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)

Spontaneous or propranolol-induced hypoglycemia can occur in uremic humans. We studied glucose kinetics (using [3-3H]glucose) in five uremic humans 24 h after hemodialysis and in seven normal controls. The effect of glucagon infusion at rates of 3, 6, 12, and 18 ng X kg-1 X min-1 at 60-min intervals was compared with either saline or beta-adrenergic blockade (propranolol infusion). In uremics, plasma glucose increased by 20-25% and by 40-50% at the 3 and 6 ng X kg-1 X min-1 glucagon doses, respectively, with no further increases at higher infusion rates. Glucose production increased transiently and in tandem with glucose uptake at each glucagon increment (P less than 0.0001). During beta-adrenergic blockade, the effect of glucagon in stimulating glucose production was blunted by 14-24% at the 6-18 ng X kg-1 X min-1 doses (P less than 0.05). During saline infusion, plasma insulin concentrations increased progressively to peak levels fourfold above basal at the 18 ng X kg-1 X min-1 dose. This increase in plasma insulin was virtually abolished by concomitant beta-adrenergic blockade (P = 0.0002). In contrast to uremic subjects, normal controls exhibited lesser degrees of hyperglycemia and hyperinsulinemia at all glucagon infusion rates. Propranolol infusion had no effect on the increments in glucose production and uptake nor on the plasma insulin response. These results suggest that in uremic humans propranolol independently reduces the hepatic response to glucagon and the insulin secretory response to hyperglycemia and/or hyperglucagonemia. These observations provide a possible mechanism for the adrenergic regulation of glucose homeostasis in uremia.
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PMID:Beta-adrenergic contribution to glucagon-induced glucose production and insulin secretion in uremia. 301 52

To characterize beta-receptors which affect pancreatic A-cell activity, the effects of propranolol (beta non-selective blockade) and metoprolol (beta 1 selective blockade) were evaluated on epinephrine modulated insulin (IRI) and glucagon (IRG) release both in basal state and during metabolic stimulus (arginine 20 mM). The isolated perfused rat pancreas model with the exclusion of stomach and duodenum was used. Epinephrine infusion (at 10(-7) M) caused a prompt and sustained increase in basal IRG secretion and significantly potentiated glucagon release in response to metabolic stimulus. Insulin secretion was markedly suppressed by epinephrine both in basal conditions and during metabolic stimulus. Propranolol (at 10(-7) M) and metoprolol (at 10(-7) M) infusion clearly and similarly counteracted epinephrine stimulatory effects on IRG secretion but failed to elicit any significant effect on the epinephrine inhibited IRI release either in basal state or during the metabolic stimulus. These results suggest that, at least in the rat, the adrenergic stimulation of IRG release is mediated through a beta 1 receptor.
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PMID:Effects of beta non-selective and beta 1 selective adrenergic blocking agents on glucagon secretion from isolated perfused rat pancreas. 302 Jan 14

The aim of the present work is to investigate a possible interaction on glucagon secretion between adenosine, a compound released by tissues in energy-deficient states, and epinephrine, the hormone of stress largely implicated in such conditions. The study was performed using the isolated perfused rat pancreas in presence of a physiological glucose concentration (5 mM). Epinephrine administered at a low concentration (0.01 microM) was ineffective on glucagon secretion, and adenosine at 1.65 microM was previously shown to be moderately stimulating. This nucleoside alone induced a transient increase of glucagon secretion rate that peaked at 300% of basal value at 2 min; in presence of epinephrine (ineffective per se) the rise induced by the nucleoside alone was doubled. This potentiating effect was not observed with the neurotransmitter norepinephrine at the dose tested. Propranolol (1 microM) did not alter the potentiating effect of epinephrine but this effect was completely suppressed by the alpha-blocker, phenoxybenzamine (6 microM). In conclusion epinephrine potentiates an adenosine-stimulating effect on glucagon secretion; this effect seems more specific for the adrenal medulla hormone epinephrine, since norepinephrine at the same dose is ineffective; it is mediated via alpha-adrenergic receptors. It is attractive to speculate that epinephrine and adenosine act in potentiating synergism on glucagon secretion; this might be of physiological importance during stressful energy-deficient situations.
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PMID:Epinephrine potentiates adenosine-stimulating effect on glucagon secretion. 303 Jan 34

