Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: EC:3.4.21.6 (thromboplastin)
13,278 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 (AT III), a major circulating anticoagulant, may be influenced by ischemia-induced changes in microvascular integrity and contribute to localized hypercoagulability. In a nonheparinized intact canine hindlimb model we determined AT III activity by chromogenic substrate assay (S-2238); coagulation changes with fibrinogen, activated partial thromboplastin time (aPTT), and prothrombin time (PT); and transvascular exchange by lymph-to-plasma total protein concentration ratio. Femoral venous plasma and lymph samples were assayed during 1 hour of steady state (C), 6 or 8 hours of aortoiliac occlusion (I), and 1 or 3 hours of reperfusion (R). Four groups were studied: GI, sham operated (n = 5); GII, moderate ischemia (n = 7), arterial pressure 30% to 45% C, GIII, 6 hours of severe ischemia (n = 7), arterial pressure 5% to 20% C; and GIV, 8 hours of severe ischemia (n = 5), arterial pressure 5% to 20% C. All parameters varied near baseline in the control group and the group with moderate ischemia. Fibrinogen decreased after 3 hours of ischemia in GIII from 218 +/- 38 to 175 +/- 46 mg/dl (mean +/- SEM) and in GIV from 254 +/- 39 to 201 +/- 44 mg/dl (p less than 0.005) as aPTT and PT increased. All parameters returned to baseline on R in GIII only. Plasma AT III decreased in GIV from 89% +/- 4.6% to 53.6% +/- 16.2% (p less than 0.005) after 3 hours and remained low during late I and R.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Activity and transport of antithrombin during acute limb ischemia. 272 60

Antithrombin is a protease inhibitor that neutralizes the activity of the serine proteases of the coagulation cascade, such as factors IXa, Xa, XIa, XIIa, and thrombin by forming a 1:1 stoichiometric complex between enzyme and inhibitor via a reactive site (arginine)-active center (serine interaction). Heparin binds to lysyl residues on antithrombin and accelerates the rate of complex formation. Studies of the binding parameters and kinetic characteristics of the heparin-antithrombin-hemostatic enzyme interactions have revealed that binding of heparin to antithrombin is responsible for a approximately 1000-fold acceleration of the thrombin-antithrombin or factor IXa-antithrombin and factor Xa-antithrombin interactions (allosteric effect). The reactions between free thrombin or free factor IXa and heparin provide an additional 4- to 15-fold enhancement in the rate of these processes (approximation effect) and account for 1-2% of the total rate of enhancement. It has been shown that commercial heparin is composed of anticoagulantly active and anticoagulantly inactive species. The anticoagulantly active mucopolysaccharide contains a unique antithrombin-binding site. Anticoagulantly inactive heparin does not possess this structure and does not bind to the protease inhibitor. Anticoagulantly active heparin also contains a critical region required for the acceleration of the various enzyme-inhibitor interactions. The two different domains of the heparin molecule interact with separate areas of antithrombin and induce distinct conformational transitions within the protease inhibitor. Anticoagulantly active heparinlike molecules (most likely a heparan sulfate with an appropriate sequence for anticoagulant activity) are found on the luminal surface of the endothelium. This heparinlike substance appears to alter the conformation of antithrombin in a manner virtually identical to that of commercial heparin. Both anticoagulantly active heparin and inactive heparin are able to suppress smooth muscle cell proliferation in vitro and in vivo and can reverse the effects of mitogenic factors such as platelet-derived growth factor. Furthermore, it has been shown that bovine aortic endothelial cells produce heparinlike molecules with growth inhibitory potency.
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PMID:Role of heparin and heparinlike molecules in thrombosis and atherosclerosis. 315 97

