Glucose‐stimulated signaling pathways in biphasic insulin secretion

Glucose‐stimulated biphasic insulin secretion involves at least two signaling pathways, the KATP channel‐dependent and KATP channel‐independent pathways, respectively. In the former, enhanced glucose metabolism increases the cellular adenosine triphosphate/adenosine diphosphate (ATP/ADP) ratio, closes KATP channels and depolarizes the cell. Activation of voltage‐dependent Ca2+ channels increases Ca2+ entry and [Ca2+]i and stimulates insulin release. The KATP channel‐independent pathways augment the response to increased [Ca2+]i by mechanisms that are currently unknown. However, they affect different pools of insulin‐containing granules in a highly coordinated manner. The β‐cell granule pools can be minimally described as reserve, morphologically docked, readily and immediately releasable. Activation of the KATP channel‐dependent pathway results in exocytosis of an immediately releasable pool that is responsible for the first phase of glucose‐stimulated insulin release. Following glucose metabolism, the rate‐limiting step for the first phase lies in the rate of signal transduction between sensing the rise in [Ca2+]i and exocytosis of the immediately releasable granules. The immediately releasable pool of granules can be enlarged by previous exposure to glucose (by time‐dependent potentiation, TDP), and by second messengers such as cyclic adenosine monophosphate (cyclic AMP) and diacylglycerol (DAG). The second phase of glucose‐stimulated insulin secretion is due mainly to the KATP channel‐independent pathways acting in synergy with the KATP channel‐dependent pathway. The rate‐limiting step here is the conversion of readily releasable granules to the state of immediate releasability, following which, in an activated cell they will undergo exocytosis. In the rat and human β‐cell the KATP channel‐independent pathways induce a time‐dependent increase in the rate of this step that results in the typical rising second‐phase response. In the mouse β‐cell the rate appears not to be changed much by glucose. Potential intermediates involved in controlling the rate‐limiting step include increases in cytosolic long‐chain acyl‐CoA levels, adenosine triphosphate (ATP) and guanosine triphosphate (GTP), DAG binding proteins, including some isoforms of protein kinase (PKC), and protein acyl transferases. Agonists that can change the rate‐limiting steps for both phases of insulin release include those like glucagon‐like peptide 1 (GLP‐1) that raise cyclic AMP levels and those like acetylcholine that act via DAG. Copyright © 2002 John Wiley & Sons, Ltd.

[1]  W. Zawalich Time-dependent potentiation of insulin release induced by alpha-ketoisocaproate and leucine in rats: possible involvement of phosphoinositide hydrolysis , 1988, Diabetologia.

[2]  E. Cerasi,et al.  Correction of diabetic pattern of insulin release from islets of the spiny mouse (Acomys cahirinus) by glucose priming in vitro , 1985, Diabetologia.

[3]  S. Hashiguchi,et al.  Time-dependent potentiation of the beta-cell is a Ca2+-independent phenomenon. , 2002, The Journal of endocrinology.

[4]  T. Südhof,et al.  Molecular determinants of regulated exocytosis. , 2002, Diabetes.

[5]  L. Eliasson,et al.  A subset of 50 secretory granules in close contact with L-type Ca2+ channels accounts for first-phase insulin secretion in mouse beta-cells. , 2002, Diabetes.

[6]  Haiying Cheng,et al.  Triggering and augmentation mechanisms, granule pools, and biphasic insulin secretion. , 2002, Diabetes.

[7]  M. Komatsu,et al.  The effects of cerulenin, an inhibitor of protein acylation, on the two phases of glucose-stimulated insulin secretion. , 2002, Diabetes.

[8]  S. Hashiguchi,et al.  Time-dependent potentiation of the (cid:1) -cell is a Ca 2 + -independent phenomenon , 2002 .

[9]  G. Sharp,et al.  Intracellular pH plays a critical role in glucose-induced time-dependent potentiation of insulin release in rat islets. , 2002, Diabetes.

[10]  L. Eliasson,et al.  Fast exocytosis with few Ca(2+) channels in insulin-secreting mouse pancreatic B cells. , 2001, Biophysical journal.

[11]  R. Vigneri,et al.  Chronic exposure to high leucine impairs glucose-induced insulin release by lowering the ATP-to-ADP ratio. , 2001, American journal of physiology. Endocrinology and metabolism.

