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)

Endogenous prostaglandin (PG) E2 production potently modulates salt and water transport in the kidney. Multiple direct effects of PGE2 on epithelial water and sodium transport have been demonstrated in the rabbit cortical collecting duct (CCD). Both functional and molecular studies now suggest that these disparate effects of PGE2 on CCD function are mediated by different EP receptors. When added in the presence of vasopressin, PGE2 inhibits cyclic AMP generation and water absorption. These effects are mediated via an inhibitory G-protein (Gi). In situ hybridization demonstrates high levels of expression of the Gi-coupled EP3 receptor in the rabbit collecting duct. However, by itself, PGE2 also stimulates cyclic AMP generation and water permeability. These effects appear to be mediated via a distinct EP receptor (possibly an EP4 receptor). PGE2 also increases intracellular Ca2+ in the CCD and inhibits Na+ absorption via a Ca(2+)-dependent mechanism. The EP1 receptor is postulated to be responsible for this action of PGE2. We suggest receptor-selective prostaglandin analogs may be used to selectively modulate sodium and water transport in the kidney.
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PMID:Functional and molecular aspects of prostaglandin E receptors in the cortical collecting duct. 762 54

We have documented new observations with respect to PGE2 action in the rabbit CCD. (1) PGE2 can inhibit both cAMP and vasopressin-induced water flow, depending on the sequence of PGE2 addition with respect to vasopressin or cAMP. (2) PGE2 inhibition of vasopressin or cAMP-stimulated water flow can be reversed with staurosporine. Thus, PGE2 inhibits vasopressin-stimulated water flow by activation of PKC and (3) PGE2 induces release of calcium from intracellular stores. These results strongly suggest the presence of a PGE2 receptor coupled to PIP2 hydrolysis. PGE2 mediated increases in cytosolic calcium are responsible for the inhibitory action of PGE2 on sodium transport. While stimulation of cAMP production by PGE2 may contribute to the inhibition of sodium transport, it is not required since in the presence of 8-CPTcAMP, PGE2 still decreases sodium transport. The effect of PGE2 on sodium transport is pertussis toxin insensitive and is unlikely to be mediated by an inhibitory G protein. Using PGE2 and one of its selective analogues, sulprostone, we have provided evidence for functionally distinct PGE2 receptors. Separate PGE2 receptor subtypes appear to be coupled to separate transport processes. These receptor subtypes may correspond to the EP1, EP2 and EP3 receptors described earlier in smooth muscle. Thus, an EP2 like receptor stimulates cAMP generation and water reabsorption while an EP1 like receptor increases [Ca++]i and inhibits sodium reabsorption. Finally, an EP3 receptor, equivalently activated by sulprostone and PGE2, may couple to Gi and mediate pertussis toxin sensitive inhibition of vasopressin-stimulated water flow.
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PMID:Cellular signalling of PGE2 and its selective receptor analogue sulprostone in rabbit cortical collecting duct. 782 28

We have cloned two isoforms of rat kidney prostaglandin E2 receptor EP3 subtype (rEP3A and rEP3B), which differ only in their cytosolic carboxyl-terminal tails (30 and 29 amino acids, respectively). The aim is to clarify the functional difference between two rEP3 receptor isoforms by examining formation of adenosine 3',5'-monophosphate (cAMP) and change in cytosolic free calcium ([Ca2+]i) in cultured cells transiently transfected with cloned rEP3A or rEP3B receptor cDNA. In immortalized renal distal tubule cells (TKC2), vasopressin (VP) stimulated cAMP formation, and the cAMP formation was significantly attenuated by a non-peptide VP receptor antagonist, OPC-31260. The VP-induced increase in cAMP formation was also attenuated by over-expression of rEP3A receptor but not that of rEP3B receptor. On the other hand, in COS-7 cells transfected with rEP3B receptor cDNA, PGE2 induced an increase in [Ca2+]i, but no increase in [Ca2+]i was observed in the cells transfected with rEP3A cDNA. In conclusion, rEP3A receptor is suggested to antagonize VP (V2) receptor by inhibiting cAMP formation, whereas rEP3B receptor is linked with Ca2+ messenger system.
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PMID:Functional difference between two isoforms of rat kidney prostaglandin receptor EP3 subtype. 794 43

We have reported two isoformes of rat prostaglandin EP3 receptor with their different carboxyl-terminal tails (rEP3A and rEP3B receptors), which are derived by alternative RNA splicing, and both receptors have been shown to be localized to renal distal tubules. In the present study, we characterized the signal transduction system of rat kidney EP3 receptors either in a renal cell line mimicking renal distal tubule cells, TKC2, or in COS-7 cells by functional expression of these receptors. We also examined the chromosomal localization of the EP3 receptor gene by fluorescence in situ hybridization (FISH). In TKC2 cells, vasopressin (AVP, 10(-7) M), prostaglandin (PG) E2 (10(-7) M), or forskolin (10(-8) M) markedly stimulated cyclic AMP formation. Overexpression of the rEP3A receptor significantly attenuated the AVP-, PGE2- or forskolin-induced cyclic AMP formation, whereas there was no change with rEP3B receptor expression. On the other hand, in COS-7 cells transfected with rEP3A receptor cDNA, PGE2 (10(-7) M) did not affect cytosolic free calcium concentration ([Ca2+]i), whereas transfection of rEP3B receptor cDNA evoked PGE2-induced increases in [Ca2+]i. Moreover, we have revealed that the rEP3 receptor gene is localized to rat chromosome 2q44-45. In conclusion, rEP3A or rEP3B receptor is suggested as a mediator of the natriuretic/diuretic action of PGE2 in renal distal tubules via a decrease in cyclic AMP formation or an increase in [Ca2+]i, respectively. Information of the gene assignment of rat EP3 receptor to rat chromosome 2q44-45 is useful for further analysis of the role of EP3 receptor in genetically hypertensive rat models.
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PMID:Functional analysis and chromosomal gene assignment of rat kidney prostaglandin EP3 receptor. 874 50

