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)

The mechanism by which intestinal secretagogues evoke fluid secretion in the small bowel and colon has been suggested to involve mucosal adenylate cyclase. Adenylate cyclase activity was assayed by conversion of [32P]ATP to [32P]cyclic AMP in a system of pure epithelial cells isolated from the small intestine of the hamster by vibration in buffer. Several gastrointestinal hormones were tested for their capacity to stimulate adenylate cyclase; vasoactive intestinal peptide and impure cholecystokinin-pancreozymin (but not the 99% pure preparation or pure cholecystokinin octapeptide) were potent stimuli, but pentagastrin, glucagon, secretin, and gastric inhibitory peptide were impotent. Two prostaglandins, PGE1 and PGE2, were potent stimuli of adenylate cyclase. Two other compounds that provoke intestinal secretion of fluid, deoxycholic acid and ricinoleic acid (castor oil), were ineffective stimuli of adenylate cyclase. These experiments do not support a clear-cut relationship between a compound's ability to stimulate adenylate cylase and its activity as an intestinal secretagogue.
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PMID:Stimulation of adenylate cyclase in homogenates of isolated intestinal epithelial cells from hamsters. Effects of gastrointestinal hormones, prostaglandins, and deoxycholic and ricinoleic acids. 56 12

Treatment with glucagon in addition to blood transfusion was compared with blood transfusion alone after one hour of hemorrhagic shock in the rat. In liver tissue Na+ increased and K+ decreased during haemorrhagic shock. After treatment the initial values were restored equally in both groups within ten minutes. Incubation of liver slices in cold Krebs' solution resulted in a pronounced increase in Na+ and decrease in K+, the values being partially restored to initial levels after subsequent incubation at 37 degrees. Thirty minutes after treatment the liver slices obtained from rats given glucagon showed a more normal ion composition after leaching and rewarming than slices from rats not given glucagon. ATP decreased and glucose and lactate increased in liver tissue during hemorrhagic shock. These variables were partially restored 30 minutes after treatment. No difference between the treatment groups was noted. Animals trreated with glucagon were, however, more efficient in reducing the elevated blood lactate level. The results suggest that the use of glucagon in the treatment of hemorrhagic shock might be of benefit for cellular function in the liver.
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PMID:Effect of glucagon and blood transfusion on liver metabolism in hemorrhagic shock. 62 13

Hepatic submitochondrial particles, prepared at neutral pH from rats pretreated with glucagon, exhibited stimulated rates of State 3 and uncoupled respiration when succinate or NADH were the substrates, but not when ascorbate plus N,N,N',N'-tetramethyl-p-phenylenediamine were employed. Measurements of 8-anilino-1-naphthalenesulfonic acid fluorescence in the particles indicated that glucagon treatment resulted in a stimulation of energization supported by succinate respiration or ATP hydrolysis. Similarly, the energy-linked pyridine nucleotide transhydrogenase and reverse electron flow reactions driven by succinate oxidation or ATP were also stimulated. The results indicate that mitochondrial substrate transport is not the prime locus of glucagon action. It is suggested that the increased level of energization in particles prepared from glucagon-treated rats is a reflection of a stimulation of the respiratory chain, possibly between cytochromes b and c, and the ATP-forming reactions.
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PMID:Glucagon treatment stimulates the metabolism of hepatic submitochondrial particles. 64 75