Plasma levels of antithrombin-heparin cofactor, determined by heparin-dependent antithrombin assay, and antithrombin III antigen were measured in 22 members of a large kindred predisposed to venous thrombosis. While 11 members had reduced plasma levels of both antithrombin-heparin cofactor and antithrombin III antigen, the levels of antithrombin-heparin cofactor were always greater than the levels of antithrombin III antigen: 66% (+/- 7%) and 49% (+/- 5%) of normal plasma, respectively. Pooled normal plasma and plasma from one of the affected family members (60% antithrombin-heparin cofactor and 47% antithrombin III antigen) were fractionated by heparin-agarose affinity chromatography. Antithrombin-heparin cofactor, which eluted from heparin-agarose with buffer containing 0.4 M NaCl and did not cross-react with antibody specific for antithrombin III and did not inhibit factor Xa at an appreciable rate in the presence of heparin, was designated heparin cofactor A. Antithrombin-heparin cofactor, which eluted from heparin-agarose with buffer containing 2.0 M NaCl, was functionally and antigenically identified as antithrombin III. The concentrations of heparin cofactor A in normal and patient plasma were similar (4.5 x 10(-7) M), while the concentration of antithrombin III in patient plasma (8.0 x 10(-7) M) was only 50% of normal (1.6 x 10(-6) M). The functional properties of both heparin cofactor A and antithrombin III obtained from patient plasma were normal. From the results of the present study it would appear that the antithrombin-heparin cofactor concentrating measured in patient plasma reflects the combined concentrations of heparin cofactor A and antithrombin III. Since heparin cofactor A does not cross-react with antibody to antithrombin III, the concentration of antithrombin III antigen in patient plasma is thus lower than the concentration of antithrombin-heparin cofactor.
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PMID:Heparin cofactor activities in a family with hereditary antithrombin III deficiency: evidence for a second heparin cofactor in human plasma. 618 96

A study was made of the interaction between prothrombin and enzymes: blood plasma kallikrein and factors alpha-XIIa and beta-XIIa immobilized on enzacryl-AH. Kallikrein-induced prothrombin proteolysis was accompanied by a decrease in prothrombin activity, appearance of BAME-esterase and poor clotting activity. As a result of fractionation of products on the column with DEAE-Sephadex A-50, some fractions that have thrombin amidase activity (splitting of the substrate S-2238) and high antithrombin activity were obtained. Antithrombin activity manifested in the inhibition of fibrinmonomer aggregation during fibrin formation. During incubation with prothrombin, factors alpha-XIIa and beta-XIIa also stimulated the appearance of BAME-esterase activity. None of the immobilized enzymes activated factor X.
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PMID:[Prothrombin--substrate for blood plasma kallikrein and factor XIIa]. 660 74

Orgaran is a LMW heparinoid composed of heparan sulphate (83% w/w) of which 4-5% has high affinity for antithrombin, dermatan sulphate (12% w/w) and chondroitin sulphate (5% w/w). To examine the contribution of the low-affinity fraction to Orgaran's antithrombotic activity we have quantitated the binding of plasma proteins to Orgaran and its component fractions in whole, hirudin-anticoagulated human plasma. Antithrombin, largely bound to the high-affinity fraction, and histidine-rich glycoprotein, interacting with low-affinity components, were the dominant proteins bound to Orgaran. Vitronectin, fibrinogen, fibronectin, heparin cofactor II, and apolipoprotein B were also detected in small amounts. The ratio of bound antithrombin, histidine-rich glycoprotein and vitronectin to GAG was negatively correlated with the Orgaran concentration in plasma, implying that the efficacy of Orgaran may not be linearly related to dose. Binding of antithrombin to the high-affinity fraction was not decreased by other plasma proteins or affected by addition of low-affinity material. Moreover, the antithrombin and anti-factor Xa activities of the high-affinity material were unaltered by low-affinity GAGs. On the basis of our results we conclude that the low-affinity material does not contribute to the antithrombotic activity of Orgaran by binding non-anticoagulant plasma proteins and releasing the high-affinity chains to interact with antithrombin and its target proteinases.
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PMID:Low-affinity material does not contribute to the antithrombotic activity of Orgaran (Org 10172) in human plasma. 752 81

Antithrombin is a member of the serine proteinase inhibitor (serpin) family which contain a flexible reactive site loop that interacts with, and is cleaved by the target proteinase. In cleaved and latent serpins, the reactive site loop is inserted into a large central beta-sheet in the same molecule, whereas in ovalbumin, a nonfunctional serpin, the reactive site loop is completely exposed and in an alpha-helical conformation. However, in neither conformation can the reactive site loop bind to target proteinases. Here we report the structure of an intact and cleaved human antithrombin complex. The intact reactive site loop is in a novel conformation that seems well suited for interaction with proteinases such as thrombin and blood coagulation factor Xa.
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PMID:The intact and cleaved human antithrombin III complex as a model for serpin-proteinase interactions. 765 6