Prostaglandin E2 is the major cyclooxygenase product of arachidonic acid metabolism produced along the nephron. This autacoid interacts with four distinct, G-protein-coupled E-prostanoid receptors designated EP1-EP4. The intrarenal distribution of each receptor has been mapped and the consequences of receptor activation examined. EP3 receptor mRNA is expressed highly in the medullary thick ascending limb (mTAL) and collecting duct (CD). EP3 receptor activation inhibits cAMP generation via Gi, thus inhibiting vasopressin-stimulated water reabsorption in the CD. EP3 receptor activation also may contribute to PGE2-mediated inhibition of NaCl absorption in the mTAL. The EP1 receptor is coupled to increased cell [Ca2+]. EP1 mRNA expression is restricted to the CD, and receptor activation inhibits Na+ absorption. PGE2 also increases cAMP generation in the cortical thick ascending limb and CD; this may be due to EP4 receptor activation. EP4 mRNA is readily detected in the CD with little detectable EP2 expression. The EP4 receptor appears to be expressed both on luminal and basolateral membranes. EP4 receptor activation also may contribute to the regulation of renin release by the juxtaglomerular apparatus. The consequences of renal EP-receptor activation for salt and water balance may be determined by the relative renal expression of each of these receptors.
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PMID:Regulation of renal function by prostaglandin E receptors. 973 61

The actions of prostaglandin (PG) E2 are mediated by four distinct classes of PGE2 E-prostanoid (EP) receptors (EP1 through EP4). However, the in vivo functions of the individual EP receptor subtypes have not been delineated. To study the functions of one of these subtypes, the EP3 receptor, we generated EP3-deficient (-/-) mice by gene targeting. EP3 -/- animals survived in expected numbers, reproduced, and had no obvious abnormalities in their major organ systems. Because the EP3 receptor is expressed at high levels in the renal medulla and cortical collecting duct, and because previous studies have suggested that the EP3 receptor might antagonize the effects of vasopressin in the distal nephron, we examined urinary concentrating functions in EP3 -/- mice. Basal urine osmolality (UOsm) was similar in groups of EP3 -/- and wild-type (EP3 +/+) mice. However, after inhibition of endogenous PGE2 production by indomethacin, UOsm increased significantly in EP3 +/+ but not in EP3 -/- mice. Despite this insensitivity to acute inhibition of prostanoid production, EP3 -/- mice concentrated and diluted their urine normally in response to a series of physiological stimuli. This suggests that PGE2 acts through the EP3 receptor to modulate urinary concentrating mechanisms in the kidney, but these effects are not essential for normal regulation of urinary osmolality.
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PMID:Urinary concentrating function in mice lacking EP3 receptors for prostaglandin E2. 984 13

Prostaglandins (PGs) have been implicated in the regulation of vasopressin (VP) and oxytocin (OT) release in response to various stimuli. To examine the site and mechanism of actions of PGs, we studied effects of PGE2 and PG-receptor agonists on supraoptic nucleus (SON) neurones of rat hypothalamic slice preparations using extracellular recording and whole-cell patch-clamp techniques. PGE2 modulated the electrical activity of more than 80% of the neurones studied. The effects of PGE2 on both phasic and non-phasic neurones were mostly excitatory, and dose-dependent. The effects of PGE2 were mimicked by PGF2alpha or the FP agonist, fluprostenol, whereas PGD2 or the selective EP, IP or TP agonist was less effective or had no effect. The effects of PGE2 were unaffected by the EP1 antagonist, SC-51322, but reduced to 80% of control by the EP1/FP/TP antagonist, ONO-NT-012, which reduced the effects of fluprostenol to 32% of control. Moreover, some neurones responsive to PGE2 did not respond to fluprostenol. Patch-clamp analysis in SON slice preparations revealed that PGE2 at 10(-6) M depolarized the membrane potential by 3.9+/-0.3 mV from the resting membrane potential of -58.4+/-2.2 mV in the current-clamp mode. In the voltage-clamp mode, PGE2 induced inward currents at a holding potential of -70 or -80 mV, while it did not affect spontaneous excitatory postsynaptic currents. PGE2 induced currents also in dissociated SON neurones and the reversal potential of the currents was -35.5+/-0.9 mV, which was similar to that of currents induced by fluprostenol. These results suggest that SON neurones possess at least two types of PG receptors, FP receptors and EP receptors of a subclass different from EP1, EP2, or EP3, and that activation of these receptors leads to the opening of nonselective cation channels, membrane depolarization and increase of the action potential discharge.
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PMID:Actions of prostaglandin E2 on rat supraoptic neurones. 987 Jul 50

