UNIPROT:P01185 - FACTA Search

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Query: UNIPROT:P01185 (vasopressin)
23,126 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A detailed study of the control of liver pyruvate dehydrogenase activity by various hormones was carried out with perfused liver and isolated hepatocytes. Vasopressin produced a significant increase in the enzyme activity in fed rats, and the time course and sensitivity of the response was similar to that of glycogen phosphorylase a. The enzyme from starved animals was resistant to hormonal activation. The possible factors involved in the above effects are discussed. Angiotensin and phenylephrine also increased pyruvate dehydrogenase activity, and the magnitude of the response was of the same order as that to vasopressin by the liver enzyme. The effects of these hormones on pyruvate dehydrogenase activity were critically dependent on extracellular Ca2+, thus suggesting a role for this ion in the mechanism of action of the hormones. Insulin did not appear to have a role in the control of the enzyme activity, as shown by its lack of effect on the enzyme. Glucagon, in contrast with previous reports, produced a rapid, transient and significant increase in pyruvate dehydrogenase activity. The physiological importance of the above effects is discussed.
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PMID:Hormonal control of pyruvate dehydrogenase activity in rat liver. 639 71

Rat hepatic zinc thionein levels can be modulated by a variety of external and internal stimuli. Metals, such as zinc or copper, induce levels 20 to 50 fold over controls. Catecholamines can increase levels 10 to 20 fold, while glucocorticoids, such as dexamethasone, can increase levels modestly by 2-6 fold. We have investigated the ability of additional hormones, which have receptors on hepatocytes, to modulate the levels of hepatic zinc thionein. Glucagon, angiotensin II, and Arg-vasopressin were administered intravenously and intraperitoneally, one time and three times, over an 11 hour period. Zinc thionein levels in rat liver were increased 1.7 to 5.6 fold by glucagon and 1.7 to 3.6 fold by angiotensin II, but not at all by Arg-vasopressin, as compared to appropriate controls. Glucagon and angiotensin II, when administered in vivo, can modulate zinc thionein levels in rat liver to an extent similar to glucocorticoids. Hepatic zinc thionein levels must now be recognized to be affected in vivo by metals, glucocorticoids, catecholamines, and polypeptide hormones.
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PMID:Effects of glucagon, Arg-vasopressin, and angiotensin II on rat hepatic zinc thionein levels. 651 26

The effects of the peptide hormones glucagon, vasoactive intestinal peptide, and vasopressin on the microcirculation of single jejunal villi were studied in anesthetized rats. By means of a recently developed in vivo video-microscopy technique, the red blood cell velocity (pretreatment value: 2.1 +/- 0.1 mm X s-1) and the diameter of the red blood cell column (5.5 +/- 0.2 micron) were measured in the villous arcade vessels. From these parameters, an index of blood flow was calculated in order to determine changes in response to intravenous infusions of the peptides. During the infusions of glucagon and vasopressin, simultaneous measurements were made of superior mesenteric artery blood flow and villous arcade flow. Glucagon (1 microgram X kg-1 X min-1) increased villous arcade flow markedly to 150.1 +/- 13.7% of control, while superior mesenteric artery flow remained unchanged. Vasoactive intestinal peptide (1 microgram X kg-1 X min-1) produced a dilation of the arcade vessel with a commensurate reduction of red cell velocity, leaving the flow index unaltered. Vasopressin (14.3 mU X kg-1 X min-1) was found to be a potent vasoconstrictor at the mucosal level, and since red cell velocity also decreased, villous flow was reduced substantially, paralleling a reduction of superior mesenteric artery flow. After the vasopressin infusion, a reactive hyperemia occurred in the villous arcades. No such increase in blood flow was observed in the superior mesenteric artery. From these findings, we conclude that the villous microvasculature is influenced by various hormones and, therefore, must occupy a prominent position in control of the circulation of the small intestine.
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PMID:Effects of glucagon, vasoactive intestinal peptide, and vasopressin on villous microcirculation and superior mesenteric artery blood flow of the rat. 661 98

