Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:P01185 (vasopressin)
 23,126 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

In vitro experiments have shown that luminally applied water-soluble vasoactive materials have limited access to arteriolar smooth muscle cells, and as a result, the responses to such agents applied luminally are less than the responses to those applied adventitially. To determine the extent to which this 'compartmentation' influences arteriolar responsiveness to blood-borne water-soluble vasoconstrictors in vivo, we applied phenylephrine, vasopressin and angiotension II to arterioles in the hamster cheek pouch both by luminal perfusion, and by topical application to the arteriolar smooth muscle via micropipettes. The arterioles were about 2 orders of magnitude more sensitive to these water-soluble vasoconstrictors when they were applied topically than when they were applied luminally. In contrast, the arterioles were almost equally sensitive to the lipid-soluble alpha 1-adrenoceptor agonist SKF 89748-A applied by either route. The venular wall appears to be much less effective as a barrier than the arteriolar endothelium. Phenylephrine and vasopressin both elicited large arteriolar constrictions when perfused through venules in close proximity to the arteriole, and these constrictions were larger than those observed when the drug was applied to the arteriole's own lumen. Our observations confirm that the arteriolar endothelium can inhibit the direct access of water-soluble blood-borne agents to the arteriolar smooth muscle in vivo, and they suggest that the capillaries and venules could be the primary routes of access for water-soluble agents from the blood to the arteriolar smooth muscle.
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PMID:Access of blood-borne vasoconstrictors to the arteriolar smooth muscle. 139 55

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

The effect of hormones on cell volume was studied in isolated perfused rat liver by assessing the intracellular water space as the difference between a [3H]inulin- and a [14C]urea-accessible space. The intracellular water space (control value 559 +/- 7 microliters/g of liver; n = 88) increased on addition of insulin (35 nM) or phenylephrine (5 microM) by 12 or 8% respectively, whereas it decreased with cyclic AMP (cAMP; 50 microM), glucagon (100 nM) or adenosine (50 microM) by 9, 13 or 6% respectively. Both insulin and glucagon exerted half-maximal effects on cell volume and cellular K+ balance at hormone concentrations found physiologically in the portal vein. Adenosine-induced cell shrinkage was explained by a net K+ release from the liver. Phenylephrine (5 microM) led to cell swelling by about 8%, which was additive to insulin-induced swelling. Extracellular ATP (20 microM) induced cell shrinkage by about 6%; this was additive to adenosine-induced shrinkage. Vasopressin (15 nM) did not appreciably change cell volume, but induced marked cell shrinkage when glucagon or cAMP was present. Insulin- and phenylephrine-induced cell swelling was counteracted by cAMP. Hormone-induced changes of intracellular water space could sufficiently explain accompanying liver mass changes induced by glucagon, cAMP, adenosine or vasopressin, but not those by phenylephrine and extracellular ATP. The data show that liver cell volume is subject to hormonal regulation, in part owing to modification of cellular K+ balance. Glucagon- and insulin-induced cell volume changes occur already in the presence of physiological hormone concentrations. The effects of Ca2(+)-mobilizing hormones on cell volume are not uniform. In view of the recently established role of cell volume changes in modulating liver cell function, the present findings open a new perspective on the mechanisms of hormone action in liver, underlining our previous hypothesis that cell volume changes may represent a 'second messenger' of hormone action.
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PMID:Regulation of cell volume in the perfused rat liver by hormones. 166 Feb 61

The model of "chemical hypoxia" with KCN plus iodoacetic acid mimics the ATP depletion and reductive stress of hypoxia. Here, we examined the effects of chemical hypoxia on cytosolic free Na+ and Ca2+ in single cultured rat hepatocytes by multiparameter digitized video microscopy and ratio imaging of sodium-binding furan indicator (SBFI) and Fura-2. Intracellular Na+ increased from about 10 mM to more than 100 mM after 20 min of chemical hypoxia, whereas cytosolic free Ca2+ remained virtually unchanged. In normoxic hepatocytes, phenylephrine (50 microM) and Arg-vasopressin (20-40 nM) induced Ca2+ oscillations in 70 and 40% of cells, respectively. These Ca2+ oscillations were suppressed after one spike following the onset of chemical hypoxia. Phenylephrine and vasopressin also increased inositol phosphate formation by 22 and 147%, respectively. This effect was suppressed by KCN plus iodoacetate. Intracellular acidosis is characteristic of chemical hypoxia. Intracellular acidosis induced by 40 mM Na-acetate suppressed Ca2+ oscillations but did not inhibit hormone-induced inositol phosphate formation. Cytosolic alkalinization also suppressed Ca2+ oscillations. However, prevention of intracellular acidosis with monensin (10 microM) did not prevent suppression of Ca2+ oscillations during chemical hypoxia. Mitochondrial depolarization with uncoupler did not change free Ca2+ levels during chemical hypoxia, indicating that mitochondria do not regulate free Ca2+ during chemical hypoxia. From these results, we conclude: 1) chemical hypoxia does not block Na+ influx across the plasma membrane; 2) Chemical hypoxia inhibits hormone-stimulated Ca2+ flux pathways across cellular membranes by two different mechanisms: (a) by ATP depletion, which disrupts hormone-myo-inositol 1,4,5-triphosphate coupling, and (b) by intracellular acidosis, which inhibits myo-inositol 1,4,5-triphosphate-stimulated Ca2+ release from intracellular stores; 3) during ATP depletion by chemical hypoxia, mitochondria do not take up Ca2+ to maintain cytosolic free Ca2+ at low concentrations.
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PMID:Suppression of Ca2+ oscillations in cultured rat hepatocytes by chemical hypoxia. 193 69

