EC:3.4.21.5 - FACTA Search

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

To study the effect of low-dose aprotinin on hemostasis in patients undergoing cardiopulmonary bypass (CPB) for coronary artery bypass operations and to elucidate the mechanism of aprotinin action, we randomized 14 of 27 patients to receive 30,000 KIU/kg aprotinin in the CPB priming volume and 7,500 KIU/kg aprotinin intravenously each hour during CPB (1 patient was excluded from the aprotinin group because of protamine shock). Intraoperative and postoperative blood loss was significantly reduced in the aprotinin group. Antithrombin III level was significantly decreased, and the levels of thrombin-antithrombin III complexes were significantly increased during CPB in both groups, indicating activation of the clotting system. The marked increase in fibrin(ogen) degradation products during CPB in the control group, indicating enhanced fibrinolytic activity, was significantly reduced in the aprotinin group. alpha 2-Plasmin inhibitor was significantly reduced during CPB in the control group. The marked increase in alpha 2-plasmin inhibitor-plasmin complexes in the control group, indicating plasmin activity, was significantly reduced in the aprotinin group. A marked decrease in the platelet count was observed during CPB similarly in both groups. These findings demonstrated that low-dose aprotinin administration was effective in reducing intraoperative and postoperative blood loss and that activation of the clotting system during CPB was not followed by hyperfibrinolysis in aprotinin-treated patients. The improved hemostasis is mainly attributable to the prevention of hyperfibrinolysis during CPB.
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PMID:Effect of low-dose aprotinin on coagulation and fibrinolysis in cardiopulmonary bypass. 768 19

Plasmin caused a modest and gradual increase in platelet cytosolic Ca2+, mediated through both Ca2+ mobilization and external Ca2+ entry. This response was associated with accelerated Ca2+ extrusion and protein tyrosine phosphorylation. Plasmin-enhanced external Ca2+ entry and Ca2+ extrusion (but not Ca2+ mobilization) were attenuated by the tyrosine kinase inhibitor, genistein. Plasmin inhibited the thrombin-evoked increase in cytosolic Ca2+ and also inhibited the Ca2+ response to the tethered peptide TRAP-6 of the thrombin receptor. Furthermore, plasmin inhibited the binding of 125I-labeled alpha-thrombin to platelets. The inhibitory effect of plasmin on the thrombin response shared some characteristics with the effect of protein kinase C stimulators but was not reversed by protein kinase C inhibitors. Plasmin did not change platelet cyclic nucleotides. These results suggest a dual effect of plasmin. Plasmin produces a small rise in platelet cytosolic Ca2+ and a tyrosine kinase-dependent enhancement of Ca2+ turnover (external Ca2+ influx and Ca2+ efflux). However, it also attenuates the thrombin-evoked cytosolic Ca2+ response by blocking Ca2+ mobilization and slowing the rate of external Ca2+ influx. The latter feature would result in a plasmin-induced inhibition of thrombogenesis.
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PMID:Duality of plasmin effect on cytosolic free calcium in human platelets. 773 44

