EC:3.1.4.3 - FACTA Search

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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)

Angiotensin II (AII) is a major regulator of aldosterone synthesis and secretion by the adrenal zona glomerulosa. Although it has been suggested by many authors that AII acts by increasing the turnover of inositol-lipids, these studies were mainly focussed on the identity and on the kinetics of appearance of inositol phosphates. The purpose of the present study was to establish a relationship between phospholipase C activation and steroidogenesis in the adrenal cortex. A primary culture of bovine adrenal glomerulosa cells was used. Dose-response curves for receptor occupation, inositol phosphate production and aldosterone secretion were made under the same experimental conditions, on the third day of culture. 125I-[Sar1, Val5, D-Phe8]AII binding to glomerulosa cells was progressively inhibited by increasing concentrations of AII up to 30 nM. Scatchard analyses showed a Kd of 1.9 +/- 1.1 nM and a maximal binding capacity of 49,000 +/- 4,500 receptors/cell (six experiments). Dose-response curves for AII-induced inositol 1,4,5-trisphosphate production showed an EC50 of 0.5 +/- 0.1 nM (five experiments). The threshold dose for AII-induced inositol phosphates was around 0.1 nM and the maximal effect was obtained with 30 nM AII. The AII-stimulated steroidogenesis occurred at a threshold dose around 0.03 nM and the maximal effect was obtained with 10 nM AII with an EC50 of 0.5 +/- 0.1 nM (five experiments). These results support previous suggestions that phospholipase C is involved in the steroidogenic action of angiotensin II.
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PMID:Implication of phospholipase C in the steroidogenic action of angiotensin II. 217 98

Previous studies have shown that external calcium (Ca2+) is required for the effects of angiotensin II (AII) on aldosterone secretion in adrenal glomerulosa zone. Using bovine adrenal glomerulosa cells prepared by collagenase dispersion, we examined whether external Ca2+ is required for the activation of phospholipase C by AII. Adrenal glomerulosa cells were exposed to Ca-EGTA buffered media to provide accurate estimates of external free Ca2+ concentrations. Phospholipase C activation was evaluated by measurement of inositol phosphates production. At 0.1 microM Ca2+ and less, sustained AII effects on inositol monophosphate (IP), inositol bisphosphate (IP2) and inositol trisphosphate (IP3) were markedly inhibited. Increasing the Ca2+ concentration to 50 microM or greater fully restored AII-induced inositol phosphates production. AII-induced increases in cytosolic Ca2+ measured by Quin-2 fluorescence, were diminished at lower external Ca2+ concentrations. Treating adrenal glomerulosa cells with Chelex-100, a strong Ca2+ binding resin, blocked early activation of phospholipase C by AII. Inhibition of IP3 production was also observed when inhibitors of Ca2+ movement across the plasma membrane were used, viz., La2+, TMB-8 and nifedipine. The requirement for Ca2+ during AII-induced activation of phospholipase C may be explained, at least partly by a requirement for Ca2+ at a site between the AII receptor and Phospholipase C.
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PMID:External calcium is required for activation of phospholipase C by angiotensin II in adrenal glomerulosa cells. 236 56

When rat adrenal whole capsules, containing the zona glomerulosa, were incubated, addition of the protein kinase C inhibitors TMB-8 (10 mumol/l), W7, H7, polymyxin-B and sphingosine (all 1 mumol/l) was found to inhibit the steroidogenic response to trypsin. Aldosterone and 18-hydroxycorticosterone were strongly, and corticosterone moderately, affected, while the production of 18-hydroxydeoxy-corticosterone was neither stimulated by trypsin nor inhibited by the protein kinase C inhibitors. Addition of neomycin, which prevents substrate interaction with phospholipase C, also inhibited the response to trypsin, while addition of phospholipase C itself stimulated aldosterone, 18-hydroxycorticosterone and corticosterone production with the same tissue sensitivity as trypsin. Addition of phospholipase A2 had no effect. Direct assay of protein kinase C activity showed that trypsin stimulation effected the translocation of Ca2+/phospholipid-activated protein kinase C from the cytosolic to the membrane fraction. When glomerulosa tissue was incubated with [32P]ATP, and cytosolic proteins were subjected to isoelectric focusing on polyacrylamide gels, autoradiography showed that incorporation of 32P into several protein components was increased by trypsin stimulation. It was concluded that trypsin exerts its stimulatory effects on steroidogenesis by activating protein kinase C; not, however, by generating the Ca2+/phospholipid-independent fragment, but possibly by enhancing the activity of phospholipase C.
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PMID:Trypsin stimulation of aldosterone and 18-hydroxycorticosterone production by rat adrenal zona glomerulosa tissue is mediated by activation of protein kinase C. 239 25