1. The development of post-exercise ketosis is not abolished by the ingestion of glucose immediately after exercise, despite inducing high insulin/glucagon ratios in the peripheral (and therefore by implication in the portal) blood. 2. To investigate the possibility of autonomic control of the liver influencing its sensitivity to the major counter-regulatory hormones, we administered 50 g glucose, either on its own, or together with 0.5 mg prazosine, 40 mg propranolol, or 15 mg propantheline, to forty-seven 48 h carbohydrate-starved athletes who had just run 25 km. 3. The blood 3-hydroxybutyrate concentration rose from 0.30 +/- 0.05 (mean +/- S.E. of mean) to 0.52 +/- 0.08 mmol/l with exercise, and then to 1.32 +/- 0.40 mmol/l at 6 h after exercise in subjects who had ingested only glucose after exercise. 4. The effects of prazosine and propantheline on the blood ketone body concentration at 2 h after exercise was not statistically significant. Propranolol, on the other hand, significantly lowered the blood 3-hydroxybutyrate concentration (compared with controls) to 0.09 +/- 0.03 mmol/l at 3 h (P less than 0.01), and 0.35 +/- 0.08 mmol/l at 6 h (P less than 0.01) after exercise. 5. The plasma insulin, glucagon, glucose and free fatty acid concentrations were unaffected by propranolol, indicating that the antiketogenesis was the result of a direct effect on ketone body metabolism. 6. Since beta-adrenergic blockade has not previously been shown to have antiketogenic activity, except in somatostatin-induced hyperketonaemia, it is concluded that its effectiveness in post-exercise ketosis can probably be ascribed to a functional hepatic insulin and glucagon deficiency.
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PMID:Beta-adrenergic blockade restores glucose's antiketogenic activity after exercise in carbohydrate-depleted athletes. 331 99

Propranolol, a non-selective beta-blocker, is known to decrease glucagon release in normal subjects. The present study was aimed at investigating the effects of propranolol on the hyperglucagonism commonly observed in patients with cirrhosis. Eight cirrhotic patients and 6 matched healthy controls were studied. The plasma concentrations of glucagon, insulin, c-peptide and glucose were measured in basal conditions and after stimulating glucagon secretion by an i.v. infusion of arginine (0.4 g/kg/30 min). The study was repeated 24 h later after inducing beta-blockade by the i.v. infusion of propranolol (10 mg). In baseline conditions, patients with cirrhosis, despite normal levels of insulin and glucose, had a marked hyperglucagonism (654 +/- 303 pg/ml vs. 269 +/- 90 in controls, P less than 0.01). Prior to propranolol, arginine infusion caused greater glucagon release in cirrhotics (71 +/- 31 ng.h.ml-1) than in controls (33 +/- 17 ng.h.ml-1, P less than 0.02), but despite a similar insulin secretion (assessed from c-peptide), blood glucose did not increase. After propranolol, glucagon secretion decreased as expected in controls (29 +/- 12 ng.h.ml-1, P less than 0.05) but experienced a paradoxical increase in cirrhotics (113 +/- 64 ng.h.ml-1, P less than 0.05). Again, despite the marked increase in glucagon release, there was no increase in glucose production, providing further evidence of the glucagon resistance that accompanies hyperglucagonism in cirrhosis. Our results suggest that hyperglucagonism with glucagon resistance might be the initial disturbance in carbohydrate metabolism in patients with cirrhosis. Contrary to what could be expected, propranolol does not correct but further accentuates this disturbance.
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PMID:Hyperglucagonism and glucagon resistance in cirrhosis. Paradoxical effect of propranolol on plasma glucagon levels. 339 82

To determine the relationship between hepatic glucose clearance and elevated epinephrine levels in sepsis, dogs with gangrenous cholecystitis were anesthetized and received either propranolol hydrochloride (mean dose, 0.29 mg/kg) or saline solution before intraduodenal glucose injection (2.5 g/kg). The amounts of glucose, insulin, and glucagon in the portal vein, the hepatic artery, and the hepatic vein were determined from the concentrations and the blood flows in these vessels over a two-hour period. Normal dogs served as controls. The amounts of glucose, insulin, and glucagon reaching the livers of both septic groups were the same. However, propranolol treatment increased the percent of glucose extracted by the liver without affecting the extractions of insulin or glucagon. Propranolol reverses the limitation of hepatic glucose extraction in sepsis by a direct effect. Whether the extracted glucose is utilizable as an energy substrate needs to be established.
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PMID:Beta-adrenergic blockade increases the hepatic extraction of glucose in sepsis. 351 91

