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)

Oxytocin (OT) and vasopressin (AVP) stimulate insulin and glucagon release from the pancreas, and evoke insulin secretion from the rat insulinoma cell line, RINm5F. To determine which AVP/OT receptor subtype is expressed in RINm5F cells, we used PCR with degenerate primers to two transmembrane domains of the AVP (V1a, V1b (or V3), V2) and OT receptors (OTRs). The single PCR fragment identified was used to obtain a full length cDNA from a RINm5F cDNA library. Comparison of the deduced amino acid sequence of this clone with uterine OTR sequences from several species (human, sheep, bovine) and to the pig kidney epithelial cell (LLC-PK1) OTR reveals a very high degree of homology. After the RIN cell OTR cDNA was stably transfected into CHO cells (CHO-OTR), the cell membranes bound iodinated oxytocin antagonist with an apparent Kd comparable to that of RIN cell membranes and those from other OT target cells. Comparison of the ligand specificities of CHO-OTR and RIN cells membranes showed that the relative Ki values of a series of OT analogues were approximately equivalent in both preparations. The rank order of apparent Ki values also corresponded to published values for the rat myometrium, where OT elicits intracellular calcium transients, and increases inositol phosphate production. In uterin endometrium and amnion cells, OT stimulates prostaglandin release. Stimulation of CHO-OTR cells with OT caused an increase in cytosolic calcium concentration originating from both intracellular and extracellular sources, and a dose-dependent increase in inositol phosphate levels. Arachidonic acid release and PGE2 synthesis were also stimulated by OT. These findings (amino acid sequence homology, binding specificity, and signal transduction/second messenger production) suggest that OTRs from RINm5F cells are indistinguishable from OTRs that have been described in other tissues. The expression of OTR in pancreatic cells implies that OT plays a role in pancreatic function.
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PMID:Molecular cloning and functional characterization of the oxytocin receptor from a rat pancreatic cell line (RINm5F). 900 55

[Arg8]vasopressin (AVP), through its V1 receptor coupled to GTP-binding proteins, and aluminum fluoride (AlF4-), which directly activates GTP-binding proteins, induced the release of [3H]arachidonate from prelabeled A7r5 vascular smooth muscle-like cells. Using fura-2-loaded cells, we observed that the release induced by AVP occurred concurrently with calcium (Ca2+) mobilization from internal stores and entry of external Ca2+, whereas AlF4(-)-dependent arachidonate release was much slower and was not accompanied by intracellular Ca2+ mobilization. Arachidonate transfer from phosphatidylcholine to phosphatidylethanolamine was an early event for both agonists, but phosphatidylinositol hydrolysis was an early event for AVP-stimulated cells and a late event for cells triggered with AlF4-. In addition, phospholipase inhibitors had no effect on arachidonate release induced by AlF4-. We investigated the enzymatic pathways involved in the releases of arachidonate, which occur in such different ways. Phospholipase A2 activities were assayed in a cell-free system with various substrates, which made it possible to differentiate between cytosolic, secretory and Ca2(+)-independent phospholipases A2. The specific activities were in the order alkenyl-AA-GPE > acyl-AA-GPE > acyl-AA-GPC in the presence of Ca2+. No significant activity was observed in the presence of Ca2+ chelators and when dipalmitoyl-glycerophosphocholine was used as a substrate. Phospholipase A2 activities did not change in homogenates from stimulated cells related to control cells. However, phospholipase A2 activity increased in membrane fractions from AVP-stimulated cells. Imunodetected phosphorylated and unphosphorylated forms of cytosolic phospholipase A2 (cPLA2) also clearly increased in the membrane fractions of AVP-stimulated cells, and only the unphosphorylated form of cPLA2 was present in AlF4(-)-triggered cells. We conclude that phospholipase C and translocation of cPLA2 can account for arachidonate release with AVP stimulation, whereas neither phospholipase C nor any phospholipase A2 activity appears to be implicated in AlF4(-)-dependent arachidonate release.
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PMID:Phospholipase A2-dependent and -independent pathways of arachidonate release from vascular smooth muscle cells. 906 36

