UNIPROT:P01275 - FACTA Search

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Query: UNIPROT:P01275 (glucagon)
26,492 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Evidence is presented that modulation of the maximum velocity of a particulate low K-m cyclic adenosine 3':5'-monophosphate (cyclic AMP) phosphodiesterase by thyroid hormones is one mechanism for the regulation of the responsiveness of rat epididymal adipocytes to lipolytic agents such as epinephrine and glucagon. Fat cells of propylthiouracil-induced hypothyroid rats are unresponsive to lipolytic agents and the V-max of particulate low K-m cyclic AMP phosphodiesterase of these cells is elevated above normal. In vivo treatment of hypothyroid rats with triiodothyronine restores to control values both the lipolytic response of the fat cells to epinephrine and the V-max of the particulate bound low K-m cyclic AMP phosphodiesterase. No similar correlation is found with the soluble high K-m cyclic AMP phosphodiesterase. The phosphodiesterases of fat cells from normal and hypothyroid rats respond identically in vitro to propylthiouracil, triiodothyronine, methylisobutylxanthine, or theophylline, although the particulate low K-m cyclic AMP phosphodiesterase is inhibited to a greater extent than soluble cyclic guanosine 3':5'-monophosphate phosphodiesterase activity. Protein kinase of fat cells from hypothyroid rats can be stimulated by cyclic AMP to the same total activity as observed in fat cells of normal rats. However, less of the protein kinase in fat cells from hypothyroid rats was in the cyclic AMP-independent form. This shift in the equilibrium of protein kinase forms is consistent with an increased activity of low K-m cyclic AMP phosphodiesterase and probably results from a lowering of the lipolytically significant pool of cyclic AMP.
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PMID:Cyclic nucleotide phosphodiesterases and thyroid hormones. 16 41

Studies were carried out on confluent cultures of human fibroblasts to explore the effect of insulin on basal and hormone-induced elevations of intracellular cyclic AMP content during short-term incubations in serum-free medium. Insulin tended to decrease basal levels of cyclic AMP but this was not statistically significant. Similarly, insulin was unable to block the elevations of intracellular cyclic AMP content induced by PGE1, epinephrine and glucagon. Paradoxically, when cells were preincubated with insulin, PGE1-stimulated cyclic AMP elevation was potentiated, possibly because insulin was conserving factors needed for a maximal PGE1 stimulus or retarding the leakage of cAMP itself. The results indicate that insulin has little or no direct effect on cyclic AMP metabolism in cultured human fibroblasts and is consistent with the known insensitivity of these cells to insulin for other parameters.
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PMID:The effect of insulin on basal and hormone-induced elevations of cyclic AMP content in cultured human fibroblasts. 16 74

1. Glucokinase is one of four glucose phosphorylating enzymes present in rat liver. Its distinctive features are a high K-m for glucose (high-K-m isozyme) and a rather narrow substrate specificity. In contrast, the other three enzymes, collectively called hexokinases or low-K-m isozymes, exhibit low K-m values for glucose and a wider substrate specificity. 2. Glucokinase is present in the liver os mammals (with some exceptions), amphibians and lower reptiles; It is absent from higher reptiles and birds. The presence or absence of glucokinase may represent an evolutionary adaptation to feeding habits and other physiological peculiarities. Differences in the immunological behavior and in the kinetic parameters of glucokinases from different taxa suggest the operation of divergent evolution. 3. The levels of glucokinase in rat liver depend strictly on the supply of carbohydrate in the diet. Glycogen phosphorylase and glycogen synthetase behave similarly, whereas other carbohydrate-metabolizing enzymes depend on the provision of either protein or protein plus carbohydrate. Glucokinase decays with a half-life of 33 hr when rats are starved or fed a carbohydrate-free diet, and is induced by the administration of glucose. The adaptive character is not exhibited by all mammals, indicating evolutionary discrimination within the same class and even within the same single order Rodentia. Enzyme adaptation in the liver may partially explain the condition known as 'hunger diabetes'. 4. The endocrine system plays a paramount role in glucokinase adaptation, since insulin is essential for glucose-dependent glucokinase induction and, on the other hand, glucagon, catecholamines and cyclic AMP prevent the induction. Glucocorticoids and some pituitary hormones modulate the rate of induction. The mechanisms underlying the hormonal regulation of glucokinase levels are not well known. 5. The variations in liver glucokinase correspond to changes in the amount of enzyme protein as assessed by immunochemical titration. This fact agrees with the effects of inhibitors of protein synthesis on glucokinase induction. 6. An antiserum against rat glucokinase reacts with the enzyme from mammals and turtles but not with the amphibian enzyme. It does not react with low-K-m hexokinases from different sources. 7. The saturation function for glucose is sigmoidal in mammalian and amphibian glucokinases but not in glucokinase from lower reptiles. The Hill's coefficient is very constant with values about 1.6. The K0.5 (concentration for half saturation) values in the different species studied vary between 1.5 and 8 mM. These kinetic parameters may be considered as another adaptive feature aimed to give maximal efficiency to the liver uptake of glucose at the changeable concentrations in the blood resulting from variations in the amount of dietary glucose.
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PMID:Adaptive character of liver glucokinase. 16 20