The purpose of this study was to examine the effects of catecholamines on skin necrosis independent of their vasoactive effects. Rat abdominal or human breast skin was excised, pinned flat, and incubated at 37 degrees C for 6 hours in a buffered salt solution containing catecholamine. At 0.1 and 6 hours the lactate dehydrogenase (LDH) released from the skin and appearing in the buffer was determined spectrophotometrically. All groups showed similar LDH levels at 0.1 hour. Rat skin treated with greater than or equal to 10(-7) M epinephrine (33 times less than the 1:200,000 used clinically) or greater than or equal to 10(-5) M norepinephrine showed a significant increase in the LDH released at 6 hours versus controls (18.75 +/- 1.25 versus 13.75 +/- 1.25 and 29.25 +/- 2.96 versus 22.00 +/- 1.96 IV, respectively). Total tissue LDH levels were not significantly different at 0.1 or 6 hours. The toxic effect of epinephrine was eliminated by the addition of propranolol or selective beta 2 blockade, but not by alpha or beta 1 blockade. Therefore, this effect appears to be mediated largely by beta 2 receptors. Similar toxic effects were seen in human breast skin treated with 1:200,000 epinephrine and were blocked with propranolol. Phenylephrine at 1:20,000 demonstrated toxicity, but angiotensin II and vasopressin did not. These studies indicate that addition of catecholamine to ischemic rat or human skin accelerates skin death within 6 hours, but that the toxicity can be reversed with beta blockade.
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PMID:Toxic effects of catecholamines on skin. 229 41

Analysis of peptides purified from high and low molecular weight fractions of rabbit atrial extracts indicates that the sequence of the first 30 residues of rabbit atriopeptigen exhibits 80% homology with the rat peptide, and that the low molecular weight rabbit peptide (28 residues) is identical to rat atriopeptin 28 (AP 28). The effects of infused 1-deaminoarginine8-vasopressin (dAVP) and phenylephrine, volume expansion, and water immersion on AP release into the circulation of the rabbit was studied. Neither dAVP, nor water immersion elevated right atrial pressure (RAP) or plasma AP levels in the anesthetized rabbits. Phenylephrine induced a sustained increase in systemic blood pressure and right atrial pressure which was accompanied by elevated plasma AP immunoreactivity which appeared to be identical to rat AP-28 on HPLC. There is obviously a preferential conservation of the AP sequence, since the C-terminal peptide is exactly the same in rabbit, rat and mouse and differs from human, dog, cow and pig only by the single substitution of an isoleucine for a methionine residue.
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PMID:Identification of the cardiac and circulating form of atriopeptin in rabbit. 294 16

In lightly anesthetized adult sheep, we determined tracheal mucosal blood flow (Qtr) by measuring the steady-state uptake of dimethyl ether from a tracheal chamber created by an endotracheal tube provided with two cuffs. Qtr normalized for carotid arterial pressure [Qtr(n)] was determined before and after the exposure of the tracheal mucosa to aerosolized phenylephrine (0.25-2.0 mg), isoproterenol (0.05-0.8 mg), and methacholine (2.5-20 mg). The same doses of methacholine were also administered during the intravenous infusion of vasopressin. The measurements were repeated after intravenous pretreatment with the respective antagonists phentolamine, propranolol, and atropine. Mean +/- SE base-line Qtr(n) was 1.2 +/- 0.1 ml.min-1.mmHg-1.10(2). The autonomic antagonists had no effect on mean Qtr(n). Phenylephrine produced a dose-dependent decrease in mean Qtr(n) (-70% at the highest dose), which was blunted by phentolamine, and isoproterenol produced a dose-dependent increase in mean Qtr(n) (40% at the highest dose), which was blocked by propranolol. Methacholine failed to alter mean Qtr(n) even when Qtr was first decreased by vasopressin. We conclude that in lightly anesthetized adult sheep 1) base-line Qtr(n) is not under adrenergic or cholinergic control, 2) a locally administered alpha-adrenergic agonist decreases and beta-adrenergic agonist increases Qtr(n) via specific receptor activation, and 3) a locally administered cholinergic muscarinic agonist has no effect on Qtr(n).
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PMID:Tracheal mucosal blood flow responses to autonomic agonists. 304 13

