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)

Detailed haemostatic changes were investigated during eight liver transplantations. The patients were divided into two groups; group 1 had minor operative bleeding (four cases) and group 2 had major bleeding (four cases). Group 2 had lower levels of platelets, fibrinogen, factor V (FV), and alpha 2-antiplasmin than group 1, and the thromboelastography showed fibrinolysis. In both groups, plasma tissue-plasminogen activator levels rose slightly. After revascularization of the graft liver, reductions in the values of PT, fibrinogen, FV and FVII were noted, along with a prolongation of the PTT and an increase in thrombin-antithrombin III complex levels. Plasma levels of protein C, protein S, antithrombin III, and plasminogen remained relatively stable throughout the operation. These results show that the preceding fibrinolysis and subsequent superimposed activation of the clotting system are the main causes of coagulopathy during liver transplantation, which correlate with the amount of operative haemorrhage and the abnormalities found in haemostatic tests.
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PMID:Coagulation disorder during liver transplantation. 177 95

Thrombin has both beneficial and harmful effects. In order of importance, at very low concentrations, alpha-thrombin firstly amplifies its own generation through the activation of factors V and VIII, which are the primary targets of antithrombotic agents. It secondly functions at the cellular level where, at low concentrations it activates platelets, and at higher concentrations, induces endothelial cell changes (e.g., shape changes, albumin transport release of plasminogen activators and other substances). It thirdly converts fibrinogen into clottable fibrin and becomes actively incorporated into the forming thrombus. In addition, it activates protein C, which in turn degrades factors V and VIII (and/or their activated forms) and causes the shutdown of thrombin generation. When compared to other serine proteinases of the blood coagulation and fibrinolytic systems, alpha-thrombin is unique in that it loses most of its proenzyme activation fragment and has developed multisite short-ranged bridge-binding interactions, which appear to explain thrombin specificity. To understand thrombin is to understand haemostasis.
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PMID:Thrombin structure and function: why thrombin is the primary target for antithrombotics. 177 99

A simulation model for the production of thrombin in plasma is presented. Values of the reaction rate constants as determined in purified systems are used and the model is tested by comparison of simulations of factor Xa, factor Va and thrombin generation curves with experimental data obtained in thromboplastin-activated plasma. Simulations of the effect of hirudin indicate that factor V is predominantly activated by thrombin and not by factor Xa. The model predicts a threshold value for the factor Xa production which, if exceeded, results in explosive and complete activation of prothrombinase. The dependence of this threshold value on different negative feedback reactions, e.g. the inactivation of thrombin and factor Xa by antithrombin III (+ heparin), is investigated. The threshold value, for control plasma in the range of 1-10 pM total factor Xa production, can be raised two orders of magnitude by accelerated inactivation of factor Xa and prothrombinase but is hardly affected by a tenfold increase in the rate of thrombin inactivation or by increased production of activated protein C. This latter effect, however, results in a more gradual input-response relation between factor Xa input and the extent of prothrombinase activation.
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PMID:Simulation model for thrombin generation in plasma. 179 46

A simple model of the initiation of thrombin formation in plasma as a response to factor Xa generation was constructed. In this model factor Xa is considered as an input with a constant concentration. Substrate depletion and inactivation by activated protein C are neglected. The resulting linear model allows a closed form solution by standard methods. With values of the reaction rate constants, as determined in purified systems, this model predicts a highly explosive and complete activation of factor V and prothrombin as a response to any given (steady state) factor Xa concentration even in situations where prothrombinase and(/or) thrombin are rapidly inactivated. However, the time delay to rapid thrombin production becomes longer at lower factor Xa concentrations. Analysis of this time delay as a function of the factor Xa concentration indicates that the gain of the feedback loop of factor V activation by thrombin is so high that the contribution of factor V activation by factor Xa is relatively unimportant for factor Xa concentrations in the nanomolar range. It appears that the time lag is mainly determined by the gain of this feedback loop: similar proportional reductions of each of these reaction rates causes a similar effect. The effects of moderately enhanced inhibition rates of thrombin and prothrombinase on the time delay depend strongly on factor Xa concentration. Only a minor prolongation of the delay is predicted for factor Xa concentrations in the nanomolar range, but for factor Xa concentrations in the 1-10 pM range, the enhanced decay will cause considerable delays. Simultaneous reduction of the turnover rate of prothrombinase results in much larger delays for the entire range of factor Xa concentrations.
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PMID:Linearized model for the initiation of factor Va, and thrombin generation. 179 50

