Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: 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)

Human adenylate cyclase (ATP pyrophosphate-lyase (cyclizing), EC 4.6.1.1) has been studied in preparations of fat cell membranes ("ghosts"). As reported earlier, under ordinary assay conditions (1.0 mM ATP, 5 mM Mg2+, 30 degrees C, 10 min incubation) the enzyme was activated 6-fold by epinephrine in the presence of the GTP analog, 5'-guanylyl-imidodiphosphate [GMP-P(NH)P] (Cooper, B. et al. (1975) J. Clin. Invest. 56, 1350-1353). Basal activity was highest during the first 2 min of incubation then slowed and was linear for at least the next 18 min. Epinephrine, added alone, was often without effect. but sometimes maintained the initial high rate of basal activity. GMP-P(NH)P alone produced inhibition ("lag") of basal enzyme early in the incubation periods. Augmentation of epinephrine effect by GMP-P(NH)P, which also proceeded after a brief (2 min) lag period, was noted over a wide range of substrate (ATP) concentrations. GTP inhibited basal levels of the enzyme by about 50%. GTP also allowed expression of an epinephrine effect, but only in the sense that the hormone abolished the inhibition by GTP. Occasionally a slight stimulatory effect on epinephrine action was seen with GTP. At high Mg2+ concentration (greater than 10 mM) or elevated temperatures (greater than 30 degrees C) GMP-P(NH)P alone activated the enzyme. Maximal activity of human fat cell adenylate cyclase was seen at 50 mM Mg2+, 1.0 mM ATP, pH 8.2, and 37 degrees C in the presence of 10(-4) M GMP-P(NH)P; under these conditions addition of epinephrine did not further enhance activity. Human fat cell adenylate cyclase of adults was insensitive to ACTH and glucagon even in the presence of GMP-P(NH)P.
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PMID:Human fat cell adenylate cyclase. Enzyme characterization and guanine nucleotide effects on epinephrine responsiveness in cell membranes. 0 40

A transient rise in cyclic guanosine 3' : 5' monophosphate (c-GMP) in the liver was observed in rats in vivo 10--20 min after partial hepatectomy. A similar increase in c-GMP in the liver was also found in rats in vivo 15 min after infusion of TGH solution (a mixture of triiodothyronine, glucagon, and heparin). In both cases, inductions of ornithine decarboxylase [EC 4.1.1.17] and tyrosine aminotransferase [EC 2.6.1.5] were found 4 hr after the beginning of the experiments. Later, 22 hr after the surgical intervention or hormone infusion, thymidine kinase [EC 2.7.1.21] was activated and liver slices were able to incorporate [3H]thymidine into DNA. These biochemical phenomena were observed commonly in regenerating liver as well as in the liver of rats infused with TGH solution. c-GMP, but not c-AMP, could induce ornithine decarboxylase and tyrosine aminotransferase in isolated, perfused liver.
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PMID:Involvement of cyclic GMP in the initial stage of hepatocytes proliferation. 1 43

In immunohistochemical studies of rat liver tissue slices and purified nuclei, adenosine 3':5'-cyclic monophosphate (cAMP) and guanosine 3':5'-cyclic monophosphate (cGMP) immunofluorescence on the nuclear membrane are sequentially increased after glucagon administration. An explanation for the increased cGMP immunofluorescence was sought in experiments in which guanylate cyclase [GTP pyrophosphate-lyase (cyclizing), EC 4.6.1.2]activity of hepatic subcellular fractions was determined. The results showed that a nuclear guanylate cyclase exists which can be distinguished from the soluble and crude particulate guanylate cyclases. The activity of the nuclear enzyme was increased by 35% in nuclei isolated from rats 30 min after glucagon injection, the time at which maximal nuclear membrane cGMP immunofluorescence is observed. Because glucagon altered both cAMP location and levels prior to the observed changes in nuclear cGMP metabolism, the hypothesis that cAMP acted as the second messenger was tested. In vitro incubation of nuclei isolated from control rats with 10(-5) M cAMP produced a 25% increase in nuclear guanylate cyclase activity. With nuclei isolated from glucagon-treated rats, no significant increase in enzyme activity was observed; this indicates that maximal stimulation of nuclear guanylate cyclase by cAMP occurred at levels that are obtained in vivo after glucagon administration. These findings suggest that hepatic nuclear cGMP content may be regulated by a specific organelle guanylate cyclase and that cAMP may be one of the determinants of this enzyme's activity.
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PMID:Regulation of hepatic nuclear guanylate cyclase. 1 62

