EC:3.4.21.5 - FACTA Search

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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)

An estrogen-responsive procoagulant activity is present in the plasma membrane fraction of immature rat uterus. This procoagulant has many of the properties of tissue factor, a widely occurring, integral membrane protein which initiates the intrinsic pathway of coagulation. Procoagulant activity was demonstrated to activate prothrombin in rat uterus, to activate human coagulation factor X, and to cause clot formation by human plasma. Procoagulant activity could be solubilized from the plasma membrane by the detergent octyl glucoside and had an apparent mol wt of 20,000-40,000 by gel filtration. Procoagulant activity was increased 4-fold within 3 h after immature rats were injected with estradiol. The increase was tissue- and hormone specific and was not affected by a warfarin-induced vitamin K deficiency. Coagulation factor VII was required for clot formation by the procoagulant. These properties are consistent with identification of the procoagulant as tissue factor. mRNA for tissue factor was increased in the uterus 3 h after estrogen stimulation. In the preceding paper we showed that prothrombin is increased in the immature uterus within 3 h of estrogen stimulation. The presence of increased amounts of a tissue factor-like procoagulant in the same time period suggests a functional relationship between these two proteins and a possible role for both in uterine development. Thrombin is a growth factor in fibroblasts and endothelial cells. We propose that after estrogen stimulation, prothrombin enters the uterus with the influx of plasma proteins and is activated by the procoagulant to thrombin. We suggest that thrombin might act as a paracrine factor early in the estrogen-stimulated development of the uterus.
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PMID:Estrogen regulation of a tissue factor-like procoagulant in the immature rat uterus. 229 81

Previous studies have indicated that activation of endothelial cells may lead to the production of tissue factor. We have studied the effect of endothelial cell activation and subsequent tissue factor synthesis on thrombus formation on the extracellular matrix in flowing blood. Endothelial cells were stimulated with tumor necrosis factor, endotoxin, or phorbol ester. Coverslips with activated cells or their extracellular matrix were introduced into a perfusion system and exposed to blood anticoagulated with 20 U/ml low molecular weight heparin. This concentration allowed manipulation of blood without activation of the coagulation cascade. Platelet deposition and fibrin formation were evaluated by morphometry, and fibrinopeptide A formation was assayed as a measure of thrombin generation. Activation of endothelial cells caused fibrinopeptide A generation in the perfusate and some deposition of fibrin on endothelial cells; however, platelets were not deposited. The matrix of the stimulated endothelium also caused enhanced fibrinopeptide A generation, and platelet aggregates and fibrin were deposited on the matrix. Maximal effects were observed with stimulation periods between 4 and 10 hours and were still clearly present after 18 hours. Increase in shear rate, perfusion time, and platelet number resulted in an increase in platelet adhesion, but platelet aggregate formation as a percentage of adhesion remained constant. Platelet aggregate formation and fibrinopeptide A generation were inhibited with antibodies against tissue factor or factor VIIa. Platelet aggregate formation alone was inhibited by antibodies against glycoprotein IIb/IIIa. Polymerization of fibrin on the matrix was best supported in perfusions at a low shear rate. The new in vitro thrombosis model presented here provides a powerful tool for study of the regulation of thrombogeneity by the vessel wall in response to various stimuli.
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PMID:Activation of endothelial cells induces platelet thrombus formation on their matrix. Studies of new in vitro thrombosis model with low molecular weight heparin as anticoagulant. 229 47

The anticoagulant, pharmacodynamic, and antithrombotic properties of a low molecular weight dermatan sulfate (molecular weight range 1600 to 8000, peak 4000) were compared with those of unfractionated dermatan sulfate (molecular weight range 12,000 to 45,000, peak 25,000). Anticoagulant activities were evaluated as the ability of the compounds to catalyze the inhibition of thrombin in the presence of heparin cofactor II in a purified system and to prolong the activated partial thromboplastin time or the thrombin clotting time of human and rabbit plasmas. On the basis of weight, low molecular weight dermatan sulfate was two times less potent than unfractionated dermatan sulfate. After bolus intravenous injection into rabbits, the volume of distribution of low molecular weight dermatan sulfate was 10 times larger than that of unfractionated compound, and the half-life of disappearance was two to four times longer despite a 1.4 to 2.3 times higher total clearance. The bioavailability of low molecular weight dermatan sulfate from its subcutaneous depot was 100%; it was absorbed faster from that depot than unfractionated dermatan sulfate. The antithrombotic activities of unfractionated and of low molecular weight dermatan sulfate were also examined with a Wessler-type model with tissue factor as the thrombogenic stimulus. When evaluated 3 minutes after a bolus intravenous injection, unfractionated dermatan sulfate was twice as active as low molecular weight dermatan sulfate on the basis of weight. With subcutaneous injection, 10 mg/kg of low molecular weight dermatan sulfate generated an activity in plasma equivalent to 5.6 micrograms/ml 1 hour later. This concentration was associated with a significant antithrombotic effect that lasted for less than 6 hours.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Pharmacologic properties of a low molecular weight dermatan sulfate: comparison with unfractionated dermatan sulfate. 229 56

