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)

Cyclic AMP output in the bile in response to intravenous secretin was measured in 11 patients, 12 baboons, and 15 dogs. Secretin was given to patients with bile drainage tubes as an intravenous bolus (1 U per kg). In baboons and dogs both secretin infusion (4 U per kg per hr) and bolus injection (1 U per kg) were used. In baboons cyclic AMP was also determined in liver, extrahepatic duct tissue, and in perfusate from isolated segments of extrahepatic bile ducts. Secretin induced a marked choleresis in all three species. In humans, biliary cyclic AMP concentration increased an average (+/- 1 SE) of 68% +/- 12% and in baboons 4-fold, but no increase occurred in dogs. In baboons, cyclic AMP concentration increased in both bile duct tissue and perfusate from isolated bile ducts concomitant with secretin choleresis, but not in liver. In humans the choleretic effects of sodium dehydrocholate, aminophylline, and glucagon were compared to dibutyryl cyclic AMP (DBcyclic AMP). All agents increased bile flow 2- to 3-fold. Cyclic AMP concentration in bile markedly increased after glucagon and DBcyclic AMP but not after sodium dehydrocholate and aminophylline. We conclude that cyclic AMP is implicated in secretin choleresis in both humans and baboons, but not in dogs. The bile duct appears to be the site of cyclic AMP elaboration induced by secretin in baboons and probably is also in man.
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PMID:Cyclic AMP in secretin choleresis. Evidence for a regulatory role in man and baboons but not in dogs. 17 81

Cholera enterotoxin, 45 mug per 250 g body weight, administered intravenously to rats, caused a 6-fold rise in the activity of liver alkaline phosphatase in 12 hr. There was no change in bile volume or in the concentration or total bile content of Na+, K+, HCO3-, or Cl- for 36 hr after the administration of cholera toxin. However, bile phospholipid output fell markedly from a control level of 15.0 +/- 1.0 mumol per 6 hr to a low level of 4.0 +/- 1.2 mumol per 6 hr in the 12- to 18-hr collection, P less than 0.001. There was a similar fall in bile acid secretion, from a control value of 9.8 +/- 0.4 mumol per 6 hr to 4.1 +/- 0.9 mumol in the 12- to 18-hr period, P less than 0.01. The cholera effect was prolonged. Bile acid and phospholipid secretion rates did not return to control values until 30 to 36 hr after the administration of cholera enterotoxin. The cholera toxin-induced reductions in bile acid and phospholipid secretion into bile did not appear to be mediated by adenyl cyclase or cyclic AMP because neither glucagon, a known stimulator of liver adenyl cyclase, nor dibutyryl cyclic AMP had any effect on the secretion into bile of bile acids or phospholipid. The administration of cholera toxin was not associated with any increase in the secretion of free choline into bile. Glucagon and dibutyryl cyclic AMP, two other substances known to increase the activity of rat liver alkaline phosphatase, also had no stimulatory effect on the secretion of free choline into bile. The results do not support the hypothesis that the main function of rat liver alkaline phosphatase is to facilitate the excretion of free choline into bile.
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PMID:Effects of cholera enterotoxin, glucagon, and dibutyryl cyclic AMP on rat liver alkaline phosphatase, bile flow, and bile composition. 17 82

