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)

Glucagon causes a rapid activation of cAMP-dependent protein kinase in rat liver parenchymal cells which correlates well with the accumulation of cAMP. Full activation of phosphorylase or inactivation of glycogen synthase is achieved with half-maximal or less activation of protein kinase. Epinephrine stimulates glycogen breakdown in these cells mainly by mechanisms involving alpha-adrenergic receptors and not beta-receptors. Activition of alpha-receptors results in rapid activation of phosphorylase and inactivation of glycogen synthase without accumulation of cAMP or activation of cAMP-dependent protein kinase. Activation of beta-receptors causes a transient rise in cAMP and a short-lived activation of protein kinase with correspondingly little stimulation of glycogenolysis.
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PMID:Studies on the role of cAMP-dependent protein kinase in the actions of glucagon and catecholamines on liver glycogen metabolism. 18 93

1. Rat hearts were perfused with 32Pi, and contractile force was increased by positive inotropic agents (agents that increase contractility). The inhibitory subunit of troponin (troponin I) was then isolated by affinity chromatography in 8M-urea, and its 32P content measured. Incorporation of phosphate into the subunit was calculated on the basis of the [gamma-32P]ATP specific radioactivity in the hearts. 2. When hearts were perfused with 30 nM-DL-isoprenaline (N-isopropylnoradrenaline), there was an increase in contractile force over 30s which was paralleled by an increase in troponin I phosphorylation. When hearts were perfused for 25s with increasing concentrations of isoprenaline from 1 NM to 0.6 muM, there was again a parallel increase in contractile force and troponin I phosphorylation. The maximum phosphorylation observed was 1.5 mol of phosphate/mol of troponin I, which was reached after 25s with 0.1 muM-isoprenaline. 3. Hearts were stimulated with a 15s pulse perfusion of 30nM-DL-isoprenaline. There was an increase in contractile force which was followed by a return to the control value within 50s. Troponin I phosphorylation increased to a plateau value which was reached within 30s, and remained constant for 60s after the isoprenaline pulse. Phosphorylase a and 3':5'-cyclic AMP concentration showed changes similar to that of the contractile force. There was no change in 3':5'-cyclic GMP concentration. 4. When hearts stimulated with a 15S pulse of isoprenaline were subsequently perfused with 0.6 muM-acetylcholine, the changes in contractile force, phosphorylase a and 3':5'-cyclic AMP were very similar to those seen with the 15s pulse of isoprenaline alone. Troponin I phosphorylation increased to a maximum 30s after the end of the isoprenaline pulse, but then rapidly decreased during the subsequent 30s. This decrease was preceded by a 60% increase in the concentration of 3':5'-cyclic GMP. 5. Hearts were perfused with 0.2 muM-glucagon for periods up to 60s. Contractile force showed little change for the first 30s, but then increased rapidly. This was paralleled by changes in 3':5'-cyclic AMP concentration. Troponin I phosphorylation increased slowly, but the increase in contractile force had reached a maximum before significant phosphorylation had occurred. 6. It is concluded that under certain conditions, e.g. immediately after beta-adrenergic stimulation, there is a good correlation between contractile force and troponin I phosphorylation. However, under other conditions, e.g. when contractile force is decreasing after removal of beta-adrenergic stimulation or in the presence of glucagon, contractile force and troponin I phosphorylation are not well correlated. These results suggest that mechanisms for modifying cardiac contractility, other than troponin I phosphorylation, must be present in rat heart.
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PMID:Studies on the phosphorylation of the inhibitory subunit of troponin during modification of contraction in perfused rat heart. 18 17