Insulin decreased markedly the adenylyl cyclase activity associated with fat cell membranes purified by centrifugation in sucrose gradients. The hormone effect was not readily evident in crude membrane preparations. The kinetics of this effect indicate that some time was required for the onset of the insulin-induced inactivation. This lag period decreased when the insulin concentration was increased. The hormone dose dependence for adenylyl cyclase inactivation measured at a fixed time (3 min) showed a 10 to 15% decrease in activity at 1 to 30 muU per ml insulin; 30 to 40% at 100 to 1000 muU per ml; and 75% at 0.1 U per ml. The insulin effect was completely abolished by 0.1 mM GMP-P(NH)P, 10mM fluoride, or 50 ng per ml glucagon, or by increasing the Mn++ concentration to 4 mM. In addition, it was partially reversed by the addition of a fraction from the sucrose gradient, which contained soluble factors. The kinetics of the adenyl cyclase-catalyzed reaction were studied using ATP or AMP-P(NH)P as adenylyl donor, and Mn++ or Mg++ as divalent cation, in the absence or presence of insulin. With ATP and Mg++ there was a striking reduction of the transient reaction rates after 1.5 min of incubation. Under these conditions the insulin effect was not evident. On the contrary, with ATP and Mn++ this spontaneous reduction of activity was less evident; however, in the presence of insulin there was a clear and marked reduction of the transient reaction rate measured after 1.5 min of incubation. With AMP-P(NH)P the kinetic data were qualitatively similar to those observed with ATP. It is concluded that under certain assay conditions adenylyl cyclase may be converted to an inactive enzyme form, and that such a conversion is more evident in the presence of Mg++ than with Mn++. In the latter case, insulin appears to enhance the rate of this conversion.
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PMID:Effects of insulin on the adenylyl cyclase activity of isolated fat cell membranes. 70 24

Gluconeogenesis by isolated hepatocytes resulted in glucose release but insignificant rates of glycogen synthesis. The effectiveness of precursors was similar for hepatocytes from fed and starved chickens except for impaired gluconeogenesis from pyruvate when compared to lactate in lactate starved chicken hepatocytes. The impairment was caused by limitations in cytosolic NADH production as a result of the mitochondrial location of phosphoenolpyruvate carboxykinase in chicken liver. The order of effectiveness of precursors on hepatic gluconeogenesis was generally similar to the effects of precursors on increasing the plasma glucose concentration in vivo. The exceptions were caused by interactions with other precursors in vivo. The alteration of the NADH/NAD+ ratio by ethanol and ATP/ADP ratio by adenosine could play significant roles in the control of precursor conversion to glucose. Physiological glucagon concentrations stimulated gluconeogenesis from precursors entering the pathway both above and below the level of triose phosphates, and its effect were mimicked by dibutyryl cyclic AMP. Previous results on the effects of precursor and glucagon injection on the plasma glucose concentration of chickens in vivo can largely be explained by effects at the hepatic level. Isolated chicken and rat hepatocytes share many common features. Qualitatively the ordering of gluconeogenic effectiveness was similar but quantitive differences existed as a result of differing activities and cellular locations of enzymes. Neither preparation readily synthesised glycogen and the sensitivity to glucagon was similar.
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PMID:Hepatic gluconeogenesis in chickens. 74 98

During the first two thirds of gestation, the concentrations of UDPG, ATP, ADP, and Mg++ in human fetal liver remain constant, whereas the concentration of Pi decreases twofold and the G-6-P and AMP concentrations increase. Incubation of human fetal liver explants with glucagon or insulin did not alter the concentrations of any of these intermediates. ATP, ADP, and Pi are inhibitors of human fetal liver glycogen synthase D-form activity, while G-6-P and AMP and Mg++ are stimulators. Ca++ at concentrations of less than 0.1 mM was found to stimulate glycogen synthase D activity. This effect of Ca++ was also observed in "physiologic" mixtures containing UDPG, G-6-P, ATP, ADP, AMP, Pi, and Mg++ at concentrations found either in liver in utero or in explants. 45Ca++ efflux from perifused (rat) fetal liver explants was stimulated by glucagon. These data provide a picture of the metabolite regulation of human fetal liver glycogen synthase activity in which the D-form may largely control glycogen synthesis in utero and hormonal effects on glycogen synthase may be induced by effects of Ca++ on the D-form.
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PMID:Hormonal regulation of glycogen metabolism in human fetal liver. II. Regulation of glycogen synthase activity. 81 98

