Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:P01275 (glucagon)
 26,492 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

In rat liver plasma membranes preactivated with guanosine 5'-[beta,gamma-imido[triphosphate (GuoPP[NH]P), GDP promoted coupling of occupied glucagon receptor to adenylyl cyclase [adenylate cyclase; ATP, pyrophosphate-lyase (cyclizing), EC 4.6.1.1] with an apparent association constant Ka of 0.1-0.15 microM. The apparent Ka for the same effect of GTP was 0.2 microM. The effect of GDP was shown not to be due to GTP formed by putative transphosphorylation reaction(s) when ATP was present in the assay as substrate. In membranes not preactivated with GuoPP[NH]P, GDP both competitively inhibited GuoPP[NH]P stimulation of adenylyl cyclase (Ki 0.10 microM) and supported stimulation of cyclizing activity (apparent Ka 0.10 microM) by glucagon. These effects of GDP occurred in the absence of added GTP and in the absence of sufficient formation of GTP by putative transphosphorylation reaction(s) to account for them. It is concluded that two levels of regulation of liver adenylyl cyclase (cyclizing) activity must exit. One level is termed "receptor regulation"; it depends on occupancy of a receptor-related R site by nucleotide and is specific for either GDP or GTP. The second level of regulation is termed "GTPase regulation"; it is inhibited by GDP, depends on both GTP and GTPase, and accounts for activation of cyclizing activity by nonhydrolyzable analogs of GTP. The data suggest that both levels of regulation coexist and may synergize, one mediating responses to stimuli external to the cell (receptor regulation) and the other mediating stimuli of intracellular origin (GTPase regulation).
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PMID:Coupling of the glucagon receptor to adenylyl cyclase by GDP: evidence for two levels of regulation of adenylyl cyclase. 22 58

1. The irradiation-inactivation procedure was used to study changes in the state of association of the protein components of adenylate cyclase in intact rat liver plasma membranes by measurement of alterations in the target size determined from the catalytic activity of the enzyme. 2. A decrease in target size at 30 degrees C in response to p[NH]ppG (guanosine 5'-[betagamma-imido]triphosphate) or GTP was demonstrated, which we take to reflect the dissociation of a regulatory subunit. The effect of GTP is potentiated by glucagon. This effect is not observed at 0 degrees C. 3. An increase in target size was observed in response to glucagon in the absence of guanine nucleotides, which we take to reflect the association of glucagon receptor with adenylate cyclase. 4. We propose a model for the activation of adenylate cyclase by glucagon in which the binding of the hormone to its receptor causes an initial association of the receptor with the catalytic unit of the enzyme and a regulatory subunit to form a ternary complex. The subsequent activation of the adenylate cyclase results from the dissociation of the ternary complex to leave a free catalytic unit in the activated state. This dissociation requires the binding of a guanine nucleotide to the regulatory subunit. 5. The effects of variation of temperature on the activation of adenylate cyclase by glucagon and guanine nucleotides were examined and are discussed in relation to the irradiation-activation data. 6. The effectiveness of hormones, guanine nucleotides and combinations of hormone and guanine nucleotides as activators of adenylate cyclase in both rat liver and rat fat-cell plasma membranes was studied and the results are discussed in relation to the model proposed, which is also considered in relation to the observations published by other workers.
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PMID:Transient complexes. A new structural model for the activation of adenylate cyclase by hormone receptors (guanine nucleotides/irradiation inactivation). 23 Aug 31