The clinical relevance of determination of plasma antithrombin III(ATIII) and alpha 2-plasmin inhibitor (alpha 2 PI) activities in patients with disseminated intravascular coagulation (DIC) was analyzed. Although the plasma ATIII activity was decreased in patients with DIC, no significant correlation was observed between plasma level of ATIII and that of thrombin-antithrombin III complex or prothrombin fragment 1+2. The extent of the decrease of ATIII in DIC was the most marked in cases associated with septicemia. The plasma level of ATIII in septicemia without DIC was significantly lower than that in DIC cases without septicemia, suggesting that the decrease of ATIII level could not be related to the pathophysiology of DIC, but to that of septicemia. The plasma half-life of ATIII in septicemia without DIC was significantly shortened in the absence of the increase of TAT level, suggesting that the extravasation of ATIII might be induced probably due to the endothelial damage in septicemia. The alpha 2-Plasmin inhibitor level was decreased in DIC patients. The decrease was the most marked (lower than 60% of normal) in patients with excessive fibrinolysis in which fibrinogen degradation was induced. The plasma level of alpha 2PI was significantly higher in the DIC cases with septicemia than in those without septicemia. The ATIII/alpha 2PI ratio was significantly lower in DIC cases with septicemia than in those with solid tumor or acute leukemia. Moreover, the ATIII/alpha 2PI ratio was significantly lower in MOF cases than in non-MOF cases in septicemia. The mortality of the MOF cases did not correlate with the ATIII/alpha 2PI ratio, but with the plasma level of PAI-1, suggesting that the decrease of ATIII/alpha 2PI ratio might not reflect the irreversible endothelial cell damage. Based on these observations, the calculation of ATIII/alpha 2PI in DIC patients would provide the following information; (1) a low ATIII/alpha 2PI ratio (less than 0.6) was frequently observed in septicemia, which could be related to the occurrence of organ dysfunction; (2) a high ATIII/alpha 2PI ratio (higher than 1.0) with the marked decrease of alpha 2PI level (lower than 60% of normal) suggests the occurrence of excessive fibrinolysis in which anti-fibrinolytic therapy should be considered when clinical bleeding was present; (3) The ATIII/alpha 2PI ratio near 1.0 was observed in DIC associated with the pathological conditions other than described above, such as solid tumors, in which the coagulation and fibrinolysis was almost equally activated.
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PMID:[Clinical relevance of determination of plasma ATIII and alpha 2 PI activities in patients with DIC--application of the molecular markers for the analysis of pathophysiology of DIC]. 810 83

Atherosclerosis is an inflammatory reaction to accumulated extracellular lipid in the arterial intima. Evidence from pathological studies indicate that there is constant deposition and lysis of fibrin within the atherosclerotic arterial wall. In patients with stable peripheral atherosclerosis, the functional severity of the disease is associated with circulating fibrinogen and degradation of cross-linked fibrin reflecting procoagulant activity in the blood-vessel wall interface, or in the wall itself. In atheromas the fibrinolytic activity is connected to macrophages, which can assemble in the plasminogen-plasmin system and generate plasmin-mediated pericellular proteolysis in tissues with inflammation. Plasmin capable of activating collagenase may therefore be a candidate for plaque rupture. The nature of the exposed vascular tissue, the inflammatory state, tissue-factor dependent thrombin generation and the degree of matrix degradation regulate platelet reactivity. Little is yet known about platelet adhesive functions in proteolyzed collagens that are the underlying substrate where platelets deposit during plaque rupture, the triggering event for thrombosis. Research in these areas is likely to improve the understanding of the thrombogenicity of atheromas when the tissue is suddenly exposed to blood.
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PMID:Inflammation in atheroma: implications for plaque rupture and platelet-collagen interaction. 813 97

Plasmin, the enzyme responsible for degradation of fibrin in blood clots and thus thrombolysis, is normally formed when its zymogen plasminogen is activated by cleavage of the Arg561-Val562 bond by specific plasminogen activators. We have altered the activation characteristics of plasminogen by substituting the P3, P2, and P1' cleavage site residues with sequences from thrombin-cleavable proteins to produce a novel thrombolytic agent which instead is activated by the blood clotting system. Plasminogen variants with thrombin cleavage sites from fibrinogen, the thrombin receptor, factor XIII, and factor XI were cleaved by thrombin with times to 50% cleavage of 28 h, 2.5 h, 5.7 min, and 3 min, respectively. In vitro clot lysis studies have shown that a variant in which the P3-P1' residues of plasminogen were substituted by the P7-P1' residues (Thr363-Ile370) from factor XI (T51) was sufficiently rapidly cleaved by thrombin to be activated by the endogenous thrombin produced by the coagulation cascade, resulting in rapid clot dissolution. Thrombin-activatable plasminogen therefore has the capacity to short circuit the physiological hemostatic mechanisms and produce fibrinolytic activity localized to the site of thrombin formation, that is, at the thrombus itself. The novel activation mechanism combined with the natural long circulating half-life of plasminogen gives this type of thrombolytic agent the potential for thrombus-selective plasmin generation and an extended duration of action.
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PMID:Plasminogen mutants activated by thrombin. Potential thrombus-selective thrombolytic agents. 820 94