The effects of insulin and glucagon on glycogen metabolism were studied in cultured fetal hepatocytes transplanted from 15-day-old fetuses. The effects of these hormones were examined just after transplantation, when the cells contained only minute amounts of glycogen, and during the 3 to 4 day culture period, when the hepatocytes were exposed to 10 muM cortisol and actively accumulated glycogen. At all stages of the culture, glucagon addition (10 nM) was followed by a rapid depletion of labeled glycogen, previously synthesized during a pulse labeling with [14C]glucose: this effect was mimicked by N6, O2'-dibutyryl adenosine 3':5'-monophosphate (dibutyryl cyclic AMP) (0.3 to 1 nM). Such a glycogenolytic effect of glucagon was observed even 6 hours after transplantation, i.e. at a time when cortisol was not present. In addition, glucagon clearly induced cyclic adenosine 3':5'-monosphosphate (cyclic AMP) accumulation in cells grown for 18 hours in the absence of cortisol. With cells grown for 3 days in the presence of cortisol, glucagon-dependent glycogenolysis was also obtained when cortisol was removed from the medium 20 hours before hormone addition. Thus the presence of cortisol is not necessary either to maintain a response to glucagon or for the onset of the glycogenolytic effect of glucagon. Insulin addition (10 nM) stimulated [14C]glucose incorporation into glycogen at all stages of the culture when grown in the presence of cortisol; no glycogenic response to insulin was observed 6 hours after transplantation where cortisol was not previously introduced. In addition, if the hepatocytes were grown in the presence of insulin alone (i.e. in the absence of cortisol) no significant storage of glycogen occurred. Maximal storage (or labeling) of glycogen was observed when hepatocytes were grown in the presence of both cortisol and insulin. The presence of cortisol was therefore necessary for the expression of the glycogenic effect of insulin. These data show that marked difference exist between the onset of developmental responses towards glucagon and insulin. The glucagon-dependent regulatory pathway should be present very early in fetal development and should not depend on cortisol. On the contrary, the onset of the insulin-dependent regulatory pathway seems to be induced during culture, and it is likely that this is caused by cortisol.
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PMID:Role of cortisol on the glycogenolytic effect of glucagon and on the glycogenic response to insulin in fetal hepatocyte culture. 17 51

Isolated adipocytes, incubated in the presence of extracellular 32Pi to steady state 32P incorporation into cellular phosphopeptides, were exposed to hormones for 5 min. Epinephrine (10(-6) M) stimulated 32P incorporation into at least 12 major phosphopeptides, distributed in the cytoplasm, endoplasmic reticulum, and plasma membrane. Quantitatively pre-eminent among these were peptides of molecular weight 123,000 and 69,000, each located both in the cytoplasm and endoplasmic reticulum. The effect of epinephrine (10(-7) M) on 32P incorporation into these two peptides was augmented by theophylline (10(-3) M) in a synergistic fashion. Norepinephrine, dibutyryl N6,O2'-dibutyryl adenosine 3':5'-monophosphate, adrenocorticotropic hormone (ACTH) (synthetic 1 to 24 fragment), and glucagon mimicked the effect of epinephrine. Insulin modified adipocyte peptide phosphorylation in two ways. When present as the sole hormone, insulin (100 microunits/ml) consistently and selectively stimulated the 32P incorporation into a peptide of molecular weight 123,000 (endoplasmic reticulum, cytoplasm) without significant alteration in the 32P content of any other major peptide. A second effect of insulin was evident when epinephrine (10(-6) M) was present simultaneously. Insulin significantly inhibited the epinephrine-stimulated phosphorylation of the molecular weight 69,000 (endoplasmic reticulum, cytoplasm) and 26,000 (plasma membrane) peptides. Nevertheless, persistence of insulin-stimulated phosphorylation of the 123,000 peptide in the presence of epinephrine was shown by a 32P content of this peptide that was greater in the presence of both hormones than with either individually. These findings indicate that in intact adipocytes: (a) epinephrine acutely alters the phosphorylation of a large number of adipocyte peptides, partly at least, via activation of adenosine 3':5'-monophosphate (cyclic AMP)-dependent protein kinase; (b) insulin opposes several epinephrine-stimulated phosphorylations in a manner consitent with its ability to lower epinephrine-stimulated intracellular cyclic AMP accumulation in adipocytes; and (c) insulin, in addition, exerts a unique stimulatory effect on adipocyte peptide phosphorylation that is independent of its effects on cyclic AMP metabolism and may be medicated by the generation of an as yet undefined intracellular "messenger" unique to insulin.
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PMID:Effects of epinephrine and insulin on phosphopeptide metabolism in adipocytes. 17 55

