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)

The physiologic significance of glucocorticoids and insulin in the regulation of hepatic gluconeogenesis was investigated during a 48-hr starvation period by studying the factors presumed to control the rate of glucose synthesis in the final gluconeogenetic pathway. Rats were used, in which glucorticoids were removed by adrenalectomy before starvation, and in which serum insulin was kept constant before and after food withdrawal by pre-feeding with a proteinfree diet. It was found that adrenalectomized rats at constantly low serum insulin levels responded to starvation as rapidly, and to the same degree, as intact control subjects (1) by a significant increase in plasma glucagon and, consequently, in hepatic cAMP concentration; (2) by a coordinate elevation of the activities of hepatic pyruvate carboxylase, P-enolpyruvate carboxykinase, and fructose-1,6-diphosphatase; (3) by systematic alterations in the concentration of effectors of gluconeogenetic key enzymes; (4) by a shifting of the cytoplasmic NAD system towards the reduced state; (5) by a decrease in the intrahepatic concentration of glycogenic precursor substrates. These results suggest that the hepatic gluconeogenic response to starvation with respect to the regulatory factors 1-5 occurs independently from changes in the concentration of plasma glucocorticoids and insulin. The crossing over of the gluconeogenetic intermediates between pyruvate and P-enolpyruvate (PEP), which was observed in intact but not in adrenalectomized rats, supports the assumption that during starvation, glucocorticoids enhance the rate of glucose production by the liver predominantly by permitting hepatic cAMP to stimulate the yet undefined mechanism, which has been demonstrated in the isolated perfused rat liver to control the substrate flow between pyruvate and PEP.
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PMID:Physiologic significance of glucocorticoids and insulin in the regulation of hepatic gluconeogenesis during starvation in rats. 18 90

1. The subcellular distribution of adenine nucleotides, acetyl-CoA, CoA, glutamate, 2-oxoglutarate, malate, oxaloacetate, pyruvate, phosphoenolpyruvate, 3-phosphoglycerate, glucose 6-phosphate, aspartate and citrate was studied in isolated hepatocytes in the absence and presence of glucagon by using a modified digitonin procedure for cell fractionation. 2. In the absence of glucagon, the cytosol contains about two-thirds of cellular ATP, some 40-50% of ADP, acetyl-CoA, citrate and phosphoenolpyruvate, more than 75% of total 2-oxoglutarate, glutamate, malate, oxaloacetate, pyruvate, 3-phosphoglycerate and aspartate, and all of glucose 6-phosphate. 3. In the presence of glucagon the cytosolic space shows an increase in the content of malate, phosphoenolpyruvate and 3-phosphoglycerate by more than 60%, and those of aspartate and glucose 6-phosphate rise by about 25%. Other metabolites remain unchanged. After glucagon treatment, cytosolic pyruvate is decreased by 37%, whereas glutamate and 2-oxoglutarate decrease by 70%. The [NAD(+)]/[NADH] ratios calculated from the cytosolic concentrations of the reactants of lactate dehydrogenase and malate dehydrogenase were the same. Glucagon shifts this ratio and also that of the [NADP(+)]/[NADPH] couple towards a more reduced state. 4. In the mitochondrial space glucagon causes an increase in the acetyl-CoA and ATP contents by 25%, and an increase in [phosphoenolpyruvate] by 50%. Other metabolites are not changed by glucagon. Oxaloacetate in the matrix is only slightly decreased after glucagon, yet glutamate and 2-oxoglutarate fall to about 25% of the respective control values. The [NAD(+)]/[NADH] ratios as calculated from the [3-hydroxybutyrate]/[acetoacetate] ratio and from the matrix [malate]/[oxaloacetate] couple are lowered by glucagon, yet in the latter case the values are about tenfold higher than in the former. 5. Glucagon and oleate stimulate gluconeogenesis from lactate to nearly the same extent. Oleate, however, does not produce the changes in cellular 2-oxoglutarate and glutamate as observed with glucagon. 6. The changes of the subcellular metabolite distribution after glucagon are compatible with the proposal that the stimulation of gluconeogenesis results from as yet unknown action(s) of the hormone at the mitochondrial level in concert with its established effects on proteolysis and lipolysis.
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PMID:Effect of glucagon on metabolite compartmentation in isolated rat liver cells during gluconeogenesis from lactate. 19 59

