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)

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

Adrenalin and glucagon inhibit glycogen, fatty acid and cholesterol synthesis by elevation of cyclic AMP, activation of cyclic AMP-dependent protein kinase and increased phosphorylation of the rate-limiting enzymes of these pathways. Here, we review recent evidence which indicates that inhibition of these biosynthetic pathways in muscle, adipose tissue and liver is much more indirect than has previously been supposed. In particular, cyclic AMP-dependent protein kinase does not appear to inhibit glycogen synthase, acetyl-CoA carboxylase and HMG-CoA reductase by phosphorylating them directly. It appears to achieve the same end result by inactivation of the protein phosphatases which dephosphorylate these regulatory enzymes in vivo, although this has only been established definitively in the case of glycogen synthesis.
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PMID:The actions of cyclic AMP on biosynthetic processes are mediated indirectly by cyclic AMP-dependent protein kinase. 165 40

We investigated the kinetics of the mitochondrial respiratory chain, proton leak, and phosphorylating subsystems of liver mitochondria from mannoheptulose-treated and control rats. Mannoheptulose treatment raises glucagon and lowers insulin; it had no effect on the kinetics of the mitochondrial proton leak or phosphorylating subsystems, but the respiratory chain from succinate to oxygen was stimulated. Previous attempts to detect any stimulation of cytochrome c oxidase by glucagon are shown by flux control analysis to have used inappropriate assay conditions. To investigate the site of stimulation of the respiratory chain we measured the relationship between the thermodynamic driving force and respiration rate for the span succinate to coenzyme Q, the cytochrome bc1 complex and cytochrome c oxidase. Hormone treatment of rats altered the kinetics of electron transport from succinate to coenzyme Q in subsequently isolated mitochondria and activated succinate dehydrogenase. The kinetics of electron transport through the cytochrome bc1 complex were not affected. Effects on cytochrome c oxidase were small or nonexistent.
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PMID:Stimulation of the electron transport chain in mitochondria isolated from rats treated with mannoheptulose or glucagon. 217 25

Phosphorylation of the beta-adrenergic receptor (beta AR) is closely associated with homologous desensitization of the beta-adrenergic receptor-coupled adenylate cyclase system. Homologous desensitization and receptor phosphorylation also occur in cell mutants which are deficient in their cAMP-dependent protein kinase (kin- mutant of S49 lymphoma cells). beta AR phosphorylation is mediated by a cAMP-independent protein kinase which phosphorylates the receptor only when it is occupied by a beta-agonist. During the time course of desensitization the beta AR kinase (beta ARK) activity is translocated from a cytoplasmic to a plasma membrane location. beta ARK translocation can also be effected by prostaglandin E1 (PGE1) suggesting that this beta ARK may represent a more general enzyme capable of phosphorylating other adenylate cyclase-coupled receptors. Thus, beta ARK may play a key role in the process of homologous desensitization of adenylate cyclase coupled receptors. Extracellular hormones interact with specific receptors at the outer surface of the plasma membrane and thus initiate a cellular response. One of the best studied transmembrane signalling systems known to be coupled to the occupancy of cell surface receptors is adenylate cyclase. The adenylate cyclase system is composed of various components all of which have been purified to homogeneity (Shorr et al., 1982; Homcy et al., 1983; Benovic et al., 1984; Codina et al., 1984; Northup et al., 1980; Sternweis et al., 1981; Bokoch et al., 1984; Pfeuffer et al., 1985). Initially, agonist binding to the receptor promotes coupling of the occupied receptor to one of the guanine nucleotide binding regulatory proteins. These proteins are members of a family of heterotrimeric proteins consisting of alpha, beta and gamma subunits. Stimulatory receptors like the beta-adrenergic (Cerione et al., 1984) or glucagon (Iyengar et al., 1979) receptors couple to the stimulatory regulatory protein Ns (or Gs) whereas inhibitory receptors like the alpha 2-adrenergic (Jacobs et al., 1976) or M2-muscarinic (Harden et al., 1982) receptors couple to the inhibitory regulatory protein Ni (or Gi). Prolonged exposure to agonist hormones, either stimulatory or inhibitory, results in an attenuation of the response to the hormonal activation, a phenomenon called tachyphylaxis or desensitization (Harden, 1983; Sibley and Lefkowitz, 1985; Sharma et al., 1975). One of the best studied models for desensitization is the beta-adrenergic receptor-coupled adenylate cyclase system. In this system two different forms of desensitization have been characterized.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:The beta-adrenergic receptor kinase: role in homologous desensitization in S49 lymphoma cells. 284 12

