EC:3.1.4.1 - FACTA Search

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Query: EC:3.1.4.1 (phosphodiesterase)
18,767 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Intact human platelets loaded with 32PO4 contain multiple phosphorylated proteins. Thrombin treatment of intact 32PO4-loaded platelets results in a 2-6-fold increase in phosphorylation of a platelet protein (designated "peak 7" protein) of approximately 40,000 mol wt as determined by sodium dodecyl sulfate polyacrylamide gel electrophoresis and by gel filtration on Sephadex G-150. A similar increase in phosphorylation was observed in a platelet protein (designated "peak 9" protein) of approximately 20,000 mol wt. The time for half-maximal phosphorylation of peak 7 and peak 9 protein was 10-14 s. The concentration of thrombin at half-maximal phosphorylation was 0.25 U/ml for both proteins. Prior incubation of platelets with dibutyryl cyclic adenosine 3',5'-monophosphate or prostaglandin E1 inhibited thrombin-induced peak 7 and peak 9 protein phosphorylation. The erythroagglutinating phytohemagglutinin of Phaseolus vulgaris, a non-proteolytic release-inducing agent, induced peak 7 and peak 9 protein phosphorylation. Thus, the characteristics of peak 7 and peak 9 protein phosphorylation are similar to those of the platelet release reaction, suggesting that the phosphorylation of these proteins may play a role in the platelet release reaction. When platelet sonicates or the supernatant fraction from platelet sonicates were incubated with [gamma-32P]ATP there was phosphorylation of both peak 7 and peak 9 proteins. This phosphorylation was unaffected by either added thrombin or adenosine 3',5'-cyclic monophosphate (cAMP) despite the presence of the phosphodiesterase inhibitor 1-methyl-3-isobutylxanthine. Thus, the thrombin-dependent phosphorylation depends upon intact platelets. When the supernatant fraction from platelet sonicates was fractionated by histone-Sepharose affinity chromatography, two distinct protein kinase enzymes were resolved, one a cAMP-dependent holoenzyme and the other a cAMP-independent enzyme. The isolated cAMP-dependent enzyme fraction catalyzed the cAMP-(but not thrombin-) stimulated phosphorylation of a protein that co-electrophoresed with peak 7 protein.
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PMID:Thrombin-induced protein phosphorylation in human platelets. 16 98

Thrombin rapidly induces the formation of labeled phosphatidic acid from platelets prelabeled with [17C]arachidonate or 32PO34- and specifically decreases by 50--75% the content of phosphatidylinositol. Ionophore A23187 also stimulates phosphatidate labeling, but less effectively than thrombin. This effect on phosphatidic acid is blocked by increasing the levels of cyclic AMP by preincubation with dibutyryl cyclic AMP, cyclic AMP-phosphodiesterase inhibitors or prostacyclin. Indomethacin and eicosatetraynoic acid do not alter the production of phosphatidate, indicating independence from cyclooxygenase or lipoxygenase products. Increased turnover of [14C]- or [32P]phosphatidate occurs within 2--5 s after platelet activation by thrombin and is observed before endogenous, 14C-labeled arachidonate can be detected. The rate of phosphatidate formation parallels the induced rate of serotonin release. Release of [3H]serotonin is not affected by eicosatetraynoic acid. Phosphatidate production reflects the generation of diacylglycerol by C-type phospholipase degradation of phosphatidylinositol. Diacylglycerol and phosphatidic acid may participate in the membrane modification related to the early changes in platelet shape, release reactions or aggregation which occur on stimulation.
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PMID:Stimulation of phosphatidic acid production in platelets precedes the formation of arachidonate and parallels the release of serotonin. 37 88

