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Query: UNIPROT:P00750 (
PLA
)
16,800
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The extracellular
Ca(2+)-sensing receptor
(CaR) responds to polycations, including Ca(2+) and neomycin. This receptor is a physiological regulator of systemic Ca(2+) metabolism and may also mediate the toxic effects of hypercalcemia. A number of divalent cations, including Pb(2+), Co(2+), Cd(2+), and Fe(2+), are toxic to the kidney, brain, and other tissues where the CaR is expressed. To determine which divalent cations can activate the CaR, we expressed the human CaR in HEK-293 cells and measured activation of phospholipase A(2) (
PLA
(2)) and the mitogen-activated protein kinase p42ERK in response to potential agonists for the receptor. HEK-293 cells expressing the nonfunctional mutant CaR R796W served as controls. Extracellular Ca(2+), Ba(2+), Cd(2+), Co(2+), Fe(2+), Gd(3+), Ni(2+), Pb(2+), and neomycin activated the CaR, but Hg(2+) and Fe(3+) did not. We analyzed the kinetics of activation of p42ERK and
PLA
(2) by the CaR in response to Ca(2+), Co(2+), and Pb(2+). The EC(50) values ranged from approximately 0.1 mM for Pb(2+) to approximately 4.0 mM for Ca(2+). The Hill coefficients were >3, indicating multiple cooperative ligand binding sites or subunits. Submaximal concentrations of Ca(2+) and Pb(2+) were additive for activation of the CaR. The EC(50) for Ca(2+) or Pb(2+) was reduced four- to fivefold by the presence of the other ion. These divalent cations also activated
PLA
(2) via the CaR in Madin-Darby canine kidney cells that stably express the CaR. We conclude that many divalent cations activate the CaR and that their effects are additive. The facts that the CaR is a promiscuous polycation sensor and that the effects of these ions are additive to activate it suggest that the CaR may contribute to the toxicity of some heavy metals such as Pb(2+), Cd(2+), Co(2+), and Fe(2+) for the kidney and other tissues where it is expressed.
...
PMID:Extracellular Ca(2+)-sensing receptor is a promiscuous divalent cation sensor that responds to lead. 1109 27
The
Ca(2+)-sensing receptor
(CaR) stimulates a number of phospholipase activities, but the specific phospholipases and the mechanisms by which the CaR activates them are not defined. We investigated regulation of phospholipase A(2) (
PLA
(2)) by the
Ca(2+)-sensing receptor
(CaR) in human embryonic kidney 293 cells that express either the wild-type receptor or a nonfunctional mutant (R796W) CaR. The
PLA
(2) activity was attributable to cytosolic
PLA
(2) (cPLA(2)) based on its inhibition by arachidonyl trifluoromethyl ketone, lack of inhibition by bromoenol lactone, and enhancement of the CaR-stimulated phospholipase activity by coexpression of a cDNA encoding the 85-kDa human cPLA(2). No CaR-stimulated cPLA(2) activity was found in the cells that expressed the mutant CaR. Pertussis toxin treatment had a minimal effect on CaR-stimulated arachidonic acid release and the CaR-stimulated rise in intracellular Ca(2+) (Ca(2+)(i)), whereas inhibition of phospholipase C (PLC) with completely inhibited CaR-stimulated PLC and cPLA(2) activities. CaR-stimulated PLC activity was inhibited by expression of RGS4, an RGS (Regulator of G protein Signaling) protein that inhibits Galpha(q) activity. CaR-stimulated cPLA(2) activity was inhibited 80% by chelation of extracellular Ca(2+) and depletion of intracellular Ca(2+) with EGTA and inhibited 90% by treatment with W7, a calmodulin inhibitor, or with KN-93, an inhibitor of Ca(2+), calmodulin-dependent protein kinases. Chemical inhibitors of the ERK activator, MEK, and a dominant negative MEK, MEK(K97R), had no effect on CaR-stimulated cPLA(2) activity but inhibited CaR-stimulated ERK activity. These results demonstrate that the CaR activates cPLA(2) via a Galpha(q), PLC, Ca(2+)-CaM, and calmodulin-dependent protein kinase-dependent pathway that is independent the ERK pathway.
