UNIPROT:P00750 - FACTA Search

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Query: UNIPROT:P00750 (PLA)
16,800 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Human mesangial cells in culture synthesize and secrete plasminogen activator inhibitor 1 (PAI-1) and tissue-type plasminogen activator (t-PA). Phorbol myristate acetate (PMA), a known activator of protein kinase C, induces a three to four-fold increase in t-PA and PAI-1 release over a period of 24 h, whereas cell-associated t-PA and PAI-1 levels remain relatively stable. A similar effect is obtained with oleylacetyl glycerol, a more physiologic protein kinase C activator. The effect of PMA is suppressed in the presence of H7, an inhibitor of cellular protein kinases, and by cycloheximide and actinomycin D, indicating a requirement for de novo protein and RNA synthesis, respectively. Northern blot analysis of PMA-treated cells reveals a rapid and transient increase in PAI-1 mRNA reaching a maximum after 4-8 h, whereas increase in t-PA mRNA levels requires 24 h. Activation of protein kinase A by addition of 8-bromocyclic AMP (8-bromo cAMP) has no significant effect on PAI-1 release but inhibits the PMA-mediated increases in PAI-1 antigen and mRNA. Addition of 8-bromo cAMP alone does not affect t-PA release. When added to PMA-stimulated cells, 8-bromo cAMP inhibits t-PA release in a dose-dependent manner, but causes a superinduction of t-PA mRNA. 8-bromo cAMP also induces a decrease in PMA-stimulated intracellular t-PA release. Similar inhibition is observed after stimulation of endogenous adenylate cyclase with prostaglandin E1 or isoproterenol. This indicates that protein kinase A activation may inhibit PMA-stimulated t-PA release via a post-transcriptional effect, e.g. inhibition of protein synthesis or activation of protein degradation. In conclusion, hormones or mediators which activate protein kinase C can stimulate t-PA and PAI-1 synthesis in human mesangial cells. Protein kinase A activation has no effect on the basal release of PAI-1 and t-PA by human mesangial cells, and, in contrast to endothelial cells, it inhibits both PMA-stimulated PAI-1 and t-PA releases. This cell-specific regulation of t-PA and PAI-1 seems to be mediated by differential transcriptional and post transcriptional mechanisms.
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PMID:Cell-specific regulation of plasminogen activator inhibitor 1 and tissue type plasminogen activator release by human kidney mesangial cells. 155 43

Tissue-type plasminogen activator (tPA) secretion is a specific response of Sertoli cells to follicle-stimulating hormone (FSH), which is lower after preincubation of the cells with low FSH concentrations because of FSH receptor/Gs protein uncoupling. In this report, we present evidence that this desensitization induced by the lowest FSH concentrations is suppressed by specific peptidic inhibitors of endogenous PKA and PKC in permeabilized Sertoli cells. In contrast, desensitization promoted by slightly higher FSH concentrations is not mediated through PKA or PKC activation but is dependent on protein neosynthesis.
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PMID:Protein kinases and protein synthesis are involved in desensitization of the plasminogen activator response of rat Sertoli cells by follicle-stimulating hormone. 792 33

Down-regulation of oncogene expression is one of the hallmarks of the process whereby transformed cells are forced into differentiation and/or growth arrest by potent inducers and therefore can represent an interim end point in cancer treatment. The differentiation inducer sodium butyrate (NaB) arrested growth of N.1 ovarian carcinoma cells and repressed expression of cyclin D1/prad1 and the invasiveness-related protease plasminogen activator-urokinase (plau). This was accompanied by the acquisition of a differentiated morphology, all of which characteristics were maintained as long as N.1 cells were exposed to the inducer. In accordance with a differentiated phenotype was the finding that fibronectin expression was increased significantly. Recently, it was shown that NaB represses the transcription factor c-myc by blocking Ca2+ signals and modulating serine threonine kinase activity. We wanted to investigate NaB-mediated interference on signals contributing to the expression on prad1, plau and growth arrest-specific 6 (gas6). Protein kinase A (PKA) inactivation de-repressed prad1 and plau transcript levels. NaB had onlygeneral but no specific influence on PKA-modulated prad1 and plau expression however. Protein kinase C activation up-regulated plau transcript levels, but not that of prad1. Prad1 expression seemed to depend on Ca2+-triggered signals. Constitutive plau expression was insensitive to additional Ca2+-mediated signals, but it became responsive upon NaB treatment.
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PMID:Genes related to growth and invasiveness are repressed by sodium butyrate in ovarian carcinoma cells. 859 56