The adrenergic control of the hormonal and hepatic metabolic response to exercise was studied in untrained fed male rats. Rats were injected intraperitoneally with either saline, the alpha-adrenergic antagonist phentolamine, or the beta-adrenergic antagonist propranolol 30 min before exercise. The rats swam for 50 min in 34-35 degrees C water with a tail weight (5% of body wt). Exercise resulted in a suppression of plasma insulin in all treatment groups; however, plasma glucagon increased only in the propranolol group. The liver glycogen content was decreased with exercise only in the saline and propranolol groups. Likewise, phosphorylating respiration of liver mitochondria isolated after exercise was higher only in the saline and propranolol groups. Thus phentolamine pretreatment blocked the liver glycogen depletion and the increased liver mitochondrial phosphorylating respiration observed after exercise in fed rats. The results suggest that alpha-adrenergic mechanisms are operant with exercise and stimulate liver glycogenolysis and mitochondrial phosphorylating respiration.
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PMID:Adrenergic influence on hormonal and hepatic metabolic response to exercise in rats. 352 35

Isolated rat hepatocytes were incubated in a medium containing 0.1 mM [32P]phosphate (0.1 mCi/ml) before exposure to epinephrine, glucagon or vasopressin. 32P-labeled glycogen synthase was purified from extracts of control or hormone-treated cells by the use of specific antibodies raised to rabbit skeletal muscle glycogen synthase. Analysis of the immunoprecipitates by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate indicated that a single 32P-labeled polypeptide, apparent Mr 88000, was removed specifically by the antibodies and corresponded to glycogen synthase. Similar electrophoretic analysis of CNBr fragments prepared from the immunoprecipitate revealed that 32P was distributed between two fragments, of apparent Mr 14000 (CB-1) and 28000 (CB-2). Epinephrine, vasopressin or glucagon increased the 32P content of the glycogen synthase subunit. CB-2 phosphorylation was increased by all three hormones while CB-1 was most affected by epinephrine and vasopressin. These effects correlated with a decrease in glycogen synthase activity. From studies using rat liver glycogen synthase, purified by conventional methods and phosphorylated in vitro by individual protein kinases, it was found that electrophoretically similar CNBr fragments could be obtained. However, neither cyclic-AMP-dependent protein kinase nor three different Ca2+-dependent enzymes (phosphorylase kinase, calmodulin-dependent protein kinase, and protein kinase C) were effective in phosphorylating CB-2. The protein kinases most effective towards CB-2 were the Ca2+ and cyclic-nucleotide-independent enzymes casein kinase II (PC0.7) and FA/GSK-3. The results demonstrate that rat liver glycogen synthase undergoes multiple phosphorylation in whole cells and that stimulation of cells by glycogenolytic hormones can modify the phosphorylation of at least two distinct sites in the enzyme. The specificity of the hormones, however, cannot be explained simply by the direct action of any known protein kinase dependent on cyclic nucleotide or Ca2+. Therefore, either control of other protein kinases, such as FA/GSK-3, is involved or phosphatase activity is regulated, or both.
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PMID:Control of glycogen synthase phosphorylation in isolated rat hepatocytes by epinephrine, vasopressin and glucagon. 643 31

In order to examine the effect of a single bout of exercise on hepatic mitochondrial function, starved untrained male rats swam at 34-35 degrees C with a tail weight (5% of body wt.) for 100 min. The rates of ADP-stimulated and uncoupled respiration were higher in the mitochondria isolated from the exercised rats regardless of the substrate utilized. Succinate-linked Ca2+ uptake was 48% greater in the exercised group; however, Ca2+ efflux was markedly depressed. The inhibition of Ca2+ uptake by Mg2+ was higher in the control group, so that the difference in Ca2+ uptake between the two groups was greater in the presence of Mg2+ than in its absence. The response of phosphorylating respiration and Ca2+ fluxes to exogenous phosphate and the pH of the assay medium differed in the exercise group. These observations with the exercised group were not related to non-specific stress. The exercise-induced mitochondrial-functional alterations are reminiscent of those obtained from mitochondria isolated from glucagon- or catecholamine-treated sedentary rats. Thus, adrenergic stimulation as well as other factors may be operating during exercise, leading to an alteration of mitochondrial function in vitro.
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PMID:Exercise-induced alterations of hepatic mitochondrial function. 716 27

The time course for the effects of acute, in vivo glucagon treatment on energy-linked functions of isolated hepatic mitochondria has been studied. After 1 min of glucagon treatment, two changes are observed in mitochondrial function. State 4 (nonphosphorylating) respiratory rates with L-glutamate as substrate are decreased. No significant change is observed in the State 4 respiratory rates with succinate as substrate at 1 min of treatment. Concurrent with the change in nonphosphorylating respiratory rates is a decrease in the half time of spontaneous calcium release from mitochondria preloaded with calcium in a phosphate-containing medium. After 2-4 min of treatment, the previously reported stimulations in rates of State 3 (phosphorylating) respiration and calcium influx into mitochondria are observed. After approximately 6 min of treatment, these changes have reached their maxima. The combined effects of increased calcium uptake rate and decreased calcium efflux rate leads to a decrease in the calcium cycling rate of mitochondria. This decrease in the cycling rate should lead to the increased efficiency of mitochondrial energy transduction and may be responsible, in part, for the increased functional capability of mitochondria isolated from glucagon-treated animals. A correlate of the reduced cycling rate is a decrease in the steady-state concentration at which the mitochondria can buffer the calcium concentration of the incubation medium. The changes observed in calcium efflux rates and respiratory rates exhibit a time course consistent with possible intermediates in the glucagon-induced stimulation of hepatic gluconeogenesis.
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PMID:Rapid action of glucagon on hepatic mitochondrial calcium metabolism and respiratory rates. 739 34