Angiotensin II (AII) in adrenal glomerulosa cells activates phospholipase C resulting in the formation of inositol phosphates and diacylglycerol rich in arachidonic acid (AA). Although glomerulosa cells can metabolize AA via cyclooxygenase (CO), this pathway plays little role in aldosterone synthesis. Recent evidence suggests that the lipoxygenase (LO) pathway may be important for hormonal secretion in endocrine tissues such as the islet of Langerhans. However, the capacity of the glomerulosa cell to synthesize LO products and their role in aldosterone secretion is not known. To study this, the effect of nonselective and selective LO inhibitors on AII, ACTH, and potassium-induced aldosterone secretion and LO product formation was evaluated in isolated rat glomerulosa cells. BW755c, a nonselective LO inhibitor dose dependently reduced the AII-stimulated level of aldosterone without altering AII binding (91 +/- 6 to 36 +/- 4 ng/10(6) cells/h 10(-4) M, P less than 0.001). The same effect was observed with another nonselective LO blocker, phenidone, and a more selective 12-LO inhibitor, Baicalein. In contrast U-60257, a selective 5-LO inhibitor did not change the AII-stimulated levels of aldosterone (208 +/- 11% control, AII 10(-9) M vs. 222 +/- 38%, AII + U-60257). The LO blockers action was specific for AII since neither BW755c nor phenidone altered ACTH or K+-induced aldosterone secretion. AII stimulated the formation of the 12-LO product 12-hydroxyeicosatetraenoic acid (12-HETE) as measured by ultraviolet detection and HPLC in AA loaded cells and by a specific RIA in unlabeled cells (501 +/- 50 to 990 +/- 10 pg/10(5) cells, P less than 0.02). BW755c prevented the AII-mediated rise in 12-HETE formation. In contrast, neither ACTH nor K+ increased 12-HETE levels. The addition of 12-HETE or its unstable precursor 12-HPETE (10(-9) or 10(-8) M) completely restored AII action during LO blockade. AII also produced an increase in 15-HETE formation, but the 15-LO products had no effect on aldosterone secretion. These studies suggest that the 12-LO pathway plays a key role as a new specific mediator of AII-induced aldosterone secretion.
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PMID:Specific action of the lipoxygenase pathway in mediating angiotensin II-induced aldosterone synthesis in isolated adrenal glomerulosa cells. 282 67

The plasma-membrane receptors, coupling mechanisms, and effector enzymes that mediate target-cell activation by angiotensin II (AII) have been characterized in rat and bovine adrenal glomerulosa cells. The AII holoreceptor is a glycoprotein of Mr approximately 125,000 under non-denaturing conditions. Photoaffinity labeling of AII receptors with azido-AII derivatives has shown size heterogeneity among the AII binding sites between species and target tissues, with Mr values of 55,000 to 79,000. Such variations in molecular size probably reflect differences in carbohydrate content of the individual receptor sites. The adrenal AII receptor, like that in other tissues, is coupled to the inhibitory guanine nucleotide inhibitory protein (Ni). However, studies with pertussis toxin have shown that stimulation of aldosterone production by AII is not mediated by Ni but by a pertussis-insensitive nucleotide regulatory protein of unidentified nature. Although Ni is not involved in the stimulatory action of AII on steroidogenesis, it does mediate the inhibitory effects of high concentrations of AII upon aldosterone production. The actions of AII on adrenal cortical function are thus regulated by at least two guanine nucleotide regulatory proteins that are selectively activated by increasing AII concentrations. The principal effector enzyme in AII action is phospholipase C, which is rapidly stimulated in rat and bovine glomerulosa after AII receptor activation. AII-induced breakdown of phosphatidylinositol bisphosphate (PIP2) and phosphatidylinositol phosphate (PIP) leads to formation of inositol 1,4,5-trisphosphate (IP3) and inositol 1,4-bisphosphate (IP2). These are metabolized predominantly to inositol-4-monophosphate, which serves as a marker of polyphosphoinositide breakdown, whereas inositol-1-phosphate is largely derived from phosphatidylinositol hydrolysis. The AII-stimulated glomerulosa cell also produces inositol 1,3,4-trisphosphate, a biologically inactive IP3 isomer formed from Ins-1,4,5-trisphosphate via inositol tetrakisphosphate (IP4) during ligand activation in several calcium-dependent target cells. The Ins-1,4,5-P3 formed during AII action binds with high affinity to specific intracellular receptors that have been characterized in the bovine adrenal gland and other AII target tissues, and may represent the sites through which IP3 causes calcium mobilization during the initiation of cellular responses.
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PMID:Angiotensin II receptors and mechanisms of action in adrenal glomerulosa cells. 282 11