Gluconeogenesis from lactate, pyruvate, fructose, alanine, and other substrates was accelerated by glucagon or epinephrine in hepatocytes isolated from rat liver. Glucagon and epinephrine also increased cyclic AMP accumulation by rat hepatocytes. Isoproterenol increased cyclic AMP but not gluconeogenesis, while phenylephrine accelerated gluconeogenesis. The activation of gluconeogenesis by epinephrine was unaffected by propranolol but blocked by dihydroergotamine. Dibutyryl cyclic AMP added to hepatocytes stimulated gluconeogenesis at concentrations as low as 1 muM. Exogenous cyclic GMP (0.1- muM) inhibited gluconeogenesis due to either glucagon or epinephrine without affecting basal gluconeogenesis. However, carbamylcholine did not affect gluconeogenesis by hepatocytes. Basal gluconeogenesis and the increases due to all agents were inhibited by removal of extracellular calcium or the presence of A-23187, D-600, or tetracaine. In contrast, added 0.1 muM cyclic GMP, 2 mM NH-4-Cl, and 10 muM phenethylbiguanide inhibited glucagon- or epinephrine-stimulated gluconeogenesis without affecting basal values. Studies with hepatocytes indicate that the hormonal activation of gluconeogenesis is not limited to substrates entering prior to triose phosphate formation. Glucagon may act by increasing cyclic AMP which acts via unknown mechanisms to increase gluconeogenesis. In contrast, epinephrine acts via a cyclic AMP-independent mechamism which does not appear to involve cyclic GMP, Ca-2+ flux, of K+ flux.
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PMID:Cyclic nucleotides and gluconeogenesis by rat liver cells. 16 60

The possibility has been explored that decreases of adenylate cyclase may explain diminished hormone sensitivity of adipose tissue with aging. Isolated cells were prepared from epididymal fat pads of rats 1-, 2-, 6-, 12-, and 24-mo old, fixed in OSO4, and sized and counted with a Coulter apparatus. Adenylate cyclase was assayed in cell membranes (ghosts) using [alpha-32P] ATP as substrate and expressed as cyclic [32P] AMP/10 min per mg protein or per 10(6) cells. Enzyme activity was determined for the basal state and in the presence of varying concentrations of glucagon, ACTH, epinephrine, and fluoride. Basal activity per cell increased in threefold between 1 and 2 mo with a comparable increase in cell surface area, suggesting synthesis of enzyme along with new cell membrane. Although epinephrine stimulated adenylate cyclase 8-fold and fluoride 12-fold throughout the life-span of the rat, stimulated activity paralleled basal levels, decreasing 60% between 2 and 24 mo per mg protein and 40% between 6 and 24 mo per cell. Glucagon stimulated adenylate cyclase 4.5-fold relative to basal in the 1-mo-old rat, but its effect then rapidly decreased and was absent by 12 mo. The fourfold stimulation by ACTH noted in the 1-mo-old animals decreased gradually with age but was still twice basal at 24 mo. Since no significant change of cell size occurred after 6 mo, diminished hormone sensitivity with senescence cannot be related to cell size. Similar age-related patterns of hormonal activation were evoked by 5'-guanylyl-imidodiphosphate [GMP-P(NH)P], a nucleotide analogue which increased both basal- and hormone-activated enzyme at all ages studied. Dose-response curves to hormones, fluoride, and GMP-P (NH)P were not affected by age. High Mg++ (50 mM) in the presence of GMP-P-(NH)P stimulated adenylate cyclase to levels greater than with fluoride, but a similar loss of activity with aging was still observed. Loss of hormone receptors may partially explain the age-related decreases of glucagon and ACTH-sensitive adenylate cyclase, but decreased basal-, epinephrine-, fluoride-, and GMP-P-(NH) P-stimulated responses suggest loss of the catalytic component of the adenylate cyclase enzyme complex in the aging fat cell membranes.
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PMID:Hormone-sensitive fat cell adenylate cyclase in the rat. Influences of growth, cell size, and aging. 17 40

1. Activation of adenylate cyclase in rat liver plasma membranes by fluoride or GMP-P (NH)P yielded linear Arrheniun plots. Activation by glucagon alone, or in combination with either fluoride or GMP-P(NH)P resulted in biphasic Arrhenius plots with a well-defined break at 28.5 +/- 1 degrees C. 2. The competitive glucagon antagonist, des-His-glucagon did not activate the adenylate cyclase but produced biphasic Arrhenius plots in combination with fluoride or GMP-P(NH)P. The break temperatures and activation energies were very similar to those observed with glucagon alone, or in combination with either fluoride or GMP-P(NH)P. 3. It is concluded that although des-His-glucagon is a potent antagonist of glucagon, it nevertheless causes a structural coupling between the receptor and the catalytic unit.
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PMID:The glucagon receptor of rat liver plasma membrane can couple to adenylate cyclase without activating it. 17 98