1. The local anaesthetic benzyl alcohol progressively activated glucagon-stimulated adenylate cyclase activity up to a maximum at 50 mM-benzyl alcohol. Further increases in benzyl alcohol concentration inhibited the activity. The fluoride-stimulated adenylate cyclase activity was similarly affected except for an inhibition of activity occurring at low benzyl alcohol concentrations (approx. 10 mM. 2. The fluoride-stimulated adenylate cyclase activity of a solubilized enzyme preparation was unaffected by any of the benzyl alcohol concentrations tested. 3. Increases in 3-phenylpropan-1-ol and 5-phenylpentan-1-ol concentrations progressively activated both the fluoride- and glucagon-stimulated adenylate cyclase activities up to a maximum, above which further increases in alcohol concentration inhibited the activities. 4. The 'break' points in Arrhenius plots of glucagon-stimulated adenylate cyclase activity in native plasma membranes, and in plasma membranes fused with synthetic dimyristoyl phosphatidylcholine so as to constitute 60% of the total lipid pool, were decreased by approx. 6 degrees C by addition of 40 mM-benzyl alcohol. This was accompanied by a fall in the associated activation energies. 6. Arrhenius plots of fluoride-stimulated adenylate cyclase activity in the presence and absence of 40 mM-benzyl alcohol were linear, although addition of benzyl alcohol caused a dramatic decrease in the associated activation energy of the reaction. 7. 5'-Nucleotidase activity was stimulated by benzyl alcohol, and the 'break' point in the Arrhenius plot of its activity was decreased by about 6 degrees C by addition of 40 mM-benzyl alcohol to the assay. 8. It is suggested that benzyl alcohol effects a fluidization of the bilayer, which is clearly demonstrated by its ability to lower the temperature of a lipid phase separation occurring at 28 degrees C in the outer half of the bilayer to around 22 degrees C. The increase in bilayer fluidity relieves a physical constraint on the membrane-bound adenylate cyclase, activating the enzyme. 9. The various inhibition phenomena are discussed in detail, together with the suggestion that the interaction between the uncoupled catalytic unit of adenylate cyclase and the lipids of the bilayer is altered on its physical coupling to the glucagon receptor.
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PMID:The activity of glucagon-stimulated adenylate cyclase from rat liver plasma membranes is modulated by the fluidity of its lipid environment. 69 51

Glucagon was iodinated with the lactoperoxidase method at pH 10.0 in the presence of propylene glycol using a substitution of 0.3 g-atom I/mol glucagon. Under these conditions the reactivity of the iodine to tyrosine at position 13 is found to be 4-fold that of the tyrosine at position 10. The amount of diiodotyrosine was less than one-twentieth that of the monoiodotyrosine at either tyrosine residue. Relatively pure monoiodo[125I]tyrosine-13-glucagon can be separated from other iodoglucagons by means of DEAE-chromatography. Such a homogeneous preparation with a known position of the iodine makes it possible to study a specific interaction between the monoiodoglucagon and the glucagon antisera or the glucagon receptor.
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PMID:Preparation of monoiodotyrosine-13-glucagon. 85 7

Adenosine inhibits the rat liver adenylate cyclase system at a regulatory site that is distinct from the glucagon receptor, the guanine nucleotide regulatory site, and the active site involved in catalysis of ATP to cyclic AMP. The effects of the nucleoside are also independent of the concentration of uncomplexed ATP (ATP4-) in the assay medium. Glucagon, but not guanine nucleotides, sensitizes the system to inhibition by adenosine. Depending on assay conditions, the hormone can shift the concentration of adenosine required for 50% inhibition by as much as 10-fold. Under optimal conditions, the apparent Ki for adenosine is 25 micron. Both Mg2+ and Mn2+ increase adenylate cyclase activity and, in order of relative potency, increase the sensitivity of the enzyme to adenosine inhibition; Mn2+ is 50- to 100-fold more potent than Mg2+. The adenosine inhibitory site exhibits stringent structural requirements for nucleoside action. Most alterations of the purine ring result in loss of activity, whereas alterations in the ribose ring are tolerated, and some deoxyadenosine analogs are even more effective than adenosine. Naturally occurring nucleosides and nucleotides, such as inosine, guanosine, and 5'-AMP, are inactive. Analog studies reveal also that inhibition of the hepatic system occurs at a site which is clearly different from the sites through which adenosine activates other adenylate cyclase systems, and that the liver enzyme appears to have no site for activation by the nucleoside.
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PMID:Regulation by glucagon and divalent cations of inhibition of hepatic adenylate cyclase by adenosine. 89 90

