UNIPROT:P01275 - FACTA Search

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Query: UNIPROT:P01275 (glucagon)
26,492 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Increased pancreatic beta-cell secretory activity usually is associated with decreased alpha-cell activity; stimulated beta-cells release gamma-aminobutyric acid, which hyperpolarizes alpha-cells, inhibiting glucagon release. Thus, insulin secretion and glucagon secretion are usually inversely coupled. This suggests that chromium and other insulin-sensitizing modalities, by down-regulating beta-cell activity, may increase glucagon secretion. Such an effect might play a role in the documented therapeutic activity of supplemental chromium and biguanides in reactive hypoglycemia, and might also be of benefit to dieters.
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PMID:Chromium and other insulin sensitizers may enhance glucagon secretion: implications for hypoglycemia and weight control. 869 48

The dorsal vagal complex (DVC) and nucleus raphe obscurus (nROb) are currently known to control vagal outflow to the stomach and the pancreas. Elucidation of neurotransmitters in these nuclei that control vagal outflow has become necessary to determine the endogenous circuitry for control of gastric motor activity and pancreatic hormone secretion. In this review, the author's data on the effects of selected peptides on intragastric pressure and gastric contractility as well as on pancreatic glucagon and insulin secretion in the DVC and nROb are presented. Microinjection of thyrotropin-releasing hormone (TRH) or pituitary adenylate cyclase-activating polypeptide (PACAP38) into the nROb results in gastric excitatory motor responses, whereas substance P (SP) and vasoactive intestinal polypeptide (VIP) evoke gastric relaxation. Irrespective of colocalization of TRH and SP in the serotonergic neurons of the nROb, these peptides independently affect gastric motor function when microinjected into the nROb. The inhibitory effect of SP on gastric motor function in the nROb is apparently mediated via nitric oxide in the DVC and involves peripheral VIP, acetylcholine, gamma-aminobutyric acid and nitric oxide. Microinjection of endothelin, PACAP38, and VIP into the DVC evokes increases in gastric motor activity. Pancreatic polypeptide, microinjected into the DVC, does not affect basal plasma insulin and glucagon concentration but potentiates glucose-stimulated insulin secretion. All these data make an important contribution to our understanding of the vagal mechanisms controlling gastric motor and endocrine pancreatic function.
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PMID:Role of selected peptides in the vagal regulation of gastric motor and endocrine pancreatic function. 887 96

Glutamic acid decarboxylase (GAD) is present in the central nervous system and in several nonneuronal tissues including the pancreatic islets. There are two isoforms with molecular weights of 65 kDa (GAD65) and 67 kDa (GAD67). The cellular specificity of the two molecular forms of GAD and their levels within the mammalian islets may be species-dependent, being coexpressed in both beta and in non-beta cells. We have examined the ovine pancreas, from the adult and fetal stages of late gestation, for the expression of GAD65 within the islet cells by double-label immunofluorescence light and confocal microscopy. In the adult tissue, GAD65 was colocalized in a majority of the beta cells (> 95%), with only a few glucagon and somatostatin cells (< 5%) showing immunolocalization. During the fetal stages GAD65 also showed a similar predominant beta-cell coexpression. The enzyme was also detected in a few fetal glucagon (< 5%) but not somatostatin cells. In the degenerating large fetal islets, GAD65 was also observed in the majority of the residual beta cells. These results demonstrate that in the ovine pancreas GAD65 is expressed during fetal development and is predominantly beta-cell-restricted. This pattern of expression is maintained during adult life. However, the physiological role of pancreatic GAD and/or its biosynthetic product, gamma-aminobutyric acid, in islet function in the sheep and in other ruminants remains unclear.
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PMID:Double-label immunofluorescence study of glutamic acid decarboxylase in the fetal and adult ovine pancreas by light and confocal microscopy: evidence for predominant beta-cell coexpression. 920 63