1. The lipids composition of rat liver plasma membranes was substantially altered by introducing synthetic phosphatidylcholines into the membrane by the techniques of lipid substitution or lipid fusion. 40-60% of the total lipid pool in the modified membranes consisted of a synthetic phosphatidylcholine. 2. Lipid substitution, using cholate to equilibrate the lipid pools, resulted in the irreversible loss of a major part of the adenylate cyclase activity stimulated by F-, GMP-P(NH)P or glucagon. However, fusion with presonicated vesicles of the synethic phosphatidylcholines causes only small losses in adenylate cyclase activity stimulated by the same ligands. 3. The linear form of the Arrhenius plots of adenylate cyclase activity stimulated by F- or GMP-(NH)P was unaltered in all of the membrane preparations modified by substitution or fusion, with very similar activation energies to those observed with the native membrane. The activity of the enzyme therefore appears to be very insensitive to its lipid environment when stimulated by F- or gmp-p(nh)p. 4. in contrast, the break at 28.5 degrees C in the Arrhenius plot of adenylate cyclase activity stimulated by glucagon in the native membrane, was shifted upwards by dipalmitoyl phosphatidylcholine, downwards by dimyristoyl phosphatidylcholine, and was abolished by dioleoyl phosphatidylcholine. Very similar shifts in the break point were observed for stimulation by glucagon or des-His-glucagon in combination with F- or GMP-P(NH)P. The break temperatures and activation energies for adenylate cyclase activity were the same in complexes prepared with a phosphatidylcholine by fusion or substitution. 5. The breaks in the Arrhenius plots of adenylate cyclase activity are attributed to lipid phase separations which are shifted in the modified membranes according to the transition temperature of the synthetic phosphatidylcholine. Coupling the receptor to the enzyme by glucagon or des-His-glucagon renders the enzyme sensitive to the lipid environment of the receptor. Spin-label experiments support this interpretation and suggest that the lipid phase separation at 28.5 degrees C in the native membrane may only occur in one half of the bilayer.
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PMID:The lipid environment of the glucagon receptor regulates adenylate cyclase activity. 17 99

Human peripheral lymphocytes were broken in a Dounce homogenizer and subcellular fractions enriched in plasma membranes or microsomal particles and mitochondria were isolated by centrifugation through a discontinuous sucrose gradient. Various agents that promote cyclic AMP accumulation in intact lymphocytes were compared in their ability to stimulate adenylate cyclase activity in the individual fractions. Plasma-membrane-rich fractions that were essentially free of other subcellular particles as judged by electron microscopy and marker enzyme measurements responded to fluoride, but weakly or not at all to prostaglandin E1 and other prostaglandins. Microsomal and mitochondrial-rich fractions responded markedly to both prostaglandin E1 and fluoride. In some, but not all, experiments phytohaemagglutinin produced a modest increase in enzyme activity in plasma-membrane-rich fractions. Catecholamines, histamine, parathyrin, glucagon and corticotropin produced little or no response. In the absence of theophylline, adenosine (1-10 micronM) stimulated basal enzyme activity, although at higher concentrations the responses to prostaglandin E1 and fluoride were inhibited. GTP (1-100 micronM) and GMP(5-1000 micronM) respectively inhibited or stimulated the response to fluoride, whereas the converse was true with prostaglandin E1.
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PMID:Adenylate cyclase activity in lymphocyte subcellular fractions. Characterization of non-nuclear adenylate cyclase. 19 77

The production of adenosine 3',5'-monophosphate (cyclic AMP) in a membrane preparation from human liver homogenate has been studied. Cyclic AMP production was enhanced by glucagon, guanylyl 5'-imidodiphosphate (GMP-PNP), or fluoride, or combinations of these. Adenosine, adenosine monophosphate (AMP) and adenosine diphosphate (ADP) at a concentration of 10(-3) mol/l antagonized the effects of all stimulants. These data suggest that inhibitory effects are exercised at the catalytic moiety of the adenylate cyclase system, or at the transducer function between hormone receptor and catalytic unit. In contrast, adenosine at a concentration of 10(-5) mol/l antagonized glucagon- but not fluoride-stimulated adenylate cyclase activity.
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PMID:Adenylate cyclase activity in human liver membranes and its inhibition by adenosine and adenine nucleotides. 21 Apr 96

Effects of glucagon and guanyl nucleotides on the rat liver plasma membrane adenylyl cyclase were studied. It was established that: 1) glucagon stimulates the fully guanyl-5'-yl imidodiphosphate (GMP-P(NH)P)-activated enzyme between 20 and 70%, provided a guanyl nucleotide is present in the assay; 2) glucagon has no effect on adenylyl cyclase activity in membranes activated fully by GMP-P(NH)P and then washed free of nucleotides. It is concluded that occupancy of the guanyl nucleotide binding site that activates the catalytic moiety of the system is not sufficient to promote hormone-receptor coupling to adenylyl cyclase and that occupancy of a second site by guanyl nucleotides is essential to effect stimulation of adenylyl cyclase by the glucagon-receptor complex. The data presented raise the question whether the guanyl nucleotide site that promotes coupling is distinct from the guanyl nucleotide site that modulates binding of glucagon to receptor and whether the occupancy of the guanyl nucleotide site associated with the catalytic moiety is necessary for coupling.
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PMID:Coupling of glucagon receptor to adenylyl cyclase. Requirement of a receptor-related guanyl nucleotide binding site for coupling of receptor to the enzyme. 21 87


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