In liver cells isolated from fed female rats, glucagon (290nM) increased adenosine 3':5'-monophosphate (cyclic AMP) content and decreased cyclic AMP binding 30 s after addition of hormones. Both returned to control values after 10 min. Glucagon also stimulated cyclic AMP-independent protein kinase activity at 30 s and decreased protein kinase activity assayed in the presence of 2 muM cyclic AMP at 1 min. Glucagon increased the levels of glycogen phosphorylase a, but there was no change in total glycogen phosphorylase activity. Glucagon increased glycogen phosphorylase a at concentrations considerably less than those required to affect cyclic AMP and protein kinase. The phosphodiesterase inhibitor, 1-methyl-3-isobutyl xanthine, potentiated the action of glucagon on all variables, but did not increase the maximuM activation of glycogen phosphorylase. Epinephrine (1muM) decreased cyclic AMP binding and increased glycogen phosphorylase a after a 1-min incubation with cells. Although 0.1 muM epinephrine stimulated phosphorylase a, a concentration of 10 muM was required to increase protein kinase activity. 1-Methyl-3-isobutyl xanthine (0.1 mM) potentiated the action of epinephrine on cyclic AMP and protein kinase. (-)-Propranolol (10muM) completely abolished the changes in cyclic AMP binding and protein kinase due to epinephrine (1muM) in the presence of 0.1mM 1-methyl-3-isobutyl xanthine, yet inhibited the increase in phosphorylase a by only 14 per cent. Phenylephrine (0.1muM) increased glycogen phosphorylase a, although concentrations as great as 10 muM failed to affect cyclic AMP binding or protein kinase in the absence of phosphodiesterase inhibitor. Isoproterenol (0.1muM) stimulated phosphorylase and decreased cyclic AMP binding, but only a concentration of 10muM increased protein kinase. 1-Methyl-3-isobutyl xanthine potentiated the action of isoproterenol on cyclic AMP binding and protein kinase, and propranolol reduced the augmentation of glucose release and glycogen phosphorylase activity due to isoproterenol. These data indicate that both alpha- and beta-adrenergic agents are capable of stimulating glycogenolysis and glycogen phosphorylase a in isolated rat liver cells. Low concentrations of glucagon and beta-adrenergic agonists stimulate glycogen phosphorylase without any detectable increase in cyclic AMP or protein kinase activity. The effects of alpha-adrenergic agents appear to be completely independent of changes in cyclic AMP protein kinase activity.
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PMID:Activation of protein kinase and glycogen phosphorylase in isolated rat liver cells by glucagon and catecholamines. 18 18

We have studied the mode of action of three hormones (angiotensin, vasopressin and phenylephrine, an alpha-adrenergic agent) which promote liver glycogenolysis in a cyclic AMP-independent way, in comparison with that of glucagon, which is known to act essentially via cyclic AMP. The following observations were made using isolated rat hepatocytes: (a) In the normal Krebs-Henseleit bicarbonate medium, the hormones activated glycogen phosphorylase (EC 2.4.1.1) to about the same degree. In contrast to glucagon, the cyclic AMP-independent hormones did not activate either protein kinase (EC 2.7.1.37) or phosphorylase b kinase (EC 2.7.1.38). (b) The absence of Ca2+ from the incubation medium prevented the activation of glycogen phosphorylase by the cyclic AMP-independent agents and slowed down that induced by glucagon. (c) The ionophore A 23187 produced the same degree of activation of glycogen phosphorylase, provided that Ca2+ was present in the incubation medium. (d) Glucagon, cyclic AMP and three cyclic AMP-dependent hormones caused an enhanced uptake of 45Ca; it was verified that concentrations of angiotensin and of vasopressin known to occur in haemorrhagic conditions were able to produce phosphorylase activation and stimulate 45Ca uptake. (e) Appropriate antagonists (i.e. phentolamine against phenylephrine and an angiotensin analogue against angiotensin) prevented both the enhanced 45Ca uptake and the phosphorylase activation. We interpret our data in favour of a role of calcium (1) as the second messenger in liver for the three cyclic AMP-independent glycogenolytic hormones and (2) as an additional messenger for glucagon which, via cyclic AMP, will make calcium available to the cytoplasm either from extracellular or from intracellular pools. The target enzyme for Ca2+ is most probably phosphorylase b kinase.
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PMID:On the role of calcium as second messenger in liver for the hormonally induced activation of glycogen phosphorylase. 18 44