The effects of arachidonic acid (AA) and arachidonic acid metabolites on vasopressin secretion and on intracellular free calcium concentration ([Ca2+]i) from both intact and streptolysin-O permeabilized isolated nerve endings of the rat neurohypophysis were studied. Arachidonic acid induced a dose-dependent increase in resting vasopressin (AVP) secretion in both intact and streptolysin-O permeabilized nerve endings. Although AA also dose-dependently induced an increase in [Ca2+]i in intact nerve endings, the AA-induced secretory response was largely independent of an increase in [Ca2+]i. Secretory responses in intact nerve endings showed AA-induced secretion to be sustained and that AA-induced vasopressin secretion occurs via exocytosis. Arachidonic acid also dose-dependently potentiated K+-depolarization evoked vasopressin release. The potentiation of secretion occurred despite an AA-induced reduction in K+-evoked Ca2+ influx. In addition, AA reinitiated secretion following a decline in the Ca2+-dependent exocytotic secretory response suggesting a separate secretory mechanism from Ca2+-induced secretion. Inhibition of the metabolic pathways for AA suggested that AA itself mediates the secretory effects and that AA is likely subject to rapid metabolism by lipoxygenases.
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PMID:Arachidonic acid regulation of vasopressin release and intracellular Ca2+ in neurohypophysial nerve endings. 911 86

Arachidonic acid (AA) can undergo monooxygenation or epoxidation by enzymes in the cytochrome P450 (CYP) family in the brain, kidney, lung, vasculature, and the liver. CYP-AA metabolites, 19- and 20-hydroxyeicosatetraenoic acids (HETEs), epoxyeicosatrienoic acids (EETs) and diHETEs have different biological properties based on sites of production and can be stored in tissue lipids and released in response to hormonal stimuli. 20-HETE is a vasoconstrictor, causing blockade of Ca(++)-activated K(+) (KCa) channels. Inhibition of the formation of nitric oxide (NO) by 20-HETE mediates most of the cGMP-independent component of the vasodilator response to NO. 20-HETE elicits a potent dilator response in human and rabbit pulmonary vascular and bronchiole rings that is dependent on an intact endothelium and COX. 20-HETE is also a vascular oxygen sensor, inhibits Na(+)/K(+)-ATPase activity, is an endogenous inhibitor of the Na(+)-K(+)-2Cl(-)cotransporter, mediates the mitogenic actions of vasoactive agents and growth factors in many tissues and plays a significant role in angiogenesis. EETs, produced by the vascular endothelium, are potent dilators. EETs hyperpolarize VSM cells by activating KCa channels. Several investigators have proposed that one or more EETs may serve as endothelial-derived hyperpolarizing factors (EDHF). EETs constrict human and rabbit bronchioles, are potent mediators of insulin and glucagon release in isolated rat pancreatic islets, and have anti-inflammatory activity. Compared with other organs, the liver has the highest total CYP content and contains the highest levels of individual CYP enzymes involved in the metabolism of fatty acids. In humans, 50-75% of CYP-dependent AA metabolites formed by liver microsomes are omega/omega-OH-AA, mainly w-OH-AA, i.e. 20HETE, and 13-28% are EETs. Very little information is available on the role of 19- and 20-HETE and EETs in liver function. EETs are involved in vasopressin-induced glycogenolysis, probably via the activation of phosphorylase. In the portal vein, inhibition of EETs exerts profound effects on a variety of K-channel activities in smooth muscles of this vessel. 20-HETE is a weak, COX-dependent, vasoconstrictor of the portal circulation. EETs, particularly 11,12-EET, cause vasoconstriction of the porto-sinusoidal circulation. Increased synthesis of EETs in portal vessels and/or sinusoids or increased levels in blood from the meseneric circulation may participate in the pathophysiology of portal hypertension of cirrhosis. CYP-dependent AA metabolites are involved in the pathophysiology of portal hypertension, not only by increasing resistance in the porto-sinusoidal circulation, but also by increasing portal inflow through mesenteric vasodilatation. In patients with cirrhosis, urinary 20-HETE is several-fold higher than PGs and TxB2, whereas in normal subjects, 20-HETE and PGs are excreted at similar rates. Thus, 20-HETE is probably produced in increased amounts in the preglomerular microcirculation accounting for the functional decrease of flow and increase in sodium reabsorption. In conclusion, CYP-AA metabolites represent a group of compounds that participate in the regulation of liver metabolic activity and hemodynamics. They appear to be deeply involved in abnormalities related to liver diseases, particularly cirrhosis, and play a key role in the pathophysiology of portal hypertension and renal failure.
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PMID:Role of cytochrome P450-dependent arachidonic acid metabolites in liver physiology and pathophysiology. 1462 96