When the endothelial cell layer is damaged, a thrombotic reaction starts on the cells' subendothelium and on the connective tissue deposited by smooth muscle cells in the deeper layers. When more severe vascular damage occurs, hemostasis will involve the vessel adventitia in which fibroblasts are found. In this article, the influence of in vitro cultured endothelial cells, smooth muscle cells, and fibroblasts on the hemostatic balance was studied. To do so, perfusions were performed with low molecular weight heparin anticoagulated blood over the extracellular matrix of the cells. This method allowed the study of tissue factor-dependent thrombin generation and its influence on formation of fibrin and platelet aggregates. The experiments described in this article show that endothelial cells isolated from different human organs interfere differently in the hemostatic response. Endothelial cells isolated from umbilical veins are nonthrombogenic; they do not synthesize tissue factor under unstimulated conditions. On their extracellular matrix, only adherent platelets are found, but no aggregates and no fibrin. Endothelial cells isolated from omentum and atrium contain tissue factor activity under unstimulated conditions. As a consequence, thrombin is generated on their surfaces, and platelet aggregates and fibrin deposition are found on the extracellular matrices after perfusions with whole blood. The matrix of smooth muscle cells and fibroblasts behaved similarly. Increase in shear rate and perfusion time resulted in an increase in platelet aggregate formation. Polymerized fibrin deposition decreased when perfusions were performed at higher shear. Both platelet aggregation and fibrin deposition were tissue factor dependent and could be blocked more than 70% by an antibody against tissue factor. Based on these results, we conclude that endothelial cells isolated from umbilical veins form the best nonthrombogenic surface in vitro. Moreover, coagulation-dependent hemostasis should be included when thrombogenicity of subendothelium is discussed, especially when it concerns matrix derived from cells present in the deeper layer of the vessel wall.
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PMID:Thrombogenicity of vascular cells. Comparison between endothelial cells isolated from different sources and smooth muscle cells and fibroblasts. 234

Antithrombotic potency of recombinant hirudins rHV2, rHV2-Lys47 and rHV2-Arg47 was studied in a model of experimental thrombosis induced by tissue factor in the rat. Venous thrombosis was induced by i.v. injection of 25 mg/kg tissue factor followed by stasis of the inferior vena cava. In this model natural recombinant hirudins, rHV2 and rHV2-Lys47 injected 5 min before thrombo-plastin totally inhibited thrombosis in the same micrograms range as heparin or natural hirudin extracted from leeches. However, the mutant variant rHV2-Arg47 gave a maximal 60% inhibition of thrombosis. Variants rHV2-Lys47 (30 micrograms/kg) and rHV2-Arg47 (157 micrograms/kg) injected 5 min before thromboplastin prevented by 90 to 100% the drop in platelet count observed during the disseminated intravascular coagulation induced by thromboplastin injection. Recombinant hirudins were less anticoagulant than heparin as measured by an APTT on rat plasma. After rat tail transection, rHV2-Lys47 caused a 2-fold smaller prolongation of the bleeding time than an equivalent antithrombotic dose of heparin. Plasmatic elimination of rHV2-Lys47 from rat plasma after i.v. injection had a fast distribution phase with a half-life of 3 min during which 90% of injected rHV2-Lys47 was lost and was followed by a slower elimination phase. Thus recombinant hirudin rHV2-Lys47 appears as a promising potent antithrombotic agent for the prevention of thrombin-dependent venous thrombosis and disseminated intravascular coagulation.
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PMID:Inhibition by recombinant hirudins of experimental venous thrombosis and disseminated intravascular coagulation induced by tissue factor in rats. 236 20

Little information is available on the prevalence and etiology of the coagulopathy present in some children with acute leukemia at disease presentation. We studied 102 children with newly diagnosed acute leukemia (50 retrospective: Group A; and 52 prospective: Group B) with prothrombin time (PT), partial thromboplastin time (PTT), thrombin time (TT), fibrinogen (FIB), and fibrin degradation products (FDP). All patients in Group B also had assessment of thrombin activation by measurement of the crosslinked fibrin fragment, D-dimer, and of primary fibrinolysis with the B beta 1-42 peptide. Additionally, ten patients from Group B had Factors II, V, VII, and X measured, and eight of these patients had measurement of tissue factor from sonicated bone marrow cells. Thirty-two percent of Group A and 40% of Group B had totally normal coagulation studies, whereas 20% of Group A and 10% of Group B had a severe coagulopathy on disease presentation. A high percentage of both groups had elevated PT (Group A, 52%; Group B, 27%) and increased FDP (Group A, 39%; Group B, 25%). In Group B, 38% of the patients had a positive D-dimer, whereas only 4% of this prospective group had an elevated B beta 1-42 peptide (P less than 0.00001). Nine of ten patients with a positive D-dimer had low levels of one or more of the extrinsic pathway factors. Three of four patients with the highest tissue factor levels were of monocytoid leukemia cell type. These data indicate that the coagulopathy associated with acute leukemia of childhood is usually mediated by thrombin activation.
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PMID:The coagulopathy of childhood leukemia. Thrombin activation or primary fibrinolysis? 238 1