The effect of sera and purified IgG isolated from plasma of 46 patients with systemic lupus erythematosus (SLE) and 9 healthy donors on the endothelial cell (EC) mediated protein C activation was investigated. Out of the 46 SLE sera used, 19 were antiphospholipid antibodies (aPL) positive. From 12 patients IgG was isolated, of which 6 contained aPL. EC were first incubated with IgG (7 mg/ml) or serum (1:1 diluted) for 1 h and then tested for their ability to promote protein C activation by thrombin, with the cells either in a monolayer or in a suspension. The normal range (mean of control values +/- 2 SD) of protein C activation was 80-120%. In contrast to others, we could not detect an inhibition of protein C activation by any of the patient IgG's or sera. The recently described cofactor for binding of antiphospholipid antibodies to phospholipids, beta 2-glycoprotein I, was purified and added to the purified IgG's. A combination of these two components did not inhibit the EC mediated protein C activation by thrombin. This study suggests that the inhibition of the protein C activation, mediated by EC, is not a general mechanism by which aPL related thrombosis can be explained.
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PMID:In vitro studies of antiphospholipid antibodies and its cofactor, beta 2-glycoprotein I, show negligible effects on endothelial cell mediated protein C activation. 179 12

Phospholipids bearing a proportion of anionic species such as phosphatidylserine are necessary to promote the anticoagulant potential of the protein C pathway. Factor Xa (200 or 350 pM) was found to activate protein C in a thrombomodulin-independent reaction requiring only phospholipids in Al(OH)3,-adsorbed plasma resupplemented with physiological concentrations of protein C (70 nM) and protein S (130 nM). All experiments were performed in the presence of an excess of hirudin. The activity of activated protein C was assessed by the survival of factor Va. The optimal phospholipid concentration range was 5 to 25 microM with a proportion of phosphatidylserine of 50% (mol/mol) resulting in a half-life of factor Va of 7.5 min in the absence of protein S and 4.2 min in its presence. Dns-EGR-Xa, an inactive derivative of factor Xa, behaved as an apparent protector of factor Va. When replacing factor Xa, thrombin at 10 nM was not an efficient protein C activator in the absence of purified human placenta thrombomodulin. In the presence of 100 pM activated protein C, factor Va half-life was 2 min in the absence of protein S and 1.1 min in its presence in the above optimal phospholipid concentration range. The presence of protein S allowed reduction of phospholipid requirements. Annexin-V (placental anticoagulant protein-I), a potent phospholipid antagonist, fully protected factor Va from degradation by phospholipid-dependent mechanisms. Factor Va was partially protected in the plasma of a patient having experienced thrombosis associated with lupus-like anticoagulant and anti-phospholipid auto-antibodies.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:The catalytic role of anionic phospholipids in the activation of protein C by factor Xa and expression of its anticoagulant function in human plasma. 179 56

After a bite by the aglyphous red-necked keelback snake Rhabdophis subminiatus a complete defibrinogenation syndrome with severe hemorrhagic diathesis developed in a 25-year-old man. In vitro studies showed that the venom gland extract of the snake contains a very active prothrombin (Factor II) activator. The thrombin generated is inhibited neither by antithrombin III nor the antithrombin-III-heparin complex. The venom gland extract stimulated also the tissue plasminogen activator; however, it did not cause direct activation of plasminogen, protein C, Factor X or direct degradation of fibrinogen.
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PMID:Hemostatic changes due to the venom gland extract of the red-necked keelback snake (Rhabdophis subminiatus). 180 26