Thrombin is thought to stimulate responsive cells by cleaving cell-surface receptors coupled to intracellular second-messenger-generating enzymes via G-proteins. In order to understand this process better, we have examined the regulation of adenylate cyclase by thrombin in the megakaryoblastic HEL cell line and compared it with platelets. A notable difference was found. In HEL-cell membrane preparations, thrombin inhibited cyclic AMP (cAMP) formation by a pertussis-toxin-sensitive mechanism comparable with that observed in platelets. In contrast, when added to intact HEL cells, thrombin activated adenylate cyclase and caused an increase in cAMP formation synergistic with that produced by forskolin and prostaglandin I2. This increase, which was not seen with platelets, was accompanied by an increase in cAMP metabolism by phosphodiesterase. Like other responses to thrombin, the increase in cAMP formation required proteolytically active thrombin and was subject to homologous desensitization. An equivalent response could be evoked by the addition of a polypeptide, derived from the N-terminus of the thrombin receptor, that has been shown to activate the receptor. The effects of thrombin could not, however, be reproduced by the addition of phorbol ester and the Ca2+ ionophore, A23187, nor be prevented with inhibitors of arachidonate metabolism. Preincubation of the cells with adrenaline, which inhibited Gs-mediated activation of adenylate cyclase, or pertussis toxin, which inhibited phospholipase C activation, had no effect on thrombin-induced cAMP formation. These results suggest that thrombin can regulate cAMP formation by two different mechanisms. First, thrombin can inhibit adenylate cyclase in a Gi-dependent manner. This effect predominates in HEL-cell membrane preparations, as it does in platelets, but is not detectable when thrombin is added to intact HEL cells. Instead, in intact HEL cells thrombin activates adenylate cyclase. Although clearly receptor-mediated, this response does not appear to involve Gi, Gs, protein kinase C, eicosanoid formation or changes in the cytosolic Ca2+ concentration.
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PMID:Dual regulation of cyclic AMP formation by thrombin in HEL cells, a leukaemic cell line with megakaryocytic properties. 131 10

Thrombin-induced platelet aggregation was inhibited in vitro by washed human neutrophils. Aggregation was inhibited in a neutrophil concentration dependent manner but glutaraldehyde fixed neutrophils had no significant effect on platelet aggregation. The neutrophil-derived inhibitory factor had the pharmacological profile of nitric oxide. Its action was potentiated by both superoxide dismutase and M&B22, 948, a selective cyclic guanosine monophosphate (cyclic GMP) phosphodiesterase inhibitor. Haemoglobin lessened this inhibitory action of neutrophils. L-Arginine, the substrate for nitric oxide formation, enhanced inhibition, whereas, L-canavanine, a structural analogue of L-arginine, prevented it. Nitric oxide release by neutrophils antagonized platelet ATP secretion and thromboxane B2 release. Inhibition was mediated by nitric oxide activation of guanylate cyclase with a subsequent rise in cyclic GMP. When neutrophils were stimulated with formyl-met-leu-phe, there was a further increase in platelet cyclic GMP. This was enhanced by superoxide dismutase, but lessened by haemoglobin. Leukotriene B4 stimulation of neutrophils promoted inhibition of platelet aggregation. Leukotriene B4 alone had no direct effect on thrombin-induced aggregation of platelets. Platelets, when incubated with neutrophils and stimulated with calcium ionophore A23187, increased leukotriene B4 production by neutrophils in a platelet concentration dependent manner. Platelets alone were unable to release leukotriene B4. The action of platelets in haemostasis is modified as they come into contact with neutrophils. This may be an important physiological mechanism.
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PMID:Platelet aggregation is inhibited by a nitric oxide-like factor released from human neutrophils in vitro. 185 Oct 34

Endothelial cells (EC) secrete platelet-derived growth factor (PDGF)-like protein, which is a potent mitogen to smooth muscle and connective tissue cells. The purpose of this study was to determine if amrinone, a phosphodiesterase inhibitor, could inhibit PDGF-like protein secretion on the basis of its ability to increase cAMP. Human umbilical artery endothelial cells (HUAEC) (n = 7) were preincubated for 4 h with amrinone (10 micrograms/mL) before coincubation with thrombin (10 IU/mL) and amrinone (10 micrograms/mL) for 18 h. The supernatant was then assayed for the presence of both PDGF-like protein by using a competitive 125I-PDGF radioreceptor inhibition assay, and cAMP by using an RIA. Thrombin-induced PDGF-like protein secretion from HUAEC was significantly inhibited by amrinone (7.8 +/- 1.6 fmol/10(6) EC) when compared with thrombin alone (12.1 +/- 2.4 fmol/10(6) EC) (p less than 0.05). Amrinone alone had no effect on baseline PDGF-like protein secretion. Amrinone inhibition of thrombin-induced PDGF-like protein secretion was comparable whether amrinone was added to HUAEC 4 or 0 h before thrombin, and it was dose dependent with a maximal inhibition of 82.7% by amrinone (160 micrograms/mL). In contrast, IL-1 alpha (10 micrograms/mL) and tumor necrosis factor (100 ng/mL) induced less secretion of PDGF-like protein from HUAEC, and this secretion was not inhibited by amrinone. Amrinone (10 micrograms/mL) significantly increased secretion of cAMP from HUAEC from a baseline value of 6.4 +/- 0.4 pmol/10(6) EC to 10.6 +/- 0.1 pmol/10(6) EC (p less than 0.01). We conclude that amrinone inhibits thrombin-induced PDGF-like protein secretion from HUAEC.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Effects of amrinone on thrombin-induced platelet-derived growth factor-like protein secretion from endothelial cells. 195 18