[12]  P. Gilon,et al.  Mechanisms and physiological significance of the cholinergic control of pancreatic beta-cell function. , 2001, Endocrine reviews.

[13]  C. Wollheim,et al.  GAD65-mediated Glutamate Decarboxylation Reduces Glucose-stimulated Insulin Secretion in Pancreatic Beta Cells* , 2001, The Journal of Biological Chemistry.

[14]  M. Komatsu,et al.  Glutamate is not a major conveyer of ATP-sensitive K+ channel-independent glucose action in pancreatic islet beta cell. , 2001, Endocrine journal.

[15]  W. Philbrick,et al.  Insulin secretion and IP levels in two distant lineages of the genus Mus: comparisons with rat islets. , 2001, American journal of physiology. Endocrinology and metabolism.

[16]  H. Mulder,et al.  Overexpression of a Modified Human Malonyl-CoA Decarboxylase Blocks the Glucose-induced Increase in Malonyl-CoA Level but Has No Impact on Insulin Secretion in INS-1-derived (832/13) β-Cells* , 2001, The Journal of Biological Chemistry.

[17]  山田 聡子 Glutamate is not a major conveyer of ATP-sensitive K[+] channel-independent glucose action in pancreatic islet β cell , 2001 .

[18]  D. Bruns,et al.  Molecular determinants of exocytosis , 2001, Pflügers Archiv.

[19]  M. MacDonald,et al.  Glutamate Is Not a Messenger in Insulin Secretion* , 2000, The Journal of Biological Chemistry.

[20]  C. Wollheim,et al.  Mitochondrial signals in glucose‐stimulated insulin secretion in the beta cell , 2000, The Journal of physiology.

[21]  J. Henquin,et al.  Triggering and amplifying pathways of regulation of insulin secretion by glucose. , 2000, Diabetes.

[22]  A. Fox,et al.  The role of dynamic palmitoylation in Ca2+ channel inactivation. , 2000, Proceedings of the National Academy of Sciences of the United States of America.

[23]  M. Komatsu,et al.  Cerulenin, an inhibitor of protein acylation, selectively attenuates nutrient stimulation of insulin release: a study in rat pancreatic islets. , 2000, Diabetes.

[24]  Erik Renström,et al.  The Cell Physiology of Biphasic Insulin Secretion. , 2000, News in physiological sciences : an international journal of physiology produced jointly by the International Union of Physiological Sciences and the American Physiological Society.

[25]  M. Prentki,et al.  Acute Stimulation with Long Chain Acyl-CoA Enhances Exocytosis in Insulin-secreting Cells (HIT T-15 and NMRI β-Cells)* , 2000, The Journal of Biological Chemistry.

[26]  M. Prentki,et al.  The role of long-chain fatty acyl-CoA esters in beta-cell signal transduction. , 2000, The Journal of nutrition.

[27]  C. Wollheim,et al.  Mitochondrial glutamate acts as a messenger in glucose-induced insulin exocytosis , 1999, Nature.

[28]  M. Resh Fatty acylation of proteins: new insights into membrane targeting of myristoylated and palmitoylated proteins. , 1999, Biochimica et biophysica acta.

[29]  P. Gilon,et al.  Alterations of insulin secretion from mouse islets treated with sulphonylureas: perturbations of Ca2+ regulation prevail over changes in insulin content , 1999, British journal of pharmacology.

[30]  S. Gonzalo,et al.  SNAP-25 Is Targeted to the Plasma Membrane through a Novel Membrane-binding Domain* , 1999, The Journal of Biological Chemistry.

[31]  Y. Miyashita,et al.  Post-priming actions of ATP on Ca2+-dependent exocytosis in pancreatic beta cells. , 1999, Proceedings of the National Academy of Sciences of the United States of America.

[32]  T. Südhof,et al.  Membrane fusion and exocytosis. , 1999, Annual review of biochemistry.

[33]  D. Pipeleers,et al.  The Changes in Adenine Nucleotides Measured in Glucose-stimulated Rodent Islets Occur in β Cells but Not in α Cells and Are Also Observed in Human Islets* , 1998, The Journal of Biological Chemistry.

[34]  M. Komatsu,et al.  Glucose action `beyond ionic events' in the pancreatic β cell , 1998 .

[35]  J. Henquin,et al.  The K+-ATP channel-independent pathway of regulation of insulin secretion by glucose: in search of the underlying mechanism. , 1998, Diabetes.