Antithrombin is a serine protease inhibitor that participates in the inactivation and removal from the circulation of thrombin and a variety of other procoagulant serine proteases. Antithrombin is also the major plasma cofactor of heparin which exerts its therapeutic effect primarily through its ability to substantially increase the rate of inactivation by antithrombin of the procoagulant serine proteases. Binding of heparin to antithrombin is thus believed to be a prerequisite for this rate enhancement effect. Heparin binding to antithrombin is mediated by a well-defined unique heparin pentasaccharide sequence. Interaction between this pentasaccharide sequence and antithrombin induces a conformational change in antithrombin, an alteration that appears to be sufficient to explain the enhanced ability of antithrombin to inhibit factor Xa and related serine proteases, but not thrombin. Heparin species with longer polysaccharide chains appear to be required in order to enhance the inhibition of thrombin by antithrombin. This may be because the enhancement of this reaction requires that heparin interacts simultaneously with both the antithrombin and the thrombin molecules. This review describes the interactions between heparin and antithrombin, focusing on the antithrombin residues which are involved in the binding of heparin. The role of the heparin-induced conformational change in enhancing serine protease inhibition by antithrombin is also explored. Then, based on available data, an hypothesis is proposed to explain the mechanisms by which heparin accelerates the rate of inactivation by antithrombin of the various serine proteases.
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PMID:Defining the heparin-binding domain of antithrombin. 818 Mar 43

Antithrombin (AT) is the principal inhibitor of thrombin in human plasma, and a member of the serine proteinase (serpin) family of proteins. Previously, we have described a point mutation in the human AT gene that converted amino acid 392 from glycine to aspartic acid which was associated with thrombotic disease in a Swedish family [(1992) Blood 79, 1428-1434]. This observation prompted us to investigate the consequences of other substitutions at this position, termed P2 with respect to the reactive centre. Site-directed mutagenesis was employed to generate seven mutants (Pro, Met, Gln, Val, Lys, Glu, and Asp), whose properties were compared with wild-type recombinant AT, following in vitro transcription and cell-free expression in a rabbit reticulocyte lysate system. With only one exception, the variant forms were less active than the wild-type in forming complexes with either alpha-thrombin, factor Xa, or trypsin. Hydrophobic (Val) or negatively charged (Asp or Glu) substitutions were particularly disruptive, in that these variants exhibited less than 10% wild-type antithrombin or antitrypsin activity. In contrast, the formation of complexes with the various proteases of the Pro variant was essentially unimpaired. We conclude that the P2 residue of AT plays a role in optimal presentation of the reactive centre to its cognate protease, and propose that the observed requirement of Gly or Pro at this position is suggestive of a bend in the polypeptide backbone that aids in this presentation.
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PMID:Site-directed mutagenesis of the P2 residue of human antithrombin. 831 64

Experiments were performed to evaluate activation of factor VII bound to relipidated tissue factor (TF) in suspension and to TF constitutively expressed on the surface of an ovarian carcinoma cell line (OC-2008). Activation was assessed by measuring cleavage of 125I-factor VII and by the ability of unlabeled factor VII to catalyze activation of a variant factor IX molecule that, after activation, cannot back-activate factor VII. Factor Xa was found to effectively activate factor VII bound to TF relipidated in either acidic or neutral phospholipid vesicles. Autoactivation of factor VII bound to TF in suspension was dependent on the preparation of TF apoprotein used and the technique of its relipidation. This highlights the need for caution in extrapolating data from TF in suspension to the activation of factor VII bound to cell surfaces during hemostasis. A relatively slow activation of factor VII bound to OC-2008 monolayers in the absence of added protease was observed consistently. Antithrombin in the presence or absence of heparin prevented this basal activation, whereas TF pathway inhibitor (TFPI/factor Xa complexes had only a limited inhibitory effect. Adding a substrate concentration of factor X markedly enhanced basal activation of factor VII, but both TFPI/factor Xa and antithrombin/heparin abolished this enhancement. Overall, our data are compatible with the hypothesis that not all factor VII/TF complexes formed at a site of tissue injury are readily activated to factor VIIa (VIIa)/TF complexes during hemostasis. The clinical significance of this is discussed.
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PMID:Studies of the activation of factor VII bound to tissue factor. 889 39


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