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)

1. The distribution of the hydrolyses of phosphatidylcholine by phospholipase A2 and phospholipase A1, and the hydrolysis of lysophosphatidylcholine by lysophospholipase, in subcellular and subsynaptosomal fractions of cerebral cortices of guinea-pig brain, was determined. 2. Noradrenaline stimulated hydrolysis by phospholipase A2 in whole synaptosomes, synaptic membranes and fractions containing synaptic vesicles. 3. Stimulation of hydrolysis by phospholipase A2 in synaptic membranes by noradrenaline was enhanced by CaCl2, and by a mixture of ATP and MgCl2. The optimum concentration of CaCl2, in the presence of ATP and MgCl2, for stimulation by 10 muM-noradrenaline was in the range 1-10muM. The optimum concentration for ATP-2MgCl2 in the presence of 1 muM-CaCl2 was in the range 0.1-1mM. 4. Hydrolysis by phospholipase A2 of synaptic membranes was also stimulated by acetylcholine, carbamoylcholine, 5-hydroxytryptamine, dopamine (3,4-dihydroxyphenethylamine), histamine, psi-aminobutyric acid, glutamic acid and aspartic acid. With appropriate concentrations of cofactors, sigmoidal dose-response curves were obtained, half-maximum stimulations being obtained with concentrations of stimulant in the range 0.1-1muM. 5. Taurine also stimulated hydrolysis of phosphatidylcholine by phospholipase A2. There were only slight stimulations with methylamine, ethylenediamine or spermidine. No stimulation was obtained with glucagon.
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PMID:The stimulation by transmitter substances and putative transmitter substances of the net activity of phospholipase A2 of synaptic membranes of cortex of guinea-pig brain. 19 82

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 temperature optimum for the positive inotropic response of guinea-pig isolated atria to single submaximal doses of isoprenaline was 25 degrees C. This was well separated from that for rate responses (37.5 degrees C). This separation was not due to changes in catechol-0-methyl-transferase or phosphodiesterase activity since it occurred with orciprenaline alone and in the presence of theophylline. The rate optima for aminophylline, histamine, glucagon, ouabain, calcium chloride and dibutyryl cAMP were essentially the same as for isoprenaline. The temperature-dependences therefore lie at a common ultimate pathway leading to the rate response. The site of temperature-dependence of the inotropic response to isoprenaline is not at the common contractile mechanisms since its optimum differed from those of ouabain and CaCl2. Activity of cAMP and its production were also eliminated as possible sites from differing optima of aminophylline, histamine and dibutyryl cAMP. The temperature-dependence may lie at the beta-adrenoceptor itself, possibly adenyl cyclase. This may be shared by glucagon although tachyphaylaxis made its optimum difficult to determine.
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PMID:Possible sites of temperature-dependent changes in sensitivity of the positive inotropic and chronotropic responses to sympathomimetic amines by comparisons of the temperature optima for a range of agonists. 64 19

1 Continuous recording of cardiac contractions and coronary flow from isolated perfused hearts of rats permitted the study of coronary reactions to: (a) cardiostimulation induced by single doses or slow infusions of noradrenaline, CaCl2, glucagon or electrically induced tachycardia; (b) short interruptions of coronary inflow (hypoxia). 2 Except during tachycardia the heart rate was kept constant at 210 beats/min by electrical pacing. 3 Metabolic coronary vasodilatation (MCD) resulting from cardiac hyperactivity induced by noradrenaline, Ca2+, tachycardia or glucagon was inhibited by administration of prostaglandin E2. Reactive hyperaemia response to hypoxia was unaffected by prostaglandin administration. 4 Inhibition of MCD could also be obtained by prolonged infusion with arachidonic acid (1.6 X 10(-7) M), presumably by its conversion into prostaglandin-like substance since arachidonic acid failed to block MCD in hearts from rats pretreated with non-steroidal anti-inflammatory drugs (indomethacin, naproxen, phenylbutazone). 5 Reactive hyperaemia was unaffected either by arachidonic acid or by blockade of the synthesis of prostaglandin-like substances by anti-inflammatory drugs. 6 Since prostaglandin synthetase inhibition does not prevent but may enhance MCD, we do not advocate prostaglandin-like substances as agents directly responsible for the coronary vasodilatation that follows cardiac hyperactivity. 7 We postulate that cardiac overproduction of prostaglandins may lead to a failure in the adaptive coronary flow response to cardiac hyperactivity (coronary insufficiency?).
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PMID:Myocardial synthesis of prostaglandin-like substances and coronary reactions to cardiostimulation and to hypoxia. 76 Aug 93