[36]  M. Prentki,et al.  Molecular or Pharmacologic Perturbation of the Link between Glucose and Lipid Metabolism Is without Effect on Glucose-stimulated Insulin Secretion , 1998, The Journal of Biological Chemistry.

[37]  M. Noda,et al.  Nutrient augmentation of Ca2+-dependent and Ca2+-independent pathways in stimulus-coupling to insulin secretion can be distinguished by their guanosine triphosphate requirements: studies on rat pancreatic islets. , 1998, Endocrinology.

[38]  W. Stühmer,et al.  κ-Conotoxin Pviia Is a Peptide Inhibiting theShaker K+ Channel* , 1998, The Journal of Biological Chemistry.

[39]  K. Kim,et al.  Essential role of acetyl-CoA carboxylase in the glucose-induced insulin secretion in a pancreatic beta-cell line. , 1998, Cellular signalling.

[40]  M. Noda,et al.  Augmentation of Insulin Release by Glucose in the Absence of Extracellular Ca2+: New Insights Into Stimulus-Secretion Coupling , 1997, Diabetes.

[41]  L. Eliasson,et al.  Rapid ATP‐Dependent Priming of Secretory Granules Precedes Ca2+ ‐Induced Exocytosis in Mouse Pancreatic B‐Cells , 1997, The Journal of physiology.

[42]  L. Eliasson,et al.  Protein kinase A‐dependent and ‐independent stimulation of exocytosis by cAMP in mouse pancreatic B‐cells , 1997, The Journal of physiology.

[43]  W. Zawalich,et al.  Influence of Pyruvic Acid Methyl Ester on Rat Pancreatic Islets , 1997, The Journal of Biological Chemistry.

[44]  K. Hashizume,et al.  ATP-sensitive K+ channel closure is not an obligatory step for glucose-induced priming of pancreatic B-cell. , 1997, Advances in experimental medicine and biology.

[45]  G. Sharp,et al.  Mechanisms of Action of VIP and PACAP in the Stimulation of Insulin Release , 1996, Annals of the New York Academy of Sciences.

[46]  Ca(2+)‐ and GTP‐dependent exocytosis in mouse pancreatic beta‐cells involves both common and distinct steps. , 1996, The Journal of physiology.

[47]  M. Komatsu,et al.  Pituitary adenylate cyclase-activating peptide, carbachol, and glucose stimulate insulin release in the absence of an increase in intracellular Ca2+. , 1996, Molecular pharmacology.

[48]  W. Zawalich,et al.  Regulation of insulin secretion by phospholipase C. , 1996, The American journal of physiology.

[49]  G. Van den Berghe,et al.  Concentration Dependence and Time Course of the Effects of Glucose on Adenine and Guanine Nucleotides in Mouse Pancreatic Islets* , 1996, The Journal of Biological Chemistry.

[50]  T. Südhof,et al.  Fatty acylation of synaptotagmin in PC12 cells and synaptosomes. , 1996, Biochemical and biophysical research communications.

[51]  G. Sharp,et al.  Glucose-dependent insulinotropic polypeptide stimulates insulin secretion via increased cyclic AMP and [Ca2+]1 and a wortmannin-sensitive signalling pathway. , 1996, Biochemical and biophysical research communications.

[52]  W. Zawalich,et al.  Species differences in the induction of time-dependent potentiation of insulin secretion. , 1996, Endocrinology.

[53]  M. Prentki New insights into pancreatic β-cell metabolic signaling in insulin secretion , 1996 .

[54]  M. Prentki,et al.  Evidence for an Anaplerotic/Malonyl-CoA Pathway in Pancreatic β-Cell Nutrient Signaling , 1996, Diabetes.

[55]  G. Sharp,et al.  A Wortmannin-sensitive Signal Transduction Pathway Is Involved in the Stimulation of Insulin Release by Vasoactive Intestinal Polypeptide and Pituitary Adenylate Cyclase-activating Polypeptide (*) , 1996, The Journal of Biological Chemistry.

[56]  T. Schermerhorn,et al.  Glucose stimulation of insulin release in the absence of extracellular Ca2+ and in the absence of any increase in intracellular Ca2+ in rat pancreatic islets. , 1995, Proceedings of the National Academy of Sciences of the United States of America.

[57]  G. Mick,et al.  Inhibitory effects of cerulenin on protein palmitoylation and insulin internalization in rat adipocytes. , 1995, Biochimica et biophysica acta.