1. A parallel dose-dependent activation of histone kinase, phosphorylase kinase and phosphorylase was observed in isolated hepatocytes incubated in the presence of glucagon; the effect of suboptimal concentrations of glucagon was antagonized by insulin. 2. An activation of phosphorylase which was not accompanied by a stable change in the activity of phosphorylase kinase was observed in hepatocytes incubated with phenylephrine, isoproterenol or vasopressin as well as on decapitation of unanesthetized animals. A dissociation of the two enzymic activities was also observed in hepatocytes incubated in the presence of a high concentration of glucose, in which phosphorylase was strongly inactivated with no change in the activity of phosphorylase kinase. 3. The activation of phosphorylase by phenylephrine in isolated hepatocytes was counteracted by insulin, greatly decreased by the absence of Ca2+ from the incubation medium, and completely suppressed by the replacement of Na+ by K+. 4. In a liver extract, phosphorylase kinase could also be activated by trypsin. Control, glucagon-activated or trypsin-activated phosphorylase kinase was inhibited by about 70% by EGTA and the activity was restored by the addition of Ca2+. 5. The mechanisms that control the activity of phosphorylase kinase and of phosphorylase are discussed.
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PMID:Hormonal and ionic control of the glycogenolytic cascade in rat liver. 19 6

1. The administration of insulin to anaesthetized rabbits caused the inactivation of liver phosphorylase and phosphorylase kinase, but did not change either the hepatic concentration of cyclic AMP or the activity of cyclic AMP-dependent histone kinase. All measured parameters were increased by the subsequent administration of glucagon. 2. Activation of glycogen synthase by insulin was only observed when phosphorylase had been strongly inactivated.
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PMID:The effect of insulin on the glycogenolytic cascade and on the activity of glycogen synthase in the liver of anaesthetized rabbits. 19 7

The glycogen pellet of dog liver extracts contains a phosphorylase phosphatase which has characteristics different from those of the phosphatases extracted from the cytosol. The phosphatase associated with glycogen is characterized by a M, of 51,000, a half maximal inhibition at 0.3 mM ATP (Hill coefficient : 2) and a Ki for Mg2+ of 1 mM. Treatment with urea or mercaptoethanol of the phosphatase associated with glycogen does not influence the activity, the Mr or the half maximal inhibition by ATP, but a decrease of the Hill coefficient for ATP is observed. A similar treatment of the phosphatases extracted from the high speed supernatant results in a decrease of the Mr of the spontaneously active form from 215,000 to 43,000, without an effect on the Ki for ATP (7 micronM), but accompanied by an increase in activity. The ATP-Mg dependent form of the phosphatase from the high speed supernatant (Mr : 138,000 ; Ka for ATP in the presence of 0.1 mM Mg2+ : 0.3 micronM), is denatured by urea or mercaptoethanol. The phosphatase associated with particulate glycogen cannot be found in the supernatant, nor the phosphorylase phosphatases present in the supernatant in the glycogen pellet. When all the glycogen is mobilized (starvation, glucagon) the phosphatase specifically associated with glycogen cannot be found as such in the cytosol. No activation of synthase beta can be detected neither with the phosphatases extracted from the cytosol nor with the enzyme released from the glycogen pellet.
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PMID:Multiple molecular forms of phosphorylase phosphatase associated with particulate glycogen and extracted from the cytosol of dog liver. 19 25