Conscious dogs (n = 6) with chronically implanted electrocardiogram electrodes and arterial and venous catheters were infused with a large dose of diltiazem (1 mg/dog per min i.v. over 60 min) to evoke hypotension and atrioventricular disturbances (AVII and AVIII blocks) which lasted for several hours. These effects are also observed in humans after accidentally or intentionally taking overdoses of diltiazem and particularly verapamil. In the intoxicated dog, administration of methylatropine (50 micrograms/kg per min i.v. over 10 min), epinephrine (0.2 and 0.4 microgram/kg per min i.v. over 60 min) and glucagon (2 micrograms/kg/min i.v. over 15 min) but not CaCl2 (3 mg/kg/min i.v. over 15 min) abolished almost entirely the AVII and AVIII blocks produced by diltiazem and re-established a normal sinus rhythm. However, these treatments failed to normalize AV conduction, and did not modify the moderate hypotensive effects of diltiazem. These findings support available clinical observations that beta-adrenoceptors agonists, glucagon and atropine rather than calcium salts are beneficial for the successful treatment of cardiovascular toxicity associated with the intake of supratherapeutic doses of diltiazem or verapamil.
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PMID:Antagonistic effects of epinephrine, glucagon and methylatropine but not calcium chloride against atrio-ventricular conduction disturbances produced by high doses of diltiazem, in conscious dogs. 207 Oct 87

The involvement of RNA/protein synthesis, calcium, calmodulin, protein kinase C, and polyamines in the lipolytic and antilipolytic (inhibition of glucagon-stimulated lipolysis) responses to GH have been investigated employing chicken adipose tissue in vitro. The lipolytic, but not the antilipolytic, effect of GH was blocked by inhibitors of RNA/protein synthesis (actinomycin D, cycloheximide, and puromycin) and calcium uptake (verapamil) and low calcium concentrations (0.28 mM CaCl2). The antilipolytic, but not the lipolytic, effect of GH was blocked by alpha-difluoromethylornithine (DFMO), a polyamine synthesis inhibitor. DFMO-induced blockade of the antilipolytic GH response was reversed by the addition of spermidine. The lipolytic and antilipolytic effects of GH were not influenced by chlorpromazine (a calmodulin inhibitor) or phorbol 12-myristate 13-acetate (PMA) (an activator of protein kinase C).
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PMID:Pharmacological investigations on the lipolytic and antilipolytic effects of growth hormone (GH) in chicken adipose tissue in vitro: evidence for involvement of calcium and polyamines. 245 90

Active glucagon receptor was solubilized with 3-(3-cholamidopropyl)dimethylammonio-1-propanesulfonate (Chaps) from rat liver plasma membranes but rapidly (less than 8 h) lost activity. Either inclusion of 1X Hanks' balanced salt solution in the 3 mM Chaps solubilization buffer or its addition after solubilization increased the percentage of total binding attributable to specific glucagon binding from approximately 10 to greater than 80%; of great importance, it increased the stability from near zero binding at 8 h to 50% binding at 48 h (4 degrees C). Of the Hanks' solution components, either NaCl (137 mM) or CaCl2 (1.26 mM) was effective in increasing specific binding to approximately 70 and 60% respectively: Mg salts were ineffective. Soluble receptor binding activity was assayed by dextran-coated charcoal adsorption of free hormone. The assay is rapid, simple, and reproducible. It is suitable for monitoring receptor activity during purification and molecular characterization. Competition binding studies gave an IC50 value of 10-20 nM (slope factor approximately 1), with or without GTP. Dissociation assays revealed GTP sensitivity when receptors were solubilized either as glucagon-receptor complexes or free receptor. Active glucagon-receptor complexes could be eluted from wheat germ lectin-agarose: neither concanavalin A-agarose nor soybean agglutinin-agarose bind receptor. A glucagon degrading activity which co-solubilized with the receptor but did not require detergent for extraction was distinguishable from the soluble receptor not only by solubility but also by its heat stability (30 degrees C), its inhibition by bacitracin, its affinity for glucagon, its retention of activity for at least 1 week at 4 degrees C, and its size.
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PMID:Stabilization of soluble active rat liver glucagon receptor. 254 42