We examined the effect of prostaglandin E2 (PGE2) on antidiuretic hormone (ADH)-dependent Na+ transport and cAMP production in isolated frog skin epithelium. ADH caused an increase in transepithelial Na+ transport and a decrease in cellular potential, indicating an increase in apical Na+ permeability. Subsequent addition of PGE2 decreased Na+ transport and repolarised the cells. The PGE2 receptor EP1/3-selective analogue sulprostone and the PGE2 receptor EP2/3-selective analogue misoprostol were able to mimic the effect of PGE2. ADH increased cellular cAMP levels, whereas PGE2, sulprostone and misoprostol were able to reduce the ADH-dependent cAMP production. Measurements of intracellular Ca2+ concentration ([Ca2+]i) revealed that it was unaffected by both PGE2 and sulprostone. The inhibitory effect of PGE2 on ADH-dependent Na+ transport was also observed in Ca2+-depleted epithelia. We conclude that ADH stimulates transepithelial Na+ transport by increasing cellular cAMP levels, whereas PGE2 inhibits ADH-dependent Na+ transport by activating EP3-type receptors, which decrease cellular cAMP levels. We have found no evidence that [Ca2+]i is involved in the regulation of ADH-dependent Na+ transport by PGE2.
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PMID:EP3 receptors inhibit antidiuretic-hormone-dependent sodium transport across frog skin epithelium. 992 61

The functional role and molecular mechanisms of action of prostaglandin E2 (PGE2) in the regulation of water osmotic permeability in osmoregulatory epithelia (mammalian collecting tubules and amphibian urinary bladder) are considered. The paper describes the modern classification of PGE2 receptors, their distribution along a nephron and receptor-coupled intracellular second messenger systems. The mechanism of the inhibitory action of PGE2 on the antidiuretic hormone-induced enhancement of water osmotic permeability is analyzed. Special attention is given to the role of PGE2 as an auto- or paracrine regulator of water osmotic permeability in the phenomenon of ADH-independent increase of water permeability observed in an isolated amphibian urinary bladder in replacements of the surrounding serous solution. It is concluded that the osmoregulatory epithelium is not only a place of the maximum level of PGE2 synthesis in the kidney but is also characterized by a great diversity of PGE2 receptor subtypes: EP1, EP2, EP3 and EP4 have been revealed in the mammalian collecting tubules. Such a diversity of PGE2 receptors is in a good agreement with different functional effects of PGE2 in the osmoregulatory epithelium. The data considered suggest that PGE2 is not less important in the regulation of water and ion transport in the osmoregulatory epithelium than antidiuretic hormone.
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PMID:Molecular mechanisms of action of prostaglandin E2 in the regulation of water osmotic permeability. 1077 75

The release of vasopressin and oxytocin is regulated by the electrical activity of magnocellular neurosecretory cells in the supraoptic and paraventricular nuclei, which is under the control of a great variety of neurotransmitters and neuromodulators. The major neural signals to the supraoptic nucleus are from excitatory glutamate inputs and inhibitory GABA inputs. In recent studies, the voltage-clamp mode of the whole-cell patch-clamp technique has been applied to slice preparations from rat hypothalamus to monitor synaptic inputs to supraoptic neurones. Spontaneous excitatory and inhibitory postsynaptic currents (EPSCs and IPSCs) are abolished by CNQX and picrotoxin, respectively, but are insensitive to tetrodotoxin, indicating that they represent quantal release of glutamate and GABA, respectively, from nerve terminals of presynaptic neurones. GABA and glutamate show remarkable suppressive effects on both EPSCs and IPSCs via presynaptic GABA(B) and mGlu receptors, respectively. Noradrenaline, which excites supraoptic neurones via postsynaptic alpha1-receptors, also suppresses IPSCs and potentiates EPSCs. On the other hand, prostaglandin E2, which excites supraoptic neurones via postsynaptic prostaglandin E2 (EP) receptors of the EP4 subclass, also suppresses IPSCs via EP3 receptors but has little effect on EPSCs. Thus pre- and postsynaptic mechanisms may act cooperatively to excite supraoptic neurones. Nitric oxide, which inhibits supraoptic neurones, potentiates IPSCs without affecting EPSCs. This provides another example for the preferential modulation of IPSCs of supraoptic neurones. On the other hand, PACAP, which causes a long-lasting increase in the firing frequency via the postsynaptic receptors, has no effect on EPSCs and IPSCs, suggesting that some ligands act only at postsynaptic receptors. Thus multiple patterns for pre- and postsynaptic modulation are present in the supraoptic nucleus, and the electrical activity of supraoptic neurones is regulated via complex mechanisms at both pre- and postsynaptic sites.
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PMID:Pre- and postsynaptic modulation of the electrical activity of rat supraoptic neurones. 1079 17

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