EC:3.1.4.3 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.1.4.3 (phospholipase C)
18,461 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The cardiovascular effects of bradykinin require additional vasoactive mediators for a fully balanced response. This includes arachidonic acid (eicosatetraenoic acid) and its metabolites, the eicosanoids (prostaglandins, leukotrienes, thromboxanes, and others). Eicosanoid generation by bradykinin is started by binding of the peptide to specific B2 receptors at the plasma membrane. This initiates G-protein coupled stimulation of phospholipase C, IP3-induced increases in cytosolic Ca2+, and stimulation of protein kinase C. Arachidonic acid is liberated from membrane phospholipids primarily via Ca(2+)-induced stimulation of phospholipase A2 and converted into tissue-specific eicosanoids by enzymes in the vicinity. In vascular tissue, most of the available arachidonic acid is converted into vasodilator prostaglandins, i.e., prostacyclin (PGI2) and prostaglandin E2 (PGE2). These prostaglandins are involved in vasodilator actions of the kinins. There is also some evidence for generation of vasoconstrictor eicosanoids, such as thromboxane A2, under certain conditions. The biological significance of kinin-related prostaglandin formation becomes apparent after inhibition of kinin breakdown by ACE inhibitors. These compounds prevent generation of vasoconstrictor angiotensin II and stimulate endothelial eicosanoid formation via local kinin accumulation. There is evidence suggesting that kinin-induced prostaglandin generation contributes to anti-ischemic, inotropic, and blood pressure-lowering effects of the compounds. This also includes inhibition of polymorphonuclear leukocyte (PMN) accumulation in injured myocardial tissue, which is antagonized by PGI2-related pathways, stimulated by ACE inhibition and/or bradykinin.
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PMID:Role of prostaglandins in the cardiovascular effects of bradykinin and angiotensin-converting enzyme inhibitors. 128 33

Endothelial cells can produce contracting factors; endothelin, a 21-amino acid peptide, is one of the most potent of these factors, which can control local vascular tone. The peptide is formed from its precursor, big endothelin, via the activity of the endothelin converting enzyme. The basal production of the peptide is stimulated by epinephrine, angiotensin II, arginine vasopressin, transforming growth factor beta, thrombin, interleukin-1 and the calcium ionophore A23187. In vascular smooth muscle cells, endothelin binds to its specific receptor (ETA-receptor and possibly ETB-receptor) which activate phospholipase C and lead to the formation of inositol trisphosphate, diacylglycerol and increased intracellular calcium levels. In certain blood vessels, the endothelin receptor is linked to voltage-operated calcium channels via a Gi-protein. This linkage may explain why calcium antagonists inhibit endothelin-induced contractions in certain, but not other blood vessels. In large conduit arteries, such as the human internal mammary artery, endothelin-induced contractions are primarily mediated by release of intracellular calcium and hence, calcium antagonists do not markedly affect the response. In contrast, in the human forearm circulation, calcium antagonists of different classes do prevent endothelin-induced contractions. Similarly, in mesenteric resistance arteries of the rat, calcium antagonists can reverse endothelin-induced contraction suggesting that calcium antagonists are particularly potent in inhibiting endothelin-induced contraction in resistance arteries, where peripheral vascular resistance and hence, blood pressure is regulated.
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PMID:Endothelin-induced vasoconstriction and calcium antagonists. 128 11

Renin-angiotensin (RA) system plays an important role in cardiovascular homeostasis. Here, we have described the recent progress in our study of renin release as well as the cellular action of angiotensin II. (1) Microdissection of an isolated afferent artery with or without macula densa (MD) has revealed that renin release is regulated by NaCl exposure to MD. Furosemide, prostaglandins (PGE2 and PGI2) and adenosine modulate its function. (2) Angiotensin (ang) II increases cytosolic free calcium and induces the formation of inositolphosphates in vascular smooth muscle cells. Deduced protein structure of ang II receptor (AT1-R) cDNA has indicated the presumed link of AT1-R with phospholipase C. Through the cellular action, ang II has been reported to regulate gene expression.
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PMID:[Mechanism of renin release and cellular action of angiotensin II]. 129 35