Activation of mitogen-activated protein kinase (MAPK) results in pleiotropic effects such as modulation of the transcription and activation of enzymes involved in signal transduction. One such enzyme is the cytoplasmic phospholipase A(2) (cPLA(2)), which releases arachidonic acid (AA). AA is the precursor of prostaglandins and leukotrienes, two inflammatory mediators, which regulate gene expression and protein kinase (PK) activity. Fumonisin B(1) (FB(1)) was shown to increase PKC translocation and stimulate MAPK. We have investigated the effect of FB(1) on the AA cascade in a human epithelial cell line and the signal transduction pathway regulating PLA(2) activation. We observed that FB(1) stimulated cPLA(2) activity and increased AA release by a mechanism independent of PKC activation and that the activation of cPLA(2) is a two-step process: the first is phosphorylation of cPLA(2) by MAPK; the second is a consequence of the increase in sphingosine inside and outside the cells after 2 h, which is known to induce a rise in intracellular free calcium. Overall, this suggests that the effect of FB(1) on cells is partially dependent on the action of FB(1) on the enzymes involved in the cell cycle, such as MAPK and PKA, and on bioactive fatty acids, such as the prostaglandins and leukotrienes, and also on disruption of sphingolipid metabolism. In addition, we have observed down-regulation of cPLA(2) activity and AA metabolism by a mechanism involving prostaglandin production, cAMP synthesis and PKA activation.
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PMID:Activation of mitogen-activated protein kinase by fumonisin B(1) stimulates cPLA(2) phosphorylation, the arachidonic acid cascade and cAMP production. 1046 11

We have constructed a cell line of 3T3-L1 which can efficiently express human GHR (3T3-L1-hGHR) after differentiation to adipocytes. The expressed hGHR was detected as two bands with approximate molecular sizes of 120K by Western analysis using hGHR specific monoclonal antibody. Maximum lipolytic activity induced by hGH in the 3T3-L1-hGHR was enhanced 10-fold as compared to that in 3T3-L1, suggesting that expressed hGHR is functionally active. Comparative analysis using bGH and hGH revealed that 70% of lipolysis stimulation by 1-10 ng/ml hGH could be attributed to hGHR-mediated response. Analyses on inhibition and phosphorylation of signaling molecules suggested that GH-induced lipolysis stimulation is dependent on gene expression and not mediated through PKA-, PKC-, PLA-, PLC-, nor MAPK-pathway but possibly through JAK-STATs pathway. Duration of STAT5 activation by hGH continued up to 48 h. We also revealed that 22 K hGH isoform, 20K hGH which has been reported as a weaker agonist for GH-induced lipolysis stimulation, possesses equipotent activity and shows stronger action in the presence of hGHBP as compared to 22 K hGH. Taken together we conclude that the hGH-induced lipolysis was not mediated through MAP-, PKA-, PKC-, nor PLA-pathway but might be mediated through STAT pathway and that 20K hGH might show higher lipolytic activity than 22 K hGH in adipose tissue that produces a large amount of GHBP.
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PMID:GH induced lipolysis stimulation in 3T3-L1 adipocytes stably expressing hGHR: analysis on signaling pathway and activity of 20K hGH. 1085 5