A rapid method for isolating highly purified rat liver plasma membrane vesicles using isotonic medium and Percoll self-forming gradient centrifugation is described. The vesicles were characterized by enzyme markers and electron microscopy. The method also yielded a fraction rich in nuclei. The vesicles transported Ca2+ in an ATP-dependent manner and this was enhanced by oxalate. The Vmax for Ca2+ uptake was 0.65 +/- 0.08 nmol/mg X min, which was approximately 18-fold higher than for other liver plasma membrane preparations, and the Km for Ca2+ was 5.2 +/- 0.4 nM. Calcium uptake was inhibited by 40-50% in vesicles isolated from rat livers perfused for 3 min with 10(-7)M vasopressin. The half-maximally effective concentration of vasopressin was 5 X 10(-10)M which correlates with that for raising cytosolic Ca2+ and phosphorylase a. Inhibition was not significant in vesicles from livers perfused with vasopressin for only 1 min, indicating that inhibition of the Ca2+ pump may not be involved in the rise in cytosolic Ca2+ observed at 1-2 s with this hormone. Epinephrine (10(-5)M) and angiotensin II (10(-7)M) inhibited Ca2+ uptake by 31 +/- 10 and 26 +/- 5%, respectively, at 3 min. Glucagon (10(-7)M) had no effect. It is proposed that the inhibitory action of the Ca2+-dependent hormones on the plasma membrane Ca2+ pump plays an important role in the actions of these hormones by prolonging the elevation in cytosolic Ca2+.
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PMID:Vasopressin-, angiotensin II-, and alpha 1-adrenergic-induced inhibition of Ca2+ transport by rat liver plasma membrane vesicles. 669 8

1. A method is described for efficient and rapid isolation of viable hepatocyte suspensions from chick embryos in the last few days of incubation. 2. Although qualitatively similar, quantitative differences exist in the hormonal control of glycogen metabolism between embryonic and hatched chicks. 3. Glucagon and adrenaline activate glycogenolysis. 4. Insulin did not inhibit basal or glucagon-stimulated glycogenolysis. 5. Phenylephrine (an alpha-adrenergic agonist), angiotensin and vasopressin, all of which activate glycogen breakdown in rat liver through a Ca2+-dependent mechanism, were without effect on chick embryo hepatocytes.
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PMID:Hormonal regulation of glycogen metabolism in hepatocyte suspensions isolated from chicken embryos. 680 8

We have adapted the high-resolution electrophoretic technique of O'Farrell to analyze phosphorylated proteins from rat hepatocytes. Total proteins were extracted from rat hepatocytes which had been incubated in the presence of [32P]phosphate and with two types of stimuli: glucagon on the one hand and the Ca2+-linked hormones on the other hand. About 200 phosphorylated polypeptides have been separated. Glucagon modifies the incorporation of [32P]phosphate in at least 17 polypeptides and dibutyryladenosine 3',5'-monophosphate mimics this hormonal effect, implying a common mechanism of action. Phenylephrine (in the presence of the beta-antagonist propranolol), vasopressin and angiotensin all modify the incorporation of [32P]phosphate in about 13 polypeptides; since the Ca2+ ionophore A23 187 reproduces the effect of these agents it may be concluded that Ca2+ mediates their effect. Not all the substrates affected by the two types of hormones are identical. Both types of stimuli increase the phosphorylation of a same set of seven proteins and decrease the phosphorylation of a same set of three proteins but seven proteins have their phosphorylation uniquely enhanced by glucagon whereas three other specific proteins get more phosphorylated by the Ca2+ -linked hormones. The clear differences between the patterns of protein phosphorylation observed in the presence of glucagon and dibutyryladenosine 3',5'-monophosphate on the one hand and by the Ca2+-linked hormones on the other hand strongly suggest different mechanisms of action for these two types of stimuli.
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PMID:Pattern of protein phosphorylation in rat hepatocytes stimulated by glucagon or by the Ca2+-linked hormones. 714 Jul 54

The hormonal responsiveness profile of the cortical collecting duct varies from one species to another. To identify the hormones and agonists that modulate the functions of this tubule segment in the human species, we generated a cell line (HCD) immortalized by SV40 virus. The tubular origin of this cell line was assessed by the expression of collecting duct-specific antigens and the ability of vasopressin to increase by nine-fold cAMP synthesis. Glucagon and adenosine stimulated cAMP synthesis, and atrial natriuretic peptide stimulated cGMP synthesis in a concentration-dependent manner. Bradykinin, adenosine and angiotensin increased intracellular calcium concentration ([Ca2+]i). Because adenosine can regulate tubular functions, we examined its role on glucagon-induced cAMP synthesis. Using adenosine analogs, we demonstrated that HCT cells both expressed adenosine type-2 (A2) receptors which stimulated cAMP production, and adenosine type-1 (A1) receptors linked to [Ca2+]i increase which inhibited glucagon-stimulated cAMP synthesis. The inhibitory effect was abolished by pertussis toxin, and was neither due to [Ca2+]i increase nor to protein kinase C activation, which indicated that some A1 adenosine receptors were directly negatively coupled to adenylyl cyclase. These results suggest that adenosine can modify human cortical collecting duct functions in opposite ways according to the adenosine receptor activated.
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PMID:Role of adenosine on glucagon-induced cAMP in a human cortical collecting duct cell line. 763 60

