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)

Factors affecting the coagulant activity of two different prothrombin complex concentrates have been investigated using a sensitive in vitro assay developed in this laboratory. One concentrate contained substantial amounts of potentially thrombogenic material, while the other, which was deliberately fortified with antithrombin III and heparin during production, was judged to be relatively nonthrombogenic. The coagulant activity of the thrombogenic concentrate has been partially identified and was due largely to the presence of coagulation factos IXa and Xa. Neither concentrate contained detectable thrombin. However, after incubation with calcium or various polyamines, large amounts of additional coagulant material, including thrombin, appeared. Heparin and antithrombin III not only neutralized the thrombogenic materials present in the thrombogenic concentrate, but also inhibited the de novo generation of coagulant enzymes during incubation with calcium. The implication of these studies on the preparation of prothrombin complex concentrates and on host susceptibility to thrombosis during the clinical use of these concentrates is discussed.
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PMID:Prothrombin complex concentrates: potentially thrombogenic materials and clues to the mechanism of thrombosis in vivo. 1 45

The effect of pH and time on the stability of heparin sodium in dextrose 5% in water (D5W) injection and in dextrose 5% in 0.45% sodium chloride injection was studied. Admixtures of heparin sodium 5,000 units/250 ml were tested after 0, 10, 20 and 30 minutes and 1, 2, 6, 12 and 24 hours of storage at room temperature. The pH of the carrier solutions was adjusted to 2, 4 or 9 prior to adding the heparin sodium. Heparin activity was measured using a thrombin clotting time assay. Samples were tested for pH changes at the same times. No substantial changes in heparin activity over the 24-hour period occurred with any of the pH-adjusted solutions. The pH of the heparin-D5W admixtures remained constant over time. The two carrier solutions, over a pH range of 2 to 9, appear to be suitable vehicles for heparin sodium.
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PMID:Effect of pH on the stability of heparin in 5% dextrose solutions. 3 53

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

Extensive aggregation of human platelets can be induced by ADP without secondaryaggregation or release of granule contents. This occurs with washed platelets in Tyrode solution containing 0.35% albumin, human fibrinogen, and apyrase, and in platelet-rich, heparin- or hirudin-plasma. Conditions that caused release during ADP-inducedaggregation were-citrate as the anticoagulant in platelet-rich plasma; addition of citrate (11-15 mM) to a suspension of washed platelets, or to hirudin-plasma or heparin-plasma; suspension of platelets in a medium containing magnesium but no calcium;and the presence of trace amounts of thrombin or aggregated gamma globulin in the platelet suspensions. Acetylsalicylic acid, phenylbutazone, or sulfinpyrazone inhibited secondary aggregation and release in all these circumstances. Heparin or hirudin inhibited ADP-INDUCED SECONDARY AGGREGATION AND RELEASE PROMOTED BY TRACES OF THROMBIN. Although fibrinogen is required for ADP-induced primary aggregation, it does not support secondary aggregation and release, provided that it has no clot-promoting activity. The main agent responsible for ADP-induced secondary aggregation and release in human, citrated, platelet-rich plasma appears to be sodium citrate. Suspending washed human platelets in a medium without calcium mimics the effect of citrate.
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PMID:Factors responsible for ADP-induced release reaction of human platelets. 5 Jul 44

Heparin cofactor, a thrombin inhibitor, is purified from human plasma by affinity chromatography on heparin-agarose. The nature of the binding between thrombin and the inhibitor is studied by treatment of the complex with 6 M guanidinium chloride, hydroxylamine, and dilute alkali. The complex is not dissociated during gel chromatography in 6 M guanidinium chloride. This result supports an earlier proposal that formation of the complex includes the formation of a covalent bond. Treatment of dodecyl sulfate-denatured complex with hydroxylamine results in dissociation of the complex to yield free thrombin and heparin cofactor. Hydroxylamine does not dissociate the complex unless it is denatured. The complex is also dissociated in dilute sodium hydroxide (pH 12) solutions. These results indicate that the covalent bond between thrombin and the inhibitor is a carboxylic ester.
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PMID:Evidence for an ester bond between thrombin and heparin cofactor. 6 Jul 92

An assay technic for measuring heparin cofactor activity in which antithrombin activity can be assessed without plasma attenuation even in the presence of therapeutic levels of heparin is presented. Heparin-activated anti-thrombin activity was markedly depressed in plasmas of four patients with disseminated intravascular coagulation and in ten patients with cirrhosis. Residual activity in those plasmas appeared qualitatively normal, and no inhibitor (platelet factor IV activity) was observed. Plasmas from patients with disseminated intravascular coagulation and cirrhosis required more heparin to obtain in vitro clotting time prolongation equivalent to normal.
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PMID:Minimal heparin cofactor activity in disseminated intravascular coagulation and cirrhosis. 6 Aug 79