We have previously demonstrated that Ca(2+)/calmodulin-dependent protein kinase (CaMK) mediates pyrimidinoceptor potentiation of LPS-elicited inducible nitric oxide synthase (iNOS) induction in murine J774 macrophages. In the present paper, we have explored the role of cyclo-oxygenase (COX)-dependent prostaglandin E(2) (PGE(2)) formation in this event. In J774 macrophages predominantly expressing P2Y(6) receptors, the simultaneous addition of UTP and lipopolysaccharide (LPS) resulted in potentiated increase in PGE(2) release. UTP-induced increased PGE(2) release was demonstrated by a concomitant increase in COX-2 protein expression, and was decreased by inhibitors specific for phosphatidylinositide-phospholipase C (PI-PLC), CaMK, protein kinase C (PKC), nuclear factor-kappa B (NF-kappaB) or COX-2. NS-398 (a selective COX-2 inhibitor) reduced LPS plus UTP-elicited iNOS induction and nitrite accumulation, supporting for the positive regulation of iNOS gene expression by endogenous PGE(2). Moreover, the cyclic AMP/PKA-dependent up-regulation of iNOS expression mediated by PGE(2) was drawn from the inhibitory effects of 2',5'-dideoxyadenosine, KT5720 and H-89. Exogenous PGE(2) induced NF-kappaB activation and potentiated nitrite accumulation in response to LPS. In addition to COX-2 induction, arachidonic acid (AA) release and steady-state mRNA levels of type V secretory phospholipase A(2) (sPLA(2)) and Ca(2+)-independent PLA(2) (iPLA(2)) were also increased in the presence of LPS and UTP; the LPS-induced increase in iPLA(2) activity was also potentiated by UTP. Taken together, we conclude that UTP-mediated COX-2 and iPLA(2) potentiation and PGE(2) formation contribute to the iNOS induction, and that CaMK activation is the primary step in the UTP enhancement of COX-2 induction.
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PMID:Pyrimidinoceptor potentiation of macrophage PGE(2) release involved in the induction of nitric oxide synthase. 1086 83

Considered to be an etiologic factor of acute pancreatitis, hypersecretion of pancreatic juice and digestive enzymes is often associated with hyperbilirubinemia. We explored the intracellular mechanisms through which bilirubin affects pancreatic exocrine secretory function by examining the effect of bilirubin on isolated rat pancreatic acini. Bilirubin stimulated amylase release in a concentration- and time-dependent manner, significantly increasing amylase release at concentrations >5 mg/100 ml and after 15 min of incubation. Coincubation of bilirubin with vasoactive intestinal polypeptide, 8-bromo-cAMP, or A-23187 had a synergistic effect on amylase release, whereas coincubation with CCK-8, carbamylcholine, or 12-O-tetradecanoylphorbol 13-acetate had an additive effect. Bilirubin did not affect acinar cAMP content or Ca(2+) efflux. Intracellular Ca(2+) pool depletion had no influence on bilirubin-evoked amylase release. The protein kinase C (PKC) inhibitors staurosporine and calphostin C partially but significantly inhibited bilirubin-stimulated amylase release, whereas the PKA inhibitor H-89 did not. The tyrosine kinase (TK) inhibitor genistein, phospholipase A(2) (PLA(2)) inhibitor indoxam, and PLC inhibitor U-73122 also inhibited amylase release. Bilirubin significantly translocated PKC activity from the cytosol to the membrane fraction and activated TK in cytosol and membrane fractions. These results indicate that bilirubin stimulates amylase release by activating PKC and TK in rat pancreatic acini and that PLC and PLA(2) partly mediate this process.
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PMID:Stimulatory effects of bilirubin on amylase release from isolated rat pancreatic acini. 1180 46

