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)

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

Exogenous cGMP can inhibit both basal and glucagon-stimulated production of glucose in liver slices from fed rats. Thus, cAMP and cGMP have opposite effects on the production of glucose in rat liver. Acetylcholine, an activator of guanylate cyclase (EC 4.6.1.2) in other systems, also inhibits the glucagon-stimulated production of glucose. No effect on glucose production was observed with secretin or exogenous GTP.
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PMID:Regulation of glucagon-stimulated production of glucose in rat liver by guanosine 3',5'-cyclic phosphate. 19 Nov 65

Agents such as 5'-guanylyl-imidodiphosphate(GppNHp), fluoride and forskolin did not activate adenylate cyclase from Tetrahymena. In addition, the cyclase was not stimulated by hormones including catecholamines and glucagon when assayed with or without GppNHp at conditions where they increased adenylate cyclase activity from rat heart. Sodium azide, NaNO2 or N-methyl-N'-nitro-N-nitroguanidine (MNNG) failed to activate Tetrahymena guanylate cyclase. Adenylate cyclase activity was activated at low free Ca2+ level and inhibited at high levels, while guanylate cyclase activity was activated by Tetrahymena calmodulin only at high physiological concn of Ca2+.
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PMID:Regulation by calcium of hormone-insensitive adenylate cyclase and calmodulin-dependent guanylate cyclase in Tetrahymena plasma membrane. 285 63

1. Two directly-acting stimulants of soluble guanylate cyclase, glyceryl trinitrate (0.1 microM) and sodium azide (10 microM), and a receptor-mediated stimulant of particulate guanylate cyclase, atriopeptin II (10 nM), each elevated the cyclic GMP content of primary cultures of pig aortic endothelial cells without affecting the cyclic AMP content. 2. Two receptor-mediated stimulants of adenylate cyclase, glucagon (1 microM) and isoprenaline (10 microM), had no effect on the cyclic AMP or cyclic GMP content of these cells, but the directly acting stimulant, forskolin (30 microM), induced a small increase in cyclic AMP content. 3. Three agents that release endothelium-derived relaxing factor (EDRF); bradykinin (0.1 microM), ATP (10 microM) and ionophore A23187 (0.1 microM), each markedly elevated the cyclic GMP content of pig aortic endothelial cells, but acetylcholine (1 microM) had no effect. None of these agents had any effect on cyclic AMP content. 4. Two agents that potentiate the actions of EDRF; M & B 22948 (100 microM) and superoxide dismutase (30 units ml-1), each elevated the cyclic GMP content of pig aortic endothelial cells without affecting the cyclic AMP content. Pretreating cells with catalase (100 units ml-1) did not affect the rise in cyclic GMP content induced by superoxide dismutase (30 units ml-1). 5. Pretreatment of pig aortic endothelial cells with haemoglobin (10 microM) reduced the resting content of cyclic GMP and blocked the increase in cyclic GMP content induced by glyceryl trinitrate (0.1 microM), sodium azide (10 microM), bradykinin (0.1 microM), ATP (10 microM), ionophore A23187 (0.1 microM), M & B 22948 (100 microM) and superoxide dismutase (30 units ml-1), but not that induced by atriopeptin II (10 nM). 6. Pretreatment of pig aortic endothelial cells with an inhibitor of soluble guanylate cyclase, methylene blue (20 microM), had no effect on the resting content of cyclic GMP. Methylene blue (20 microM) blocked the increase in cyclic GMP content induced by glyceryl trinitrate (0.1 microM), M & B22948 (100 microM) and bradykinin (0.1 microM), but not that induced by atriopeptin II (10 nM). 7. The data show that soluble guanylate cyclase, particulate guanylate cyclase and adenylate cyclase are present in pig aortic endothelial cells. They further suggest that EDRF, produced spontaneously or in response to vasoactive agents, elevates endothelial cyclic GMP content by stimulating soluble guanylate cyclase. It is possible that this may serve as a feedback loop by which the endothelial cell modulates EDRF production.
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PMID:Endothelium-derived relaxing factor and atriopeptin II elevate cyclic GMP levels in pig aortic endothelial cells. 289 77