The neuroblastoma line SK-N-SH consists of distinct and interconverting cell types, which include a neuroblast phenotype (SH-SY5Y), an epithelial phenotype (SH-EP), and an intermediate cell type (SH-IN). In SH-SY5Y cells, only muscarinic receptor activation produced stimulation of phosphoinositide turnover, whereas in SH-EP cells, where muscarinic receptors are not present, the peptides bradykinin, endothelin, and angiotensin II stimulated phosphoinositide hydrolysis with EC50 values of 16, 6, and 0.7 nM, respectively, and a rank order of maximal effects of bradykinin greater than endothelin greater than angiotensin II. Fetal calf serum at concentrations between 1 and 10% was also a potent stimulator of phosphoinositide hydrolysis in SH-EP cells but not in SH-SY5Y cells. In the intermediate cell clone, SH-IN, phosphoinositide hydrolysis was stimulated not only by muscarinic receptors, but also by endothelin, bradykinin, and serum, an indication that this cell type harbors all the kinds of receptors that are differentially expressed in the other two cell types. The effects of the three peptides--bradykinin, endothelin, and angiotensin II--on phosphoinositide hydrolysis in SH-EP cells were additive, a result suggesting that the three kinds of receptors may activate distinct transducer proteins and/or phospholipase C subtypes. Pretreatment of intact SH-EP cells with pertussis toxin under conditions sufficient to ADP-ribosylate 90-95% of the endogenous guanine nucleotide regulatory protein substrates did not impair the ability of any of the receptors to stimulate phosphoinositide hydrolysis in any of the cell types. In contrast, short-term exposure to the phorbol ester 12-O-tetradecanoylphorbol 13-acetate (1 microM) abolished the stimulation of phosphoinositide hydrolysis mediated by peptide receptors in SH-EP cells and partially inhibited that by muscarinic receptors in SH-SY5Y cells. Prolonged incubation of SH-EP cells with phorbol ester resulted in a recovery of receptor responsiveness, the extent and rate of which were different for each receptor type. In contrast, there was no recovery of responsiveness for muscarinic receptors in SH-SY5Y cells. The pattern of phorbol ester-mediated effects depended on the cell rather than on the receptor type. In fact, muscarinic receptor responsiveness in SH-IN, the intermediate cell type, was desensitized by and recovered from treatment with phorbol esters in a manner more similar to peptide receptors in SH-EP than to muscarinic receptors in SH-SY5Y. These data suggest that the transduction mechanisms by which distinct receptor types are coupled to phosphoinositide hydrolysis in the three cell phenotypes differ in sensitivity to feedback regulation by protein kinase C.
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PMID:The epithelial phenotype of human neuroblastoma cells express bradykinin, endothelin, and angiotensin II receptors that stimulate phosphoinositide hydrolysis. 130 39

Mesangial cells possess a variety of receptors for hormones and autacoids. They are also equipped with ectoenzymes whose function may be to control the availability of autacoids and hormones at their receptor sites. Several examples are considered. Receptors for angiotensin II (AII) are present both on murine and human mesangial cells. One single group of receptors has been demonstrated in each of these preparations. Mesangial cell AII receptors are linked to phospholipase C via a G protein. They belong to the AT1 subtype because (125I)AII is displaced from its binding sites preferentially by AT1 antagonists such as DUP 753 and EXP 3,174, whereas AT2 antagonists are much less potent. AT1 antagonists suppress the biological effects of AII in mesangial cells, including the stimulation of intracellular calcium concentration and the increase of prostaglandin synthesis and of (3H)leucine incorporation. Mesangial cells also have receptors for atrial natriuretic factor, but the distribution between B receptors with guanylate cyclase activity and clearance (C) receptors varies with the species. Both types are present in murine mesangial cells, whereas only C receptors are found in human mesangial cells. In contrast, human epithelial cells possess both B and C receptors. Ecto-5'-nucleotidase activity results in the production of adenosine, which acts on mesangial cells through A1 and A2 receptors. This enzyme is markedly induced in rat mesangial cells by interleukin-1, whose effect is mediated in part by prostaglandin E2 and cAMP. Various other cAMP-stimulating agents also induce 5'-nucleotidase expression in rat mesangial cells. Ectopeptidases are present in all glomerular cell types but essentially in epithelial cells.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Cell surface receptors and ectoenzymes in mesangial cells. 131 10