Several new PLA(2)s have been identified based on their nucleotide gene sequences. They were classified mainly into three groups: cytosolic PLA(2) (cPLA(2)), secretary PLA(2) (sPLA(2)), and intracellular PLA(2) (iPLA(2)). They differ from each other in terms of substrate specificity, Ca(2+) requirement and lipid modification. The questions that still remain to be addressed are the subcellular localization and differential regulation of the isoforms in various cell types and under different physiological conditions. It is required to identify the downstream events that occur upon PLA(2) activation, particularly target protein or metabolic pathway for liberated arachidonic acid or other fatty acids. Understanding the same will greatly help in the development of potent and specific pharmacological modulators that can be used for basic research and clinical applications. The information of the human and other genomes of PLA(2)s, combined with the use of proteomics and genetically manipulated mouse models of different diseases, will illuminate us about the specific and potentially overlapping roles of individual phospholipases as mediators of physiological and pathological processes. Hopefully, such understanding will enable the development of specific agents aimed at decreasing the potential contribution of individual secretary phospholipases to vascular diseases. The signaling cascades involved in the activation of cPLA(2) by mitogen activated protein kinases (MAPKs) is now evident. It has been demonstrated that p44 MAPK phosphorylates cPLA(2) and increases its activity in cells and tissues. The phosphorylation of cPLA(2) at ser505 occurs before the increase in intracellular Ca(2+) that facilitate the binding of the lipid binding domain of cPLA(2) to phospholipids, promoting its translocation to cellular membranes and AA release. Recently, a negative feed back loop for cPLA(2) activation by MAPK has been proposed. If PLA(2) activation in a given model depends on PKC, PKA, cAMP, or MAPK then inhibition of these phosphorylating enzymes may alter activities of PLA(2) isoforms during cellular injury. Understanding the signaling pathways involved in the activation/deactivation of PLA(2) during cellular injury will point to key events that can be used to prevent the cellular injury. Furthermore, to date, there is limited information available regarding the regulation of iPLA(2) or sPLA(2) by these pathways.
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PMID:Phospholipase A(2) isoforms: a perspective. 1274 26

1. In visceral smooth muscles, both M(2) and M(3) muscarinic receptor subtypes are found, and produce two major metabolic effects: adenylyl cyclase inhibition and PLCbeta activation. Thus, we studied their relevance for muscarinic cationic current (mI(CAT)) generation, which underlies cholinergic excitation. Experiments were performed on single guinea-pig ileal cells using patch-clamp recording techniques under conditions of weakly buffered [Ca(2+)](i) (either using 50 microm EGTA or 50-100 microm fluo-3 for confocal fluorescence imaging) or with [Ca(2+)](i) 'clamped' at 100 nm using 10 mm BAPTA/CaCl(2) mixture. 2. Using a cAMP-elevating agent (1 microm isoproterenol) or a membrane-permeable cAMP analog (10 microm 8-Br-cAMP), we found no evidence for mI(CAT) modulation through a cAMP/PKA pathway. 3. With low [Ca(2+)](i) buffering, the PLC blocker U-73122 at 2.5 microm almost abolished mI(CAT), in some cases without any significant effect on [Ca(2+)](i). When [Ca(2+)](i) was buffered at 100 nm, U-73122 reduced both carbachol- and GTPgammaS-induced mI(CAT) maximal conductances (IC(50)=0.5-0.6 microm) and shifted their activation curves positively. 4. U-73343, a weak PLC blocker, had no effect on GTPgammaS-induced mI(CAT), but weakly inhibited carbachol-induced current, possibly by competitively inhibiting muscarinic receptors, since the inhibition could be prevented by increasing the carbachol concentration to 1 mm. Aristolochic acid and D-609, which inhibit PLA(2) and phosphatidylcholine-specific PLC, respectively, had no or very small effects on mI(CAT), suggesting that these enzymes were not involved. 5. InsP(3) (1 microm) in the pipette or OAG (20 microm) applied externally had no effect on mI(CAT) or its inhibition by U-73122. Ca(2+) store depletion (evoked by InsP(3), or by combined cyclopiazonic acid, ryanodine and caffeine treatment) did not induce any significant current, and had no effect on mI(CAT) in response to carbachol when [Ca(2+)](i) was strongly buffered to 100 nm. 6. It is concluded that phosphatidylinositol-specific PLC modulates mI(CAT) via Ca(2+) release, but also does so independently of InsP(3), DAG, Ca(2+) store depletion or a rise of [Ca(2+)](i). Our present results explain the previously established 'permissive' role of the M(3) receptor subtype in mI(CAT) generation, and provide a new insight into the molecular mechanisms underlying the shifts of the cationic conductance activation curve.
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PMID:Phospholipase C, but not InsP3 or DAG, -dependent activation of the muscarinic receptor-operated cation current in guinea-pig ileal smooth muscle cells. 1466 35

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.
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PMID:[Calcimimetics]. 1652 Oct 71

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