Expression of activation of rat liver adenylate cyclase by the A1 peptide of cholera toxin and NAD is dependent on GTP. The nucleotide is effective either when added to the assay medium or during toxin (and NAD) treatment. Toxin treatment increases the Vmax for activation by GTP and the effect of GTP persists in toxin-treated membranes, a property seen in control membranes only with non-hydrolyzable analogs of GTP such as Gpp(NH)p. These observations could be explained by a recent report that cholera toxin acts to inhibit a GTPase associated with denylate cyclase. However, we have observed that one of the major effects of the toxin is to decrease the affinity of guanine nucleotides for the processes involved in the activation of adenylate cyclase and in the regulation of the binding of glucagon to its receptor. Moreover, the absence of lag time in the activation of adenylate cyclase by GTP, in contrast to by Gpp(NH)p, and the markedly reduced fluoride action after toxin treatment suggest that GTPase inhibition may not be the only action of cholera toxin on the adenylate cyclase system. We believe that the multiple effects of toxin action is a reflection of the recently revealed complexity of the regulation of adenylate cyclase by guanine nucleotides.
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PMID:Essential role of GTP in the expression of adenylate cyclase activity after cholera toxin treatment. 21 59

Acute glucagon treatment of intact rats has been found to cause a stimulation of hepatic mitochondrial respiration as measured by monitoring oxygen uptake polarographically. Rates of State 3 respiration with several NAD-linked substrates and succinate were increased significantly after hormonal treatment and isolation of mitochondria. This stimulation cannot be ascribed to a partial uncoupling effect since State 4 respiration as measured by monitoring oxygen uptake polarographically. Rates of State 3 respiration with either slightly increased or unchanged. Furthermore, rates of uncoupled respiration with these substrates were also stimulated after hormonal treatment. On the other hand, respiratory rates (State 3, 4, and uncoupled) with ascorbate-N,N,N',N'-tetramethyl-p-phenylenediamine as substrate were unaffected by glucagon treatment. The hormonally stimulated rates of respiration produced a corresponding increase in the rate of generation of high energy state as indicated in measurements of Ca2+ uptake by isolated mitochondria. Rates of Ca2+ uptake were monitored by two methods: measurement of initial rates of proton ejection following CaCl2 additions and measurement of disappearance of Ca2+ from the suspension medium using murexide as indicator in a dual wavelength spectrophotometer. A significant stimulation in the initial rate of succinate-dependent Ca2+ uptake was noted after glucagon treatment of animals and isolation of hepatic mitochondria. No effect of the hormonal treatment was seen on the extent of Ca2+ uptake or the stoichiometry of H+ ejected per Ca2+ taken up. That the hormonal effect on Ca2+ transport is at the level of the substrate-induced generation of high energy state is indicated by the observation that no effect of glucagon treatment is seen on ATP-dependent Ca2+ uptake. Glucagon-induced changes in the activities of substrate-metabolizing enzymes are considered unlikely for the following reasons: (a) previously published data showed a lack of a hormonal effect on pyruvate-metabolizing enzymes and (b) data in this study showing no effect of glucagon treatment on the activity of NAD-malate dehydrogenase as measured in mitochondrial lysates. All of these observations are consistent with either an activation of mitochondrial substrate transport and/or a stimulation of mitochondrial electron transport by glucagon treatment. Regardless of the exact mechanism involved, the effect of the hormonal treatment is to produce an increase in ATP synthetic and ion-pumping capability during a period of increased energy demand, i.e. increased gluconeogenesis.
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PMID:Glucagon stimulation of mitochondrial respiration. 24 Aug 44

The effect of tolbutamide on pyridine nucleotides and insulin secretion stimulated by aminophylline, 3,5-AMP-dibutyrate or glucagon was studied in pancreatic islets of rats previously treated with 6-aminonicotinamide (6-AN), an inhibitor of pyridine nucleotide synthesis. After being incubated for 60 min in a Krebs-Ringer-Bicarbonate-Buffer in the absence of glucose, pancreatic islets of rats i.p. injected with 35 mg/kg of 6-AN 6 hrs before pancreas removal contained about 30% less NADP and NADPH than did islets of control rats. No changes of NDA or NADH were observed in islets of 6-AN-treated animals. Addition of 16.5 mM glucose led to an increase of NADH, NADPH and a decrease of NADP in islets of both groups of animals; NAD levels remained unchanged. In vitro addition of tolbutamide to islets of control rats did not affect the levels of NADPH or NADP in the presence of 5.5 mM glucose. When 16.5 mM glucose were present, a decrease of NADPH and an increase of NADP was obvious. No effect of tolbutamide on insular NADPH or NADP was observed in islets of rats previously treated with 6-AN be it in the presence of 5.5 or 16.5 mM glucose. In islets of 6-AN-treated rats insulin release in response to aminophylline or 3,5-AMP-dibutyrate in the presence of 5.5 mM glucose was significantly depressed, when compared to islets of untreated controls. Addition of tolbutamide increased insulin release due to aminophylline, 3,5-AMP-dibutyrate or glucagon islets of controls. Tolbutamide alone was without effect. In islets of 6-AN-treated rats aminophylline, 3,5-AMP-dibutyrate or glucagon stimulated insulin release only when tolbutamide was present. Our data suggest that there is no direct interference of tolbutamide with pyridine nucleotides of pancreatic islets, and that tolbutamide increases the secretory response of the beta-cell to aminophylline, 3,5-AMP-dibutyrate or glucagon when insulin release due to these agents is inhibited during decrease of insular NADP and NADPH, caused by 6-AN.
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PMID:Effect of tolbutamide on aminophylline-, 3,5-AMP-dibutyrate- or glucagon-induced insulin release from pancreatic islets after impairment of pyridine nucleotide metabolism caused by 6-aminonicotinamide (6-AN). 24 43