We have previously demonstrated that chemically modified thrombin preparations induce endothelial cell (EC) adhesion, spreading and cytoskeletal reorganization via an Arg-Gly-Asp (RGD) sequence and the alpha v beta 3 integrin. Native thrombin, however, did not exhibit adhesive properties, consistent with crystal structure analysis, showing that Gly-Asp residues of the RGD epitope are buried within the molecule. We have now identified a possible physiological mean of converting thrombin to an adhesive protein. Plasmin, the major end product of the fibrinolytic system, converted thrombin to an adhesive protein for EC in a time and dose-dependent manner. EC adhesion and spreading was also induced by a low molecular weight (approximately 3,000 D) cleavage fragment generated upon incubation of thrombin with plasmin. Cell adhesion mediated by this fragment was completely inhibited by the synthetic peptide GRGDSP. Conversion of thrombin to an adhesive molecule was significantly enhanced in the presence of heparin or heparan sulfate, while other glycosaminoglycans (GAGs) (e.g., dermatan sulfate, keratan sulfate, chondroitin sulfate) had no effect. The role of cell surface heparan sulfate in thrombin conversion to EC adhesive protein was investigated using CHO cell mutants defective in various aspects of GAG synthesis. Incubation of both thrombin and a suboptimal amount of plasmin on the surface of formaldehyde fixed wild-type CHO-KI cells resulted in an efficient conversion of thrombin to an adhesive molecule, as indicated by subsequent induction of EC attachment. In contrast, there was no effect to incubation of thrombin and plasmin with fixed CHO mutant cells lacking both heparan sulfate and chondroitin sulfate, or with cells expressing no heparan sulfate and a three-fold increase in chondroitin sulfate. A similar gain of adhesive properties was obtained upon incubation of thrombin and plasmin in contact with native, but not heparinase-treated extracellular matrix (ECM) produced by cultured ECs. It appears that cell surface and ECM-associated heparan sulfate modulate thrombin adhesive properties through its heparin binding site in a manner that enables suboptimal amounts of plasmin to expose the RGD domain. Our results demonstrate, for the first time, a significant modulation of thrombin molecule by heparin, resulting in its conversion to a potent adhesive protein for ECs. This conversion is most effective in contact with cell surfaces, basement membranes and ECM.
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PMID:Thrombin adhesive properties: induction by plasmin and heparan sulfate. 824 31

Fibrin thrombi form at sites of injury, where leukocytes release a variety of oxidants. To determine whether oxidants might affect proteins of the fibrinolytic system, we examined the effects of various oxidants on plasmin. Plasmin was not inhibited by micromolar concentrations of hypochlorous acid, chloramine T, or H2O2. Neither Fe nor Cu affected plasmin alone or in the presence of H2O2. However, incubation of plasmin with 5 mumol/L Cu(I or II) in the presence of the reducing agent ascorbic acid resulted in a loss of its hydrolytic activity towards proteins as well as towards small synthetic substrates. The addition of EDTA, but not mannitol, prevented its inactivation. Inactivation was prevented by the addition of catalase and accelerated by hydrogen peroxide. Preincubation of plasmin with the competitive inhibitor alpha-N-acetyl-L-lysine methyl ester prevented inactivation by Cu(II) and ascorbate. These results together suggest site-specific oxidation of plasmin's active site. Treatment of the plasminogen activators tissue plasminogen activator and two-chain urokinase-type plasminogen activator, as well as trypsin, neutrophil elastase, and thrombin with Cu(II) and ascorbate resulted in a loss of their amidolytic and proteolytic activity, indicating the general susceptibility of serine proteases to this type of oxidation. Oxidation of the zymogens Glu-plasminogen and single-chain urokinase-type plasminogen activator by Cu(II) and ascorbate resulted in the failure of these molecules to generate active enzymes when treated with plasminogen activators or plasmin, respectively. The active site His residue may be the target of oxidative inactivation, as evidenced by the partial protection afforded plasmin by the addition of Zn(II), histidine, or the platinum derivative, platinum(II) (2,2':6',2"-terpyridine) chloride. Because platelets contain micromolar concentrations of Cu and leukocytes are rich in ascorbate, Cu-dependent site-specific oxidation might play a role in modulating proteolytic events and the life span of thrombi formed at sites of tissue injury.
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PMID:Oxidative inactivation of plasmin and other serine proteases by copper and ascorbate. 836 3

