 7-d Ix gobies. Serum levels of ammonia, the principal nitrogenous waste in this species, were not affected by glucagon treatment but were reduced slightly by GH treatment (30% reduction; p < 0.05). Cortisol treatment, on the other hand, increased ammonia levels twofold, suggesting that the glucocorticoid induces a negative nitrogen balance. These results indicate that the counterregulatory hormones--glucagon and cortisol--are effective diabetogenic factors in the Ix goby, capable of driving metabolic imbalance in this model of IDDM.

Published

2000

44. Lack of suppression of glucagon contributes to postprandial hyperglycemia in subjects with type 2 diabetes mellitus.

Author

Shah P, Vella A, Basu A, Basu R, Schwenk WF, and Rizza RA

Subjects

Blood Glucose drug effects, C-Peptide blood, C-Peptide metabolism, Diabetes Mellitus, Type 2 blood, Female, Galactose metabolism, Glucagon blood, Glucagon pharmacology, Glycogen metabolism, Human Growth Hormone blood, Humans, Hyperglycemia blood, Infusions, Intravenous, Insulin blood, Insulin pharmacology, Insulin Secretion, Male, Middle Aged, Blood Glucose metabolism, Diabetes Mellitus, Type 2 physiopathology, Glucagon physiology, Hyperglycemia physiopathology, Insulin metabolism, Postprandial Period

Abstract

We tested the hypothesis that a lack of suppression of glucagon causes postprandial hyperglycemia in subjects with type 2 diabetes. Nine diabetic subjects ingested 50 g glucose on two occasions. On both occasions, somatostatin was infused at a rate of 4.3 nmol/kg x min, and insulin was infused in a diabetic insulin profile. On one occasion, glucagon was also infused at a rate of 1.25 ng/kg x min to maintain portal glucagon concentrations constant (nonsuppressed study day). On the other occasion, glucagon infusion was delayed by 2 h to create a transient decrease in glucagon (suppressed study day). Glucagon concentrations on the suppressed study day fell to about 70 ng/L during the first 2 h, rising thereafter to approximately 120 ng/L. In contrast, glucagon concentrations on the nonsuppressed study day remained constant at about 120 ng/L throughout. The decrease in glucagon resulted in substantially lower (P < 0.001) glucose concentrations on the suppressed compared with the nonsuppressed study days (9.2+/-0.7 vs. 10.9+/-0.8 mmol/L) and a lower (P < 0.001) rate of release of [14C]glucose from glycogen (labeled by infusing [1-14C]galactose). On the other hand, flux through the hepatic UDP-glucose pool (and, by implication, glycogen synthesis), measured using the acetaminophen glucuronide method, did not differ on the two occasions. We conclude that lack of suppression of glucagon contributes to postprandial hyperglycemia in subjects with type 2 diabetes at least in part by accelerating glycogenolysis. These data suggest that agents that antagonize glucagon action or secretion are likely to be of value in the treatment of patients with type 2 diabetes.

Published

2000

45. Integral rein control in physiology II: a general model.

Author

Saunders PT, Koeslag JH, and Wessels JA

Subjects

Calcitonin metabolism, Calcium metabolism, Humans, Models, Biological, Parathyroid Hormone metabolism, Blood Glucose metabolism, Glucagon physiology, Insulin physiology

Abstract

We generalize the principle of integral rein control to include other systems which partition in such a way that the equilibrium values of some variables are not dependent on the equations governing those variables. Instead, they are determined by the dynamics of other, "regulator" variables. We improve our earlier model for the control of glucose by insulin and glucagon by relaxing the condition necessary for it to operate. The two hormones do not have to be inhibited in the same way; they need only respond to the same combination of their concentrations. We also present a model for the control of ionized calcium by PTH and calcitonin and suggest that the role of chromogranin A may be to stabilize an otherwise unstable system., (Copyright 2000 Academic Press.)

Published

2000

46. Elimination of glucagon-like peptide 1R signaling does not modify weight gain and islet adaptation in mice with combined disruption of leptin and GLP-1 action.

Author

Scrocchi LA, Hill ME, Saleh J, Perkins B, and Drucker DJ

Subjects

Animals, Cell Division, Crosses, Genetic, Feeding Behavior drug effects, Female, Glucagon blood, Glucagon-Like Peptide 1, Glucagon-Like Peptide-1 Receptor, Glucose Tolerance Test, Heterozygote, Insulin blood, Insulin metabolism, Insulin Secretion, Islets of Langerhans cytology, Leptin pharmacology, Male, Mice, Mice, Knockout, Mice, Obese, Peptide Fragments blood, Protein Precursors blood, Receptors, Glucagon deficiency, Receptors, Glucagon genetics, Receptors, Leptin, Sex Characteristics, Signal Transduction, Feeding Behavior physiology, Glucagon physiology, Insulin genetics, Islets of Langerhans physiology, Leptin physiology, Peptide Fragments physiology, Protein Precursors physiology, Receptors, Glucagon physiology, Weight Gain physiology