Glutamate decarboxylase (GAD) of pancreatic beta cells seems to be involved in the development of autoimmune reactivities which occur in insulin-dependent diabetes mellitus. Little is known about the regulation and role of the GAD activity in normal beta cells. In the betaTC6 line, the enzymatic product, gamma-aminobutyric acid (GABA) was reported to be released under glucose stimulation, thus supporting the concept that GABA transmits a suppressive action of glucose-stimulated beta cells on neighbouring alpha cells. In this study GABA was found to be released from normal rat beta cells. Over 24-h culture periods, the released amounts represented a constant fraction (25% per h) of the cellular GABA content. Cellular GABA content and release were dose-dependently increased by the glutamine concentration in the medium; both values decreased following a sustained (24 h) glucose activation (culture at 10 or 20 mmol/l glucose instead of 3 mmol/l). The variations in the medium GABA content did not parallel the changes in insulin release, indicating that both beta-cell secretory products follow different routes of storage and release. We suggest that beta cells can discharge GABA via exocytosis of microvesicles storing GABA as well as via direct transport from the cytoplasmic pool of newly formed product. Variations in GABA production result in parallel changes in extracellular GABA concentration; the high fractional release of GABA makes it also a likely parameter of the cellular GAD activity. Since chronically elevated glucose levels result in a reduced GABA discharge from the beta cells, it is conceivable that the subsequent decrease in GABA-mediated suppression of the alpha cells is responsible for a higher glucagon release, as observed in diabetes.
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PMID:Nutrient regulation of gamma-aminobutyric acid release from islet beta cells. 944 48

A single, large dose of N-methyl-D-aspartate (NMDA) or quisqualic acid (QA) injected into the chick eye has been shown previously to destroy many retinal amacrine cells and to induce excessive ocular growth accompanied by myopia. The purpose of this study was to identify distinct populations of retinal cells, particularly those believed to be involved in regulating ocular growth, that are sensitive to NMDA or QA. Two pmol of NMDA or 0.2 micromol of QA were injected unilaterally into eyes of 7-day-old chicks, and retinas were prepared for observation 1, 3, or 7 days later. Retinal neurons were identified by using immunocytochemistry, and cells containing fragmented DNA were identified by 3'-nick-end labelling in frozen sections. NMDA and QA destroyed many amacrine cells, including those immunoreactive for vasoactive intestinal polypeptide, Met-enkephalin, and choline acetyltransferase, but they had little effect upon tyrosine hydroxylase-immunoreactive cells. Other cells affected by both QA and NMDA included those immunoreactive for glutamic acid decarboxylase, gamma-aminobutyric acid, parvalbumin, serotonin, and aminohydroxy methylisoxazole propionic acid (AMPA) receptor subunits GluR1 and GluR2/3. Cells largely unaffected by QA or NMDA included bipolar cells immunoreactive for protein kinase C (alpha and beta isoforms) and amacrine cells immunoreactive for glucagon. DNA fragmentation was detected maximally in many amacrine cells and in some bipolar cells 1 day after exposure to QA or NMDA. We propose that excitotoxicity caused by QA and NMDA induces apoptosis in specific populations of amacrine cells and that these actions are responsible for the ocular growth-specific effects of QA and NMDA reported elsewhere.
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PMID:Immunocytochemical characterization of quisqualic acid- and N-methyl-D-aspartate-induced excitotoxicity in the retina of chicks. 952 96

Glucagon-like peptide-1 (GLP-1) released from the intestine is a potent stimulator of glucose-dependent insulin secretion. To elucidate the factors regulating GLP-1 secretion, we have studied the enteroendocrine GLUTag cell line. GLP-1 secretion was stimulated in a dose-dependent fashion by activation of protein kinase A or C with forskolin or phorbol 12,13-dibutyrate, respectively (by 2.3 +/- 0.5-fold at 100 microM and 4.3 +/- 0.6-fold at 0.3 microM, respectively; P < 0.01-0.001). Of the regulatory peptides tested, only glucose-dependent insulinotropic peptide stimulated the release of GLP-1 (by 2.3 +/- 0.2-fold at 0.1 microM; P < 0.001); glucagon was without effect, and paradoxically, the inhibitory neuropeptide somatostatin-14 increased secretion slightly (by 1.6 +/- 0.3-fold at 0.01 microM; P < 0.05). In tests of several neurotransmitters, only the cholinergic agonists carbachol and bethanechol stimulated peptide secretion in a dose-dependent fashion (by 2.3 +/- 0.5- and 1.7 +/- 0.3-fold at 1000 microM; P < 0.05-0.001); the beta-adrenergic agonist isoproterenol and the chloride channel inhibitor gamma-aminobutyric acid did not affect release of GLP-1. Long chain monounsaturated fatty acids (18:1), but not saturated fatty acids (16:0), also stimulated the release of GLP-1 (by 1.7 +/- 0.1-fold at 150 microM; P < 0.001). Consistent with the presence of a cAMP response element in the proglucagon gene, activation of the protein kinase A-dependent pathway with forskolin increased proglucagon messenger RNA transcript levels by 2-fold (P < 0.05); glucose-dependent insulinotropic peptide and phorbol 12,13-dibutyrate were without effect. Therefore, by comparison with results obtained using primary L cell cultures or in vivo models, GLUTag cells appear to respond appropriately to the regulatory mechanisms controlling intestinal GLP-1 secretion.
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PMID:Regulation of glucagon-like peptide-1 synthesis and secretion in the GLUTag enteroendocrine cell line. 975 89