GRP is a pancreatic neuropeptide and may be of importance for the neural control of insulin and glucagon secretion. In this study, we investigated the effects of GRP on basal and stimulated insulin and glucagon secretion in the mouse. Intravenous injections of GRP at dose levels exceeding 2.12 nmol/kg were found to rapidly increase basal plasma levels of both insulin and glucagon. Furthermore, at a low dose level without effect on basal plasma insulin levels, GRP was found to potentiate the insulin response to both glucose (by 40%; p less than 0.05) and to the cholinergic agonist carbachol (by 57%; p less than 0.01). Also, GRP was at this dose level found to potentiate the glucagon response to carbachol (p less than 0.01). Glucose abolished GRP-induced glucagon secretion. Moreover, methylatropine given at a dose level that totally abolishes carbachol-induced insulin secretion inhibited GRP-induced insulin secretion by 39% (p less than 0.05) and GRP-induced glucagon secretion by 25% (p less than 0.01). L-Propranolol at a dose level that totally abolishes beta-adrenergically-induced insulin secretion inhibited GRP-induced insulin secretion by 52% (p less than 0.01) and GRP-induced glucagon secretion by 15% (p less than 0.05). In summary, we have shown that GRP stimulates basal and potentiates stimulated insulin and glucagon secretion in mice, and that the stimulatory effects of GRP on insulin and glucagon secretion are partially inhibited by muscarinic blockade by methylatropine or by beta-adrenoceptor blockade by propranolol. We conclude that GRP activates potently both insulin and glucagon secretion in the mouse by mechanisms that are partially related to the muscarinic and the beta-adrenergic receptors.
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PMID:Gastrin releasing peptide (GRP): effects on basal and stimulated insulin and glucagon secretion in the mouse. 355 68

Propranolol (1) decreases hepatic blood flow and glucagon (2) exerts an opposite effect on hepatic circulation. The effects of these drugs on the pharmacokinetics of phenazone (3; antipyrine)-a compound with low coefficient of hepatic extraction, and sodium salicylate (4) that is highly extracted by liver, were studied on rabbits. It was shown that changes in the pharmacokinetics of 3 and 4 in the presence of 1 or 2, seemed to be interactions between these drugs in the haemodynamic phase.
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PMID:The influence of propranolol and glucagon on the pharmacokinetics of antipyrine and sodium salicylate. 367 60

A single acute IV injection (1 microgram/kg) of the synthetic replicate of Somatocrinin (GRF) in 40 children with growth hormone (GH) deficiency induces a marked plasma GH increase, although heterogeneous. Clinical tolerance is excellent. Compared to Propranolol + Glucagon (P + G), GRF induces a better GH response. It also discriminates better idiopathic GH deficiency (n = 13), where mean GH peak = 6.5 ng/ml (3.3 after P + G) from GH deficiency secondary to a brain tumor (n = 24) where mean GH peak = 15.5 ng/ml (5.0 after P + G) GRF induces a slight Prolactin (Prl) increase, more obvious when basal Prl is elevated. However there is no correlation between GH and Prl responses to GRF even with basal hyperprolactinemia. GH response to GRF seems to slowly decrease after radiation therapy. GRF is a new potent, well tolerated secretagogue of GH and improves the diagnostic quality of the etiology of GH deficiency.
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PMID:[Somatocrinin and children in 1984. Application to the etiological diagnosis of somatotropin deficiencies]. 392 94

The effects of endogenous epinephrine (E), released by glucagon injection, and exogenously infused E on plasma norepinephrine (NE) and cardiovascular responses before and after beta-blockade were studied in patients with essential hypertension and in age-matched normotensive controls. The resting plasma NE and E levels were significantly higher in the borderline hypertensive subjects (NE: 251 +/- 21 pg/ml [SEM], p less than 0.005; E: 57 +/- 5, p less than 0.05, n = 18) than in controls (NE: 129 +/- 12; E: 39 +/- 5, n = 18). An intravenous injection of glucagon (1.0 mg) induced a transient rise of both plasma catecholamine levels and blood pressure in every subject studied. Plasma E levels rose transiently and returned to the basal levels by 20 minutes after the injection, whereas plasma NE levels showed a more prolonged rise over 20 minutes. beta-Blockade with propranolol did not affect the plasma E response to glucagon, but inhibited the prolonged rise of plasma NE levels. An intravenous infusion of exogenous E (1.25-1.50 micrograms/min) for 30 minutes caused an apparent rise of both plasma NE levels and blood pressure, which lasted more than 60 minutes after stopping the E infusion. Propranolol did not affect the time course of plasma E but again inhibited the prolonged rise of both plasma NE levels and blood pressure. No significant differences could be observed in the cardiovascular or plasma NE responses to glucagon or to E infusion between normal and hypertensive subjects. These findings lend support to the view that plasma E can act physiologically as a sustained stimulator of presynaptic beta-adrenergic receptors, which leads to an enhanced NE release from peripheral sympathetic nerve terminals and a rise of blood pressure in humans.
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PMID:The effects of epinephrine on norepinephrine release in essential hypertension. 398 65


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