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)

Alanine and glutamine formation and release were studied using the intact epitrochlaris preparation of rat skeletal muscle. Epinephrine reduced the release of alanine and glutamine in a concentration-dependent manner. Measurable inhibition was observed at 10(-9) M epinephrine, and maximal inhibition was obtained at 10(-5) M. Norepinephrine also reduced alanine and glutamine formation and release but the concentration required for maximal inhibition was approximately 100-fold greater than for epinephrine. Isoproterenol (beta agonist), but not phenylephrine (alpha agonist), reproduced the effects of epinephrine, and propranolol (beta antagonist), but not phentolamine (alpha antagonist), blocked the effect of the catecholamine. N6,O2'-Dibutyryl adenosine 3':5'-monophosphate reproduced the effects of epinephrine and theophylline potentiated the effect of submaximal concentrations of the hormone. Glucagon and prostaglandin E2 had no observable effect on amino acid release. Insulin did not modify the inhibition of alanine and glutamine release produced by epinephrine. Alanine and glutamine formation from added precursor amino acids was unaffected by epinephrine or cyclic adenosine 3':5'-monophosphate. Epinephrine reduced alanine formation in muscles obtained from diabetic rats or animals treated with thyroxine or cortisone. These findings indicate that physiological levels of catecholamines reduce alanine and glutamine formation and release from skeletal muscle. This effect is mediated by a beta-adrenergic receptor and the adenylate cyclase system and can be accounted for by an inhibition of muscle protein degradation.
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PMID:Alanine and glutamine synthesis and release from skeletal muscle. IV. beta-Adrenergic inhibition of amino acid release. 17 62

Plasma glucagon rises after major injury and could act to increase gluconeogenesis and ureagenesis in the post-traumatic state. This study documents the effect of prolonged glucagon infusion on ureagenesis and nitrogen excretion, as well as possible sources of the increased ureagenesis, in normal man. Four healthy men fasted for 6 days during intravenous infusion of glucose (750 gmday), establishing a steady state of minimal ureagenesis. Glucagon (1 mg/day) then was added to the infusion for 5 days. Glucose alone was given for the final 2 days. Forearm muscle flux of metabolites was determined by standard arterial-deep venous sampling and capacitance plethysmography. Glucagon concentration was suppressed during glucose infusion (11 +/- 13 pg/ml) and rose to levels seen in subjects with major trauma during glucagon infusion (669 +/- 138 pg/ml). Glucose infusion stabilized urine nitrogen excretion at 1.54 +/- 0.42 gm of N/sq m/day. Nitrogen excretion increased to 2.40 +/- 0.53 gm of N/sq m/day with glucagon infusion, with urea accounting for the increased excretion. Excretion of 3-methylhistidine was unchanged. Plasma amino acid concentration was strikingly reduced on the first day of glucagon infusion, where it stabilized. Forearm flux showed a slight net release of amino acid nitrogen during glucose infusion. Addition of glucagon to the glucose infusion resulted in a net uptake of nitrogen by forearm skeletal muscle. These evidences strong suggest that glucagon infusion in normal man increases ureagenesis, not only at the expense of the free amino acid pool, but by the hydrolysis of visceral protein as well, with muscle protein being maintained.
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PMID:The effects of glucagon on protein metabolism in normal man. 38 36

In order to assess the role of glucagon in human protein metabolism and to examine its action as a "catabolic" hormone, studies were conducted in two normal male subjects over an 8-day period. After minimum and stable urinary nitrogen excretion had been produced by the continuous nasogastric administration of carbohydrate (720 g/day) for 8 consecutive days, a continuous intravenous infusion of glucagon (1.0 mg/24 hr) was superimposed on days 7 and 8. Excretion of total nitrogen (N) and urea-N increased significantly (p less than 0.05). Excretion of 3-methylhistidine was unaltered, suggesting that the source of the N losses produced by glucagon did not derive from increased muscle proteolysis. Although striking hypoaminoacidemia was produced, the reductions of extracellular amino acids alone could not account for all of the extra urea excreted. These data suggest that hyperglucagonemia in normal man induces mild nitrogen losses by stimulation of hepatic ureogenesis from free intracellular amino acid pools and not by increased rates of muscle protein breakdown.
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PMID:Glucagon infusion in normal man: effects on 3-methylhistidine excretion and plasma amino acids. 40 91