The ontogenesis of the hepatic glucagon-sensitive adenylate cyclase system has been studied in the rat. With a partially purified liver membrane preparation, fetal adenylate cyclase was less responsive to glucagon than the enzyme from neonatal or adult livers. Similar results were obtained in gently prepared liver homogenates, suggesting that destruction of essential components of the fetal liver membrane did not account for the relative unresponsiveness of the adenylate cyclase enzyme to glucagon. Investigation of other factors that might account for diminished fetal hepatic responsiveness to glucagon indicate (a) minimal glucagon degradation by fetal membranes relative to 8-day or adult tissue; and (b) available adenylate cyclase enzyme, as suggested by a 13-fold increase over basal cyclic AMP formation with NaF in fetal liver membranes. These results indicate that neither enhanced glucagon degradation nor adenylate cyclase enzyme deficiency accounts for the relative insensitivity of the fetal hepatic adenylate cyclase system to glucagon. In early neonatal life, hepatic adenylate cyclase responsiveness to glucagon rapidly developed and was maximal 6 days after birth. These changes were closely paralleled by a fivefold increase in glucagon binding and the kinetically determined Vmax for cyclic AMP formation. These observations suggest that (a) fetal hepatic unresponsiveness to glucagon may be explained by a limited number of glucagon receptor sites; (b) during the neonatal period, the development of glucagon binding is expressed primarily as an increase in adenylate cyclase Vmax; (c) the ontogenesis of hepatic responsiveness to glucagon may be important in the resolution of neonatal hypoglycemia.
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PMID:Development of glucagon sensitivity in neonatal rat liver. 95 86

Glucagon stimulated the incorporation of Na2H32PO4 and L-(14C)serine into phosphatidylserine in heart muscle slices. The increase above control was about 2-fold at ten minutes and 6-fold at thirty minutes for (32P) and 12-fold as early as three minutes for (14C)serine. Although a smaller, but significant, incorporation of (32P) into phosphatidylethanolamine was also observed, glucagon did not stimulate the incorporation of (14C)serine into phosphatidylethanolamine. Glucagon did not significantly augment the incorporation of either tracer into phosphatidylcholine, lysophosphatidylcholine, phosphatidylinositol, cardiolipin, phosphatidic acid, or sphingomyelin. Dibutyryl cyclic 3',5'-AMP did not increase the incorporation of (32P) or (14C)serine into phosphatidylserine. Since phosphatidylserine appears to serve a critical role in coupling the glucagon receptor to the catalytic moiety of adenylate cyclase, the data suggest that the hormone may initially increase the amount of its own coupler.
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PMID:Glucagon-mediated stimulation of (32P) orthophosphate and (14C) serine incorporation into phosphatidylserine in cardiac muscle slices. 124 47

The ligand-induced internalization of the hepatic glucagon receptor has been studied in rats in vivo using cell fractionation. Injection of glucagon (11 nmol/100 g BW) led to a 2- to 3-fold increase in glucagon-binding activity in Golgi-endosomal (GE) fractions along with a 10-20% decrease in binding activity in plasma membrane (PM) fractions. These changes were time and dose dependent, reaching a maximum by 12-24 min and undergoing reversal in 2 h. Glucagon injection also caused a 20% decrease in glucagon binding to the total particulate fraction, which did not occur when binding was measured in the presence of the detergent octylglucoside. The change in glucagon-binding activity in PM and GE fractions resulted mainly from a change in receptor number; affinity remained unaffected (apparent Kd, 0.5 and 5 nM, respectively). A 5- to 10-fold increase in the glucagon content of GE fractions was observed in glucagon-treated rats. Neither the distribution of PM and Golgi marker enzymes nor that of the asialoglycoprotein receptor was affected by glucagon treatment. Regardless of glucagon treatment, glucagon receptors in GE fractions were less sensitive to GTP than receptors in PM fractions with respect to both inhibition of steady state binding and dissociation of prebound ligand. On sodium dodecyl sulfate-polyacrylamide gel electrophoresis, glucagon-receptor complexes formed in PM and GE fractions and subsequently cross-linked showed the same apparent mol wt (57 kilodaltons). In addition, they were identically sensitive to N-glycanase treatment, with two major species of lower mol wt generated. However, only cross-linked complexes associated with PM fractions showed detectable GTP sensitivity. GE fractions displayed a GTP-sensitive adenylate cyclase activity that was about 12 times lower than that of PM fractions. In both fractions, activity was stimulated by the addition of forskolin (8-fold) and, to a lesser extent, glucagon (3-fold). In vivo glucagon treatment led to an increase in activity in GE, but not PM, fractions. These results are consistent with the view that upon acute occupancy, hepatic glucagon receptors are rapidly and specifically internalized along with their ligand. During this process, receptor retained structural integrity and uncouple, albeit partially, from other components of the adenylate cyclase system.
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PMID:Ligand-mediated internalization of glucagon receptors in intact rat liver. 131 25

