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)

We describe a patient who developed a severe coagulopathy after being bitten by a red-necked keelback snake (Rhabdophis subminiatus), a species which is generally considered non-venomous. The patient's blood was incoagulable due to complete depletion of fibrinogen. Comprehensive coagulation studies were performed to identify the mechanism(s) by which the snake toxin caused the coagulopathy. It was found to contain a potent prothrombin activator, probably an activator of protein C and possibly also a factor X activating enzyme. The fibrinolysis was secondary to intravascular fibrin formation; there were no indications for a direct fibrinogenolytic activity in the snake toxin. Remarkably, there was virtually no consumption of antithrombin III, despite extensive thrombin formation; this feature appears to be not uncommon after snake bites, but is still unexplained.
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PMID:Haemostatic effects in vivo after snakebite by the red-necked keelback (Rhabdophis subminiatus). 142 Aug 21

Human protein C is a vitamin K-dependent plasma glycoprotein that circulates as an inactive zymogen. At the endothelial cell surface, thrombin in complex with the integral membrane protein thrombomodulin converts protein C to its active form by specific cleavage of an activation peptide. The activated form of protein C has potent anticoagulant activity as a feedback regulator of thrombin generation (reviewed in refs 4-6), and also has profibrinolytic, anti-ischaemic and anti-inflammatory properties. Protein C is effective in the treatment of model and human thrombotic diseases but, except when it has been used to treat genetic or acquired deficiencies and microvascular thrombosis, it is administered as the activated enzyme, which has a short biological half-life. We have altered two putative inhibitory acidic residues near the thrombin cleavage site, which results in a 30-fold increase in substrate utilization by alpha-thrombin. We combined these changes with a genetically altered glycoform to generate a zymogen protein C with a 60-fold increased cleavage rate by free alpha-thrombin, independent of its cofactor thrombomodulin. We show that this 'proform' of protein C, unlike the natural circulating zymogen, can be activated by thrombin generated in clotting human plasma, resulting in an inhibition of further clot formation. Our data therefore show that we have engineered a site-activated agent, which only has anticoagulant activity when significant amounts of thrombin are being generated.
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PMID:Enhancing protein C interaction with thrombin results in a clot-activated anticoagulant. 143 7

Ca(++)-dependent monoclonal antibody specific to gamma-carboxyglutamic acid (Gla) domain of protein C was produced. It did not cross-react to the other vitamin K-dependent plasma proteins but to protein C of the other species. Using this monoclonal antibody, PC01, rabbit (170 micrograms), rat (60 micrograms) and mouse (40 micrograms) protein Cs were isolated from 100 ml of their plasma by affinity chromatography. All of these protein Cs were two chain form linked by disulfide bond as well as human protein C and activated by thrombin-thrombomodulin complex. Rat and mouse protein Cs showed similar characters to human protein C. On the other hand rabbit protein C had different M(r) of heavy and light chains and showed lower anticoagulant activity compared with human protein C.
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PMID:Purification of rabbit, rat and mouse protein C with the use of monoclonal antibody to human protein C, PC01. 144 May 33

The present study was undertaken to elucidate the effect on platelet aggregation of the prothrombin-converting reaction on platelets with or without activated protein C (APC). A reaction mixture of washed platelets from human individuals, Factor Xa and prothrombin markedly induced platelet aggregation; maximum aggregation rates, 31.3-92.5%, and times to reach to maximum aggregation, 11.6 to 20.1 min. This aggregation was inhibited by the addition of APC with 50% inhibition concentration (IC50) value of 14.4 U/ml. APC also inhibited thrombin generation in the reaction mixture in a dose-dependent manner with IC50 value of 0.96 U/ml. However, APC did not inhibit the thrombin (0.1 CU/ml)-induced platelet aggregation at concentrations of up to 30 U/ml. These findings suggest that APC has no direct inhibitory effect on platelet aggregation and that APC inhibits platelet aggregation through inhibition of thrombin generation.
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PMID:Inhibitory effect of activated protein C on platelet aggregation induced by the prothrombin-converting reaction. 144 May 35