Net hepatic uptakes of plasma alanine (Ala), glutamate (Glu), and glutamine (Gln) were measured before and during intraportal glucagon infusions in five normaland four insulin-and alloxan-treated (ITA), conscious, fed sheep. Since hyperinsulinemia is associated with glucagon administration, ITA sheep were used so that constant plasma insulin levels could be maintained. Glucose turnover was determined by a vena caval infusion of glucose-6-'3H. In addition, in ITA sheep, Ala-'14C wasinfused for measurement of plasma Ala turnover, its unidirectional organ metabolism, and contribution to glucose synthesis. During infusion of glucagon, the net hepatic uptake of Ala increased significantly (P is less than 0.01) from control values of 3.8 plus or minus 0.5 and 2.7 plus or minus 0.6 mmol/h to 5.9 plus or minus 1.0 and 5.5 plus or minus 0.8 mmol/h in normal and ITA sheep, respectively. Similarly, Gin uptake increased from 4.3 plus or minus 1.4 and 1.6 plus or minus 0.5 to 5.5 plus or minus1.6 and 3.7 plus or minus 1.0 mmol/h, respectively. The conversion of Ala to glucose increased from control values of 1.7 plus or minus 0.5 to 3.0 plus or minus 0.5 mmol/h. Arterial plasma Ala and Gin concentrations decreased about 25% during glucagon administration, presumably as a result of their increased hepatic uptakes. A decreasein utilization of plasma Ala, but no change in production was calculated for the nonhepatic tissues, indicating that glucagon increased gluconeogenesis from Ala at the expense of muscle protein synthesis. Glucagon thus has a direct effect on the liver butonly an indirect effect on other tissues.
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PMID:Effect of glucagon on plasma alanine and glutamine metabolism and hepatic gluconeogenesis in sheep. 115 95

Incorporation of L-[1-13C]leucine into muscle protein and leg exchange of L-[15N]phenylalanine were used to assess the effects over 240 min of amino acid supply on leg protein turnover in anesthetized, overnight-fasted (Landrace x Great White) female pigs. In all pigs, plasma insulin and glucagon stability was ensured by infusion of somatostatin (8 micrograms.kg-1.h-1), insulin (6 mU.kg-1.h-1), and glucagon (72 ng.kg-1.h-1). Mixed amino acid infusion (260 mg.kg-1.h-1) caused a 2- to 2.5-fold elevation of arterial plasma phenylalanine and leucine; in a control group (no amino acid infusion), an increase in phenylalanine and leucine concentration was observed as a result of the hormone clamp. Plasma insulin and glucagon concentrations were steady and not significantly different between control and amino acid-infused groups during the final 240 min, but plasma glucose fell (P less than 0.05) in both groups (4.57 +/- 0.17 to 3.15 +/- 0.73 mM). Muscle protein synthetic rate (estimated from the change in L-[1-13C]leucine incorporation compared with labeling of [13C]leucyl-tRNA) was greater in amino acid-infused (0.076%/h) than in control (0.053%/h) pigs. In the control group, leg amino acid balance was negative (Phe alone, -10.2 +/- 9.4 nmol Phe.100 g-1.min-1; total amino acids, -0.27 +/- 1.04 micrograms amino N.100 g-1.min-1), but during amino acid infusion, balance was positive (Phe alone, +33.6 +/- 8.8 nmol Phe.100 g-1.min-1; total amino acids, +58.2 +/- 4.9 micrograms amino N.100 g-1.min-1).(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Stimulation of protein synthesis in pig skeletal muscle by infusion of amino acids during constant insulin availability. 141 25

Stimulation of the immune system results in a series of metabolic changes that are antagonistic toward growth. Monokines, including interleukin-1, tumor necrosis factor, and interleukin-6, are released from cells of the monocyte-macrophage lineage after recognition of immunogens. They appear to mediate homeorhetic response, which alters the partitioning of dietary nutrients away from growth and skeletal muscle accretion in favor of metabolic processes which support the immune response and disease resistance. These alterations include 1) decreased skeletal muscle accretion due to increased rates of protein degradation and decreased protein synthesis; 2) increased basal metabolic rate resulting in increased energy utilization; 3) use of dietary amino acids for gluconeogenesis and as an energy source instead of for muscle protein accretion; 4) synthesis by the liver of acute phase proteins; 5) redistribution of iron, zinc, and copper within the body due to the hepatic synthesis of metallothionein, ferritin, and ceruloplasmin; (6) impaired accretion of cartilage and bone; and 7) release of hormones such as insulin, glucagon, and corticosterone. These monokines also influence the differentiation of cells. Tumor necrosis factor suppresses the differentiation of myoblasts and adipocytes whereas the chicken monokine myelomonocytic growth factor induces the differentiation of granulocytes.
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PMID:Monokines in growth and development. 171 68

The counter-regulatory hormones, including glucagon, may be involved in the generation of postoperative negative nitrogen balance. We examined the influence of glucagon on whole body and forearm muscle protein kinetics, determined by L-[1-13C, 15N]leucine, in two matched groups of healthy fasting subjects. In one study somatostatin alone was infused continuously (0.12 mg h-1) and in another with glucagon (0.04 mg h-1) to generate insulin resistance. Somatostatin infusion increased leucine oxidation (P less than 0.05) and reduced the negative protein balance (P less than 0.01) across the forearm; the 15 per cent decrease in protein breakdown was not significant. Whole body leucine kinetics showed increased flux (P less than 0.05) and synthesis (P less than 0.01) but reduced oxidation (P less than 0.05). Hyperglucagonaemia caused a threefold enhancement of leucine oxidation (P less than 0.02), while the negative protein balance further increased (P less than 0.05) across the forearm. Whole body leucine flux was unchanged; oxidation increased (P less than 0.01) and synthesis decreased (P less than 0.01). These studies confirm that physiological hyperglucagonaemia during insulin resistance is catabolic in the short-term and indicates, for the first time, that glucagon may influence muscle protein metabolism acutely in man. We suggest that therapeutic manoeuvres designed to reduce glucagon levels after surgery may ameliorate protein kinetic abnormalities.
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PMID:Influence of glucagon on protein and leucine metabolism: a study in fasting man with induced insulin resistance. 204 89

