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)

Hepatocytes were isolated from fed rats with glucose and insulin and freom fasted rats with glucagon in all media in an attempt to obtain cells which might be fixed preferentially in either the glycolytic or gluconeogenic state. When tested enzymatically, both "fed" and fasted" cells catalyzed glucose formation from lactate (gluconeogenesis) and lactate formation from fructose (fructolysis); lactate formation from glucose may have occurred in "fed" cells. Thus it was impossible, at least in the C3 part of the metabolic pathways between triosephosphate and pyruvate, to fix the hepatocytes in either metabolic state. The shift from glycolysis to gluconeogenesis could be investigated for the C3 part in "fasted" cells with fructose as the glycolytic and lactate as the gluconeogenic substrate. Lactate was first formed from fructose and later reutilized to a large extent. This reconsumption was blocked by the gluconeogenesis inhibitor quinolinate, both when tested enzymatically and radiochemically. Thus fructolysis was shifted to lactate gluconeogenesis. This shift at the assumed phosphoenolpyruvate/pyruvate cycle was autoregulatory, i.e. dependent on substrates and independent of circulating horomes. Maximal velocities and half saturating concentrations were determined for fructose and for lactate as substrates. The kinetic data obtained, especially the sigmoidal pattern of fructolysis, could nicely explain phenomenologically the rather sudden slow-down of lactate production and the shift to lactate consumption. The levels of the metabolites ATP, ADP, AMP, fructose bisphosphate and alanine, which control the enzymes of the assumed phosphoenolypyruvate/pyruvate cycle, were determined in the cytosol and in the mitochondria before and after the shift from fructose glycolysis to lactate gluconeogenesis. The changes observed could not explain the shift. Experiments with [14C] fructose plus unlabelled lactate and reciprocally, with unlabelled fructose plus [14C] lactate, clearly reveled that within the C3 part, glycolysis and gluconeogenesis were catalyzed simultaneously. The simultaneity of and the shift between fructolysis and gluconeogenesis by the liver cell suspension can best be explained by assuming two metabolically different types of hepatocytes rather than one type of hepatocyte with metabolically equal or different cell compartment. In vivo, the different types of hepatocytes would form a gluconeogenic and a glycolytic zone within the liver parenchyma. Since, under normal conditions, the size of these metabolic zones should remain unaltered, the shift from net glycolysis to net gluconeogenesis would be dependent primarily on substrate concentrations (autoregulation).
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PMID:Autoregulatory shift from fructolysis to lactate gluconeogenisis in rat hepatocyte suspensions. The problem of metabolic zonation of liver parenchyma. 95 64

Adenylate cyclase (EC 4.6.1.1) activity in mouse liver plasma membranes is increased fivefold when animals are pretreated with cholera toxin. The increase in activity is detectable within 20 min of an intravenous injection of the toxin. The response of the control and cholera-toxin-activated adenylate cyclase to hormones, GTP, and NaF is complex. GTP causes the same fold stimulation of control and toxin-activated cyclase, but glucagon and NaF remain the most potent activators of liver adenylate cyclase irrespective of whether the enzyme is activated by cholera toxin. Determination of kinetic parameters of adenylate cyclase indicates that cholera toxin, hormones, and NaF do not change the affinity of the enzyme for ATP-Mg nor do they alter the Ka for free Mg2+. High concentrations of Mg2+ inhibit adenylate cyclase that is stimulated by either cholera toxin, glucagon, or NaF. These same Mg2+ concentrations have no effect on the basal activity of the enzyme or its activity in the presence of GTP.
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PMID:Cholera toxin and adenylate cyclase: properties of the activated enzyme in liver plasma membranes. 100 Mar 62

By measuring the specific radioactivity of glucose released from isolated perfused livers of normal, fed rats in the presence of [U-14C]fructose, the gluconeogenetic and glycogenolytic contributions to glucose production were estimated. After 20 min of perfusion with 4 mM fructose, glycogenolysis was inhibited by 40% in the absence and by 70% in the presence of glucagon (3 nM). Glucagon decreased the release of lactate plus pyruvate and enhanced glucose formation from fructose without affecting its uptake. Glycerol (4 mM) and xylitol (3 mM) had qualitatively similar, but smaller effects on glucagon-stimulated glycogenolysis. The glucagon-mediated phosphorylase b to a conversion was not altered by fructose, indicating that glycogenolysis was decreased as a consequence of an inhibition of phosphorylase a. During the first minutes after the addition of fructose, decreased ATP/AMP ratios and tissue Pi levels correlated with a transient increase of phosphorylase a activity. It was concluded that the effects of fructose on the control of hepatic glycogenolysis and glucose production were the result of a complex interplay between a transient b to a conversion of phosphorylase and an inhibition of the a-form of the enzyme, possibly by fructose 1-phosphate and other phosphorylated metabolites.
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PMID:Interactions of glucagon and fructose in the control of glycogenolysis in perfused rat liver. 100 7