The adenylate-cyclase activator forskolin, the guanylate-cyclase stimulator sodium nitroprusside, the phosphodiesterase inhibitor Ro 15-2041, different Ca-entry blockers, as well as various vasodilators, and the atrial natriuretic peptide were tested for antiplatelet activity. Thrombin, vasopressin, ADP, arachidonic acid, and the dihydropyridine Ca agonist CGP 28392 were used as platelet activators. The physiological and biochemical parameters of platelet function studied included shape-change reaction, intracellular free-Ca modulation, and cyclic nucleotide formation. When inhibition of the shape-change response occurred, it was accompanied by inhibition of the increase in intracellular free Ca. Furthermore, the results suggest a possible intracellular site of action of Ca entry blockers in platelets, and confirm the importance of modulation of cyclic nucleotides in the regulation of platelet function, regardless of the mechanism of platelet activation. Additional antiplatelet activity of antihypertensive agents may have a beneficial effect in reducing the associated risk of thrombo-embolic complications in essential hypertension.
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PMID:Vasodilating agents and platelet function: intracellular free calcium concentration, cyclic nucleotides, and shape-change response. 243 9

Thrombin inhibits adenylate cyclase and stimulates GTP hydrolysis by high-affinity GTPase(s) in membranes of human platelets at almost identical concentrations. Both of these thrombin actions are similar to those observed with agonist-activated alpha 2-adrenoceptors coupling to the inhibitory guanine nucleotide-binding protein N1. However, stimulation of GTP hydrolysis caused by adrenaline (alpha 2-adrenoceptor agonist) and by thrombin at maximally effective concentrations was partially additive, whereas with regard to adenylate cyclase inhibition no additive response was observed. Furthermore, treatment of platelet membranes with pertussis toxin, which inactivates Ni and largely abolishes thrombin- and adrenaline-induced adenylate cyclase inhibition and adrenaline-induced GTPase stimulation, decreased the thrombin-induced stimulation of GTP hydrolysis by only about 30%. Additionally, the thiol reagent N-ethylmalemide (NEM) at rather low concentrations abolished thrombin- and adrenaline-induced stimulation of GTP hydrolysis was decreased by only 30-40% by treatment of platelet membranes with even high concentrations of NEM. Treatment with cholera toxin, which inhibits GTPase activity of the Ns (stimulatory guanine nucleotide-binding) protein, has no effect on thrombin-stimulated GTP hydrolysis. The data suggest that thrombin interaction with its receptor sites in platelet membranes leads to stimulation of two GTP-hydrolysing enzymes. One of these enzymes is apparently Ni and is also activated by agonist-activated alpha 2-adrenoceptors and is inactivated by pertussis toxin and NEM treatment. The other GTP-hydrolysing enzyme activated by thrombin may represent a guanine nucleotide-binding protein apparently involved in the coupling of thrombin receptors to the phosphoinositide phosphodiesterase.
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PMID:Evidence for two GTPases activated by thrombin in membranes of human platelets. 302 30

Despite their physicochemical and mechanistic differences platelet activating factor (or acetylglycerylether phosphorylcholine; AGEPC) and thrombin, both platelet stimulatory agents, induce phosphoinositide turnover in platelets. We therefore investigated the stimulation of the phosphoinositide phosphodiesterase by these agents and questioned whether they evoked hydrolysis of the same or different pools of phosphoinositides. [3H]Inositol-labelled rabbit platelets were challenged with thrombin and/or AGEPC under a variety of protocols, and the phospholipase C mediated production of radioactive inositol monophosphate (IP); inositol bisphosphate (IP2) and inositol trisphosphate (IP3) was used as the parameter. AGEPC (1 X 10(-9) M) caused a transient maximum (5 to 6-fold) increase in [3H]IP3 at 5 s followed by a decrease. Thrombin (2 U/ml) elicited an increase in [3H]IP3 at a much slower rate than AGEPC; 2 fold at 5 s, 5 fold at 30 s and a maximum 6 to 8-fold at 2-5 min. Compared to AGEPC, thrombin stimulated generation of [3H]IP2 and [3H]IP were severalfold higher. When thrombin and AGEPC were added together to platelets there was no evidence for an additive increase in inositol polyphosphate levels except at earlier time points where increases were submaximal. When AGEPC was added at various time intervals after thrombin pretreatment, no additional increases in [3H]IP3 were observed over that maximally seen with thrombin or AGEPC alone. In another set of experiments, submaximal increases (about 1/4 and 1/2 of maximum) in [3H]IP3 were achieved by using selected concentrations of thrombin (0.1 U and 0.3 U, respectively) and then AGEPC (1 X 10(-9) M) was added for 5 s. Once again the increase in [3H]IP3 was close to the maximal level seen with thrombin or AGEPC individually. It is concluded that thrombin and AGEPC differentially activated phosphoinositide phosphodiesterase (phospholipase C) in rabbit platelets and that the stimulation of the phospholipase C by these two stimuli causes IP3 production via hydrolysis of a common pool of phosphatidylinositol 4,5-bisphosphate.
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PMID:Activation of phospholipase C in platelets by platelet activating factor and thrombin causes hydrolysis of a common pool of phosphatidylinositol 4,5-bisphosphate. 303 49