Dynamics of protein C concentration was studied in rat blood after administration of thrombin and thromboplastin. Administration of 0.5 ml 1% thromboplastin caused fast decrease of protein C concentration, down to 60% of the initial level, within 3 min, while activity of factor V reached the minimal rate (30%) within 5 min. Content of protein C returned to the initial level in blood within 2-2.5 hrs and of factor V--within 6 hrs. After administration of thrombin 3 NIH in content of protein C was decreased to 91.3% whereas heparin was released only after injection of 6 NIH. The data obtained suggest that the protein C system responded earlier to occurrence of thrombin in circulation as compared with the neurohumoral regulators of the anticoagulation system; the protein C system is one of primary mechanisms of the antithrombosis defence.
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PMID:[Participation of protein C in reaction of the anti-coagulant system to intravenous administration of thrombin and thromboplastin to rats]. 144 Dec 96

The association between congenital deficiencies and recurrent thrombosis strongly suggests that antithrombin III, protein C and protein S play a major role in inhibiting thrombin formation in vivo. Genetic analysis using DNA fragment amplification by polymerase chain reaction and direct gene sequencing has led to the identification of many novel mutations in qualitative and quantitative deficiencies. Elucidation of the molecular basis of these deficiencies is critical to our understanding of natural antithrombotic mechanisms. It not only provides information on the structural features governing protein function, but also permits a better classification, based on genomic abnormalities of hereditary deficiencies responsible for mild to severe phenotypes and may prove of further value to define the most pertinent plasma assays for routine diagnosis.
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PMID:Molecular abnormalities responsible for thrombosis. Genetic aspects. 144 49

We describe here the alteration of thrombin specificity induced by its interaction with glycocalicin. Glycocalicin is the external part of platelet glycoprotein Ib alpha (GPIb alpha) and contains binding sites for von Willebrand factor and thrombin. Taking advantage of its solubility, we have used glycocalicin in competition assays on various thrombin activities. Glycocalicin did not inhibit chromogenic substrate hydrolysis nor diisopropylfluorophosphate iPr2 (PF) incorporation, indicating that thrombin binding to GPIb does not alter access to or the conformation of the thrombin catalytic site. Glycocalicin competitively inhibited thrombin binding to fibrin (Ki = 0.1 mumol/L) and blocked fibrinogen clotting activity of thrombin. Glycocalicin also inhibited thrombin binding to thrombomodulin in a competitive manner (Ki = 3 to 5 mumol/L), but failed to prevent thrombin interaction with protein C in the absence of thrombomodulin. Previous results have indicated that GPIb binds to thrombin within the anion binding exosite masked by the carboxy-terminal hirudin peptide 54-65. The present results confirm the implication of the anion binding exosite in GPIb recognition, and further indicate that the thrombin binding site for GPIb overlaps with the thrombin binding sites for fibrin and thrombomodulin, whereas it is distinct from the thrombin binding site for protein C. Some of the structural requirements for thrombin binding to GPIb appear to be very similar to those reported for binding to its platelet receptor. However, thrombin-GPIb interaction does not appear to compete with receptor hydrolysis but rather increases the sensitivity and the rate of platelet responses elicited by the receptor.
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PMID:Thrombin interaction with platelet glycoprotein Ib: effect of glycocalicin on thrombin specificity. 145 Apr 5