...
PMID:The Ca2+-sensing receptor activates cytosolic phospholipase A2 via a Gqalpha -dependent ERK-independent pathway. 1127 41
The action of extracellular calcium on the
calcium receptor
in parathyroid cells results in activation of phospholipase C (PLC), PLD, and
PLA
(2). The
PLA
(2)-arachidonic acid (AA) intracellular signaling pathway mediates inhibition of parathyroid hormone (PTH) secretion. In addition, stimulation of the
calcium receptor
produces increases in intracellular calcium levels. It was demonstrated that high extracellular phosphate levels reduce the production of AA, a mechanism by which phosphate may stimulate PTH secretion. The objective was to determine, in parathyroid tissue, whether AA production is stimulated by increases in intracellular calcium levels and to investigate whether the decreased AA production induced by high extracellular phosphate levels could be modified by increases in intracellular calcium levels. Experiments were performed in vitro using parathyroid tissue. The intracellular calcium level was increased by incubation with an ionophore (A23187), which increases calcium influx across the cell membrane, or thapsigargin, which releases calcium from intracellular stores. The phosphate concentration in the medium was normal (1 mM) or high (4 mM). The response to calcium was evaluated by incubation with 0.6 or 1.35 mM calcium concentrations. AA production by parathyroid tissue was measured by gas chromatography. In parathyroid tissue incubated with either a calcium ionophore or thapsigargin, there was an increase in AA production, together with inhibition of PTH secretion, suggesting that
PLA
(2) is activated by the elevation in intracellular calcium levels. Therefore, the effect of intracellular calcium level elevation on AA production in the presence of high extracellular phosphate levels was evaluated. The results demonstrate that, despite high phosphate levels in the medium, both the ionophore and thapsigargin were capable of inducing a marked increase in AA production, which was associated with a decrease in PTH secretion. In conclusion, in parathyroid tissue, AA levels can be regulated by an ionophore and thapsigargin, both of which increase cytosolic calcium concentrations. The stimulation of PTH secretion by high phosphate levels can be prevented by increases in intracellular calcium levels.
...
PMID:Regulation of arachidonic acid production by intracellular calcium in parathyroid cells: effect of extracellular phosphate. 1185 73
Current therapy for secondary hyperparathyroidism in uremia has relatively poor success in achieving the target levels of parathyroid hormone (PTH), calcium and phosphate established by the NKF-K/DOQI guidelines. The discovery and characterization of a new membrane receptor able to sense minimal Ca changes (
CaSR
) started intensive research in the attempt to characterize better its functions and its finding compounds, which could modulate its activity.
CaSR
is expressed not only in the cells that secrete calcium-regulating hormones (parathyroid cells and thyroid C-cells) and in cells involved in calcium transport mechanisms (ie intestinal cells, bone-forming osteoblasts, and cells of different nephron segments), but also in other tissues with, as yet, a not completely defined role.
