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)

By devising and applying quantitative methods for the assay of thrombin and autoprothrombin C and by developing techniques for their purification, it was possible to obtain information about the function and properties of antithrombin. The inhibitor is a protein for which the initial purification steps consist of removing fibrinogen from plasma by heating to 56 degrees for 3 min, removing prothrombin complex by absorption on barium carbonate, absorbing the antithrombin on aluminum hydroxide, and eluting with phosphate buffer. Antithrombin is limited in its capacity to neutralize thrombin activity, and, under some conditions, the rate of inhibition was accelerated, but equivocal results were involved. Heparin cofactor was found to be essential for retarding the formation of thrombin, and, by inference, it is essential for retarding the formation of autoprothrombin C. Heparin cofactor and antithrombin III are the same. Thrombin absorbs on fibrin, and this has been referred to as the "antithrombin I effect." Interference with the thrombin-fibrinogen reaction by mixtures of antithrombin III and heparin is called the "antithrombin II henomenon." The acceleration of thrombin inactivation at the time thrombin forms is called the "antithrombin IV effect." It was discovered that antithrombin III neutralizes thrombin, as well as autoprothrombin C. The inhibitor and the enzyme form a mutual depletion system. To assay for antithrombin III, a standard quantity of thrombin (about 1,100U/ml) was reacted with antithrombin III for 2 hr. The percent thrombin inactivated was then measured. In random samples of human blood, a wide range of antithrombin III concentration was found. The inhibitor is relatively stable in plasma and serum. It is not changed in concentration when Dicumarol therapy is instituted. Ether extraction of plasma reduces antithrombin III activity. Seitz filtration of plasma did not remove activity. Under special conditions, antithrombin III enhances esterase activity of thrombin. Under special conditions, thrombin regenerates from the thrombin-antithrombin III complex. Antithrombin III neutralizes the activity of prethrombin-E and thrombin-E; consequently, an active histidine center found in the B1 chain of thrombin is not essential for the binding of antithrombin. Autoprothrombin II-A activity was neutralized by antithrombin III. Autoprothrombin C was found to be neutralized by antithrombin III; the amounts required varied with the molecular forms of autoprothrombin C. Thrombin and autoprothrombin C apparently occupy the same binding sites on antithrombin III. An equation was developed to account for all the known characteristics of antithrombin III functions. The kinetic aspects of thrombin neutralization were found to correspond exactly with those of autoprothrombin C. Antithrombin III is a high-capacity inhibitor of the two most powerful enzymes in blood coagulation.
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PMID:Antithrombin III: a backward glance o'er travel'd roads. 4 4

Antithrombin activity has been identified in intact washed human platelets. An apparent activity was demonstrated at platelet concentrations above 0.31 X 10(9)/ml, when platelet suspensions were incubated with 2.0 NIH units/ml of thrombin. Neither red cells nor white cells revealed antithrombin activity. No significant loss of the platelet antithrombin activity was observed after ten successive washings or after treatment of platelets with antibodies to antithrombin III or alpha2-macroglobulin. Almost the same amount of antithrombin activity as normal platelets was demonstrated in the platelets from an afibrinogenemic patient. Pre-treatment of platelets with trypsin, papain, and neuroaminidase reduced the activity significantly, whereas lipase was without effect. The platelet antithrombin reacted with thrombin in less than 3 seconds, and this rapid reaction of platelet antithrombin was different from that of plasma antithrombin III or fibrinogen. The thrombin-like clotting activity of ancrod was inhibited by fibrinogen but not platelets. Also, unlike plasma antithrombin III or fibrinogen, brief exposure to heat (56 degrees C or 60 degrees C) reduced considerable amounts of platelet antithrombin activity. These results suggest that platelets possess a specific antithrombin with different characteristics from other known antithrombins.
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PMID:Antithrombin activity of intact human platelets. 5 97

Antithrombin activities in 30 severely malnourished children and 40 normal children were estimated in clotting tests by thrombin neutralisation as anti-Xa and by a heparin antithrombin assay; and by immunodiffusion as alpha 2-globulin and alpha 1-antitrypsin. The patients' mean alpha 2-globulin was severely depressed, and there were less marked depletions in mean values for thrombin neutralisation, anti-Xa, and in the heparin antithrombin assay (which showed the flat curve thought to reflect a thrombotic tendency). The alpha 1-antitrypsin values were normal. The findings support the concept of antithrombin as the summation of alpha 2-globulin and alpha 1-antitrypsin (with alpha 2-macroglobulin); and the low values may be related to the high incidence of thrombosis reported in childhood malnutrition, although it was not seen in these patients.
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PMID:Antithrombin activities in childhood malnutrition. 11 90