Results on the effects of peptides on the phospholipid metabolism and steroid and cyclic AMP (cAMP) outputs of rat adrenal capsular cells (96% zona glomerulosa, 4% zona fasciculata) were obtained in a series of three batch experiments. Their significance was examined by analysis of variance. Incorporation of [32P] into phosphatidylcholine, phosphatidic acid and phosphatidylinositol was measured. Production of [3H]inositol-1 monophosphate, inositol-1,4 bisphosphate and inositol-1,4,5 tris-phosphate was estimated after prelabelling with [3H]inositol followed by 1 min incubation with a steroidogenic stimulus. Angiotensin II (0.25 nmol/l to 0.25 mumol/l) highly significantly (P less than 0.01) stimulated aldosterone and corticosterone outputs, [32P] incorporation into phosphatidic acid and phosphatidylinositol (but not into phosphatidylcholine) and the production of the three [3H]inositol phosphates. Aldosterone and corticosterone outputs were stimulated by alpha-MSH (above 0.1 nmol/l). However, incorporation of [32P] was not significantly increased until 10 mumol alpha-MSH/l but, unlike with angiotensin II, incorporation into phosphatidylcholine was also then stimulated. Also, the production of the inositol phosphates was not increased significantly (P greater than 0.05) by any dose of alpha-MSH (10 nmol/l, 1 mumol/l and 0.1 mmol/l) used. Therefore, it can be concluded that alpha-MSH does not stimulate phospholipase C in rat zona glomerulosa cells. In further experiments, it was also found that there were significant increases in cAMP as well as in steroid outputs above 1 nmol alpha MSH/l (highly significant above 10 nmol alpha-MSH/l). There were plateaux of the outputs of both steroids and cAMP from 0.1 to 1 mumol alpha-MSH/l. However, there were further increases in steroid and cAMP outputs of the capsular cells at higher doses. Concomitant results on the stimulation of corticosterone output by zona fasciculata-reticularis cells indicate that this additional increase was mostly due to the stimulation of the contaminating zona fasciculata cells. It was also confirmed that alpha-MSH preferentially stimulates steroidogenesis by the zona glomerulosa. However, under our conditions, alpha-MSH highly significantly increased the output of cAMP by both zona fasciculata and glomerulosa cells.
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PMID:Effects of alpha-melanocyte-stimulating hormone on the cyclic AMP and phospholipid metabolism of rat adrenocortical cells. 302 Jan 42

We have previously demonstrated that if C62B glioma cells are prelabeled with [1-14C]arachidonate, cholinergic stimulation results in liberation of radioactive arachidonate and accumulation of radioactive phosphatidate. Cells prelabeled with [2-3H]inositol and stimulated with acetylcholine in the presence of 25 mM LiCl accumulate glycerophosphoinositol and inositol phosphates. The acetylcholine-stimulated accumulation of these products is indicative of activation of both phospholipases A2 and C. When prelabeled cells are pretreated overnight with dexamethasone prior to acetylcholine stimulation, there is preferential inhibition of those products dependent upon phospholipase A2 activity (arachidonate and glycerophosphoinositol accumulation are inhibited 77 and 63%, respectively). During the same time period when phospholipase A2-dependent products are accumulating, there is little effect on the production of phospholipase C-dependent products (acetylcholine-stimulated accumulation of phosphatidate or of inositol phosphates was inhibited by less than 10%). Treatment of C62B cells with two other glucocorticoids, betamethasone and cortisone, produced results similar to those of dexamethasone as did treatment with quinacrine, a phospholipase A2-selective inhibitor. Pretreatment of C62B cells with the mineralocorticoid, aldosterone, did not alter acetylcholine-stimulated response. These results suggest that glucocorticoid treatment results in a preferential inhibition of phospholipase A2 with little effect on the generation of phospholipase C products.
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PMID:Glucocorticoids inhibit the liberation of arachidonate but not the rapid production of phospholipase C-dependent metabolites in acetylcholine-stimulated C62B glioma cells. 311 43