The main characteristics of the blood coagulation system is its high potential of autoamplification. Cascade reactions consisting of successive activations of zymogens into their respective serine-proteinase active form culminate in the generation of thrombin, the central enzyme of the system. Blood coagulation is under control of two major natural regulatory mechanisms limiting the extension of the thrombus. The first one with antithrombin III as the central element, directly inhibits thrombin and other activated clotting factors in cooperation with heparans synthetized by the vascular wall. The second one, the protein C pathway, limits thrombin generation, through its ability to block the amplification potential of feedback reactions. The physiological significance of these regulatory mechanisms is clearly emphasized by the frequency of recurrent thrombotic episodes affecting subjects presenting an inherited deficiency of one of these components, estimated between 50 and 70%. Patients with protein S deficiency, the essential cofactor of activated protein C, exhibit a surprisingly high tendency to arterial thrombosis. The biological investigation of thromboembolic disease must be focused on antithrombin III, protein C and protein S deficiency using functional assays when available or feasible in order to detect both qualitative and quantitative defects.
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PMID:[Congenital deficiencies of natural anticoagulant systems responsible for recurrent thromboembolism]. 182 3

We measured concentrations of the natural anticoagulant protein C; its cofactor, protein S; and the carrier protein C4b-binding protein (C4BP), in 24 patients with severe infection and 13 with septic shock. Decreased antithrombin III levels were found in 16 of 24 infection patients and all shock patients; high thrombin-antithrombin (TAT) complexes were present in 16 of 24 infection and 12 of 13 shock patients. Protein C concentrations were significantly reduced compared to healthy blood donors, to 60 +/- 14% (infection) and 47 +/- 20% (septic shock) (mean +/- 1 SD). Total protein S levels were not reduced (119 +/- 36.7 and 88 +/- 20.0%, normal value 96 +/- 15%). Free protein S was also normal (27 +/- 9.4 and 30 +/- 8.7%, normal value 29 +/- 9%). The percentage free of total protein S was normal in shock patients (35 +/- 8.5%), but significantly reduced in patients without shock (23 +/- 5.3%). C4BP was significantly higher than normal in the latter group (135 +/- 43%), but not in the shock group (118 +/- 40%), possibly due to increased consumption. Thus, no deficiency of total or free protein S was found in these patients, who had evidence of activated coagulation but no clinical DIC.
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PMID:Protein C, protein S and C4b-binding protein in severe infection and septic shock. 182 15

The protein C anticoagulant system provides important control of the blood coagulation cascade. The key protein is protein C, a vitamin K-dependent zymogen which is activated to a serine protease by the thrombin-thrombomodulin complex on endothelial cells. Activated protein C functions by degrading the phospholipid-bound coagulation factors Va and VIIIa. Protein S is a cofactor in these reactions. It is a vitamin K-dependent protein with multiple domains. From the N-terminal it contains a vitamin K-dependent domain, a thrombin-sensitive region, four EGF) epidermal growth factor (EGF)-like domains and a C-terminal region homologous to the androgen binding proteins. Three different types of post-translationally modified amino acid residues are found in protein S, 11 gamma-carboxy glutamic acid residues in the vitamin K-dependent domain, a beta-hydroxylated aspartic acid in the first EGF-like domain and a beta-hydroxylated asparagine in each of the other three EGF-like domains. The EGF-like domains contain very high affinity calcium binding sites, and calcium plays a structural and stabilising role. The importance of the anticoagulant properties of protein S is illustrated by the high incidence of thrombo-embolic events in individuals with heterozygous deficiency. Anticoagulation may not be the sole function of protein S, since both in vivo and in vitro, it forms a high affinity non-covalent complex with one of the regulatory proteins in the complement system, the C4b-binding protein (C4BP). The complexed form of protein S has no APC cofactor function. C4BP is a high molecular weight multimeric protein with a unique octopus-like structure. It is composed of seven identical alpha-chains and one beta-chain. The alpha- and beta-chains are linked by disulphide bridges. The cDNA cloning of the beta-chain showed the alpha- and beta-chains to be homologous and of common evolutionary origin. Both subunits are composed of multiple 60 amino acid long repeats (short complement or consensus repeats, SCR) and their genes are located in close proximity on chromosome 1, band 1q32. Available experimental data suggest the beta-chain to contain the single protein S binding site on C4BP, whereas each of the alpha-chains contains a binding site for the complement protein, C4b. As C4BP lacking the beta-chain is unable to bind protein S, the beta-chain is required for protein S binding, but not for the assembly of the alpha-chains during biosynthesis.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Protein S and C4b-binding protein: components involved in the regulation of the protein C anticoagulant system. 183 51

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