Bovine adrenocortical cells from the zona fasciculata/reticularis were isolated and their phosphoinositides labelled to a steady state with [3H]inositol in primary culture. Experiments performed on these cells in the presence of Li+ have shown that, over a period of 60 min, angiotensin II (AII; 10(-7) M) stimulated a linear increase in [3H]inositol phosphates that was sustained through the utilization of two hormone-sensitive subpools of prelabelled lipid (30% and 45% respectively), and a rapid resynthesis of [3H]phosphoinositide into one of these pools using cytosolic [3H]inositol. The 30% pool was used immediately on stimulation, and was sustained at a steady-state size of 10-15% during the first 30 min of stimulation through rapid resynthesis using cytosolic [3H]inositol. Only after 30 min, when the cytosolic [3H]inositol was depleted and resynthesis could no longer occur, did the additional 45% pool start to supply further substrate to the phospholipase C, thereby further sustaining the generation of [3H]inositol phosphates. Once this pool was depleted however (by approximately 60 min), [3H]inositol phosphate generation finally ceased. These findings establish the differential use of two metabolically distinct hormone-sensitive pools of phosphoinositide following AII stimulation in bovine adrenocortical cells, events which are dependent upon the availability of cytosolic inositol for phosphoinositide resynthesis.
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PMID:Evidence for two distinct hormone-sensitive [3H]phosphoinositide pools in bovine adrenocortical zona fasciculata/reticularis cells stimulated with angiotensin II. 132 35

The intracellular mechanisms of action of alpha-MSH in rat adrenocortical cells were examined. When rat adrenal capsule (largely glomerulosa) cells were stimulated with a range of concentrations of alpha-MSH there was significant stimulation of aldosterone secretion at 10(-10) mol/l, although cyclic AMP was not increased until high concentrations of alpha-MSH were used (10(-6) mol/l and above). However, cells incubated with ACTH showed an increase in aldosterone secretion at 10(-11) mol/l and levels of cyclic AMP were elevated at 10(-9) mol ACTH/l. When rat adrenal whole capsules were incubated with alpha-MSH, membrane-bound protein kinase C (PKC) activity was increased and cytosolic enzyme activity decreased, showing PKC activation. Stimulation with angiotensin II also induced translocation of PKC activity, but ACTH did not. When [3H]inositol-loaded glomerulosa cells were stimulated with alpha-MSH there was significant generation of [3H]inositol trisphosphate (IP3) at concentrations of alpha-MSH which stimulated secretion of aldosterone. Significantly increased levels of [3H]IP3 were also measured when loaded cells were exposed to angiotensin II. ACTH did not cause any significant stimulation of [3H]IP3 production at any concentration used. These results indicate that activation of PKC and phospholipase C is important in modulating the steroidogenic effect of alpha-MSH.
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PMID:Studies on the intracellular mechanism of action of alpha-melanocyte-stimulating hormone on rat adrenal zona glomerulosa. 132 51

Endothelial cells produce the 21-amino acid peptide endothelin, which is formed from its precursor, big endothelin, via the activity of converting enzyme. The basal production of the peptide is stimulated by epinephrine, angiotensin II, arginine vasopressin, transforming growth factor beta, thrombin, interleukin-1, and hypoxia. In vascular smooth muscle, endothelin binds to a specific receptor (ETA-subtype), which activates phospholipase C, leads to the formation of inositol trisphosphate, diacylglycerol (which activates protein kinase C), and increased intracellular Ca2+. In certain blood vessels, the endothelin receptor on vascular smooth muscle is linked to a voltage-operated Ca2+ channel via a G-protein. This explains why Ca2+ antagonists inhibit endothelin-induced contractions in certain, but not all, blood vessels. In the human forearm circulation, Ca2+ antagonists do prevent endothelin-induced contractions and unmask endothelin-induced vasodilation mediated by endothelial prostacyclin production (via the ETB-receptor). The pulmonary circulation plays an important role in the metabolism of endothelin, as the lungs take up large quantities of the peptide during passage. Endothelin has profound vasoconstrictor effects in the pulmonary circulation (and also in bronchial tissue), and its production is augmented in pulmonary hypertension. In systemic hypertension, the circulating endothelin levels appear to be normal. In atherosclerosis and other forms of vascular disease, circulating endothelin levels are increased. Thus, endothelin is a potent mediator in the systemic and pulmonary circulation and, in particular, in diseases of the vasculature.
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PMID:Endothelin: systemic arterial and pulmonary effects of a new peptide with potent biologic properties. 133 60