Evidence suggests that ethanol desensitizes hepatocytes to the trophic effects of hormones. Cyclic AMP-dependent signals are important regulators of intermediary metabolism, cellular proliferation and differentiation, and modulate liver growth during hepatic regeneration. The events leading to cyclic AMP accumulation after partial hepatectomy were characterized in rats consistently fed ethanol-containing diets and compared with results in rats fed isocaloric amounts of nonethanol diet to determine whether altered cyclic AMP-dependent signal transduction contributes to ethanol-associated aberrations in hepatic growth regulation. Ethanol treatment significantly inhibited hepatic accumulation of cyclic AMP after partial hepatectomy. This was most likely the result of decreased synthesis of cyclic AMP because activation of adenylyl cyclase by agents acting through receptors (e.g., glucagon or isoproterenol), GTP-binding proteins (GTP-gamma-S) and directly on adenylyl cyclase (e.g., forskolin) was significantly inhibited in ethanol-fed rats. Both homologous and heterologous desensitization contributed to this effect. beta 1-Adrenergic receptors were relatively down-regulated 6 hr after partial hepatectomy in ethanol-fed rats, whereas glucagon receptor kinetics were similar in the two groups. Liver membrane expression of GTP-binding proteins differed markedly after partial hepatectomy in ethanol-fed and pair-fed rats. Ethanol significantly inhibited post-partial hepatectomy induction of the stimulatory G protein, Gs alpha but led to overexpression of the inhibitory, G(i)2 alpha, subunit. Steady-state messenger RNA levels of these G proteins were similar in ethanol-fed and pair-fed rats, suggesting that ethanol inhibits G protein expression posttranscriptionally.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Chronic ethanol consumption disturbs G-protein expression and inhibits cyclic AMP-dependent signaling in regenerating rat liver. 133 Aug 68

We have investigated (by use of intact and saponinpermeabilized canine hepatocytes) the roles of Mg2+ and guanyl nucleotides in regulating glucagon-receptor interactions. In contrast to intact cells, saponinpermeabilized hepatocytes bind [[125I]iodo-Tyr10]glucagon according to a single first-order process and exhibit a single apparent dissociation constant for glucagon binding during steady-state incubations. Further analysis of the permeabilized cell system demonstrated (a) the temperature-sensitive action of Mg2+ to enhance the extent and affinity of glucagon-receptor interactions at steady-state, (b) the conversion of Mg(2+)-independent hormone-receptor complexes to Mg(2+)-dependent complexes, (c) the effect of guanyl nucleotides to inhibit specifically the Mg(2+)-dependent component of glucagon-receptor interactions, (d) the more rapid association of glucagon with receptor during cell incubations occurring in the presence of guanyl nucleotides or in the absence of Mg2+, and (e) the ability of guanyl nucleotides to induce both high and low affinity states of glucagon-receptor interactions. Additional experiments identified an effect of cell incubations in the presence of glucagon to limit the subsequent binding of hormone, the ability of GDP, GTP, or guanosine-5'-3-O-(thio)triphosphate (GTP gamma S) to dissociate previously bound glucagon, and a specific requirement for GDP to re-activate the glucagon receptor for additional cycles of hormone binding. A model is presented in which (a) glucagon binds to receptor in a Mg(2+)-independent fashion, (b) glucagon-receptor complexes are converted to a Mg(2+)-dependent state, (c) guanyl nucleotide exchange initiates both an alteration in glucagon-receptor affinity and the subsequent dissociation of hormone, and (d) in the context of the intact cell, G protein-mediated hydrolysis of GTP to GDP is required to reinitialize the system.
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PMID:Identification of a Mg(2+)- and guanyl nucleotide-dependent glucagon receptor cycle by use of permeabilized canine hepatocytes. 133 86


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