The present data disagree with earlier suggestions that thrombin's effect on platelets is to cause a decrease in intracellular cyclic 3',5'-adenosine monophosphate. Washed human platelets or platelet-rich plasma were incubated at 37 degrees C with human thrombin. After centrifugation, the supernates were assayed for nucleotides and calcium released. The platelet pellets, and in some experiments the supernates as well, were assayed by radioimmunoassay for intracellular cyclic AMP. In the washed platelet system, increasing doses of thrombin to 0.5 U/cc induced increasing release of nucleotides and calcium. This was accompanied by an average twofold increase in intracellular cyclic AMP levels. Prostaglandin E(1), which inhibited 30-50% of release, induced a four- to fivefold increase in cyclic AMP levels that was additive to the cyclic AMP-stimulatory effect of thrombin. Theophylline, which inhibited only 20-40% of nucleotide release, was synergistic with thrombin in the intracellular accumulation of cyclic AMP. The time-course of cyclic AMP accumulation in response to thrombin was slower than thrombin-induced nucleotide release. Similar findings were made in the platelet-rich plasma system where thrombin stimulation of nucleotide release also resulted in a marked accumulation of intracellular cyclic AMP. Thrombin did not appear to stimulate the release of intracellular cyclic AMP. The mechanism underlying these observations was not apparent. The thrombin had no measurable inhibitory effect on platelet phosphodiesterase activity in either intact washed cells or the platelet homogenate supernates. Furthermore, thrombin inhibited, rather than stimulated, platelet adenyl cyclase activity in both intact washed cells and washed platelet particulate fractions. Of note, however, was the finding that thrombin did not completely inhibit the adenyl cyclase activity of prostaglandin-stimulated cells. Further work is needed to clarify the significance of this observation.Nonetheless, the accumulation of intracellular cyclic AMP in response to thrombin observed in the present study suggests that the antagonistic actions of various agents on the platelet release reaction, thought to underlie platelet function, may depend upon a mechanism more intricate than a straightforward mediation through directly opposite effects on platelet cyclic AMP.
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PMID:Thrombin-induced increase in intracellular cyclic 3',5'-adenosine monophosphate in human platelets. 434 94

An analysis of prostaglandin-stimulated adenosine 3',5'-cyclic monophosphate (cyclic AMP) accumulation in cultured human umbilical vein endothelial cells showed prostacyclin (PGI2) to be the most potent agonist followed by prostaglandin (PG)H2, which was more potent than PGE2, while PGD2 was essentially inactive. The endothelial cells studied apparently have a high rate of cyclic AMP phosphodiesterase activity because significant PGI2-mediated increases in cyclic AMP could not be shown in the presence of the phosphodiesterase inhibitor isobutylmethylxanthine (MIX). Endoperoxide PGH2-stimulation of cyclic AMP accumulation was inhibited 75--80% by the prostacyclin synthetase inhibitors 12-hydroperoxyeicosatetraenoic acid or 9,11-azoprosta-5,13-dienoic acid. These data indicate that the PGH2-stimulation is due primarily to conversion to PGI2. The beta-adrenergic agonist L-isoproterenol stimulated cyclic AMP accumulation in the endothelial cells. This accumulation was completely blocked by propranolol. However, stimulation of cyclic AMP accumulation by the beta-adrenergic agent did not equal that induced by PGI2. Furthermore, the PGI2 response could not be blocked by propranolol. Thrombin-stimulated PGI2 biosynthesis was attenuated by PGE1 or isoproterenol in the presence of MIX. MIX alone was less effective than a combination of PGE1 or isoproterenol plus MIX. These data suggest two potential effects of PGI2 biosynthesis by endothelial cells: first, the PGI2 can elevate cyclic AMP in platelets, and second, endothelial cell cyclic AMP can be elevated as well, so that subsequent PGI2 synthesis will be attenuated.
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PMID:Regulation of endothelial cell cyclic nucleotide metabolism by prostacyclin. 625 64

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