The effects of low density lipoprotein (LDL) and high density lipoprotein (HDL3) on second messenger systems were investigated in cultured human vascular smooth muscle cells (VSMC) and compared with those of angiotensin II (Ang II) and platelet-derived growth factor (PDGF-BB). Phosphoinositide metabolism was studied in myo-[2-3H]-inositol prelabelled VSMC using high performance liquid anion-exchange chromatography. The spectra of inositol phosphate isomers increased after stimulation with either Ang II, LDL, HDL3 or PDGF-BB were qualitatively identical. Major increases occurred in 4-IP1, 1,4-IP2, 1,3,4-IP3 and 1,3,4,5-IP4. These are metabolic conversion products of 1,4,5-IP3 for which only a minor increase was found. Thus lipoproteins, like Ang II and PDGF-BB, activate polyphosphatidylinositol-specific phospholipase C. Intracellular Ca2+ concentrations ([Ca2+]i) were studied in fura-2 loaded VSMC. In monolayer cultures LDL and HDL3 increased [Ca2+]i with kinetics comparable to those for Ang II. Relative to the effects of these agonists, the PDGF-BB-induced increase in [Ca2+]i was slower in onset and the decay from peak [Ca2+]i levels more gradual. Fluorescence recordings from single cells exposed to LDL and HDL3 revealed a prolonged series of transient oscillations of [Ca2+]i, a phenomenon typical for calcium-mobilizing hormones. Additionally, as found for Ang II, preincubation of VSMC with either phorbol 12-myristate, 13-acetate, forskolin or 8-bromo-cyclic GMP inhibited LDL- and HDL-induced accumulation of [3H]-inositol monophosphate. We propose that LDL and HDL3 stimulate signal transduction in VSMC via mechanisms analogous to those of Ca(2+)-mobilizing hormones.
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PMID:Phosphoinositide and calcium signalling responses in smooth muscle cells: comparison between lipoproteins, Ang II, and PDGF. 133 16

Renal proximal tubule sodium reabsorption is enhanced by apical or basolateral angiotensin II (AII). Although AII activates phospholipase C (PLC) in other tissues, AII coupling to PLC on either apical or basolateral surfaces of proximal tubule cells is unclear. To determine if AII causes PLC activation, and the differences between apical and basolateral AII receptor function, receptors were unilaterally activated in rat proximal tubule cells cultured on permeable, collagen-coated supports. Apical AII incubation resulted in concentration- and time-dependent inositol trisphosphate (IP3) formation. Basolateral AII caused greater IP3 responses. Apical AII-induced IP3 generation was inhibited by DuP 753, suggesting that the type 1 AII receptor subtype mediated proximal tubule PLC activation. Apical AII signaling did not result from paracellular ligand leak to basolateral receptors since AII-induced PLC activation occurred when basolateral AII receptors were occupied by Sar-Leu AII or DuP 753. Inhibition of endocytosis with phenylarsine oxide prevented apical (but not basolateral) AII-induced IP3 formation. Cytoskeletal disruption with colchicine or cytochalasin D also prevented apical AII-induced IP3 generation. These results demonstrate that in cultured rat proximal tubule cells, AII is coupled to PLC via type 1 AII receptors and cytoskeleton-dependent endocytosis is required for apical (but not basolateral) AII receptor-mediated PLC activation.
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PMID:Cytoskeleton-dependent endocytosis is required for apical type 1 angiotensin II receptor-mediated phospholipase C activation in cultured rat proximal tubule cells. 133 76

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