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)

Insulin and glucagon degradation by rat kidney homogenates and subcellular fractions was examined under a variety of conditions including high and low substrate concentrations, at pH 4 and pH 7, with and without glutathione. At high insulin concentration (4.1 - 10(-5) M) insulin degradation by the homogenate was greatest at pH 4 but at low insulin concentration (1 - 10(-10) M) insulin degradation was greatest at pH 7. At either high or low glucagon concentration glucagon degradation by the homogenate was greatest at pH 7. Glutathione at pH 7 stimulated insulin degradation at high insulin concentrations and inhibited insulin degradation at low concentrations; Glucagon degradation at pH 7 was inhibited at both high and low concentrations of glucagon by glutathionemseparation of kidney into cortex and medulla prior to homogenation produced a pattern of insulin and glucagon degradation identical to the whole homogenate but glucagon degradation by the medulla was greater than by the cortex. Examination of degradation by subcellular fractions revealed that at high concentration at neutral pH most insulin was degraded by the 100 000 X g pellet but at low insulin concentrations over 90% of the activity was in the 100 000 X g supernatant; At pH 7, at both high and low concentrations, most glucagon-degrading activity was in the 100 000 X g pellet, although the cytosol also had activity; At pH 4 most degradation occurred in the lysosomal fractions. Separation into cortex and medulla again showed similar distribution of activity as the whole gland with the medulla having more glucagon-degrading activity than the cortex. With low insulin concentrations the cortex 100 000 X g supernatant had higher relative specific activities than the medulla supernatant. Examination of recoveries of enzyme activity revealed that the subcellular fractions consistently had markedly less insulin-degrading activity than the original homogenate. This loss of activity was only discernible when insulin degradation was performed at pH 7 at low substrate concentrations. Comparable losses of glucagon-degrading activity were not seen.
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PMID:Insulin and glucagon degradation by the kidney. I. Subcellular distribution under different assay condition. 0 5

Severe resistance to subcutaneous insulin but sensitivity to intravenous insulin persisted for 15 months in a 17-year-old diabetic girl. Heat-labile insulin-degrading activity was present in the patient's ketotic sera and in the 100,000 g fraction (soluble fraction) of adipose tissue. Serum-degrading activity was not inhibited by N-ethylmaleimide. The soluble fraction also degraded glucagon and B chain but not growth hormone or myoglobin. It was inhibited by incubation with the patient's nonketotic sera, normal sera, or Trasylol. Glutathione-insulin-transhydrogenase (GIT) activity was 66% of normal. The biopsy of adipose tissue at remission showed a normal level of insulin- and glucagon-degrading activity. The activity was eluted from Sephadex G200 as a single peak and had properties consistent with those of the insulin-specific protease (ISP). The increased degrading activity present during insulin resistance had properties not shared with ISP, suggesting the presence of an uncharacterized protease.
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PMID:Insulin resistance caused by massive degradation of subcutaneous insulin. 10 40

Adenylate cyclase in rat adipocyte membranes was inactivated as a result of treatment with sulfhydryl oxidants or with p-chloromercuribenzoate as well as by S-alkylating agents. The inhibition of the basal and isoproterenol- or glucagon-stimulated enzyme activity by the oxidants or the mercurial could be reversed by adding thiols to the isolated membranes. The activity of the enzyme paralleled the cellular glutathione (GSH) content. Lowering of intracellular glutathione by incubating the cells with specific reactants resulted in the inhibition of both basal and hormone-stimulated adenylate cyclase activity in the isolated membranes. Activity could be partly restored by supplying glucose to the incubation medium of intact cells. The fluoride-stimulated adenylate cyclase was also inhibited by the oxidants or the sulfhydryl inhibitors. The results suggest that adenylate cyclase may be partly regulated by oxidation-reduction. Thus, a direct relationship between both basal and hormone-stimulated adenylate cyclase activity and the cellular redox potential, determined by the cellular level of reduced glutathione, may be ascribed to the protection of the catalytic -SH groups of the enzyme from oxidative or peroxidative reactions and maintenance of the redox optimum for the reaction.
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PMID:Role of cellular redox state and glutathione in adenylate cyclase activity in rat adipocytes. 44 43