Rat liver plasma membranes are shown to catalyze the formation of adenosine 5'-phosphoroglycerol and adenosine 5'-phosphoromethanol from ATP and glycerol or methanol, respectively. In the presence of 2.7 M glycerol and 1 mM ATP, 30 nmol of adenosine 5'-phosphoroglycerol were formed in 10 min per mg of rat liver plasma membranes. The structures of these phosphodiesters were determined from the following evidence. Radioactivity was incorporated into the nucleotide from [alpha-32P]ATP, [2,8-3H]ATP, or [2-3H]glycerol. Treatment with snake venom phosphodiesterase I converted the nucleotides to AMP. The compound formed from glycerol and ATP co-migrated with adenosine 5'-phosphoroglycerol synthesized from glycerol and adenosine 5'-phosphoromorpholidate in five thin layer chromatography systems. The methyl derivative co-migrated with adenosine 5'-phosphoromethanol synthesized from methanol and adenosine 5'-phosphormorpholidate in several thin layer chromatography systems. The synthesis of these phosphodiesters was also catalyzed by chicken embryo fibroblast membranes and solubilized rat liver plasma membranes but not by rat heart plasma membrane preparations. Formation of significant amounts of these phosphodiesters required relatively high concentrations of the alcohols (greater than 1 M). The alcohol concentration dependence did not exhibit substrate saturation at physiologically meaningful concentrations of glycerol or methacol. It is proposed that either the alcohols examined were not the natural substrates for this enzyme or that the alcohol/AMP phosphodiesters were formed as a result of trapping of an enzyme/nucleotide intermediate. Adenosine 5'-phosphoroglycerol formation was inhibited approximately 50% by 15 mM NaF. Epinephrine, norepinephrine, glucagon, and prostaglandin E1 were without effect. Alloxan, an inhibitor of adenylate cyclase did not inhibit formation of adenosine 5'-phosphoroglycerol. It is concluded that adenylate cyclase was not responsible for formation of these phosphodiesters. The physiological significance of this reaction remains undefined.
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PMID:Formation of adenosine 5'-phosphoroglycerol from ATP and glycerol by rat liver plasma membranes. 83 37

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

RMI 12330 A, (N,-(cis-2-phenylcyclopentyl) azacyclotridecan-2-imine hydrochloride), has been reported to inhibit choleratoxin-induced intestinal hypersecretion, presumably via an inhibition of mucosal adenylate cyclase (ATP:pyrophosphate-lyase (cyclizing), EC 4.6.1.1). We report here that the adenylate cyclase activity of a rat liver plasma membrane preparation was inhibited by concentrations of RMI 12330 A ranging from 10 muM to 5mM. Similar effects were observed when the adenylate cyclase preparation was assayed in the presence of 10 mM NaF, 0.1 muM glucagon or 1 muM (--)-epinephrine plus 10 muM GTP. The effect of RMI 12330 A was not due to the inhibition of the regenerating system present in the incubation medium, since the effect was preserved in its absence. The inhibition brought about by RMI 12330 A was due to a decrease in the maximal velocity of the reaction; the affinity of the enzyme for the substrate remained unmodified. The inhibition was immediate and irreversible, even after several washes of the membranes previously preincubated with the drug. Complete inhibition of cyclase was obtained at a concentration of 370 nmol of RMI 12330 A per mg of membrane protein. The drug acted with a similar dose-response curve upon intact as well as detergent-dispersed cyclase preparations.
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PMID:RMI 12330 A, an inhibitor of adenylate cyclase in rat liver. 91 55

Chloralose-anaesthesized dogs, starved for 24 hours, were used to determine the effects of 10 microgram/kg glucagon, administered i.v. as a single bolus injection, on liver substrates in situ (glycogen, glucose-1-phosphate, glucose-6-phosphate, glucose, fructose-6-phosphate, fructose-1,6-diphosphate, triose phosphates, glycerol-3-phosphate, phosphoenolypyruvate, pyruvate, lactate, citrate, malate, ATP, ADP, and AMP). liver samples were obtained by instant deep-freezing with Wollenberger clamps on four consecutive occasions at 10-minute intervals. Heart rate and blood pressure were continuously monitored. Serial liver sampling per se had no significant effects on liver metabolism or systemic haemodynamics in a group of control animals. In a second group glucagon, administered after the initial freeze-clamp sampling to obtain baseline values, led to a marked activation of the glycogenolytic pathway resulting in glucose release from the liver.
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PMID:Effects of glucagon on liver metabolism in intact dogs. 92 72


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