We report here on a patient whose abnormal fibrin clot was detected via the measurement of clot rigidity with a simple buoyant inner cylinder elastometer. The patient's clinical coagulation studies were all within normal limits except for prolonged thrombin and reptilase clotting times and high level of fibrin split products. The measured rigidity of the patient's clot was approximately ten times lower than that of a clot formed from normal pooled plasma. Light scattering studies indicated that this modified structure was not caused by a gross change in gel fiber morphology. Antithrombin activity was eliminated as a possible cause of the altered clot structure; this suggests the possibility of a modified fibrinogen. Abnormalities in the reptilase time and fibrinogen levels in two siblings support the hypothesis that the modification is an inherited defect. We suggest that the simple measurement of rigidity can be used rountinely to detect abnormalities in plasma clot structure. The screening for such disorders should be of importance to clinician, patient, and biochemical researcher.
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PMID:Detection of an abnormal plasma clot structure by a simple rigidity assay. 50 10

Hemostasiologic effects of intravenous application of Reptilase were investigated in a randomized double blind study in the course of normal abdominal and vaginal hysterectomies. Coagulation factors and thrombocytes were checked before, after, 40 minutes after as well as 24 hours after the operation. Significant shortening of the clot observation time resulted 40 minutes after the injection of 1 ml Reptilase. A small but highly significant decrease of thrombocytes was observed 40 minutes after the end of the operation when Reptilase was injected. Further coagulation screening tests: Quick test, PTT and thrombin time were without statistically differences in both patients groups from the beginning till 24 hours after the operation. A significant decrease in Factor V concentrations resulted 40 minutes after the injection of Reptilase, whereas no changes were seen in the placebo patient group. Too, Factor XIII values and Antithrombin 3 concentrations decreased after the administration of Reptilase. There was no abnormal raise of fibrin-monomers in both groups. Enhanced fibrinolysis with elevated FDP-levels were measured in none of the cases. The administration of Reptilase induced a short lasting augmentation of blood coagulation but without any signs of disseminated intravascular coagulation.
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PMID:[Coagulation factors and thrombocytes after application of Reptilase in the course of gynecologic operations (author's transl)]. 65 62

The effect of some mono- and divalent cations was examined on thrombin--antithrombin reaction in vitro. It was found that 0--0.1 M sodium- or potassium chloride did not affect either thrombin or antithrombin activity; at higher concentrations thrombin activity decreased. Calcium chloride as well as magnesium chloride at concentrations from 0 to 0.5 M increased enzyme activity, whereas at higher concentrations the activity decreased. Thrombin inactivation by antithrombin was also accelerated at calcium or magnesium chloride concentrations above 0.04 M. Antithrombin was inactivated at pH 7.3 at 65 degrees C in some minutes and heparin failed to protect it against heat denaturation. Thrombin inactivation by antithrombin did not proceed at 0 degrees C in 60 min, but the interaction between thrombin and antithrombin was facilitated in the presence of heparin.
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PMID:Some properties of human progressive antithrombin. 75 68

The Hageman factor dependent pathways are influenced by several control proteins which modulate the extent of activation and biologic activity of these enzyme substrates (Fig. 1). C1 INH plays a prominent role by acting at the common initiating step for all three Hageman factor dependent systems and its deficiency produces disease in man. Alpha-2 macroglobulin appears to play an important role in the fibrinolytic sequence, having potent activity towards both plasminogen activator and plasmin. Antithrombin most prominently influences the state of activation of the coagulation sequence by regulating the enzymatic activities of activated Factors XI, IX and X and, most importantly, that of thrombin. Significantly, deficiency of antithrombin results in increased thrombosis in man.
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PMID:Plasma inhibitors of the Hageman factor dependent pathways. 79 48