[58]  K. Hashizume,et al.  Mechanism of glucose-induced biphasic insulin release: physiological role of adenosine triphosphate-sensitive K+ channel-independent glucose action. , 1995, Endocrinology.

[59]  S. Chen,et al.  More Direct Evidence for a Malonyl-CoA–Carnitine Palmitoyltransferase I Interaction as a Key Event in Pancreatic β-Cell Signaling , 1994, Diabetes.

[60]  M. Komatsu,et al.  ATP-sensitive K+ channel-independent glucose action in rat pancreatic beta-cell. , 1994, The American journal of physiology.

[61]  F. Ashcroft,et al.  Calcium-independent potentiation of insulin release by cyclic AMP in single β-cells , 1993, Nature.

[62]  G. Sharp,et al.  Glucose-induced insulin release in islets of young rats: time-dependent potentiation and effects of 2-bromostearate. , 1992, The American journal of physiology.

[63]  A. Yates,et al.  Stimulation of insulin secretion by glucose in the absence of diminished potassium (86Rb+) permeability. , 1992, Biochemical pharmacology.

[64]  M. Komatsu,et al.  Dual Functional Role of Membrane Depolarization/Ca2+ Influx in Rat Pancreatic B-Cell , 1992, Diabetes.

[65]  P. Gilon,et al.  Evidence that glucose can control insulin release independently from its action on ATP-sensitive K+ channels in mouse B cells. , 1992, The Journal of clinical investigation.

[66]  M. Prentki,et al.  Malonyl-CoA and long chain acyl-CoA esters as metabolic coupling factors in nutrient-induced insulin secretion. , 1992, The Journal of biological chemistry.

[67]  W. Malaisse,et al.  Hexose metabolism in pancreatic islets. Effect of (-)-hydroxycitrate upon fatty acid synthesis and insulin release in glucose-stimulated islets. , 1991, Biochimie.

[68]  M. Prentki,et al.  A role for malonyl-CoA in glucose-stimulated insulin secretion from clonal pancreatic beta-cells. , 1989, The Journal of biological chemistry.

[69]  S. Aust,et al.  Inhibition of superoxide and ferritin-dependent lipid peroxidation by ceruloplasmin. , 1989, The Journal of biological chemistry.

[70]  Effects of aging on insulin synthesis and secretion. Differential effects on preproinsulin messenger RNA levels, proinsulin biosynthesis, and secretion of newly made and preformed insulin in the rat. , 1988, The Journal of clinical investigation.

[71]  G. Sharp,et al.  Glucose induces insulin release and a rise in cytosolic calcium concentration in a transplantable rat insulinoma. , 1986, Endocrinology.

[72]  Stephen J. H. Ashcroft,et al.  Glucose induces closure of single potassium channels in isolated rat pancreatic β-cells , 1984, Nature.

[73]  D. Cook,et al.  Intracellular ATP directly blocks K+ channels in pancreatic B-cells , 1984, Nature.

[74]  V. Grill Nutrient-induced priming of insulin and glucagon secretion. Effects of alpha-ketoisocaproic acid. , 1982, Endocrinology.

[75]  C. Wollheim,et al.  Regulation of insulin release by calcium. , 1981, Physiological reviews.

[76]  E. Cerasi,et al.  Potentiation and inhibition of insulin release in man following priming with glucose and with arginine--effect of somatostatin. , 1979, Acta endocrinologica.

[77]  E. Cerasi,et al.  Immediate and time-dependent effects of glucose on insulin release from rat pancreatic tissue. Evidence for different mechanisms of action. , 1978, The Journal of clinical investigation.

[78]  G. Grodsky,et al.  A threshold distribution hypothesis for packet storage of insulin and its mathematical modeling. , 1972, The Journal of clinical investigation.

[79]  G. Grodsky,et al.  A Threshold Distribution Hypothesis for Packet Storage of Insulin: II. Effect of Calcium , 1972, Diabetes.

[80]  H. Landahl,et al.  [Further studies on the dynamic aspects of insulin release in vitro with evidence for a two-compartmental storage system]. , 1969, Acta diabetologica latina.

[81]  G. Grodsky,et al.  Dynamics of insulin secretion by the perfused rat pancreas. , 1968, Endocrinology.

[82]  P. Lacy,et al.  Method for the Isolation of Intact Islets of Langerhans from the Rat Pancreas , 1967, Diabetes.