Incubation of rat fat pad membranes with 5-guanylyliminodiphosphonate [Gpp-(NH)p] and 5-guanylylmethylenediphosphonate [Gpp(CH2)p], but not GTP (with or without hormones), at 24 degrees or 30 degrees (but not at 4 degrees) greatly stimulates adenylate cyclase activity [ATP pyrophosphate-lyase (cyclizing), EC 4.6.1.1] measured after thoroughly washing the membranes. The rate of activation is relatively slow, even with very high (and saturating) concentrations of the analogs. Binding alone appears to be insufficient for activation. Hormones (catecholamines, glucagon) increase the rate but not the extent of activation, even when saturating analog concentrations are used. The dependence on analog concentration (apparent Km) varies with the time of incubation. GTP and very high concentrations of ATP inhibit the activation by Gpp(NH)p, but this effect is dependent on the length of incubation and can be overcome with time. The activated state is not reversed upon incubation of the washed membranes at 30 degrees, even in the presence of GTP, or by solubilization with nonionic detergents. Also, Gpp(NH)p can directly stimulate the control, solubilized enzyme. The activated state of the solubilized enzyme persists upon specific adsorption to and subsequent elution from an organomercurial-agarose column. It is suggested that after forming reversible Michaelis complexes of relatively low affinity, these analogs may react irreversibly with the GTP regulatory site of the enzyme, perhaps forming p(NH)p- and p(CH2)p-covalent enzyme intermediates which capture the activated state of the enzyme. GTP, after binding, may normally activate the enzyme by forming a "labile" pyrophosphoryl enzyme intermediate, and hormone receptors may function to increase the rate of formation (and thus concentration) of this active state of the enzyme.
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PMID:Activation of adenylate cyclase by phosphoramidate and phosphonate analogs of GTP: possible role of covalent enzyme-substrate intermediates in the mechanism of hormonal activation. 105 66

The effects of various nucleosides and nucleotides upon glucagon secretion from the isolated perfused rat pancreas were studied. Increasing glucagon secretion was found with increasing concentrations of exogenous cyclic AMP (2 X 10(-4) M, 2 X 10(-3) M and 1 X 10(-2) M). Stimulation of alpha cell secretion was also found with 2 X 10(-3) M 2'AMP, 3'AMP, 5'AMP, ADP, Adenosine, NADP, and NADPH. One X 10(-3) M cyclic GMP elicited significant glucagon secretion. The pattern of glucagon release was similar in all cases with peak secretion occurring during the 30- to 90-s time period following initiation of the stimulus. No significant increase of glucagon secretion was found in response to ATP, guanosine, 2'GMP, 3'GMP, 5'GMP, GTP, xanthosine, inosine, adenine, xanthine, thymidine, cytidine, ribose, nicotinamide, and uric acid. On the basis of the above results, the structural requirement for stimulation of glucagon secretion appears to be adenine linked to ribose, with phosphate groups being unnecessary. The conclusion of this study is that a new class of compounds capable of stimulating glucagon secretion has been identified, and important questions are thus raised about the mechanism of the action of exogenous cyclic AMP.
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PMID:Nucleotide and nucleoside stimulation of glucagon secretion. 110 53

The epinephrine sensitivity in vitro of the adenylate cyclase system in liver plasma membranes from adrenalectomized rats was increased by the addition of 1 to 100 muM GTP or GDP in the incubation medium. Basal and glucagon-stimulated cyclase activities were also enhanced by GTP and GDP. These effects occurred even in the absence of an ATP-regenerating system. They were mimicked by 5'-guanyl diphosphonate and a series of guanyl derivatives, indicating that the structural requirement for the GTP action is not very stringent. Guanyl nucleotides did not increase the affinity of the adenylate cyclase system for the activating hormones, nor did they protect the enzyme activity against denaturation. Their synergic effect was due to an enhancement of the affinity of the enzyme for the substrate MgATP and also to an increase of the maximal velocity of the reaction. It is proposed that the guanyl nucleotides act directly and primarily upon the catalytic component of the cyclase system, independently of their effects on the binding of the activating hormones to liver plasma membrane. Since the activating effects of epinephrine and glucagon are similar in the presence of GTP, but not in its absence, it is suggested that the lower efficiency of epinephrine under normal conditions is not due to intrinsic membrane characteristics, but rather, to superimposed extraneous modulations.
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PMID:The epinephrine-sensitive adenylate cyclase of rat liver plasma membranes. Role of guanyl nucleotides. 114 Dec 21