Hormone-induced desensitization of hormonal regulation of cyclic AMP (cAMP) content has been described in a number of tissues. In the present study, we examined responses of rat liver to glucagon after periods of sustained exposure to the hormone in vivo and in vitro. In intact anesthetized rats infused with glucagon (50 ng/min) for 1 h or more and in liver slices incubated with the hormone (10 muM) for this period, hepatic cAMP responsiveness to glucagon was significantly blunted compared with that of tissue exposed to the hormone for shorter periods. The reduction in hepatic cAMP responsiveness to glucagon appeared to be fully expressed by 2 h. With the doses of hormone employed, the sequential alterations in hepatic responsiveness seemed to be limited to the cAMP system, since other parameters of glucagon action did not wane with time. Diminished hepatic cAMP responsiveness during sustained hormonal exposure could not be attributed to decreased glucagon availability, accelerated extracellular release of cAMP, hepatic ATP depletion, or enhanced phosphodiesterase activity. Studies in vitro suggested that modulation of the cAMP response occurred at the level of adenylate cyclase (AC). During sustained exposure of hepatic slices to glucagon, reductions in glucagon-responsive AC correlated temporally with those in cAMP and both changes were reversible. Alterations in glucagon-responsive AC were demonstrated over a wide range of ATP (10 muM-0.1 mM) and glucagon (10 nM-5 MM) concentrations in the cyclase reaction mixture, and appeared to be a noncompetitive phenomenon relative to glucagon. Maximal NaF-responsive AC did not fall concomitantly with time. Thus, the reduction in glucagon-responsive AC was probably not related to a reduction in the catalytic unit of the enzyme, but could have been due to an alteration in glucagon binding to its receptor sites, or in the coupling mechanism involved in transmission of the hormonal signal to the catalytic unit.
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PMID:Reduced sensitivity of the hepatic adenylate cyclase-cyclic AMP system to glucagon during sustained hormonal stimulation. 17 80

Isolated rat hearts were perfused with a subinotropic concentration of glucagon during an hypoxic perfusion to determine whether glucagon would enhance recovery upon reoxygenation. Rat hearts were divided into two groups: 1) those perfused with glucose-free Tyrode's solution and 2) those perfused with Tyrode's solution containing glucose. During 3 min of hypoxic exposure, untreated hearts and hearts perfused with glucagon both demonstrated a dramatic decrease in contractile force regardless of whether glucose was included in the medium. However, when glucose was present in the perfusion medium cardiac performance was better during both hypoxia and the period of reoxygenation. Furthermore, during reoxygenation, the recovery of contractile force was significantly greater in glucagon-perfused hearts than in controls. Cardiac levels of cyclic AMP and cyclic GMP were monitored at various periods of hypoxic exposure to test the existence of a correlation between the concentrations of these cyclic nucleotides and cardiac performance. During reoxygenation of untreated hearts, the hearts perfused with glucose-free medium attained 45-50 percent of the contractile force seen in glucagon-treated hearts. This enhanced recovery in the glucagon-treated hearts was associated with decreases in cyclic GMP levels at the end of the hypoxic period. At this time, the cyclic GMP levels in the glucagon-treated hearts were only 25-55 percent of the levels seen in untreated hearts that were also exposed to hypoxia. The effect of glucagon on cyclic AMP content in untreated hearts and in hearts receiving glucagon was not significantly different at 3 min of hypoxia. These studies suggest that subinotropic concentrations of glucagon exert a protective effect on the hypoxic rat heart that is not related to the direct inotropic properties of this hormone but which may involve a modulation in cardiac cyclic GMP availability.
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PMID:Effects of glucagon on cardiac cyclic nucleotides in the hypoxic heart. 17 99

The effect of the nutritional state (fasted or fed) on the binding of glucagon and on the glucagon-stimulated cyclic AMP accumulation in the presence of theophylline was studied in isolated rat liver cells. The binding of glucagon was higher in cells from fed than in those from fasted rats at each concentration of glucagon tested between 0.1 and 36 nM. The specific binding of the hormone was about 2-fold higher in cells from fed than from fasted rats. At concentrations of glucagon between 0.1 and 2.2 nM, the accumulation of cyclic AMP in the presence of 1 mM theophylline was higher in the cells from fed rats. Furthermore, 4 times as much glucagon was required to elicit half-maximal cyclic AMP accumulation in the cells of fasted (1.47 nM) than in the cells of fed (0.35 nM) rats. These data suggest that, in isolated rat liver cells, both glucagon binding to receptor sites and glucagon-stimulated cyclic AMP levels in the presence of theophylline can be affected by the nutritional status of the animal.
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PMID:Effect of feeding and fasting on the early steps of glucagon action in isolated rat liver cells. 17 72