Antithrombin is the most important physiological proteinase inhibitor of thrombin and other coagulation proteinases. It is a single chain glycoprotein of MW 58,200 which has sequence homology with alpha 1-antitrypsin and other members of the serpin superfamily of inhibitors. Two functional domains of importance have been identified, the reactive centre that interacts with the proteinase and a heparin binding domain. Failure to maintain an adequate level of functional antithrombin in plasma results in an increased risk of thromboembolism: deficiency can be inherited or acquired. There is still uncertainty regarding the prevalence of inherited deficiency and the prevalence of thrombosis in affected individuals. The production of antithrombin is under the control of a single gene which is localized on chromosome 1q 23-25. Characterization of the coding sequence, which is distributed over seven exons, has allowed the analysis of the molecular basis for inherited antithrombin deficiency. To date more than 100 cases have been successfully investigated at the gene and/or protein sequence level and 40 novel mutations have been identified. Mutations causing amino acid substitutions solely affecting the heparin binding site have thus far been located primarily at the N-terminal region of the molecule, residues 7-129; this region has been postulated to align as a positive groove in the molecule that forms the primary contact region for the essential antithrombin binding pentasaccharide of heparin. Not all the residues in which substitutions have been found are basic and some serve to maintain the conformation of nearby basic regions. Examples of this are provided by the Pro-41 to Leu mutation and a recently investigated mutant, Leu-99 to Phe. The reactive site defects are an interesting group, including those that alter P1, P1' and P12-P10 residues. Perhaps more remote mutations can also be included such as Pro-429 to Leu. The P1 and P1' mutations directly block interaction of the proteinase with anti-thrombin, while P12-P10 mutants (which have mutations affecting serpin strand s4A) enable the substrate reaction to proceed to completion, i.e. the antithrombin-thrombin complex is not stabilized and the mutant inhibitor is transformed into a substrate. The effect of the Pro-429 to Leu substitution is impairment of the reactive site and heparin binding, and the finding that this variant is not completely recognized by some MAbs implies a conformational change at the C terminus. Another group (nine cases) of interesting mutations is emerging, that has its primary defect in or near serpin strand 1C, amino acid sequence 402-407.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Antithrombin and its deficiency states. 164 10

Antibody inhibitors against human thrombin are rare and have remained poorly characterized. We report the case of a 40-yr-old patient who developed a potent thrombin inhibitor revealed by mild bleeding symptoms and marked prolongation of most laboratory clotting times. After two years of evolution, he died from cerebral hemorrhage. The inhibitor, a polyclonal IgG, was associated with hematological and immunological criteria of autoimmune disorder. Antithrombin IgG was isolated from the patient's plasma by protein A- and thrombin-affinity chromatography. Fab fragments inhibited amidolytic activity of alpha thrombin, and thrombin-thrombomodulin catalyzed protein C activation with a Ki of approximately 10(-8) M in a noncompetitive manner. Alpha to gamma conversion of thrombin resulted in a moderate loss of affinity for the inhibitor. Upon complex formation of thrombin with staphylocoagulase or alpha 2-macroglobulin (alpha 2M), inhibition was decreased by two orders of magnitude and acquired an apparent competitive character. In Western blot experiments, the antibody reacted with active alpha-thrombin, did not react with chloromethylketone-inhibited thrombin and reacted with a lower affinity with iPr2P-thrombin. The inhibitor did not block thrombin binding to benzamidine-, heparin-, or fibrin-Sepharose, but displaced proflavin from its complex with thrombin. Taken together, these results indicate that the patient's autoantibody recognized a conformational structure which includes, at least in part, the apolar binding site adjacent to the catalytic site of thrombin.
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PMID:An acquired antithrombin autoantibody directed toward the catalytic center of the enzyme. 171 42

A synthetic tetradecapeptide having the sequence of the region of the antithrombin chain amino-terminal to the reactive bond, i.e. comprising residues P1 to P14, was shown to form a tight equimolar complex with antithrombin. A similar complex has previously been demonstrated between alpha 1-proteinase inhibitor and the analogous peptide of this inhibitor (Schulze, A. J., Baumann, U., Knof, S., Jaeger, E., Huber, R. and Laurell, C.-B. (1990) Eur. J. Biochem. 194, 51-56). The antithrombin-peptide complex had a conformation similar to that of reactive bond-cleaved antithrombin and, like the cleaved inhibitor, also had a higher conformational stability and lower heparin affinity than intact antithrombin. These properties suggest that the peptide bound to intact antithrombin at the same site that the P1 to P14 segment of the inhibitor occupies in reactive-bond-cleaved antithrombin, i.e. was incorporated as a sixth strand in the middle of the major beta-sheet, the A sheet. The extent of complex formation was reduced in the presence of heparin with high affinity for antithrombin, which is consistent with heparin binding and peptide incorporation being linked. Antithrombin in the complex with the tetradecapeptide had lost its ability to inactivate thrombin, but the reactive bond of the inhibitor was cleaved as in a normal substrate. These observations suggest a model, analogous to that proposed for alpha 1-proteinase inhibitor (Engh, R.A., Wright, H.T., and Huber, R. (1990) Protein Eng. 3, 469-477) for the structure of intact antithrombin, in which the A sheet contains only five strands and the P1 to P14 segment of the chain forms part of an exposed loop of the protein. The results further support a reaction model for serpins in which partial insertion of this loop into the A sheet is required for trapping of a proteinase in a stable complex, and complete insertion is responsible for the conformational change accompanying cleavage of the reactive bond of the inhibitor.
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PMID:Conversion of antithrombin from an inhibitor of thrombin to a substrate with reduced heparin affinity and enhanced conformational stability by binding of a tetradecapeptide corresponding to the P1 to P14 region of the putative reactive bond loop of the inhibitor. 173 Jul 29

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