This study was conducted to determine whether an amino acid solution enriched with branched-chain amino acids altered protein catabolic rates and plasma ammonia in patients with cirrhosis. Nine stable subjects were given two peripheral intravenous infusions: a standard amino acid solution (solution A) and a branched-chain-enriched solution containing 97% more leucine (solution B). Each solution was given for separate 9-day (group 1, n = 6) or 3-day (group 2, n = 3) periods. Amino acid solutions delivered 0.7 gm protein.kg-1.day-1. Diets provided an additional 0.3 gm protein plus maintenance calories. Protein turnover was assessed by a primed continuous infusion of [1-14C] leucine in six patients (three patients in group 1 and three patients in group 2). Nitrogen balance and urinary 3-methyl histidine excretion were determined in group 1 patients. Compared with solution A, solution B increased leucine flux and leucine oxidation but had no significant effect on protein synthesis or catabolism based on the plasma specific activity of either leucine or alpha-ketoisocaproic acid. The additional leucine infused with solution B was quantitatively oxidized. Nitrogen balance did not differ with the two solutions and there was also no difference in the urinary excretion of 3-methyl histidine, suggesting that muscle protein catabolism was unchanged. Plasma ammonia concentration decreased significantly during the infusion of solution B and was associated with a slight fall in plasma glucagon concentration. The results indicated that a branched-chain-enriched amino acid solution did not alter protein synthesis or catabolism although it did lower the plasma ammonia when compared with a standard amino acid formula in stable cirrhotic patients.
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PMID:Effects of branched-chain amino acids on nitrogen metabolism in patients with cirrhosis. 219 23

We examined how the substances, especially glucose, free fatty acids (FFA) and ketone bodies, and hormones associated with energy metabolism change with the disease progress in Duchenne muscular dystrophy (DMD). Serum creatine kinase (CK) activity was used as an index of the stage of DMD, because this activity is exponentially decreases with the progress of the disease. The glucose concentration in DMD patients with CK activity of less than 1,000 U/l (low CK) was significantly lower than that in controls, although there was no significant difference between that in DMD patients with CK activity of more than 1,00 U/l (high CK) and that in controls. The FFA concentration in both high CK and low CK patients was significantly higher than that in controls. The FFA concentration in low CK patients tended to be higher than that in high CK patients. The ketone body concentration in low CK patients was significantly higher than that in controls and that in high CK patients. The [glucagon]:[insulin] ratio in low CK patients was significantly higher than that in controls and that in high CK patients. It was also observed in a correlational study that the glucose concentration decreased with the age and the decrease in CK activity, i.e., with the progress of DMD. The FFA and ketone body concentrations increased with the decrease in the glucose concentration. The decrease in the glucose concentration may be due to a caloric shortage and/or degenerated muscle, which cannot supply enough gluconeogenic substrates, such as alanine. The kinetics of insulin and glucagon in DMD may help to maintain the glucose metabolism. Increased concentrations of FFA and ketone bodies may be helpful in the advanced stage of DMD, as energy sources and as substrates, sparing muscle protein.
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PMID:Glucose, free fatty acid and ketone body metabolism in Duchenne muscular dystrophy. 224 Apr 59

Increased plasma levels of the catabolic hormones glucagon, epinephrine, and cortisol have been implicated in mediating various metabolic alterations in trauma and sepsis. Their role in altered protein turnover and amino acid transport in skeletal muscle during sepsis, however, is not known. In the current study, rats were infused with a mixture of the catabolic hormones for 16 hours. Control animals were infused with vehicle solution. Protein synthesis and degradation rates were measured in incubated, intact soleus muscles as incorporation of 14C-phenylalanine into protein and release of tyrosine into incubation medium, respectively. Muscle amino acid uptake was determined by measuring the intracellular to extracellular ratio of [3H]-alpha-aminoisobutyric acid after incubation for 2 hours. Infusion of catabolic hormones for 16 hours resulted in elevated plasma glucose and lactate levels, reduced plasma concentrations of most amino acids, and accelerated muscle protein breakdown, similar to previous findings in septic rats. Protein synthesis rates and amino acid uptake in incubated muscles were not significantly different in control and hormone-infused rats. The current study suggests that increased muscle proteolysis in sepsis and severe injury may be mediated in part by catabolic hormones. In contrast, reduced muscle protein synthesis and amino acid uptake are probably signaled by other substances or mechanisms.
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PMID:Effect of catabolic hormone infusion on protein turnover and amino acid uptake in skeletal muscle. 230 36


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