The regulation of Ca2+ influx in rat hepatocytes by glucagon and cyclic AMP (cAMP) was investigated. Exposing hepatocytes to glucagon resulted in an increase in the initial rate of Ca2+ entry. The concentrations of glucagon producing half-maximal and maximal stimulation of Ca2+ entry were 10(-10) and 10(-8) M, respectively. A similar stimulation of Ca2+ influx was obtained in cells exposed to cAMP analogues or to forskolin. Exposing hepatocytes suspended in nominally Ca(2+)-free medium to glucagon for 3 min produced a 9% decrease in the size of the vasopressin-sensitive Ca2+ pool; in contrast, N6,2'-O-dibutyryladenosine 3':5'-cyclic monophosphate (Bt2cAMP) slightly augmented the size of this pool. Glucagon and Bt2cAMP synergized the initial vasopressin-stimulated Ca2+ and Mn2+ influx rates, but only moderately increased the initial rate of Ca2+ entry after thapsigargin addition. The glucagon- and Bt2cAMP-stimulated Ca2+ influx was inhibited by the same antagonists of the plasma membrane Ca2+ carriers that mediate Ca2+ entry during stimulation by vasopressin. Thus, cAMP does not stimulate Ca2+ entry through either a capacitative type of mechanism or inositol phosphate turnover. The authors' findings instead suggest that cAMP acts directly, or through protein kinase A on the same Ca2+ carriers that are activated by phospholipase C-linked receptor agonists.
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PMID:Cyclic AMP stimulates Ca2+ entry in rat hepatocytes by interacting with the plasma membrane carriers involved in receptor-mediated Ca2+ influx. 781 85

Glucagon (Glu) influences renal tubular function and growth, although the signal transduction of Glu in the kidney still remains obscure. Rabbit cortical tubules were transformed by the pSV-neo3 gene to make a homogeneous cell colony, which responded to vasopressin but not to parathyroid hormone. The [Ca2+]i of the cells at the 9-10th passages was measured by the fluorescence indicator, fura-2. The [Ca2+]i was increased by Glu (10(-8) M) or bradykinin (10(-8) M), between which heterologous desensitization was observed. The Glu range of 10(-14) to 10(-6) M) significantly increased [Ca2+]i, while cAMP was not produced at any dose of Glu. Since the ranges of doses were from physiological to pharmacological, two concentrations of 10(-13) and 10(-8) M were employed to investigate the mechanisms. Glu at 10(-13) M led to a sustained rise in [Ca2+]i, which was completely blocked by external EGTA (5 mM, Ca-free solution). Glu at 10(-8) M provided a similar level of peak and sustained rise in [Ca2+]i, the sustained phase of which was blunted in Ca-free solution. Inositol tri/tetra phosphates were significantly increased by 10(-8) M, but not by 10(-13) M Glu. These data suggest that [Ca2+]i elevation is a major component of Glu-induced second messengers in the physiological and pharmacological range of doses of Glu, and that there might be two classes of pathways leading to increase in [Ca2+]i in transformed rabbit cortical collecting tubule cells.
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PMID:Glucagon increases intracellular free calcium in a distal tubular cell line. 802

A study was made of the initial responses of perfusate Ca2+ fluxes and bile flow to Ca(2+)-mobilizing agonists, following refinements to the methods for analysing these parameters in the perfused rat liver. Net Ca2+ efflux induced by vasopressin commences at 15 s, reaches a maximal rate at 35 s and declines to zero by 55 s, when Ca2+ influx commences. Vasopressin-induced increases in bile flow commence by 20 s, attain a maximal rate by 35 s and begin to decline at 50 s, to reach basal values by 90 s. Concomitant administration of glucagon modifies each of these actions of vasopressin in the following ways: it decreases by 5 s the time of onset of net Ca2+ efflux, and the time and magnitude of such efflux, and the time of onset of bile flow is decreased to 15 s, and the flow reaches maximal rates by 30 s. When the alpha 1-adrenergic agonist phenylephrine is used in place of vasopressin, Ca2+ efflux commences at 17-18 s and is greater in magnitude; little bile flow is induced by this agonist. Glucagon modifies the action of phenylephrine in the following ways: the onset of Ca2+ efflux is brought forward by 2-3 s, it is of lower magnitude and Ca2+ influx begins by 45 s; bile flow commences by 15-20 s, and reaches a maximum at 30 s, where the rate is much greater than in the absence of glucagon; this rate gradually declines to be near basal by 80 s. The onset of agonist-induced oxygen uptake was also brought forward by the co-administration of glucagon. Comparison of agonist-induced plasma-membrane Ca2+ fluxes and bile flow (with or without glucagon administration) suggests that correlations can be made between net Ca2+ fluxes and the transient increases seen in bile flow.
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PMID:The synergistic action (cross-talk) of glucagon and vasopressin induces early bile flow and plasma-membrane calcium fluxes in the perfused rat liver. 803 69

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