The role of cytosol components in the loss of rat liver adenylate cyclase activity which occurs during the preparation of particulate fractions from crude homogenates was studied. Epinephrine (5 micron)-, glucagon (10 micron)-, and fluoride (5 mM)- stimulated activities of twice-washed particulates were 31%, 58% and 67% of the homogenate activities, respectively. Addition of cytosol (100,000 X g supernatant devoid of adenylate cyclase activity) restored these activities to 82%, 88% and 80%. Cytosol also increased particulate basal activity from 60% of homogenate activity to 98%. The cytosol components capable of increasing adenylate cyclase activity were heat labile, nondialyzable, stable to freezing at -20 degrees, resistant to change of pH between 2 and 12, and unaffected by EGTA and NAD. Pretreatment with pepsin destroyed the effects of cytosol on both epinephrine- and glucagon-sensitive activities, whereas trypsin destroyed the effect of cytosol only on epinephrine-sensitive activity. The cytosol effect on adenylate cyclase was specific, since several purified proteins and ubiquitin, did not stimulate enzyme activity. Only part of the cytosol effect could be attributed to its GTP content. GTP at the concentration present in cytosol stimulated epinephrine-sensitive activity but significantly less than did cytosol, while GTP had no effect on glucagon-sensitive activity. Dialyzed cytosol retained its effectiveness even after removal of most (97%) of its GTP to a concentration where GTP had only a minimal effect on epinephrine-sensitive activity. Cytosol, unlike GTP, stimulated rather than inhibited activation by fluoride. Cytosol thus appears to contain at least two different protein components, which increase the activity of the two hormone-sensitive adenylate cyclases and presumably account in part for losses of adenylate cyclase activities seen during the preparation of particulates from homogenates.
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PMID:Activation of epinephrine and glucagon-sensitive adenylate cyclases of rat liver by cytosol protein factors. Role in loss of enzyme activities during preparation of particulate fractions, quantitation and partial characterization. 72 79

The metabolic effects of glucagon and glucagon plus insulin on the isolated rat livers perfused with 10 mM sodium L-lactate as substrate were studied. Glucagon stimulated gluconeogenesis, ketogenesis and ureogenesis at the concentration used of 2.1 nM. The addition of insulin to give a glucagon-to-insulin ratio of 0.2 reversed all the glucagon effects. The glucagon enhancement of gluconeogenesis was accompanied by a rise in cytosolic and mitochondrial state of reduction of the NAD system and a fall in the [ATP]/[ADP] ratio. The analysis of the intermediary metabolite concentrations suggested, as possible sites of glucagon action, the steps between pyruvate and phosphoenolpyruvate as well as the reactions catalyzed by phosphofructokinase and/or fructose bisphosphatase. All the changes in metabolite contents were abolished when insulin was present. Glucagon increased the intramitochondrial concentration of all the metabolites, whose intracellular distribution was calculated. The finding of a significant rise in the calculated intramitochondrial concentration of oxaloacetate points to pyruvate carboxylation as an important site of glucagon interaction with the gluconeogenic pathway. A primary event in the glucagon action redistributing intracellular metabolites seems to be the mitochondrial entry of malate. The possibility is discussed that the changes in metabolite cellular distribution were brought about by the increased cellular state of reduction caused by the hormone.
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PMID:Glucagon and insulin control of gluconeogenesis in the perfused isolated rat liver. Effects on cellular metabolite distribution. 117 30