Rat liver regeneration is regulated by a humoral signal that includes insulin and a sustained elevation in glucagon. The intracellular response is characterized by a rise in cAMP as well as altered cGMP metabolism, i.e. increased particulate guanylate cyclase activity. To evaluate the role of hormones in the regulation of guanylate cyclase during liver regeneration, the enzyme activity of primary cultures of rat hepatocytes was examined. Hepatocytes were maintained for 22 h in medium containing various combinations of insulin, glucagon, and cAMP. The cells were then harvested and homogenized and the guanylate cyclase activity was assessed in vitro. Hepatocytes maintained in 100 nM insulin exhibited a 42% (p < 0.001) increase in guanylate cyclase activity when compared to cells cultured in medium alone. Incubation with glucagon (100 nM) produced a 52% (p < 0.01) rise. In the presence of insulin (100 nM), culturing with as little as 5 nM glucagon resulted in increased activity, and 100 nM glucagon produced a 161% (p < 0.001) rise above cultures maintained in insulin alone. Thus, the combination of the two hormones produced an effect that was significantly (p < 0.01) greater than additive. Dibutyryl cAMP and 8-bromoadenosine 3':5'-monophosphoric acid were at least as effective as glucagon; the enzyme activity of cells maintained in 5 microM N6,02'-dibutyryl adenosine 3':5'-monophosphoric acid and 100 nM insulin was 243% (p < 0.001) above those in insulin alone. The findings suggest that the activity of hepatocyte guanylate cyclase is regulated by a synergistic action of insulin and glucagon and that positive interactions between the two cyclic nucleotide second messenger systems exist.
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PMID:The role of insulin, glucagon, and cAMP in the regulation of hepatocyte guanylate cyclase activity. 610 19

Somatostatin has been shown to inhibit the release of various polypeptide hormones including insulin, glucagon, gastrin, thyroid stimulating hormone, and growth hormone. The mechanism by which somatostatin inhibits the release of these various polypeptide hormones has not been fully elucidated. It has been reported that somatostatin increases the level of the second messenger cyclic GMP in rat brain and in the anterior pituitary gland. The present investigation was designed to determine if these responses seen in the anterior pituitary gland and brain were due to activation of guanylate cyclase [GTP-pyrophosphate lyase (cyclizing), E.C.4.6.1.2.], the enzyme that catalyzes the formation of cyclic GMP. Somatostatin at a concentration of 2 pM enhanced guanylate cyclase activity two-fold in rat cerebrum and anterior pituitary gland. This enhancement of guanylate cyclase activity was also seen in rat liver, pancreas, stomach, and small intestine at the same concentration of somatostatin. Increasing the concentration of somatostatin to 20 microM, caused a marked inhibition of guanylate cyclase activity in all these tissues. Dose-reponse curves done on gastric guanylate cyclase activity revealed that over a concentration range of 2 pM to 0.2 microM, somatostatin had a stimulatory effect on guanylate cyclase activity while at concentrations above 10 microM somatostatin was inhibitory to guanylate cyclase activity. The biphasic pattern of enhancement of guanylate cyclase activity at lower concentrations of somatostatin and inhibition at higher concentrations may help to explain some of the discrepancies seen with previous investigations with somatostatin, hormone release, and cyclic nucleotide metabolism.
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PMID:The interrelationship of somatostatin and guanylate cyclase activity. 611 Jan 70

Cyclic AMP formation from ATP was stimulated by unpurified and partially purified soluble hepatic guanylate cyclase in the presence of nitric oxide (NO) or compounds containing a nitroso moiety such as nitroprusside, N-methyl-N-nitro-N-nitrosoguanidine (MNNG), nitrosyl ferroheme, and S-nitrosothiols. Cyclic AMP formation was undetectable in the absence of NO or nitroso compounds and was not stimulated by fluoride or glucagon, indicating the absence of adenylate cyclase activity. The nitroso compounds failed to activate, whereas fluoride or glucagon activated, adenylate cyclase in washed rat liver membrane fractions. Cyclic GMP formation from GTP was markedly stimulated by the soluble hepatic fraction in the presence of NO or nitroso compounds. Cyclic AMP formation by partially purified guanylate cyclase was competitively inhibited by GTP and cyclic GMP formation is well-known to be competitively inhibited by ATP. Therefore, it appears that activated guanylate cyclase, rather than adenylate cyclase, was responsible for the formation of cyclic AMP from ATP. Formation of cyclic AMP of cyclic GMP was enhanced by thiols, inhibited by hemoproteins and oxidants, and required the addition of either Mg2+ or Mn2+. Further, several nitrosyl ferroheme compounds and S-nitrosothiols stimulated the formation of both cyclic AMP and cyclic GMP by the soluble hepatic fraction. These observations support the view that soluble guanylate cyclase is capable, under certain well-defined conditions, of catalyzing the conversion of ATP to cyclic AMP.
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PMID:Adenosine 3',5'-monophosphate formation by preparations of rat liver soluble guanylate cyclase activated with nitric oxide, nitrosyl ferroheme, S-nitrosothiols, and other nitroso compounds. 611 40