Recently, we reported that intracerebroventricularly (i.c.v.) administered arginine-vasopressin evokes the release of noradrenaline and adrenaline from adrenal medulla by brain thromboxane A2-mediated mechanisms in rats. These results suggest the involvement of brain arachidonic acid in the vasopressin-induced activation of the central adrenomedullary outflow. Arachidonic acid is released mainly by two pathways: phospholipase A2 (PLA2)-dependent pathway; phospholipase C (PLC)- and diacylglycerol lipase-dependent pathway. In the present study, therefore, we attempted to identify which pathway is involved in the vasopressin-induced release of both catecholamines from adrenal medulla using urethane-anesthetized rats. Vasopressin (0.2 nmol/animal, i.c.v.)-induced elevation of plasma noradrenaline and adrenaline was dose-dependently reduced by neomycin [0.28 and 0.55 micromol (250 and 500 microg)/animal, i.c.v.] and 1-[6-[[(17beta)-3-methoxyestra-1,3,5(10)-trien-17-yl]amino]hexyl]-1H-pyrrole-2,5-dione (U-73122) [5 and 10 nmol (2.3 and 4.6 microg)/animal, i.c.v.] (inhibitors of PLC), and also by 1,6-bis(cyclohexyloximinocarbonylamino)hexane (RHC-80267) [1.3 and 2.6 micromol (500 and 1000 microg)/animal, i.c.v.] (an inhibitor of diacylglycerol lipase). On the other hand, mepacrine [1.1 and 2.2 micromol (500 and 1000 microg)/animal, i.c.v.] (an inhibitor of PLA2) was largely ineffective on the vasopressin-induced elevation of plasma catecholamines. These results suggest that vasopressin evokes the release of noradrenaline and adrenaline from adrenal medulla by the brain PLC- and diacylglycerol lipase-dependent mechanisms in rats.
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PMID:Brain phospholipase C-diacylglycerol lipase pathway is involved in vasopressin-induced release of noradrenaline and adrenaline from adrenal medulla in rats. 1536 56

Arachidonic acid (AA) regulates many aspects of vascular smooth muscle behaviour, but the mechanisms linking receptors to AA release are unclear. In A7r5 vascular smooth muscle cells pre-labelled with (3)H-AA, vasopressin caused a concentration-dependent stimulation of 3H-AA release that required phospholipase C and an increase in cytosolic [Ca2+]. Ca2+ release from intracellular stores and Ca2+ entry via L-type channels or the capacitative Ca2+ entry pathway were each effective to varying degrees. Selective inhibitors of PLA2 inhibited the 3H-AA release evoked by vasopressin, though not the underlying Ca2+ signals, and established that cPLA2 mediates the release of AA. We conclude that in A7r5 cells vasopressin stimulates AA release via a Ca2+-dependent activation of cPLA2.
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PMID:Stimulation of arachidonic acid release by vasopressin in A7r5 vascular smooth muscle cells mediated by Ca2+-stimulated phospholipase A2. 1682 86