A system using hepatocyte suspensions in vitro was developed for studying the synthesis of albumin, fibrinogen and transferrin. Conditions for optimum survival of the hepatocyte and for synthesis of these plasma proteins were defined for this system. These conditions included the use of horse serum (17.5 percent, v/v, heat-inactivated), an enriched medium (Waymouth's MB 752/1), an O2 tension of between 18.7 times 10(3) and 26.7 times 10(3) Pa and constant stirring. Albumin, fibrinogen and transferrin synthesis rates were obtained of 0.32 p 0.094(10), 0.12 p 0.030(11) and 0.097 p 0.017(10) [mean p S.D. (n)]mg/h per g of hepatocytes respectively. These rates were maintained for the first 12h of study and synthesis continued at a diminished rate up to 48h. The synthesis of albumin was decreased in a medium containing less amino acids and glucose, but that of fibrinogen was substantially unaffected. ATP concentrations up to 12h and RNA/DNA ratios up to 24h were comparable with values in vivo. The ability to study cells up to 48h permitted us to find that the addition of a mixture of hormones consisting of glucagon, cortisol, tri-iodothyronine and growth hormone enhanced fibrinogen synthesis. Addition of insulin to the above mixture resulted in increased synthesis for albumin and transferrin but not for fibrinogen.
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PMID:Albumin, fibrinogen and transferrin synthesis in isolated rat hepatocyte suspensions. A model for the study of plasma protein synthesis. 114 94

The metabolic effects of glucagon and glucagon plus insulin on the isolated rat livers perfused with 10 mM sodium L-lactate as substrate were studied. Glucagon stimulated gluconeogenesis, ketogenesis and ureogenesis at the concentration used of 2.1 nM. The addition of insulin to give a glucagon-to-insulin ratio of 0.2 reversed all the glucagon effects. The glucagon enhancement of gluconeogenesis was accompanied by a rise in cytosolic and mitochondrial state of reduction of the NAD system and a fall in the [ATP]/[ADP] ratio. The analysis of the intermediary metabolite concentrations suggested, as possible sites of glucagon action, the steps between pyruvate and phosphoenolpyruvate as well as the reactions catalyzed by phosphofructokinase and/or fructose bisphosphatase. All the changes in metabolite contents were abolished when insulin was present. Glucagon increased the intramitochondrial concentration of all the metabolites, whose intracellular distribution was calculated. The finding of a significant rise in the calculated intramitochondrial concentration of oxaloacetate points to pyruvate carboxylation as an important site of glucagon interaction with the gluconeogenic pathway. A primary event in the glucagon action redistributing intracellular metabolites seems to be the mitochondrial entry of malate. The possibility is discussed that the changes in metabolite cellular distribution were brought about by the increased cellular state of reduction caused by the hormone.
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PMID:Glucagon and insulin control of gluconeogenesis in the perfused isolated rat liver. Effects on cellular metabolite distribution. 117 30

Glucagon and adrenaline exert their action upon the liver via the cyclic AMP synthetizing system located in the plasma membrane. The enzyme adenylate cyclase is further regulated by guanyl nucleotides. It has been recently shown that the rat liver plasma membrane system could respond to GTP by simultaneous increase in the cyclase activity in response to glucagon and by the dissociation of this hormone from its binding sites (1). Unambiguous relationship between the activating effect of GTP upon the cyclase and its action upon glucagon binding has not been determined yet (2). This problem was approached using the in vitro action of epinephrine as a model. When 1 to 100 muM GTP or DGP were added to rat liver plasma membranes isolated from adrenalectomized animals, they increased markedly the response of the cyclase system to epinephrine. These effects could be observed in the absence of an ATP-regenerating system and were mimicked by 5'-guanylyl diphosphonate; GTP and GDP were the most active compounds followed by ITP, CTP and by a series of guanyl derivatives. UTP, as well as guanosine, GMP, cyclic GMP and ppGpp were inactive. Guanyl nucleotides did not increase the affinity of the cyclase system for the activating hormones, but enhanced the affinity for ATP-Mg and also the Vmax of the reaction. Finally, GTP, ATP, CTP, UTP but not GDP displaced epinephrine bound to plasma membranes by a mere chelation phenomenon. It is concluded that 1) guanyl nucleotides do not act primarily by influencing the binding of hormones to the membranes; 2) they act directly upon the catalytic subunit of the cyclase; 3) the low concentrations of GTP required for its action strongly suggest that this nucleotide plays a role in the physiological regulation of the intrahepatic cyclic AMP level.
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PMID:[Role of guanidylic nucleotides in the adenylate cyclase activity of the rat liver]. 120 15

Glucagon and beta-adrenergic compounds such as 1-isoproterenol stimulated the low activity of an ATP-utilizing enzyme located on the cell membranes of normal keratinocytes. Addition of beta-antagonist propranolol to the incubation medium prevented the stimulatory effect of 1-isoproterenol. We considered, therefore, the reaction product being due to epidermal membrane-bound adenyl cyclase activity. In psoriatic epidermis the basal adenyl cyclase activity was low, similar to normal epidermis, however, glucagon and 1-isoproterenol failed to stimulate the enzyme activity in psoriasis under the same conditions. It seems, therefore, that the beta-adrenergic-cAMP cascade as a regulatory epidermal control mechanism of induced proliferation is ineffective in this disease.
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PMID:[Lack of beta-adrenergic stimulation of membrane bound adenyl cyclase in psoriasis as compared to normal epidermis (author's transl)]. 124 87


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