Rats were acutely administered ethanol as a primed constant infusion in order to produce sustained blood ethanol levels of 8-12 or 55-65 mM. At the end of ethanol infusion the livers were either freeze-clamped in vivo or isolated and perfused for metabolic studies. The rate of gluconeogenesis and its responsiveness to phenylephrine (10 microM), prostaglandin F2 alpha (5 microM) and glucagon (10 nM), as well as the redox state of the cytosolic NAD(+)-NADH system were assessed in livers isolated from acutely ethanol-treated rats, and subsequently perfused without ethanol. For liver clamped in vivo, high- but not low-ethanol treatment decreased the ATP content by 31% and slightly increased ADP and AMP content, resulting in a decreased energy charge (11%). Glutamate and aspartate content was also increased in high-dose ethanol-infused rats with no changes in malate and 2-oxoglutarate content. Gluconeogenesis with saturating concentrations of lactate (4 mM)+pyruvate (0.4 mM) was delayed in reaching a plateau in the livers of high-dose ethanol-treated rats and its response to all three stimulators was impaired. Low-dose ethanol treatment only decreased the liver response to phenylephrine. While the perfused livers of low-dose ethanol-treated rats displayed no changes in adenine nucleotide content, the livers of high-dose ethanol-treated rats had a decreased ATP (35%) and an increased AMP (77%) content, paralleled by a fall in the total adenine nucleotides (14%) and energy charge (14%). No differences were observed between the saline- and ethanol-treated rats with respect to malate-aspartate shuttle intermediate concentration in perfused livers. Also, the livers of high-, but not low-dose ethanol-treated rats had a more negative value of NAD(+)-NADH redox state as compared to the livers of control rats. The data suggest that acute ethanol intoxication produces changes in liver metabolism and its responsiveness to hormones/agonists that are demonstrable for at least 2 hr after isolation and perfusion of the liver.
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PMID:Effects of acute alcohol intoxication on gluconeogenesis and its hormonal responsiveness in isolated, perfused rat liver. 135 76

Pancreatic B-cells exposed in vivo or in vitro to streptozotocin (SZ), the N-nitrosourea derivative of glucosamide, present a long-lasting impairment in the production and release of insulin while other cell functions are better preserved. This functional impairment is associated with a defective mitochondrial function. To further study the mechanisms behind SZ actions, mouse pancreatic islets were exposed in vitro to SZ (1.5 mM) or to different concentrations of methyl methanesulfonate (MMS; 2, 4 and 6 mM). The effect of the aglucone moiety of SZ, nitroso-N-methylurea (NMU; 2, 4 and 6 mM) was also tested. Islets were either studied immediately after exposure to the drugs (day 0) or after six days in culture following toxin treatment (day 6). On day 0 the islets showed a decrease in the NAD + NADH content, decreased glucose oxidation rates and an impaired insulin release in response to glucose. Six days after exposure to SZ there was still impaired glucose oxidation and insulin release, and decreased islet insulin mRNA and insulin content, but the NAD + NADH content was again similar to the control group. On the other hand, islets which survived for 6 days in culture following exposure to either MMS or NMU were able to regain normal B-cell function. The mouse islets exposed to SZ, NMU and MMS showed on day 6 a 30-40% decrease in the content of the mitochondrial DNA encoded cytochrome b mRNA and a 60-70% decrease in total mitochondrial DNA, as evaluated by dot and Southern blot analysis. Only SZ decreased the insulin mRNA content whereas both MMS and NMU decreased the glucagon mRNA content. As a whole, the data obtained indicate that SZ, NMU and MMS induce damage to the mitochondrial genome, and this may contribute to the B-cell dysfunction observed after SZ treatment. It is conceivable that the glucose moiety of SZ may direct the methylation to other intracellular sites besides the mitochondrial DNA, thus explaining the different functional responses of islets following exposure to SZ and NMU.
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PMID:Exposure of pancreatic islets to different alkylating agents decreases mitochondrial DNA content but only streptozotocin induces long-lasting functional impairment of B-cells. 183 18

When the Gs in rat liver membranes was prelabeled with [32P]NAD and cholera toxin, solubilized with octylglucoside, and then analyzed by sucrose density gradient centrifugation, it was fractionated into two peaks with approximate molecular sizes of 12-13S and 3-4S. Pretreatment without or with GDP beta S of the labeled membranes resulted in a larger peak in the high molecular weight region, whereas pretreatment with glucagon plus GTP gamma S caused almost equal peaks in both regions. The affinity-purified anti-nucleoside diphosphate (NDP) kinase antibodies only precipitated the Gs in high molecular weight region. Under the same condition, small but significant NDP kinase activity was associated with the high molecular weight Gs region although a large portion of the enzyme activity was recovered in fractions where it alone should appear (6.2S). Both Lubrol-PX and digitonin solubilized the Gs in forms insensitive to immunoprecipitation by anti-NDP kinase antibodies although the latter detergent was able to solubilize the Gs in a high molecular weight form, that is, a ternary glucagon-receptor-G protein complex. These results demonstrate that Gs and membrane-associated NDP kinase may exist in part in a complexed form in membranes. Physiological relevance of the complex formation in membrane signal transduction is discussed.
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PMID:Evidence for complex formation between GTP binding protein(Gs) and membrane-associated nucleoside diphosphate kinase. 215 21

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