Patients with acute myocardial infarction who undergo thrombolytic therapy may shortly thereafter present evidence for increased platelet activation and thrombin activity, and recurrent thrombosis. This study investigated whether plasmin activates platelets and prothrombin in recalcified platelet-rich plasma (RPRP) to cause (at least in part) these side-effects of thrombolytic therapy. Plasmin (0.1 and 1.0 CU/ml) addition to RPRP with microM r-tick anticoagulant peptide (the latter a factor Xa inhibitor which abrogates prothrombin activation by prothrombinase at the concentration used) resulted in no change in the concentration of prothrombin fragment 1 + 2, or in the expression of GMP-140, the resting and activated GP IIb-IIIa conformers, and GPIb on platelets. Thus, plasmin neither activates platelets nor prothrombin in RPRP. However, plasmin accelerated platelet activation and secretion, and prothrombin fragment 1 + 2 production in RPRP. When combined with 1 microM r-tick anticoagulant peptide and 1 or 10 mM alpha-thrombin to RPRP, plasmin also increased the number of GMP-140 molecules expressed/platelet without enhancing alpha-thrombin binding to the platelets. Additionally, plasmin accelerated prothrombin activation when it was added to washed platelets resuspended in factor V depleted plasma simultaneously with 10 mM CaCl2, 10 nM alpha-thrombin for 10 s (to activate platelets and platelet factor V), followed by 4 microM hirudin and 1 nM factor Xa. Thus, plasmin potentiates the platelet release reaction in response to alpha-thrombin (probably by increasing the availability of factor V on the platelets) to enhance prothrombin activation in RPRP. These actions of plasmin may contribute to the increased platelet activation and thrombotic side-effects that can occur after thrombolytic therapy.
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PMID:Plasmin accelerates platelet-dependent prothrombinase formation without activating the platelets. 860 17

We tested the hypothesis that the inhibition of thrombin-induced platelet activation by plasmin is mediated via the enzymatic action of plasmin on the functional thrombin receptor. We monitored the binding of the anti-thrombin receptor antibody [anti-TR-(34-46)] to platelets; this binding is sensitive to the cleavage of the thrombin receptor at amino acid residues Arg-41 to Ser-42. Plasmin inhibited anti-TR-(34-46) binding in dose- and time-dependent manners. The inactive synthetic peptide with the amino acid sequence 40-55 of the thrombin receptor (D-FPRSFLLRNPNDKYEPF) was similarly cleaved by thrombin and plasmin to an active peptide (SFLLRNPNDKYEPF) that produced robust cytosolic Ca2+ responses. At high concentrations, plasmin itself can activate platelets. We explored this effect with the use of anti-TR-(1-160). This antibody abolished the cytosolic Ca2+ responses to thrombin and to the thrombin receptor-activating peptide SFLLRN but did not attenuate the plasmin-induced cytosolic Ca2+ response. Thus plasmin inhibits thrombin-evoked platelet activation by cleaving the thrombin receptor, but the plasmin-induced cytosolic Ca2+ response is not due to the generation of the tethered peptide of the thrombin receptor.
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PMID:Plasmin-platelet interaction involves cleavage of functional thrombin receptor. 876 30

Insulin-like growth factor binding protein (IGFBP)-3 was exposed to plasmin, thrombin, and pregnancy serum, substances normally present at the endothelial surface in enriched concentrations. The NH2-termini of the proteolytic fragments were sequenced, and their ability to bind insulin-like growth factor (IGF) and heparin was assessed by ligand blotting. Plasmin generated at least five fragments, three beginning at the NH2-terminus of IGFBP-3 and two with NH2-termini corresponding to middle portions of IGFBP-3. The dominant fragment bound both IGF and heparin while NH2-terminal fragments bound only IGF. Thrombin generated three and serum five easily identified fragments; the dominant fragments, beginning at midportions of IGFBP-3, retained IGF and heparin affinity, whereas the remaining fragments had differential affinities for IGF and heparin. We suggest that such fragments, when generated at the endothelia surface, have the potential to alter regional vascular concentrations of IGF and thus influence both IGF and endothelial function.
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PMID:IGFBP-3 proteolysis by plasmin, thrombin, serum: heparin binding, IGF binding, and structure of fragments. 884 39

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