CaSR
stimulation by the agonists is followed by the activation of a great number of G-proteins mediated intracellular signalling pathways (PLC,
PLA
, PLD, PKC, PKA, etc). At the level of parathyroid cells, the main effect is the increase in IP3, followed by a mobilization of intracellular Ca stores, which inhibit PTH secretion in a few seconds or minutes. Long-term
CaSR
stimulation is also able to induce a reduction in both PTH synthesis and parathyroid cell proliferation. More than 100 mutations of the gene coding for
CaSR
have been described. Some of these mutations are matched by a gain or reduction/loss of function. Notwithstanding,
CaSR
is widely represented on different tissue cells, the main clinical manifestations of the above genetic changes mainly involve PTH and calcium metabolism. A great number of inorganic and organic cations can interact with the Ca-sensitive N-terminus domain of
CaSR
, mimicking Ca effects (type I calcimimetics), but these substances have substantial limitations for use in clinical practice. A second class of compounds was produced (NPS R-467, S-467, R-568, S-568, AMG 073), for use in the clinical setting, type II calcimimetics. These compounds, after having interacted with the membrane-spanning domains of the
CaSR
, induce conformational changes in the N-terminus domain, increasing its affinity for Ca. The preclinical experiences with calcimimetics demonstrated that they were effective in reducing circulating PTH, preventing the progression of secondary hyperparathyroidism, suppressing parathyroid cell proliferation, and reversing osteitis fibrosa at least in animal models. Clinical studies were performed mainly using AMG 073, due to its greater bioavailability and more consistent pharmacokinetic profile. Clinical studies performed in primary hyperparathyroidism proved AMG 073 to be effective in reducing both PTH and Ca serum levels, with a good safety profile. Further studies, mainly focused on the efficacy of AMG 073 in the control of secondary hyperparathyroidism in uremia, confirmed the efficacy of this compound in reducing PTH levels >30% in about 50% of patients. Furthermore, the fall in PTH was matched by a reduction in both calcium and phosphate serum levels of about 5-7%, with a significant reduction in calcium x phosphate product (about 15%). The latter aspect represents a unique pharmacological profile, as compared to all the other available therapeutic means to control secondary hyperparathyroidism in uremia. In addition to their effectiveness, calcimimetics present a relatively safe profile, the only adverse events referred to consist of transient and easily remediable hypocalcemic episodes and some gastrointestinal discomfort symptoms. However, although calcimimetics represent a real advancement in the field of treating secondary hyperparathyroidism in uremic patients, their use should be matched by the awareness that previously the success of a high number of new drugs proposed have been flawed by negative consequences in the long term. Therefore, strict clinical control is necessary in the next few years when the use of these new compounds will widen.
...
PMID:[Calcimimetics]. 1652 Oct 71
The perivascular sensory nerve (PvN)
Ca(2+)-sensing receptor
(CaR) is implicated in Ca(2+)-induced relaxation of isolated, phenylephrine (PE)-contracted mesenteric arteries, which involves the vascular endogenous cannabinoid system. We determined the effect of inhibition of diacylglycerol (DAG) lipase (DAGL), phospholipase A(2) (
PLA
(2)), and cytochrome P-450 (CYP) on Ca(2+)-induced relaxation of PE-contracted rat mesenteric arteries. Our findings indicate that Ca(2+)-induced vasorelaxation is not dependent on the endothelium. The DAGL inhibitor RHC 802675 (1 microM) and the CYP and
PLA
(2) inhibitors quinacrine (5 microM) (EC(50): RHC 802675 2.8 +/- 0.4 mM vs. control 1.4 +/- 0.3 mM; quinacrine 4.8 +/- 0.4 mM vs. control 2.0 +/- 0.3 mM; n = 5) and arachidonyltrifluoromethyl ketone (AACOCF(3), 1 microM) reduced Ca(2+)-induced relaxation of mesenteric arteries. Synthetic 2-arachidonoylglycerol (2-AG) and glycerated epoxyeicosatrienoic acids (GEETs) induced concentration-dependent relaxation of isolated arteries. 2-AG relaxations were blocked by iberiotoxin (IBTX) (EC(50): control 0.96 +/- 0.14 nM, IBTX 1.3 +/- 0.5 microM) and miconazole (48 +/- 3%), and 11,12-GEET responses were blocked by IBTX (EC(50): control 55 +/- 9 nM, IBTX 690 +/- 96 nM) and SR-141716A. The data suggest that activation of the CaR in the PvN network by Ca(2+) leads to synthesis and/or release of metabolites of the CYP epoxygenase pathway and metabolism of DAG to 2-AG and subsequently to GEETs. The findings indicate a role for 2-AG and its metabolites in Ca(2+)-induced relaxation of resistance arteries; therefore this receptor may be a potential target for the development of new vasodilator compounds for antihypertensive therapy.
...
PMID:Cytochrome P-450 metabolites of 2-arachidonoylglycerol play a role in Ca2+-induced relaxation of rat mesenteric arteries. 1837 19