Transitional epithelium lining rabbit urinary bladders was isolated and studied in vitro. The homogeneity of the isolated epithelium was demonstrated by light and electron microscopical monitoring as well as cell culture studies. Transitional epithelium responded to epinephrine and prostaglandin E1 (PGE1) in the presence of 2mM 1-methyl, 3-isobutylxanthine (MIX) with increases in intracellular levels of cyclic adenosine 3':5'-monophosphate (cyclic AMP). Corticotropin, aldosterone, insulin, parathyroid hormone and vasopressin were slightly but significantly stimulatory under similar conditions. Glucagon and oxytocin were not stimulatory at the concentrations tested. The effects of epinephrine and PGE1 were potentiated by 2mM MIX 20-fold or greater. The cells were slightly more sensitive to PGE1 then to epinephrine. The prostaglandin produced a noticeable response at about 10nM, while effects of epinephrine were discernible at 0.1muM. Maximal responses to both effectors were seen at about 10muM. The action of 10muM epinephrine, but not 10muM PGE1, was completely abolished by 0.1mM propranolol. Responses to combinations of epinephrine and PGE1 were additive. Cyclic AMP accumulated in the incubation medium of transitional epithelial cells exposed to epinephrine, PGE1, MIX, or combinations of the agonists. The appearance of cyclic AMP in the medium was slow compared to the rate of intracellular accumulation, but reached significant levels following prolonged stimulation.
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PMID:The effects of hormones on cyclic adenosine 3':5'-monophosphate accumulation in transitional epithelium of the urinary bladder. 17 60

Catecholamines increased guanosine 3':5'-monophosphate (cyclic GMP) accumulation by isolated rat liver cells. The increases in cyclic GMP due to 1.5 muM epinephrine, isoproterenol, or phenylephrine were blocked by phenoxybenzamine but not by propranolol. The possibility that cyclic GMP is involved in the glycogenolytic action of catecholamines seems unlikely since cyclic GMP accumulation is also elevated by carbachol, insulin, A23187, and to a lesser extent by glucagon. Furthermore, carbachol had little effect on glycogenolysis while insulin actually inhibited hepatic glycogenolysis. The rise in cyclic GMP due to carbachol was abolished by atropine and that due to all agents was markedly reduced by the omission of extracellular calcium. However, the glycogenolytic action of glucagon and catecholamines was only slightly inhibited by the omission of calcium. The only agent which was unable to stimulate glycogenolysis in calcium-free buffer was the divalent cation ionophore A23187. There was a drop in ATP content of liver cells during incubation in calcium-free buffer which was accompanied by an inhibition of glucagon-activated adenosine 3':5'-monophosphate (cyclic AMP) accumulation. The presence of calcium inhibited the rise in adenylate cyclase activity of lysed rat liver cells due to glucagon or isoproterenol but not that due to fluoride. These results suggest that the stimulation by catecholamines and glucagon of glycogenolysis is not mediated through cyclic GMP nor does it depend on the presence of extracellular calcium. Cyclic GMP accumulation was increased in liver cells by agents which either inhibit, have little affect, or accelerate glycogenolysis. The significance of elevations of cyclic GMP in rat liver cells remains to be established.
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PMID:Studies on the role of cyclic guanosine 3':5'-monophosphate and extracellular Ca2+ in the regulation of glycogenolysis in rat liver cells. 17 60

The effect of insulin-induced hypoglycemia on plasma cyclic AMP levels was studied in normal volunteers, adrenalectomized, and sympathectomized subjects. Significant increases in plasma glucagon were observed in all groups. Normal subjects all had two- to threefold rises in plasma cAMP while no response was seen in any adrenalectomized or sympathectomized subject. These findings suggest that the mechanism for enhanced plasma cAMP release during insulin-induced hypoglycemia is catecholamine dependent. Glucagon does not contribute significantly to this response.
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PMID:Mechanism of plasma cyclic AMP response to hypoglycemia in man. 17 82


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