Inactivation of alpha- and beta-thrombin by antithrombin-III and heparin was studied, since it had been suggested that two forms of thrombin exist with respect to heparin sensitivity (Machovich 1975b). It was found that the inactivation rates of alpha- and beta-thrombin by antithrombin were different, namely alpha-thrombin was more sensitive to antithrombin than beta-thrombin. Heparin facilitated the complex formation between alpha-thrombin and antithrombin-III, whereas beta-thrombin inactivation was only slightly affected. Furthermore, heparin protected alpha-thrombin against the inactivating effect of heat, while beta-thrombin lost its activity during the heat treatment. These findings suggest that the formation of beta-thrombin in blood circulation may have an important role in thrombosis predisposition.
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PMID:Inactivation of alpha- and beta- thrombin by antithrombin-III and heparin. 6 98

Inactivation of alpha- and beta-thrombin by alpha 2-macroglobulin, by alpha 1-proteinase inhibitor and by antithrombin-III and heparin was studied. The amount of alpha- and beta-thrombin inactivated by antithrombin-III was proportional to the concentration of the inhibitor, but the inactivation rates of the two forms of thrombin were different. Heparin facilitated complex-formation between alpha-thrombin and antithrombin-III, whereas inactivation of beta-thrombin by antithrombin was only slightly influenced, even at a heparin concentration two orders of magnitude higher. alpha 2-Macroglobulin inhibited both alpha- and beta-thrombin activity similarly, i.e. the amount of alpha- and beta-thrombin inactivated as well as the rates of their inhibition were the same. alpha 1-Proteinase inhibitor also formed a complex with alpha- and beta-thrombin, similarly to antithrombin-III, although the inactivation of the enzyme needed high inhibitor concentration and long incubation time. These results suggest that the inactivation of beta-thrombin, if it occurs in the plasma, is also controlled by plasma inhibitors.
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PMID:Inactivation of alpha- and beta-thrombin by antithrombin-III, alpha 2-macroglobulin and alpha 1-proteinase inhibitor. 7 48

The interaction of heparin with chemically modified thrombin and heparin cofactor is studied. Amidinated heparin cofactor does not bind to heparin-agarose and the reaction rate of the amidinated inhibitor with unmodified thrombin is not affected by heparin. Likewise, thrombin modified with 1,2--cyclohexanedione does not bind to heparin agarose and the reaction rate of the modified enzyme with unmodified inhibitor is not affected by heparin. In the absence of heparin, the modified and unmodified proteins react at the same rate in all possible combinations. Affinity chromatography of diisopropylphosphoryl thrombin on heparin cofactor coupled to Sephadex G--50 is used to study the binding of heparin cofactor and thrombin to heparin. The thrombin for all experiments is tritium-labeled and then inactivated with diispropylfluorophosphate. Thrombin is not bound to heparin cofactor-Sephadex columns. However, after treatment of the columns with a heparin solution, thrombin binds tightly, and is eluted at high ionic strength. Bound thrombin can also be eluted with either excess non-radioactive thrombin or excess free heparin. Heparin-dependent binding of thrombin does not occur if the heparin cofactor-Sephadex is heat-denatured. The ability of heparin to couple solution-phase thrombin to solid-phase heparin cofactor indicates that a ternary complex is formed. Analysis of the binding of the proteins to heparin by a dye displacement method suggests that at least one site on heparin binds to thrombin but not to heparin cofactor. Further support for a catalytic role for heparin derives from the ability of catalytic concentrations of heparin to enhance the rate of hydrolysis of prothrombin by thrombin, another protein pair which bind mutually to heparin.
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PMID:A catalytic role for heparin. Evidence for a ternary complex of heparin cofactor thrombin and heparin. 7 28

The interaction between thrombin and alpha-2-macroglobulin was studied on human purified materials, either in the presence or in the absence of heparin, by kinetic analysis of thrombin inhibition and polyacrylamide gel electrophoresis. In the absence of heparin, binding of thrombin to alpha-2-macroglobulin, shown by electrophoresis, leads to the loss of the coagulant property of the enzyme. In the presence of heparin the rate of inhibition of thrombin clotting activity by alpha-2-macroglobulin is strongly decreased. Heparin binds to thrombin, impairing the formation of thrombin-alpha-2-macroglobulin complex. These data show that heparin paradoxically protects thrombin from inhibition by alpha-2-macroglobulin whereas it increases the enzyme inhibition by antithrombin III. Such a phenomenon could be of practical interest for treatment of thrombosis in patients with high plasma level of alpha-2-macroglobulin and low level of antithrombin III, such as occurs in the nephrotic syndrome.
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PMID:[Heparin inhibition of the antithrombin activity of alpha-2-macroglobulin]. 8 15

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