The effect of Ca2+-mobilizing hormones, vasopressin, angiotensin II and the alpha-adrenergic agonist phenylephrine, on the metabolic flux through the tricarboxylic acid cycle was investigated in isolated perfused rat livers. All three Ca2+-mobilizing agonists stimulated 14CO2 production and gluconeogenesis in livers of 24-h-fasted rats perfused with [2-14C]pyruvate. Prazosin blocked the phenylephrine-elicited stimulation of 14CO2 and glucose production from [2-14C]pyruvate whereas the alpha 2-adrenergic agonist, BHT-933, did not affect the rates of 14CO2 and glucose production from [2-14C]pyruvate indicating that the phenylephrine-mediated response involved alpha 1-adrenergic receptors. Phenylephrine, vasopressin and angiotensin II stimulated 14CO2 production from [2-14C]acetate in livers derived from fed rats but not in livers of 24-h-fasted rats. In livers of 24-h-fasted rats, perfused with [2-14C]acetate, exogenously added pyruvate was required for an increase in the rate of 14CO2 production during phenylephrine infusion. This last observation suggests increased pyruvate carboxylation as one of the mechanisms involved in stimulation of tricarboxylic acid cycle activity by the Ca2+-mobilizing agonists, vasopressin, angiotensin II and phenylephrine.
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PMID:Hormonal regulation of the tricarboxylic acid cycle in the isolated perfused rat liver. 309 66

1. In isolated hepatocytes prelabelled with [14C]-arachidonic, -stearic, -linoleic, -oleic or -palmitic acids, vasopressin increased the amount of radioactivity present in diacylglycerols. The largest increase was observed in cells labelled with arachidonic or stearic acids. 2. In cells prelabelled with [14C]- or [3H]-arachidonic acid, the onset of the increase in radioactivity in diacylglycerols induced by vasopressin was slow, the increase was partly dependent on the presence of extracellular Ca2+, and was associated with an increase in radioactivity present in phosphatidic acid which was more rapid in onset. Vasopressin decreased the amount of [3H]arachidonyl-phosphatidylinositol 4,5-bisphosphate, but the magnitude of this decrease was less than 10% of the observed increase in radioactivity in [3H]arachidonyl-diacylglycerol. 3. The concentration of vasopressin which gave half-maximal increase in [14C]arachidonyl-diacylglycerol at low extracellular Ca2+ was 10-fold higher than that which gave half-maximal stimulation of 45Ca2+ efflux. Phenylephrine, but not glucagon, also increased the amount of [14C]arachidonyl-diacylglycerol. 4. It is concluded that an early action of vasopressin on the liver cell is to increase the flux of carbon from phospholipids, including the phosphoinositides, to diacylglycerols.
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PMID:Evidence from studies employing radioactively labelled fatty acids that the stimulation of flux through the diacylglycerol pool is an early action of vasopressin on hepatocytes. 311 41

Phenylephrine, vasopressin and glucagon each increased the amount of active (dephospho) pyruvate dehydrogenase (PDHa) in isolated rat hepatocytes. Treatment with 4 beta-phorbol 12-myristate 13-acetate (PMA) opposed the increase in PDHa caused by both phenylephrine and glucagon, but had no effect on the response to vasopressin: PMA alone had no effect on PDHa. As PMA is known to prevent the phenylephrine-induced increase in cytoplasmic free Ca2+ concentration ([Ca2+]c) and to diminish the increase [Ca2+]c caused by glucagon, while having no effect on the ability of vasopressin to increase [Ca2+]c, these data are consistent with the notion that in intact cells an increase in [Ca2+]c results in an increase in the mitochondrial free Ca2+ concentration, which in turn leads to the activation of PDH. In the presence of 2.5 mM-Ca2+, glucagon caused an increase in NAD(P)H fluorescence in hepatocytes. This increase is taken to reflect an enhanced activity of mitochondrial dehydrogenases. PMA alone had no effect on NAD(P)H fluorescence; it did, however, compromise the increase produced by glucagon. When the extracellular free [Ca2+] was decreased to 0.2 microM, glucagon could still increase NAD(P)H fluorescence. Vasopressin also increased fluorescence under these conditions; however, if vasopressin was added after glucagon, no further increase in fluorescence was observed. Treatment of the cells with PMA resulted in a smaller increase in NAD(P)H fluorescence on addition of glucagon: the subsequent addition of vasopressin now caused a further increase in fluorescence. Changes in [Ca2+]c corresponding to the changes in NAD(P)H fluorescence were observed, again supporting the idea that [Ca2+]c indirectly regulates intramitochondrial dehydrogenase activity in intact cells. PMA alone had no effect on pyruvate kinase activity, and the phorbol ester did not prevent the inactivation caused by glucagon. The latter emphasizes the different mechanisms by which the hormone influences mitochondrial and cytoplasmic metabolism.
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PMID:The glucagon-induced activation of pyruvate dehydrogenase in hepatocytes is diminished by 4 beta-phorbol 12-myristate 13-acetate. A role for cytoplasmic Ca2+ in dehydrogenase regulation. 359 19


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