1. The receptor-activated mechanisms that mediate the steroidogenic actions of angiotensin II (AII) have been characterized in rat and bovine adrenal glomerulosa cells. In rat adrenal cells, the AII receptor is coupled to a guanine nucleotide inhibitory protein which reduces adenylate cyclase activity and cyclic AMP production. However, receptor-mediated stimulation of aldosterone production by AII is exerted through a separate pertussis-insensitive nucleotide regulatory protein that subserves coupling of activated receptors to phospholipase C. 2. In AII-stimulated glomerulosa cells, hydrolysis of phosphatidylinositol (4,5)-bisphosphate (PIP2) by phospholipase C yields diacylglycerol and inositol 1,4,5-trisphosphate (Ins-P3), which act as second messengers by activating calcium-calmodulin and calcium-phospholipid dependent protein kinase pathways. Ins-1,4,5-P3 is a potent stimulus of intracellular calcium mobilization, and is promptly inactivated by two major routes of metabolism. Direct degradation of Ins-1,4,5-P3 by a 5-phosphatase gives inositol 1,4-bisphosphate which in turn is metabolized to inositol-4-monophosphate. The latter product can be derived only from higher inositol phosphates, and thus serves as a specific marker of polyphosphoinositide breakdown in agonist-stimulated cells. In contrast, inositol-1-phosphate is largely derived from phosphatidylinositol hydrolysis, which is not increased during the initial phase of AII action. 3. Ins-1,4,5-P3 formed in AII-stimulated glomerulosa cells is also phosphorylated by a calcium-calmodulin dependent 3-kinase to form inositol 1,3,4,5-tetrakisphosphate (Ins-P4), which is rapidly dephosphorylated to the biologically inactive Ins-1,4,5-P3 isomer, Ins-1,3,4-trisphosphate. The latter metabolite, like Ins-1,4,5-P3, is both degraded to lower phosphates (Ins-3,4,P2 and Ins-1,3-P2) and phosphorylated to form a new tetrakisphosphate isomer (Ins-1,3,4,6-P4). Ins-1,4,5-P3 formed during AII action is bound with high affinity to specific intracellular receptors through which InsP3 causes calcium mobilization during the initiation of cellular responses to AII and other calcium-dependent ligands.
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PMID:Control of glomerulosa cell function by angiotensin II: transduction by G-proteins and inositol polyphosphates. 315 62

The stimulation of phosphoinositide metabolism by angiotensin II (Ang II) was studied in [3H]inositol-labelled bovine adrenal glomerulosa cells. After separation of the phosphoinositols by ion-exchange high-performance liquid chromatography, it was shown that the formation of inositol 1,4,5-trisphosphate (Ins(1,4,5)P3) and inositol 1,3,4-trisphosphate (Ins(1,3,4)P3) followed distinct kinetics. The first compound to increase upon stimulation with 10(-7) M Ang II was Ins(1,4,5)P3, which reached a maximum (250% of basal level) within 10 s. At lower concentrations of Ang II, this response was slower. The formation of Ins(1,4,5)P3 depended upon the concentration of Ang II, with an EC50 of 2.4 +/- 1.5 X 10(-9) M Ang II. The potency of Ang II in stimulating the turnover of phosphoinositides and in increasing the biosynthesis of aldosterone was very similar, whereas the peptide was ten times more potent in its ability to mobilize Ca2+. Ang II was also able to stimulate the production of Ins(1,4,5)P3 in permeabilized glomerulosa cells. This effect was mimicked by a non-hydrolysable analog of GTP (GTP gamma S), suggesting that a GTP binding protein is involved in the mechanism coupling the Ang II membrane receptor to phospholipase C. These results strengthen the view that Ins(1,4,5)P3 plays a key role as second messenger in the steroidogenic response to Ang II in adrenal glomerulosa cells.
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PMID:Inositol trisphosphate isomers in angiotensin II-stimulated adrenal glomerulosa cells. 326 Dec 66

Regulation of aldosterone secretion is complex both in terms of the number of secretagogues that can influence its biosynthesis and the number of second messengers utilized by these secretagogues (Table 1, Figure 1). ACTH primarily acts via the adenylate cyclase system through a stimulatory G protein; however, there is evidence that at low concentration it may also activate calcium influx and phospholipase C in some species. The primary effect of AII is activation of phospholipase C, which increases both calcium release from intracellular stores and calcium flux across the cell membrane and activates protein kinase C. Potassium depolarizes the membrane, thereby activating calcium flow through voltage-dependent calcium channels. It also directly or indirectly causes release of calcium from intracellular binding sites. A small change in cAMP levels may also be involved in the sustained secretory response to potassium. Species variation in the regulation of aldosterone secretion probably exists; the control mechanisms in the human appear to be closer to those in the rat than to those in cow and sheep. How changes in dietary sodium and potassium modify aldosterone secretion and the adrenal's responsiveness to secretagogues remains unclear. Yet these effects may be of considerable importance, both in terms of understanding the overall regulation of aldosterone secretion and in resolving the discrepancies in the results obtained under different experimental conditions.
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PMID:Regulation of aldosterone secretion. 328 99

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