The effects of starvation on the hepatic glycogen synthase and phosphporylase systems were sequentially assessed in fed and 24-120-hr-fasted rats. Enzymic changes before and after glucose were correlated with simultaneous measurements of hepatic cyclic AMP and glycogen concentrations and glucose, insulin, and glucagon concentrations in the portal vein plasma. Fasting caused parallel changes in plasma glucose and hepatic glycogen concentrations with decreases by 24 hr and subsequent increases, which correlated with increases in hepatic synthase l and decreases in phosphorylase activites. Hepatic cyclic AMP levels increased as 24-48 hr, decreased below fed levels at 96 hr, and increased again at 120 hr. Fasting caused progressive impairment of glucose disposal, decreased basal and postglucose insulin concentrations, and decreased basal glucagon levels at 48-72 hr. Hepatic synthase l increments following glucose were exaggerated in 48-120-hr-fasted rats, although consistent phosphorylase decrements were seen only in fed rats. There was no clearcut relationship between synthase activation and phosphorylase inactivation following glucose in fed or fasted rats.
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PMID:Effect of starvation on hepatic glycogen metabolism and glucose homeostasis. 20 23

In normal fed rats, glycogen synthase D phosphatase activity in a glycogen pellet preparation was only partially inhibited (approximately 50%) by high concentrations of EDTA. However, the proportion of phosphatase activity inhibited by EDTA was markedly and rapidly (15 s) increased following glucagon or cAMP administration. Epinephrine administration did not alter the proportion of activity inhibited by EDTA. Glucose administration rapidly (2 min) reduced the proportion of synthase phosphatase activity inhibitable by EDTA. That is, the effect of glucose was just the opposite of that produced by glucagon or cAMP. Insulin administration had no effect on phosphatase activity. Synthase phosphatase activity assayed in the absence of EDTA was similar in all groups except for a moderate increase after glucose administration. Addition of Mg2+ completely reversed EDTA inhibition. Phosphorylase phosphatase activity in each group was not modified by addition of EDTA, although the percentage of phosphorylase in the alpha form was higher in glucagon-treated and lower in the glucose-treated animals as expected. These data suggest the presence of rapidly interconvertible forms of either synthase phosphatase or its substrate synthase D, detectable as a change in EDTA inhibitability and subject to glucose and glucagon control.
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PMID:In vivo glucose-, glucagon-, and cAMP-induced changes in liver glycogen synthase phosphatase activity. 20 88

Epinephrine rapidly activates phosphorylase in hepatocytes, mainly by a mechanism(s) involving alpha-adrenergic and not beta-adrenergic receptors. The alpha-adrenergic mechanism does not involve accumulation of cAMP or activation of cAMP-dependent protein kinase. It is impaired when hepatocytes are depleted of calcium by EGTA treatment and is rapidly restored by readdition of calcium. Basal phosphorylase is also lowered by calcium deficiency and rapidly increased by calcium but not other divalent cations. The divalent cation ioniphore A23187 increases phosphorylase a levels in hepatocytes in a calcium-dependent manner. Calcium deficiency does not modify the effects of glucagon, cAMP, or beta-adrenergic activation on phosphorylase. Activation of alpha-adrenergic receptors rapidly increases 45Ca fluxes in hepatocytes. Glucagon produces similar effects, but supraphysiological concentrations are required. The hypothesis is advanced that alpha-adrenergic activation of phosphorylase involves alterations in cell calcium such that there is an increase in cytosolic Ca2+ concentration leading to increased phosphorylase kinase activity. Epinephrine induces greater cAMP accumulation in calcium-depleted cells than in normal cells. The effect is mediated by alpha-adrenergic and not beta-adrenergic receptors. Calcium deficiency also cuases cAMP accumulation in hepatocytes incubated with phenylephrine but does not modify the responses of the cells to isoproterenol, glucagon, or cAMP. Low concentrations of calcium rapidly reverse alpha-adrenergic receptor-mediated cAMP accumulation in calcium-depleted cells. The hypothesis is advanced that calcium normally exerts an inhibitory effect on a linkage between alpha-adrenergic receptors and adenylate cyclase in hepatocytes.
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PMID:Mechanisms of catecholamine actions on liver carbohydrate metabolism. 20 89

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