In the current study, we aimed to determine the cardiovascular effects of arachidonic acid and peripheral mechanisms mediated these effects in normotensive conscious rats. Studies were performed in male Sprague Dawley rats. Arachidonic acid was injected intracerebroventricularly (i.c.v.) at the doses of 75, 150 or 300 microg and it caused dose- and time-dependent increase in mean arterial pressure and decrease in heart rate in normal conditions. Maximal effects were observed 10 min after 150 and 300 microg dose of arachidonic acid and lasted within 30 min. In order to evaluate the role of main peripheral hormonal mechanisms in those cardiovascular effects, plasma adrenaline, noradrenaline, vasopressin levels and renin activity were measured after arachidonic acid (150 microg; i.c.v.) injection. Centrally injected arachidonic acid increased plasma levels of all these hormones and renin activity. Intravenous pretreatments with prazosin (0.5 mg/kg), an alpha1 adrenoceptor antagonist, [beta-mercapto-beta,beta-cyclopentamethylenepropionyl1, O-Me-Tyr2-Arg8]-vasopressin (10 microg/kg), a vasopressin V1 receptor antagonist, or saralasin (250 microg/kg), an angiotensin II receptor antagonist, partially blocked the pressor response to arachidonic acid (150 microg; i.c.v.) while combined administration of these three antagonists completely abolished the effect. Moreover, both individual and combined antagonist pretreatments fully blocked the bradycardic effect of arachidonic acid. In conclusion, our findings show that centrally administered arachidonic acid increases mean arterial pressure and decreases heart rate in normotensive conscious rats and the increases in plasma adrenaline, noradrenaline, vasopressin levels and renin activity appear to mediate the cardiovascular effects of the drug.
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PMID:Peripheral mechanisms involved in the pressor and bradycardic effects of centrally administered arachidonic acid. 1857 95

1. The aims of the present study were to determine the cardiovascular effects of arachidonic acid (AA) and to investigate the peripheral mechanisms mediating these effects in haemorrhage-induced hypotensive rats. 2. Acute haemorrhage was induced by withdrawing a total volume of 2.2 mL blood/100 g bodyweight over a period of 10 min. Rats were then injected with 75-300 microg, i.c.v., AA and cardiovascular changes were monitored over the next 60 min. Plasma catecholamine and vasopressin levels, as well as plasma renin activity (PRA), were measured 10 min after injection of 150 microg AA in haemorrhage-induced hypotensive awake rats. In addition, rats were pretreated with saline (1 mL/kg, i.v.), the vasopressin V(1) receptor antagonist [beta-mercapto-beta,beta-cyclopentamethylenepropionyl(1),O-Me-Tyr(2),Arg(8)]-vasopressin (10 microg/kg, i.v.), the alpha(1)-adrenoceptor antagonist prazosin (500 microg/kg, i.v.), the non-specific angiotensin II receptor antagonist saralasin (250 microg/kg, i.v.) or a combination of these three antagonists 5 min before injection of AA (150 microg, i.c.v.). The effects of these antagonists on responses to AA were determined. 3. Arachidonic acid caused dose- and time-dependent increases in mean arterial pressure and heart rate and reversed hypotension in haemorrhaged rats. Haemorrhage itself produced an increase in plasma catecholamine and vasopressin levels, as well as PRA; injection of AA produced further increases in these parameters, ranging from 39-123%, under hypotensive conditions. Under hypotensive conditions, pretreatment of rats with all three receptor antagonists produced similar partial blockade of the pressor response to AA, but not the increase in heart rate. Moreover, combined administration of all three receptor antagonists prior to the i.c.v. injection of 150 microg AA completely abolished the pressor response to AA in haemorrhage-induced hypotensive rats. 4. These results indicate that centrally administered AA reverses hypotension by increasing blood pressure and heart rate in the hypotensive setting. The observed increases in plasma catecholamine and vasopressin levels, as well as PRA, mediate the pressor response to AA in haemorrhage-induced hypotensive rats.
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PMID:Cardiovascular effects of centrally administered arachidonic acid in haemorrhage-induced hypotensive rats: investigation of a peripheral mechanism. 1970 98


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