The role of extracellular calcium in the glycogenolytic effects of calcium-dependent hormones was examined in a rat liver perfusion system. Decreasing the perfusate CaCl2 concentration resulted in a concentration-dependent inhibition of glucose output by maximal concentrations of vasopressin (20 nM) and angiotensin II (10 nM), but not of glucagon (1.4 nM), cyclic AMP (100 microM), dibutyryl cyclic AMP (10 microM) or phenylephrine (5 microM). However, the effect of phenylephrine was inhibited when livers were perfused with CaCl2-free perfusate containing 0.5 mM EGTA in a duration-dependent manner. These effects were exerted through the inhibition of the maximal response of each hormone, and were associated with a parallel decrease in phosphorylase activation but not with changes in tissue cyclic AMP concentrations. When livers were preloaded with 45Ca for 45 min and then washed for either 15 min or 45 min, these hormones elicited a rapid and transient 45Ca efflux regardless of the perfusate calcium concentration. The sequential perfusion of two hormones resulted in the loss of 45Ca efflux by the second hormone. These results suggest that the glycogenolytic effects of vasopressin and angiotensin II depend on the extracellular calcium and that of phenylephrine primarily on the cellular calcium. It was also demonstrated that these calcium-dependent hormones mobilize calcium from the same pools. However, the mobilization of cellular calcium does not necessarily correlate directly with the glycogenolytic actions of vasopressin and angiotensin II.
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PMID:Role of extracellular calcium and calcium efflux in the activation of hepatic glycogenolysis by calcium-dependent hormones. 299 15

Mitochondria were prepared by a method including a Percoll purification step after the rapid homogenization of livers of fed rats which had been perfused either under unstimulated conditions or in the presence of vasopressin and/or glucagon. The two hormones separately or together increased the total calcium content of the mitochondria. This enhancement was accompanied by parallel increases in activities of the Ca2+-sensitive intramitochondrial enzymes pyruvate dehydrogenase and 2-oxoglutarate dehydrogenase. The effects of the two hormones on total mitochondrial calcium and on the activities of the oxidative enzymes were additive. The persistent enhancements of mitochondrial calcium content and enzyme activities were partially reversed by the addition of Na+ ions to the mitochondrial incubations; these effects of Na+ were blocked by diltiazem, a selective inhibitor of Na+-induced Ca2+ release. Mitochondria from control livers were incubated in vitro with CaCl2 to achieve various calcium content, and mitochondrial enzyme activities and calcium content were measured. A good correlation was obtained between the total calcium content and the activities of pyruvate dehydrogenase and oxoglutarate dehydrogenase. The results obtained are consistent with the hypothesis that vasopressin and glucagon additively cause increases in intramitochondrial [Ca2+] and so bring about the activations of these key enzymes of mitochondrial oxidative metabolism.
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PMID:Vasopressin and/or glucagon rapidly increases mitochondrial calcium and oxidative enzyme activities in the perfused rat liver. 301 64

Basal and stimulated adenylate cyclase specific activity was characterized in gill plasma membrane of freshwater-adapted trout by measuring the conversion of [alpha-32P]ATP into [alpha-32P]cyclic AMP. Both basal and isoproterenol- or sodium fluoride-stimulated enzyme activities were linear with time and protein concentration. The optimum activities were obtained using a pH buffer of 7.5 and a temperature of 20 degrees. The Km for ATP was 0.5 mM in the presence or absence of the stimulators. The presence of 10(-5) M guanosine-5'-triphosphate and 4 X 10(-3) M MgCl2 (2.41 X 10(-3) M free Mg2+) was required to optimize not only the basal activity but also the stimulation ratio (test/control) produced by these agents. On the contrary, Ca2+ was inhibitory. IC50 for CaCl2 was 5 X 10(-4) M (10(-7) M free Ca2+) in the presence or absence of the stimulators. Under these conditions, the basal adenylate cyclase specific activity was 400-450 pmol/mg protein/10 min. A maximal stimulation was produced by isoproterenol or PGE1 10(-5) M (50% increase over basal activity) or by glucagon 5.7 X 10(-10) M (30%). In addition, this enzyme displayed high sensitivity to sodium fluoride which induced a particularly large maximal effect (370%) at a concentration of 10(-2) M.
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PMID:Basal and stimulated adenylate cyclase activity in the gill epithelium of the rainbow trout. 362 74


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