Addition of the cyclic AMP phosphodiesterase inhibitors theophylline (10- minus 2 M) or papaverine (10- minus 4 M) leads to a complete inhibition of lactose synthesis in incubated guinea pig mammary gland slices. Addition of 10- minus 5 M cyclic AMP or dibutyryl cyclic AMP results in 1 30-40% inhibition of the synthesis, which effect is not increased by applying higher concentrations of these compounds. A 30-40% inhibition can also be obtained with epinephrine (5 - 10- minus 5 M), or isoproterenol (10- minus 4 M), but the polypeptide hormones glucagon (10- minus 7 M), insulin (1 munit/ml) and relaxin (10 mug/ml) do not significantly affect lactose synthesis. Cytochalasin B (5 mug/ml) inhibits lactose production by 58and colchicine (10- minus 5 M) by 25%. These experiments suggest that an increase in the intracellular level of cyclic AMP either through its addition, through hormonal stimulation of its synthesis, or through inhibition of its intracellular breakdown, leads to an inhibition of lactose production in lactating mammary gland. This effect of cyclic AMP is similar to that of progesterone, which is known to inhibit lactation in vivo and the withdrawal of which at parturition has been postulated to initiate lactogenesis.
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PMID:Inhibition by cyclic AMP of lactose production in lactating guinea pig mammary gland slices. 16 55

Insulin has been shown to lower cyclic AMP (cAMP) levels in hormonally sensitive tissue. The mechanism by which this lowering occurs has not yet been fully defined. We studied the effects of insulin on rat adipose tissue cyclic nucleotide phosphodiestrase (PDE) in an incubation system. The adipose tissue used was from both normal animals and animals rendered diabetic by intravenous injections of streptozotocin. Rat epididymal fat pads were incubated in a Krebs-Ringer bicarbonate-4% albumin system with O, 100, 1,000 or 10,000 PU/ml insulin (INS); epinephrine (EPI) or glucagon (GLU) at several different concentrations. After 15 min of incubation, each tissue was homogenized, centrifugated, and the supernatant assayed for cAMP PDE activity using the breakdown of (3-H)cAMP. The data was used to characterize cAMP PDE into apparent high and low K-m PDE components. In the normal animals, INS increased Vmax of the low Km PDE components; 100 pU/ml INS, 30%, 1000 p1/ML INS, 40; and 10,000 pU/ml INS, 20%. In contrast, streptoxotocin diabetes lowered this Vmax by 30%. In the diabetic animals, INS also increased Vmax by 30%. In the diabetic animals, INS also increased Vmax of the low Km PDE component; 100 pU/ml INS, 30%; 1000 pU/ml INS, 50% and 10,000 pU/ml INS, 100%. Epinephrine at 1, 10, and 100 pg/ml stimulated low Km cAMP PDE activity by 67%, 73% and 44% respectively. The stimulatory effect of EPI on both the low and high Km cAMP PDE activity was neutralized by propranolol or adenosine. In comparison to EPI, GLU at very low concentrations, 10-9M, stimulated low Km cAMP PDE. These studies suggest that some of the biologic actions of insulin, an antilipolytic substance, are mediated through activation of low Km PDE. Furthermore, this enzymatic activity is lower in experimental diabetes. The stimulation of low Km PDE by lipolytic hormones may reflect a long-range protective action of these agents.
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PMID:Effect of insulin and lipolytic hormones on cyclic AMP phosphodieterase activity in normal and diabetic rat adipose tissue. 16 58

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

Insulin action is discussed with emphasis on events that occur at the plasma membrane. A summary is presented of previous studies which indicate that the insulin receptor of fat and liver cells is a large glycoprotein, partially buried in the outer surface of the plasma membrane, with a high (K-D approximately 10-10 M) and specific affinity for insulin. The participation of membrane phospholipids in the binding of insulin and the role of sialic acid residues in the transmission of the insulin binding signal are discussed. The relation of insulin action to its effects on cyclic nucleotide levels is explored. On the one hand, insulin action (glucose transport) is inhibited by compounds (cholera toxin, ACTH, glucagon and L-norepinephrine) that stimulate adenylate cyclase; conversely, insulin both inhibits the lipolytic action of these compounds, and raises cellular levels of cyclic GMP. An hypothesis is presented whereby a single cyclase species may be responsible for the formation of either cyclic AMP or cyclic GMP, depending on the nature of the hormone stimulus. The role of membrane phosphorylation in the action of insulin is discussed in the context of experiments demonstrating a specific inhibition by ATP of insulin-mediated glucose transport, in association with the phosphorylation of two specific membrane proteins. The ability of insulin to modulate cyclic nucleotide levels in cultured cells and to act as a growth factor is discussed. Insulin stimulates DNA synthesis and the uptake of alpha-aminoisobutyric acid in human fibroblasts, which effects are also mediated by epidermal growth factor. Insulin acts at concentrations much higher than those obtained in vivo, whereas epidermal growth factor acts at concentrations thought to be physiological. The insulin binding sites (K-D is approximately equal to 10-9 M) related to growth, and observed both in human fibroblasts and in lectin-stimulated and leukemic human lymphocytes would not be appreciably occupied at physiological insulin concentrations. The implications of such 'low affinity' binding sites for insulin are discussed in relation to the action of other growth factors.
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PMID:Insulin: interaction with membrane receprots and relationship to cyclic purine nucleotides and cell growth. 16 82