A transgene consisting of an upstream glucokinase (GK) promoter fragment linked to coding sequences of the human growth hormone gene was expressed in certain neuroendocrine cells of the pancreas, pituitary, brain, gut, thyroid, and lungs of mice. In pancreas, the transgene was expressed in a nonuniform manner among beta cells and in a variable but substantial fraction of the other islet cell types. In pituitary, it was expressed in corticotropes, and in brain, it was expressed in cells of the medial hypothalamus. Within the gut transgene expression was detected in a subset of enteroendocrine cells of the stomach and duodenal epithelium, some of which also exhibited glucagon-like polypeptide-1 immunoreactivity. In thyroid, transgene expression was observed in C cells of neonatal animals, whereas in the lung, it was expressed among rare endocrine cells of the bronchopulmonary mucosa. RNA polymerase chain reaction analysis of human growth hormone mRNA corroborated the tissue-specific transgene expression pattern. Prompted by the finding of transgene expression in specific neuroendocrine cells, we sought to determine whether GK mRNA and GK itself was also expressed in the brain and gut, tissues not previously associated with the expression of this enzyme. Using rat tissues, GK mRNA was detected by RNA polymerase chain reaction in both the brain and intestine and was localized to specific cells in the hypothalamus and enteric mucosa by in situ hybridization. A high Km glucose phosphorylating activity was detected from isolated rat jejunal enterocytes that displayed a chromatographic elution profile identical to hepatic GK. GK immunoreactivity was detected in cells of the medial hypothalamus with many of the same cells also displaying GLUT2 immunoreactivity. Together, these studies provide evidence for upstream GK promoter activity, GK mRNA, and GK itself in certain neuroendocrine cells outside the pancreatic islet and lead us to suggest that GK may play a broader role in glucose sensing by neuroendocrine cells than was thought previously.
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PMID:Analysis of upstream glucokinase promoter activity in transgenic mice and identification of glucokinase in rare neuroendocrine cells in the brain and gut. 810 9

Glucose, that Claude Bernard has demonstrated in 1850 to be synthesized and secreted by the liver, is an important regulator of gene transcription in all types of organisms. In vertebrates, it especially regulates transcription of metabolic genes in the liver and fat tissue, activating genes encoding enzymes and regulators of the glycolytic and lipogenic pathways. Working with the L-type pyruvate kinase gene we have found that in hepatocytes glucose-dependent gene regulation requires: Presence of the GLUT2 glucose transporter, necessary to allow for an effective depletion in glucose 6-phosphate (G-6P) under gluconeogenic conditions. Phosphorylation of glucose to G-6P assured either by insulin-dependent glucokinase or by another hexokinase isoform. Most likely, entry of G-6P in the pentose phosphate pathway. Modulation of a kinase/phosphatase cascade, in particular inhibition of the 5'AMP-activated protein kinase. Signalling through a glucose response complex assembled onto a glucose-response element (GIRE) located in regulatory regions of glucose-responsive genes. The activators USF belong to the complex, and are required for a normal gene activation by glucose, as evidenced from the phenotype of knock-out mice deficient in USF. The study of USF-defective knock-out mice suggest that USF could be involved in nutritional activation of a whole class of genes regulated by glucose, and not by insulin itself. In particular, lipogenic genes and the ob gene, encoding the leptin satiety hormone, are abnormally responsive to diet in USF-/- mice. The transactivation potential of USF would be modulated by a glucose sensor system implying the COUP-TFII transcription inhibitor. The main role of insulin in the glucose response of genes like the L-PK gene is to induce the glucokinase gene. Glucagon, through cyclic AMP, inhibits L-PK gene transcription mainly through activation of PKA. The PKA catalytic subunit could act by phosphorylating member(s) of the glucose-response complex, or of contiguous transcription factor, e.g. HNF4. In conclusion, through a pluridisciplinary approach ranging from Claude Bernard-derived biology to modern molecular biology, important progress have been made during the last years on the mechanisms of the regulation of gene transcription by glucose in vertebrates.
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PMID:[From the glycogenic function of the liver to gene regulation by glucose]. 987 95

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