A comparison of the maximal rates of biliary excretion (Tm), of dye in dogs infused with either BSP or its glutathione conjugate (BSP-GSH) was carried out. Tm was much higher when BSP-GSH rather than BSP was infused. This was accounted for by a significantly higher concentration of dye in bile of dogs receiving BSP-GSH. Evidence is presented that BSP and its conjugated metabolites compete for a common transport carrier and that BSP disproportionately depresses the biliary excretion of conjugated dye compounds. This latter observation accounts for the depressed dye Tm found during infusion of BSP. Choleresis invariably accompanied dye excretion. When BSP-GSH was infused, enhanced bile flow could be accounted for by the predicted osmotic activity of dye transported into bile. By contrast, the choleresis measured during infusion of BSP was significantly greater than that predicted. An additional mechanism for choleresis is operative, therefore, when unconjugated BSP is infused. Administration of taurocholate enhanced dye Tm when BSP-GSH was infused. Since increments of canalicular bile flow induced by theophylline and glucagon did not enhance dye excretion into bile, this effect by taurocholate appears to be related to taurocholate excretion per se rather than to the enhanced canalicular bile flow which accompanies its excretion.
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PMID:Biliary excretion of dye in dogs infused with BSP or its glutathione conjugate. 96 90

We reported that glucagon and phenylephrine decrease hepatocyte GSH by inhibiting gamma-glutamylcysteine synthetase (GCS), the rate-limiting enzyme in GSH synthesis (Lu, S.C., J. Kuhlenkamp, C. Garcia-Ruiz, and N. Kaplowitz. 1991. J. Clin. Invest. 88:260-269). In contrast, we have found that insulin (In, 1 microgram/ml) and hydrocortisone (HC, 50 nM) increased GSH of cultured hepatocytes up to 50-70% (earliest significant change at 6 h) with either methionine or cystine alone as the sole sulfur amino acid in the medium. The effect of In occurred independent of glucose concentration in the medium. Changes in steady-state cellular cysteine levels, cell volume, GSH efflux, or expression of gamma-glutamyl transpeptidase were excluded as possible mechanisms. Both hormones are known to induce cystine/glutamate transport, but this was excluded as the predominant mechanism since the induction in cystine uptake required a lag period of greater than 6 h, and the increase in cell GSH still occurred when cystine uptake was blocked. Assay of GSH synthesis in extracts of detergent-treated cells revealed that In and HC increased the activity of GCS by 45-65% (earliest significant change at 4 h) but not GSH synthetase. In and HC treatment increased the Vmax of GCS by 31-43% with no change in Km. Both the hormone-mediated increase in cell GSH and GCS activity were blocked with either cycloheximide or actinomycin D. Finally, when studied in vivo, streptozotocin-treated diabetic and adrenalectomized rats exhibited lower hepatic GSH levels and GCS activities than respective controls. Both of these abnormalities were prevented with hormone replacement. Thus, both in vitro and in vivo, In and glucocorticoids are required for normal expression of GCS.
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PMID:Insulin and glucocorticoid dependence of hepatic gamma-glutamylcysteine synthetase and glutathione synthesis in the rat. Studies in cultured hepatocytes and in vivo. 135 65

