Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:3.4.21.5 (thrombin)
 33,306 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

When human 125I-labeled Factor Xa is incubated with washed platelets, prothrombin, and Ca2+, a small amount of thrombin is formed which causes the platelet release reaction after a period of time that decreases as the Xa concentration is increased from 0.9 to 19 ng/ml. After a further lag period, the Xa binds reversibly to receptors on the platelet surface and rapid thrombin formation follows (3 units or 1 mug of thrombin formed per min per ng of Xa bound to 10(8) platelets). When platelets are treated with either htrombin (0.5 units/ml) or calcium ionophore A23187 prior to addition of Xa, binding begins immediately. Thrombin formation occurs at the platelet surface at rates that correlate with the amount of Xa bound. Dibutyryl cyclic AMP inhibits the release reaction, Xa binding, and rate of thrombin generation in parallel. The platelet Xa receptor is distinct from the previously described thrombin receptor and appears to be a protein because treatment of platelets with thrombin at 50 units/ml destroys Xa binding sites. The results suggest that specific receptors for Xa appear on the platelet surface after the release reaction occurs. The bound Xa catalyzes thrombin formation 1000-fold faster than does Xa added to reactions in which phospholipids are substituted for platelets.
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PMID:Interaction of coagulation factor Xa with human platelets. 33 55

Factor D, when preincubated with platelet suspensions, at concentrations as low as 1.2 micrograms/ml, inhibited thrombin-induced platelet aggregation. No inhibition of collagen or arachidonic acid-induced platelet aggregation was found. Inhibition occurred, but to a lesser extent, when thrombin and factor D were added to platelets at the same time. No inhibition occurred when factor D was added after thrombin. Thrombin was able to overcome inhibition by factor D by increasing its concentration. Diisopropyl-phosphorofluoridate-inactivated factor D also inhibited thrombin-induced platelet aggregation so that enzymatic activity of factor D was not required for inhibition. Factor D absorbed with hirudin coupled to Sepharose 6B showed no decrease in inhibitory capacity. 125I-Factor D bound to platelets in a manner suggesting an equilibrium reaction similar to thrombin. At low factor D input, binding was linear, whereas at higher input, binding began to approach saturation. Binding of 125I-labeled thrombin to platelets was inhibited by factor D. Analysis of these data show that factor D does not alter the total number of thrombin molecules which bind to the platelet surface at saturation. However, the dissociation constant for thrombin is altered from 2.78 to 6.90 nM in the presence of factor D (20 micrograms/ml). Factor D is thus a competitive inhibitor of thrombin binding, although the affinity of factor D for the platelet thrombin receptor is much less than that of thrombin. These phenomena occur at physiologic concentrations of factor D. Therefore, factor D may function in vivo as an inhibitor of platelet aggregation.
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PMID:Properdin factor D: effects on thrombin-induced platelet aggregation. 46 86

In this study we have explored the interaction of thrombin with platelets from human and rat. Compared to human platelets, rat platelets suspended in plasma required a higher concentration of thrombin for aggregation. This difference in sensitivity to thrombin was maintained when platelets were washed and suspended in buffer. Platelets from both mammals bound thrombin and showed a similar number of binding sites. However, the apparent dissociation constant of thrombin binding for rat platelets was approximately 15-fold higher than that for human. Thus, the decreased aggregation response of rat platelets may be due to a reduced binding of thrombin to its receptor. It is known that the thrombin receptor is located on the platelet surface. Gel electrophoresis of platelets followed by specific staining as well as fluorography showed significant differences in the surface glycoproteins of human and rat platelets. Human platelets showed labeled components corresponding to 210,000 and 160,000 daltons, whereas rat platelets showed glycoproteins with molecular weights of 240,000 and 190,000. A 135,000-dalton component was present in platelets from both sources. These results suggest that either or both glycoproteins of 210,000 and 160,000 daltons may be involved in the interaction of thrombin with human platelets.
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PMID:Interaction of thrombin with mammalian platelets. 47 73

Thrombin binds with high affinity to specific cell-surface receptors on washed human platelets. We present experiments indicating that thrombin binding correlates withe the release reaction when binding is perturbed by anions. Marked differences in the affinity of human 125I-thrombin for platelets wer observed in various isotonic buffers at pH 7.4. At low concentrations of thrombin (0.001-0.01 U/ml), binding was 5-fold greater in Tris-sodium acetate and 12-fold greater in Tris-sodium cacodylate than in Tris-sodium chloride. These anion-induced changes in 125I-thrombin binding paralleled changes in [14C] serotonin release when both parameters were measured in the same platelets. Thus, equivalent release occurred for equal amounts of thrombin bound in all buffers, even though the thrombin concentration varied by up to 30-fold. After approximately 100 molecules of thrombin bound per platelet, complete release occurred in all buffers in 2 min. The effect of anions was specific for the thrombin-receptor interaction as there was no corresponding effect on the binding of erythroagglutinating phytohemagglutinin (E-PHA) to platelets nor on E-PHA or collagen-induced serotonin release. The various anions did not alter platelet morphology as judged by electron microscopy. The anions had no effect on thrombin esterase catalytic activity. In addition, the total number of thrombin receptors per platelet was approximately the same in all buffers. Thus anions alter the affinity between platelet thrombin receptors and a site on thrombin distinct from the catalytic site. We conclude that the thrombin receptor is essential for thrombin-induced platelet reactions.
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PMID:The perturbation of thrombin binding to human platelets by anions. 115 95