Pancreatic beta-cells express glutamate decarboxylase (GAD), which is responsible for the production and release of gamma-aminobutyric acid (GABA). Over a 24-h culture period, total GABA release by purified rat beta-cells is eightfold higher than the cellular GABA content and can thus be used as an index of cellular GAD activity. GABA release is 40% reduced by glucose (58 pmol/10(3) cells at 10 mM glucose vs. 94 pmol at 3 mM glucose, P < 0.05). This suppressive effect of glucose was not observed when glucose metabolism was blocked by mannoheptulose or 2,4-dinitrophenol; it was amplified when ATP-dependent beta-cell activities were inhibited by addition of diazoxide, verapamil, or cycloheximide or by reduction of extracellular calcium levels; it was counteracted when beta-cell functions were activated by nonmetabolized agents, such as glibenclamide, IBMX, glucagon, or glucacon-like peptide-1 (GLP-1), which are known to stimulate calcium-dependent activities, such as hormone release and calcium-dependent ATPases. These observations suggest that GABA release from beta-cells varies with the balance between ATP-producing and ATP-consuming activities in the cells. Less GABA is released in conditions of elevated glucose metabolism, and hence ATP production, but this effect is counteracted by ATP-dependent activities. The notion that increased cytoplasmic ATP levels can suppress GAD activity in beta-cells, and hence GABA production and release, is compatible with previous findings on ATP suppression of brain GAD activity.
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PMID:Correlation between GABA release from rat islet beta-cells and their metabolic state. 1188 16

L-Glutamate is believed to function as an intercellular transmitter in the islets of Langerhans. However, critical issues, i.e. where, when and how L-glutamate appears, and what happens upon stimulation of glutamate receptors in the islets, remain unresolved. Vesicular glutamate transporter 2 (VGLUT2), an isoform of the vesicular glutamate transporter essential for neuronal storage of L-glutamate, is expressed in alpha cells (Hayashi, M., Otsuka, M., Morimoto, R., Hirota, S., Yatsushiro, S., Takeda, J., Yamamoto, A., and Moriyama, Y. (2001) J. Biol. Chem. 276, 43400-43406). Here we show that VGLUT2 is specifically localized in glucagon-containing secretory granules but not in synaptic-like microvesicles in alpha TC6 cells, clonal alpha cells, and islet alpha cells. VGLUT1, another VGLUT isoform, is also expressed and localized in secretory granules in alpha cells. Low glucose conditions triggered co-secretion of stoichiometric amounts of L-glutamate and glucagon from alpha TC6 cells and isolated islets, which is dependent on temperature and Ca(2+) and inhibited by phentolamine. Similar co-secretion of L-glutamate and glucagon from islets was observed upon stimulation of beta-adrenergic receptors with isoproterenol. Under low glucose conditions, stimulation of glutamate receptors facilitates secretion of gamma-aminobutyric acid from MIN6 m9, clonal beta cells, and isolated islets. These results indicate that co-secretion of L-glutamate and glucagon from alpha cells under low glucose conditions triggers GABA secretion from beta cells and defines the mode of action of L-glutamate as a regulatory molecule for the endocrine function. To our knowledge, this is the first example of secretory granule-mediated glutamatergic signal transmission.
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PMID:Secretory granule-mediated co-secretion of L-glutamate and glucagon triggers glutamatergic signal transmission in islets of Langerhans. 1241 5