Our present work characterized the role of hormone-mediated signal transduction pathways in regulating hepatic reduced glutathione (GSH) synthesis. Cholera toxin, dibutyryl cAMP (DBcAMP), and glucagon inhibited GSH synthesis in cultured hepatocytes by 25-43%. Cellular cAMP levels exhibited a lower threshold for stimulation of the GSH efflux than inhibition of its synthesis. The effect of DBcAMP was independent of the type of sulfur amino acid precursor and cellular ATP levels and unassociated with increased GSH mixed disulfide formation or altered GSH/oxidized glutathione ratio. In liver cytosols, addition of DBcAMP and cAMP-dependent protein kinase (A-kinase) inhibited GSH synthesis from substrates (cysteine, ATP, glutamate, and glycine) by approximately 20% which was prevented by the A-kinase inhibitor. However, if only substrates of the second step in GSH synthesis were used (gamma-glutamylcysteine, glycine, and ATP), DBcAMP and A-kinase exerted no inhibitory effect. Phenylephrine, vasopressin, and phorbol ester also inhibited GSH synthesis in cultured cells by approximately 20%, and depleted cell GSH independent of the type of sulfur amino acid precursor. Cellular cysteine level was unchanged despite the significant fall in GSH after glucagon or phenylephrine treatment. Pretreatment with either staurosporine, C-kinase inhibitor, or calmidazolium, a calmodulin inhibitor, partially prevented but, together, completely prevented the inhibitory effect of phenylephrine. The same combination had no effect on the inhibitory effect of glucagon. The effects of hormones were confirmed in both the intact perfused liver and after in vivo administration. Thus, two classes of hormones acting through distinct signal transduction pathways may down-regulate hepatic GSH synthesis by phosphorylation of gamma-glutamylcysteine synthetase.
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PMID:Hormone-mediated down-regulation of hepatic glutathione synthesis in the rat. 164 17

High yields of human hepatocytes (up to 23 X 10(6) viable cells/g) were obtained from small surgical liver biopsies (1 to 3 g) by a two-step collagenase microperfusion method. Cell viability was about 95%, attachment efficiency of hepatocytes seeded on fibronectin-coated plates was 80% within 1 h after plating, and cells survived for about 2 wk in serum-free Ham's F12 containing 0.2% bovine serum albumin, 10(-8) M insulin, and 10(-8) M dexamethasone. To evaluate the metabolism of human hepatocytes in serum-free conditions, we measured their most characteristic biochemical functions and compared them to those reported for human liver. After 24 h in culture, glycogen content was 1250 +/- 177 nmol glucose/mg cell protein and remained stable for several days. Gluconeogenesis from lactate in hormone-free media was (3.50 +/- 0.17 nmol glucose.mg-1.min-1) similar to that reported for human liver. Insulin at 10(-8) M activated glycolysis (X1.40) and glycogenesis (X1.34), and glucagon at 10(-9) M stimulated gluconeogenesis (X1.35) and glycogenolysis (X2.18). Human hepatocytes synthesized albumin, transferrin, fibrinogen, alpha 1-antitrypsin, alpha 1-antichymotrypsin, alpha 1-acid glycoprotein, haptoglobin, alpha 2-macroglobulin, and plasma fibronectin and excreted them to the culture medium. Maximum protein synthesis was stimulated by 10(-9) M dexamethasone. Basal urea synthesis oscillated between 2.5 and 3.5 nmol.mg-1 cell protein.min-1, about 5 times the value estimated for human liver. Cytochrome P-450 decreased in culture but it was still 20% of freshly isolated hepatocytes by Day 5 in culture. In addition, ethoxycumarin-O-deethylase and aryl hydrocarbon hydroxylase could be induced in vitro by treatment with methyl cholanthrene. Glutathione levels were similar to those reported for human liver (35 nmol.mg-1). The results of our work show that adult human hepatocytes obtained from small surgical biopsies and cultured in chemically defined conditions express their most important metabolic functions to an extent that is similar to that reported for adult human liver.
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PMID:Culture of human hepatocytes from small surgical liver biopsies. Biochemical characterization and comparison with in vivo. 215 94