Vitamin K-dependent protein S is an anticoagulant plasma protein serving as cofactor to activated protein C in degradation of coagulation factors Va and VIIIa on membrane surfaces. In addition, it forms a noncovalent complex with complement regulatory protein C4b-binding protein (C4BP), a reaction which inhibits its anticoagulant function. Both forms of protein S have affinity for negatively charged phospholipids, and the purpose of the present study was to elucidate whether they bind to the surface of activated platelets or to platelet-derived microparticles. Binding of protein S to human platelets stimulated with various agonists was examined with FITC-labeled monoclonal antibodies and fluorescence-gated flow cytometry. Protein S was found to bind to membrane microparticles which formed during platelet activation but not to the remnant activated platelets. Binding to microparticles was saturable and maximum binding was seen at approximately 0.4 microM protein S. It was calcium-dependent and reversed after the addition of EDTA. Inhibition experiments with monoclonal antibodies suggested the gamma-carboxyglutamic acid containing module of protein S to be involved in the binding reaction. An intact thrombin-sensitive region of protein S was not required for binding. The protein S-C4BP complex did not bind to microparticles or activated platelets even though it bound to negatively charged phospholipid vesicles. Intact protein S supported binding of both protein C and activated protein C to microparticles. Protein S-dependent binding of protein C/activated protein C was blocked by those monoclonal antibodies against protein S that inhibited its cofactor function. In conclusion, we have found that free protein S binds to platelet-derived microparticles and stimulates binding of protein C/activated protein C.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Binding of anticoagulant vitamin K-dependent protein S to platelet-derived microparticles. 146 47

The purpose of the study was to test whether APC: alpha 1AT complex is a useful clinical marker of the activation of coagulation. The rationale for this is that activated protein C may appear in circulation at an early stage of blood coagulation, when subcoagulant amounts of thrombin are formed. Given the relatively higher half-life of APC: alpha 1AT as compared to that of thrombin:AT-III (TAT) complexes, we hypothesized that APC:alpha 1AT could represent an amplification of the thrombin generated in the first events of coagulation. Using sandwich ELISA's we measured APC: alpha 1AT and TAT complexes as well as complexes of AT-III with its target proteases in normal subjects and in several clinical groups of patients prone to thrombotic episodes, including pregnancy, preeclampsia, hemodialysis, gynecological tumors, diabetes and oral contraceptives. APC: alpha 1AT complex was significantly increased in all clinical groups as compared to normal subjects and showed relatively higher increases than did TAT and ATM complexes in the majority of the groups studied. There was a significant and positive correlation between APC: alpha 1AT and TAT complex levels in the majority of the groups, as well as between TAT and ATM and between APC: alpha 1AT and ATM complex levels. We conclude that APC: alpha 1AT complex can be used as a sensitive marker of prethrombotic states.
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PMID:Activated protein C: alpha 1-antitrypsin (APC: alpha 1 AT) complex as a marker for in vitro diagnosis of prethrombotic states. 152 6

Protein C is a natural anticoagulant glycoprotein which prevents intravascular clot formation. Protein C functions as an anticoagulant when converted to an active serine protease (activated protein C). Activated protein C is formed at the site of the endothelial injury in response to blood clotting and helps limit the size of blood clots. We tested the hypothesis that by temporarily blocking the activation of intrinsic protein C, we could reduce subsequent surgical blood loss from a microvascular surgical wound. The formation of activated protein C was blocked systemically by intravenous administration of a monoclonal antibody (HPC4) which binds to circulating protein C and prevents its conversion to activated protein C. Domestic pigs were blindly pretreated with intravenous HPC4 or saline then underwent partial-thickness skin graft harvesting to create a reproducible microvascular wound. Blood loss was measured from each wound and the hemostatic effect of protein C blockade was compared to intravenous saline alone as well as to topical thrombin or thromboplastin. We found that blocking the activation of protein C significantly (P = 0.005) reduces surgical blood loss in this model by 27% compared to saline control animals. Intravenous HPC4 performed equally as well as topical thrombin or tissue thromboplastin. In addition, topical thrombin acted synergistically with HPC4 to reduce blood loss an additional 44% (P = 0.01) as compared to intravenous HPC4 or topical thromboplastin alone. Autopsies performed 1 week after HPC4 treatment showed no evidence of systemic thrombosis resulting from the protein C blockade.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Blockade of protein C activation reduces microvascular surgical blood loss. 152 31


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