Islets of Langerhans contain gamma-aminobutyrate (GABA) and may use it as an intercellular transmitter. In beta-cells, GABA is stored in synaptic-like microvesicles and secreted through Ca(2+)-dependent exocytosis. Vesicular inhibitory amino acid transporter (VIAAT), which is responsible for the storage of GABA and glycine in neuronal synaptic vesicles, is believed to be responsible for the storage and secretion of GABA in beta-cells. However, a recent study by Chessler et al. indicated that VIAAT is expressed in the mantle region of islets. In the present study, we investigated the precise localization of VIAAT in rat islets of Langerhans and clonal islet cells and found that it is present in alpha-cells, a minor population of F-cells and alphaTC6 cells, and clonal alpha-cells but not in beta-cells, delta-cells, or MIN6 m9-cells (clonal beta-cells). Combined biochemical, immunohistochemical, and electronmicroscopical evidence indicated that VIAAT is specifically localized with glucagon-containing secretory granules in alpha-cells. ATP-dependent uptake of radiolabeled GABA, which is energetically coupled with a vacuolar proton pump, was detected in digitonin-permeabilized alphaTC6 cells as well as in MIN6 m9 cells. These results demonstrate that functional neuronal VIAAT is present in glucagon-containing secretory granules in alpha-cells and suggest that the ATP-dependent GABA transporter in beta-cells is at least immunologically distinct from VIAAT. Because glucagon-containing secretory granules also contain vesicular glutamate transporter and store L-glutamate, as demonstrated by Hayashi et al., the present results suggest more complex features of the GABAergic phenotype of islets than previously supposed.
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PMID:Vesicular inhibitory amino acid transporter is present in glucagon-containing secretory granules in alphaTC6 cells, mouse clonal alpha-cells, and alpha-cells of islets of Langerhans. 1288 24

In islets of Langerhans, L-glutamate is stored in glucagon-containing secretory granules of alpha-cells and cosecreted with glucagon under low-glucose conditions. The L-glutamate triggers secretion of gamma-aminobutyric acid (GABA) from beta-cells, which in turn inhibits glucagon secretion from alpha-cells through the GABAA receptor. In the present study, we tested the working hypothesis that L-glutamate functions as an autocrine/paracrine modulator and inhibits glucagon secretion through a glutamate receptor(s) on alpha-cells. The addition of L-glutamate at 1 mmol/l; (R,S)-phosphonophenylglycine (PPG) and (S)-3,4-dicarboxyphenylglycine (DCPG), specific agonists for class III metabotropic glutamate receptor (mGluR), at 100 micromol/l; and (1S,3R,4S)-1-aminocyclopentane-1,3,4-tricarboxylic acid (ACPT-I) at 50 micromol/l inhibited the low-glucose-evoked glucagon secretion by 87, 81, 73, and 87%, respectively. This inhibition was dose dependent and was blocked by (R,S)-cyclopropyl-4-phosphonophenylglycine (CPPG), a specific antagonist of class III mGluR. Agonists of other glutamate receptors, including kainate and quisqualate, had little effectiveness. RT-PCR and immunological analyses indicated that mGluR4, a class III mGluR, was expressed and localized with alpha- and F cells, whereas no evidence for expression of other mGluRs, including mGluR8, was obtained. L-Glutamate, PPG, and ACPT-I decreased the cAMP content in isolated islets, which was blocked by CPPG. Dibutylyl-cAMP, a nonhydrolyzable cAMP analog, caused the recovery of secretion of glucagon. Pertussis toxin, which uncouples adenylate cyclase and inhibitory G-protein, caused the recovery of both the cAMP content and secretion of glucagon. These results indicate that alpha- and F cells express functional mGluR4, and its stimulation inhibits secretion of glucagon through an inhibitory cAMP cascade. Thus, L-glutamate may directly interact with alpha-cells and inhibit glucagon secretion.
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PMID:Metabotropic glutamate receptor type 4 is involved in autoinhibitory cascade for glucagon secretion by alpha-cells of islet of Langerhans. 1504 15

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