Abstract

Leptin and glucagon-like peptide 1 (GLP-1) exhibit opposing actions in the endocrine pancreas. GLP-1 stimulates insulin biosynthesis, secretion, and islet growth, whereas leptin inhibits glucose-dependent insulin secretion and insulin gene transcription. In contrast, GLP-1 and leptin actions overlap in the central nervous system, where leptin has been shown to activate GLP-1 circuits that inhibit food intake. To determine the physiological importance of GLP-1 receptor (GLP-1R)-leptin interactions, we studied islet function and feeding behavior in ob/ob:GLP-1R(-/-) mice. Although GLP-1R actions are thought to be essential for glucose-dependent insulin secretion, the levels of fasting glucose, glycemic excursion after glucose loading, glucose-stimulated insulin, and pancreatic insulin RNA content were similar in ob/ob:GLP-1R(+/+) versus ob/ob:GLP-1R(-/-) mice. Despite evidence linking GLP-1R signaling to the regulation of islet neogenesis and proliferation, ob/ob:GLP-1R(-/-) mice exhibited significantly increased islet numbers and area and an increase in the number of large islets compared with GLP-1R(+/+) or (-/-) mice (P < -0.01 to 0.05). Similarly, growth rates and both shortand long-term control of food intake were comparable in ob/ob:GLP-1R(+/+) versus ob/ob:GLP-1R4(-/-) mice. Furthermore, leptin produced a similar inhibition of food intake in GLP-1R(-/-), ob/ob:GLP-1R(+/+), and ob/ob:GLP1R4(-/-) mice. These findings illustrate that although leptin and GLP-1 actions overlap in the brain and endocrine pancreas, disruption of GLP-1 signaling does not modify the response to leptin or the phenotype of leptin deficiency in the ob/ob mouse, as assessed by long-term control of body weight or the adaptive beta-cell response to insulin resistance in vivo.

Published

2000

47. Fatty acids and insulin secretion.

Author

Amery CM and Nattrass M

Subjects

Animals, Glucagon physiology, Humans, Insulin physiology, Insulin Secretion, Models, Biological, Fatty Acids, Nonesterified metabolism, Insulin metabolism

Published

2000

48. Hormonal control of renal and systemic glutamine metabolism.

Author

Gerich JE, Meyer C, and Stumvoll MW

Subjects

Epinephrine administration & dosage, Glucagon administration & dosage, Humans, Insulin administration & dosage, Epinephrine physiology, Glucagon physiology, Glutamine metabolism, Insulin physiology, Kidney metabolism

Abstract

Glutamine is the most abundant free amino acid in the human body. Recent studies indicate that it may be an important vehicle for interorgan nitrogen and carbon transport. However, relatively little is known about hormonal factors regulating its metabolism in humans. We review here our recent work on the effects of insulin, glucagon and epinephrine on plasma glutamine kinetics and its conversion to glucose by liver and kidney.

Published

2000

49. Present and potential future use of gene therapy for the treatment of non-insulin dependent diabetes mellitus (Review).

Author

Freeman DJ, Leclerc I, and Rutter GA

Subjects

Adult, Animals, Blood Glucose analysis, Cell Transplantation, Diabetes Mellitus, Type 2 genetics, Diabetes Mellitus, Type 2 physiopathology, Gene Expression Regulation, Genes, Synthetic, Genetic Vectors, Glucagon genetics, Glucagon physiology, Glucagon-Like Peptide 1, Glucokinase genetics, Glucokinase physiology, Glucose Transporter Type 2, Humans, Hyperinsulinism etiology, Hypoglycemic Agents pharmacology, Hypoglycemic Agents therapeutic use, Insulin metabolism, Insulin Resistance, Insulin Secretion, Islets of Langerhans drug effects, Islets of Langerhans metabolism, Islets of Langerhans Transplantation, Mice, Middle Aged, Monosaccharide Transport Proteins genetics, Monosaccharide Transport Proteins physiology, Muscle Contraction, Nitric Oxide physiology, Nitric Oxide Synthase genetics, Nitric Oxide Synthase physiology, Nitric Oxide Synthase Type I, Pancreatitis-Associated Proteins, Peptide Fragments genetics, Peptide Fragments physiology, Promoter Regions, Genetic, Protein Precursors genetics, Protein Precursors physiology, Proteins genetics, Proteins physiology, Rats, Trans-Activators genetics, Trans-Activators physiology, Antigens, Neoplasm, Biomarkers, Tumor, Diabetes Mellitus, Type 2 therapy, Genetic Therapy, Homeodomain Proteins, Insulin genetics, Lectins, C-Type

Abstract

This review describes the latest approaches towards using gene therapy as a treatment for non-insulin dependent diabetes mellitus (NIDDM; Type 2 diabetes). We examine attempts to directly deliver the insulin gene to non-beta-cells, to improve insulin secretion from existing beta-cells and to develop ex vivo approaches to implanting genetically modified cells. Future research into the pathology of non-insulin dependent diabetes, combined with the latest developments in gene delivery systems, may potentially make gene therapy an attractive alternative NIDDM treatment in the future.

Published

1999

50. Effects of glucagon, insulin, amylin and CGRP on feeding.

Author

Geary N

Subjects

Amyloid metabolism, Amyloid physiology, Animals, Calcitonin Gene-Related Peptide metabolism, Calcitonin Gene-Related Peptide physiology, Glucagon metabolism, Glucagon physiology, Humans, Insulin metabolism, Insulin physiology, Islet Amyloid Polypeptide, Amyloid pharmacology, Calcitonin Gene-Related Peptide pharmacology, Eating drug effects, Gastrointestinal Agents pharmacology, Glucagon pharmacology, Hypoglycemic Agents pharmacology, Insulin pharmacology

Abstract

The roles of the pancreatic peptides glucagon, insulin, and amylin in the inhibitory control of feeding are reviewed. Calcitonin gene-related peptide (CGRP) is also included because it is structurally and functionally related to amylin and because known amylin and CRRP receptors are activated by both peptides. Glucagon-like peptide 1, in contrast, is structurally distinct from pancreatic glucagon and does not cross-react with glucagon receptors, so it is not considered. Several detailed reviews of the feeding effects of these peptides have appeared recently; where appropriate, these are cited rather than the primary literature., (Copyright 1999 Harcourt Publishers Ltd.)

Published

1999