The soluble guanylate cyclase activity of rat liver appears to be stimulated in VITRO by insulin at pMolar concentrations, while proinsulin, denaturated insulin or desoctapeptide insulin, are not able to stimulate the studied enzymic activity. Corresponding concentrations of other peptide hormones such as corticotropin (ACTH) or glucagon, either in the absence or in the presence of bacitracin, do not show any effect on the investigated enzymic system. Insulin stimulation of the soluble guanylate cyclase is characterized by a significant increase in the Vmax together with a decrease of the apparent Km. Insulin at low concentrations doesn't affect the cyclic GMP hydrolyzing activity; conversely higher concentrations of the hormone, while exerting a less marked effect on the guanylate cyclase activity, inhibit the cyclic GMP hydrolyzing activity.
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PMID:Low insulin concentrations stimulate in vitro the soluble guanylate cyclase activity of rat liver. 613 76

Rat liver is known to contain both a nitric oxide-stimulated guanylate cyclase and a cGMP-stimulated cAMP-phosphodiesterase. To evaluate the possible function of this system, the effect of the nitric oxide generating compound S-nitroso-N-acetylpenicillamine on glycogenolysis was evaluated in isolated rat hepatocytes. S-nitroso-N-acetylpenicillamine (1.0 mM) inhibited glucagon-stimulated glycogenolysis by 15%, but had no effect on basal rates of glycogenolysis. Inhibition of hepatocyte glycogenolysis by S-nitroso-N-acetylpenicillamine was associated with accumulation of cGMP (1.5 pmol/2.0 x 10(6) cells/2 min.). Exogenous 8-Br-cGMP (1.0 mM) inhibited hepatocyte glucagon-stimulated glycogenolysis by a magnitude similar to that observed with S-nitroso-N-acetylpenicillamine. S-nitroso-N-acetylpenicillamine had no effect on phenylephrine-stimulated glycogenolysis, but inhibited 8-bromo-cAMP-stimulated glycogenolysis by 15%. These observations suggest that S-nitroso-N-acetylpenicillamine inhibits cAMP-mediated stimulation of glycogenolysis at a site distal to adenylate cyclase. In summary, hepatocyte glucagon-stimulated glycogenolysis was inhibited to a small, but significant, degree by S-nitroso-N-acetylpenicillamine. This inhibition is consistent with a nitric oxide mediated stimulation of guanylate cyclase and consequent stimulation of cAMP-phosphodiesterase activity. Nitric oxide may contribute to altered carbohydrate homeostasis under pathophysiologic conditions.
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PMID:Inhibition of glucagon-stimulated glycogenolysis by S-nitroso-N-acetylpenicillamine. 839 88

ANP increases insulin levels in vivo. Because in vitro an ANP-induced increase in cGMP levels of islets of Langerhans was observed but no simultaneous increase in insulin release, secreted glucagon may be a candidate for this second messenger affected by ANP. The inhibitory effect of glucose on glucagon secretion was pronounced by 1.0 nM ANP at 3.0 mM glucose as well as at 5.6 and 8.3 mM glucose. Because in other tissues cGMP (the specific second messenger of ANP1 inhibits Ca2+ channels, the uptake of 45Ca2+ was investigated. ANP (1.0 nM) inhibited 45Ca2+ uptake, which was nearly completely abolished by a pertussis toxin (PT) pretreatment. The inhibition of 45Ca2+ uptake fits to inhibitory ANP effects on glucagon secretion but does not fit to insulin secretion. The glucagon secretion coupling cascade affected by ANP probably involves an increase in cGMP because 8-Br-cGMP (a membrane-permeable cGMP analogue) also decreased glucagon secretion. ANP(4-23), a truncated form of ANP, which is selective for the ANP clearance receptor, also inhibited glucagon secretion. HS-42-1, a guanylate cyclase receptor antagonist, tended to reverse the effect of ANP on glucagon release. The data indicate that in the presence of ANP, the in vivo homeostasis of glucose, though plasma insulin levels are increased, is not due to an ANP-mediated increase in glucagon secretion; ANP has a complex inhibitory effect on glucagon release. The data further indicate that the ANP-induced inhibition of glucagon secretion probably involves the cGMP system, an inhibition of Ca2+ uptake and the involvement of PT-sensitive G-proteins. Moreover, an involvement of the clearance receptor seems to be likely. ANP is a valuable tool for investigating glucagon secretion from pancreatic islets because paracrine effects of insulin can be excluded.
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PMID:Atrial natriuretic peptide (ANP)-induced inhibition of glucagon secretion: mechanism of action in isolated rat pancreatic islets. 889 23


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