Cyclic GMP and cyclic AMP have been localized in rat liver, small intestine, and testis by a fluorescent immunocytochemical procedure. In liver, cyclic AMP is distributed along sinusoids predominantly, and increased fluorescence is seen sinusoidal areas after glucagon administration. Cyclic GMP is located in nuclear elements and on the plasma membranes of hepatocytes. In jejunum, cyclic AMP is found predominantly at the basal and lateral sides of brush border cells and in the lamina propria, while cyclic GMP is located to the brush border membrane, smooth muscle, and nuclear elements. In testis, cyclic AMP is found in cytoplasm of cells at the perimeter of the seminiferrous tubules and in interstitial cells, while cyclic AMP is visualized on the plasma membrane of the cells lining the tubules. Cyclic GMP is also seen on chromosomes of premeiotic spermatocytes and in sperm. These data provide histological evidence implicating diverse roles for the nucleotides in these tissues. The nuclear localization of cyclic GMP in all of these tissues suggests a role for the nucleotide in nucleus-directed events.
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PMID:Immunohistochemical localization of 3': 5'-cyclic AMP and 3': 5'-cyclic GMP in rat liver, intestine, and testis. 16 76

Glucagon causes marked elevations of glomerular filtration rate (GFR) in dogs when administered intravenously (i.v.) in small doses. The associated natriuresis is thought to be entirely due to increments in the filtered sodium load. In this study, renal denervation, thyroparathyroidectomy, and blockade of cholinergic, alpha- and beta-adrenergic, dopaminergic and histaminergic receptors did not prevent the usual glucagon-induced elevations of GFR or rate of sodium excretion (UNaV). This effect of glucagon was not mediated through the release of cyclic AMP, or by plasma compositional changes of Ca-2+, K+, or amino acids. Pure porcine secretin, in doses of 5--10 mug/min delivered either i.v. or into the left renal artery did not alter GFR; clearance of the p-aminohippurate (CPAH) or UNaV in either hydropenic or saline-loaded dogs. Nor did this polypeptide, structurally very similar to glucagon, abolish the effect of glucagon on GFR. It did, however, partially inhibit the glucagon-induced natriuresis, presumably by preventing a previously undetected glucagon action on tubular reabsorption of sodium.
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PMID:Further observations on the response of the glomerular filtration rate to glucagon: comparison with secretin. 16 50

The glycogenolytic effect of glucagon has been studied in fetal hepatocytes cultured for 3 to 4 days in the presence of cortisol (10 muM). The hepatocytes, when transplanted from young fetuses (15-day-old), contain only minute amounts of glycogen, whereas when cultured 3 to 4 days in the presence of cortisol, they contain high levels of stored glycogen. Glucagon induced a rapid but partial mobilization of glycogen, which was maximal after 2 hours. The half-maximal response was observed with about 0.1 nM glucagon. The glycogenolytic effect of glucagon in fetal hepatocytes is probably mediated by cyclic adenosine 3':5'-monophosphate (cyclic AMP) as in adult liver. This effect was mimicked by cyclic AMP and N-6, O-2-dibutyryl cyclic AMP, (dibutyryl cyclic AMP), and potentiated by theophylline. Glucagon addition was followed by accumulation of cyclic AMP in the cells within 2 min. Glucagon produces a marked stimulation of the rate of glycogen breakdown and an inhibition of the rate of incorporation of [14-C] glucose into glycogen. The glycogeneolytic effect of a single addition of glucagon was reversed within 4 hours. A second addition of glucagon at this time was unable to induce a new glycogenolytic response. A resistance to glucagon stimulation appeared in the cells after a first exposure to the hormone. This refractoriness was also shown by the loss of glucagon-dependent cyclic AMP accumulation and was not linked to the release by the cells of a "hormone antagonist" into the medium. The hepatocytes resistant to the action of glucagon retained their response to cyclic AMP, dibutyryl cyclic AMP, and norepinephrine. Finally, glycogenolytic concentrations of cyclic AMP and of its dibutyryl derivative failed to induce a refractoriness to glucagon.
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PMID:Glycogenolytic response to glucagon of cultured fetal hepatocytes. Refractoriness following prior exposure to glucagon. 16 9

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