We have investigated the antithrombotic properties of prothrombin fragment 1.2 (F1.2) in this study. To do this, we established the minimum concentration of human placental tissue factor or human alpha-thrombin that was lethal in mice within 5 min after intravenous injection. Prothrombin F1.2 protected the mice from the lethal effect of tissue factor or alpha-thrombin in a dose dependent manner, with 500 micrograms (14 nmoles) of prothrombin F1.2 per mouse being the minimum amount required to protect all mice from the lethal effect of either thrombogenic stimulus. The minimum dose of heparin which protected mice from the lethal effect of thrombin or tissue factor was 6 units or approximately 3.3 nmoles. The observation that prothrombin F1.2 has antithrombotic properties suggests prothrombin F1.2 can modulate coagulation in vivo, as it has previously been shown to do in vitro.
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PMID:The antithrombotic properties of human prothrombin fragment 1.2 in mice. 240 43

An anticoagulant protein was purified from the EDTA extract of human placental tissue. The purified protein had a molecular weight of 73,000 on sodium dodecyl sulfate polyacrylamide gel electrophoresis under both reducing and non-reducing conditions. Because this protein had the ability to bind phospholipids such as phosphatidylserine, phosphatidylinositol, and cardiolipin in the presence of Ca2+, this protein was designated as calphobindin II (CPB-II). CPB-II prolonged the clotting time of normal plasma when coagulation was induced by tissue factor, cephalin and ellagic acid or recalcification, but did not affect thrombin-initiated fibrin formation. CPB-II also inhibited the activation of prothrombin by the complete prothrombinase complex or factor Xa-phospholipid-Ca2+ but not that by phospholipid-free factor Xa. In addition, CPB-II had an inhibitory activity against phospholipase A2.
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PMID:Isolation and characterization of an anticoagulant protein from human placenta. 252 73

In addition to calphobindin-I (a placental coagulation inhibitor), another anticoagulant protein (calphobindin-II) was isolated from the EDTA extract of human placenta. The purified protein had a molecular weight of 68,000 daltons according to sodium dodecyl sulfate polyacrylamide gel electrophoresis under both reduced and non-reduced conditions. This protein prolonged prothrombin time, activated partial thromboplastin time and recalcification time, but did not affect thrombin time. This substance also inhibited both factor X activation by a complex of [factor VII-tissue factor-Ca2+] and factor II activation by a complex of [factor Xa-phospholipid-Ca2+]. This protein was a stronger anticoagulant than calphobindin-I.
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PMID:[Isolation of calphobindin-II and its mechanism of anticoagulant activity]. 253 Nov 90

We have studied the effects of two human pancreatic cancer and two human small cell lung cancer cell lines on clotting and platelet aggregation. Both pancreatic lines markedly shortened recalcification times and induced platelet aggregation. The lung cancer lines produced little shortening of recalcification times and no platelet aggregation. The clotting and aggregation activities of the pancreatic lines were further characterized. Recalcification times following the addition of cancer cell line material to plasmas deficient in factors VII and X were markedly prolonged, suggesting that the activity is due to tissue factor. Hirudin, an inhibitor of thrombin from the saliva of leeches, and rabbit polyclonal immunoglobulin G anti-bovine brain tissue factor inhibited both procoagulant and aggregation activities. Apyrase (an enzyme degrading ADP), diisopropylfluorophosphate (a serine protease inhibitor) and L-trans-epoxysuccinylleucylamido(4-guanidino)butane (a cysteine protease inhibitor) failed to inhibit these activities. Increasing concentrations of heparin inhibited platelet aggregation. Subcellular fractionation studies showed these activities to be localized to the plasma membrane. The association between mucin and the acceleration of clotting has been well described. The absence of mucin in electron micrographs of these pancreatic whole cells, membrane fractions, and shed microvesicles, as well as the failure of chaotropic agents (i.e., agents stripping material extrinsic to the cell membrane such as mucin) to abrogate this activity support these activities being intrinsic to the plasma membrane. These data strongly suggest that these activities are due to tissue factor which appears to be released as microvesicles in vitro. The release of tissue factor via microvesicles in vivo is one possible mechanism for the coagulopathy sometimes seen in patients with pancreatic carcinoma.
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PMID:Identification of tissue factor in two human pancreatic cancer cell lines. 254 21

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