We wished to determine whether the metabolism of arachidonic acid, through lipoxygenase and cytochrome P-450 pathways, is involved in production of endothelium-derived relaxing factor(s) (EDRFs) in canine femoral veins. Veins were removed from anesthetized dogs and cut into rings. Endothelium was deliberately removed from some rings. In separate sets of experiments, rings were incubated with either AA861 (10(-5) M) or TMK777 (10(-6) M), inhibitors of 5-lipoxygenase, nordihydroguaiaretic acid (NDGA 3 x 10(-6) M), an inhibitor of lipoxygenase or proadifen (SKF 525A, 10(-6) M), an inhibitor of cytochrome P-450. In addition, some rings were incubated with a combination of indomethacin (10(-5) M) and NG-monomethyl-L-arginine (L-NMMA 10(-4) M) or, where appropriate, a solvent control. Concentration-response curves were obtained for acetylcholine, adenosine diphosphate, thrombin, A23187, and nitric oxide in rings contracted with a submaximal concentration of prostaglandin F2 alpha. AA861 and TMK777 did not alter endothelium-dependent relaxations to the agonists, whether with or without indomethacin and L-NMMA. However, indomethacin plus L-NMMA reduced endothelium-dependent relaxations to thrombin. These results suggest that metabolism of arachidonic acid, through lipoxygenase and cytochrome P-450 pathways, does not produce an EDRF in veins. However, thrombin receptor-activated relaxations are mediated in part by products of the cyclooxygenase pathway and nitric oxide.
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PMID:Role of lipoxygenase and cytochrome P-450 in production of endothelium-derived relaxing factors in canine femoral veins. 127 84

Thrombin not only plays an important role in thrombosis and haemostasis but may also be involved in other pathological situations such as the progression of atherosclerotic plaque formation, inflammatory response and neurodegenerescence. It is therefore important to be able to control the action and/or the generation of this enzyme. With this aim in view, a great number of synthetic or recombinant direct thrombin inhibitors have recently been made. They block either the thrombin catalytic site or an anion-binding exosite which is a recognition site for some of its substrates (fibrinogen, thrombin receptor, thrombomodulin, heparin cofactor II) or act on both sites. Some of these inhibitors have revealed a number of advantages over heparin in experimental animal models of thrombosis and haemorrhagic risk. On-going clinical studies with some candidates will establish their real interest for patients.
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PMID:Direct thrombin inhibitors. 130 May 40

We recently isolated a cDNA clone encoding a functional platelet thrombin receptor that defined a unique mechanism of receptor activation. Thrombin cleaves its receptor's extracellular amino terminal extension, unmasking a new amino terminus that functions as a tethered peptide ligand and activates the receptor. A novel peptide mimicking this new amino terminus was a full agonist for platelet secretion and aggregation, suggesting that this unusual mechanism accounts for platelet activation by thrombin. Does this mechanism also mediate thrombin's assorted actions on non-platelet cells? We now report that the novel thrombin receptor agonist peptide reproduces thrombin-induced events (specifically, phosphoinositide hydrolysis and mitogenesis) in CCL-39 hamster lung fibroblasts, a naturally thrombin-responsive cell line. Moreover, these thrombin-induced events could be recapitulated in CV-1 cells, normally poorly responsive to thrombin, after transfection with human platelet thrombin receptor cDNA. Our data show that important thrombin-induced cellular events are mediated by the same unusual mechanism of receptor activation in both platelets and fibroblasts, very likely via the same or very similar receptors.
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PMID:Thrombin-induced events in non-platelet cells are mediated by the unique proteolytic mechanism established for the cloned platelet thrombin receptor. 130 20

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

Platelet activation by thrombin plays a critical role in hemostasis and thrombosis. Based on structure-activity studies of a cloned platelet thrombin receptor, we designed two "mirror image" antagonists of thrombin and thrombin receptor function. First, "uncleavable" peptides mimicking the receptor domain postulated to interact with thrombin were found to be potent thrombin inhibitors. Second, proteolytically inactive mutant thrombins designed to bind but not cleave the thrombin receptor were found to be specific antagonists of receptor activation by thrombin. The effectiveness of these designed antagonists in blocking thrombin-induced platelet activation suggests a model for thrombin-receptor interaction and possible strategies for the development of novel antithrombotic agents.
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PMID:"Mirror image" antagonists of thrombin-induced platelet activation based on thrombin receptor structure. 131 Jun 95

The mechanism by which thrombin induces neurite retraction was studied in NB2a mouse neuroblastoma cells. The rapid effect of thrombin (completed within minutes) appears to involve an interaction between its anion-binding exosite and the thrombin receptor. Structural alterations of this site increase the EC50 for thrombin-mediated retraction, and a hirudin C-terminal peptide that blocks this site inhibits the response. The thrombin effect was mimicked by a 14 amino acid peptide starting with Ser-42, at the proposed cleavage site of the human thrombin receptor. The protein kinase inhibitors staurosporine and H-7 blocked thrombin-induced retraction. It is therefore proposed that thrombin-mediated neurite retraction is caused by cleavage-induced activation of the thrombin receptor and involves stimulation of a protein kinase(s).
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PMID:Thrombin causes neurite retraction in neuronal cells through activation of cell surface receptors. 131 Aug 64


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