The efflux of GSH has been shown previously to be a saturable process in both isolated rat hepatocytes and perfused liver, suggesting a carrier-mediated transport mechanism. The possibility in hormonal regulation of this process has been raised by recent reports. Our present work examined the role of hormones known to affect intracellular signal transduction mechanisms on GSH efflux in cultured rat hepatocytes and perfused rat livers. We found that cAMP-dependent factors, such as cholera toxin (CT), dibutyryl cAMP, forskolin, and glucagon all stimulated GSH efflux in cultured rat hepatocytes. The efflux kinetics were compared in cultured cells incubated with or without CT; the stimulation of GSH efflux was related to a near doubling of the Vmax while exhibiting no significant alteration of the Km. The increase in intracellular cAMP level associated with the threshold for this stimulatory effect was 25% above control. The stimulatory effect of CT could not be blocked by cyclohexamide pretreatment or reversed by colchicine treatment. The stimulatory effect of glucagon was abolished in the presence of ouabain but not in the presence of barium. On the other hand, hormones which act through Ca2+ and protein kinase C, such as phenylephrine and vasopressin, had no effect on GSH efflux in the cultured cells. In the perfused liver model, glucagon (10 nM) and dibutyryl cAMP (8 microM) stimulated sinusoidal GSH efflux to 130 and 144% of control values, respectively, and increased bile flow while not affecting biliary GSH efflux. Finally, the physiological significance of glucagon-mediated stimulation of sinusoidal GSH efflux was assessed by both plasma GSH and glucose levels in response to in vivo glucagon infusion. The threshold dose of glucagon for significant increase in plasma GSH (5.21 pmol/min) was lower than for glucose (15.61 pmol/min). At the highest glucagon infusion rate (261 pmol/min), plasma GSH level doubled while glucose level increased 80%. In conclusion, increased cAMP stimulates GSH efflux in cultured rat hepatocytes and perfused livers. The stimulatory effect of cAMP is exerted at the sinusoidal pole and appears to be mediated by hyperpolarization of hepatocytes by stimulation of Na(+)-K(+)-ATPase. In vivo studies confirmed the importance of cAMP-mediated stimulation of sinusoidal GSH efflux as it resulted in significant elevation of the plasma GSH level.
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PMID:Hormonal regulation of glutathione efflux. 216 79

Glutathione (GSH) is released into hepatic sinusoids by a carrier-mediated process. The importance of transmembrane potential difference (PD) as a driving force for hepatic efflux of GSH from isolated perfused rat liver was investigated. The membrane PD was measured using intracellular microelectrodes as PD was altered over the physiological range by ion substitution in the perfusate. The effect of a change in membrane PD on the rate of efflux of GSH into the perfusate was determined. Because GSH carries a net negative charge at physiological values of pH, we predicted that hyperpolarization of cells would increase efflux, whereas depolarization would decrease efflux. Three different manipulations were used to depolarize the hepatocyte membrane to a similar degree, and variable effects on GSH efflux were observed. Substitution of Cl with gluconate in the perfusate depolarized the hepatocyte but had no effect on GSH efflux, whereas substitution of Na with choline in the perfusate increased GSH efflux to 110% of basal values. Perfusion with K+ inhibited GSH efflux by 21%. The latter two manipulations were associated with evidence of hepatic injury. Hyperpolarization of the hepatocyte also had variable effects on GSH efflux. Substitution of Cl with nitrate in the perfusate transiently increased the membrane PD and decreased GSH efflux, whereas perfusion with glucagon caused a sustained increase in membrane PD but did not alter GSH efflux rates. None of the latter manipulations was associated with hepatic injury and thus no consistent relationship between membrane PD and sinusoidal efflux of GSH was demonstrated. We conclude that in the isolated perfused rat liver, efflux of GSH is not driven directly by membrane PD.
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PMID:Hepatic efflux of glutathione by the perfused rat liver: role of membrane potential difference. 318 47

The hepatic, microsomal, thiol:protein disulfide oxidoreductase catalyzes the glutathione (GSH) reduction of protein disulfides to sulfhydryl groups. In the presence of physiological concentrations of glucagon this activity increased from 2.3 to 6.4 fold in isolated microsomes. The stimulation had a P50 for glucagon of 7.8 X 10(-10) M which was only observed at microsomal protein concentrations of less than 100 micrograms/ml and in the presence of a GSH reducing system. This latter observation suggests that the stimulation may be inhibited by the presence of oxidized glutathione. These data support the hypothesis that glucagon may act in part by stimulating the reduction of protein disulfides by the thiol:protein disulfide oxidoreductase.
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PMID:Glucagon activation of the thiol:protein disulfide oxidoreductase in isolated, rat, hepatic microsomes. 352 Feb 1

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