EC:3.4.21.73 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.4.21.73 (urokinase-type plasminogen activator)
10,685 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Procoagulant, anticoagulant, and fibrinolytic activities are associated with endothelial cells and involve the production, secretion, and receptor mediated binding of proteins involved in these processes. The procoagulant aspect of endothelial cells function involves the production and release of von Willebrand Factor(vWF), the production of tissue factor, and the presence of Factor IX/IXa receptors on the cell surface. Secretion of vWf will promote the initial steps in thrombus formation by supporting platelet-platelet interaction and platelet-subendothelial matrix adhesion. Tissue factor which is undetectable in resting cells appears after exposure to various cytokines and initiates factor VIIa activation of factors IX and X. Receptors of Factor IX/IXa are also present and mediate the assembly of the prothrombinase complex on the endothelial cell surface. The anticoagulant pathway involves the cell surface protein thrombomodulin, protein C and its cofactor protein S. Thrombomodulin binds thrombin which activates protein C which in the presence of protein S cleaves and inactivates Factors V and VIII. Inactivation of these two coagulation cofactors halts the coagulation. Finally, endothelial cells also play a pivotal role in the fibrinolytic system. Production and regulated secretion of tissue plasminogen activator creates a profibrinolytic state in the endothelial cell environment. In addition, receptors for plasminogen and urokinase are also present, constituting a cell surface mediated fibrinolytic pathway. Plasminogen activator inhibitor type I, the primary inhibitor of tPA, is also produced by endothelial cells. Thus endothelial cells can promote and inhibit fibrinolysis, depending on the prevailing environmental conditions.
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PMID:[Endothelial cells and vascular hemostasis]. 131 12

The in vitro effects of thrombomodulin on the inactivation of single chain urokinase-type plasminogen activator (scu-PA) by thrombin were investigated by incubating scu-PA with varying concentrations of human thrombin, in both the absence and presence of soluble rabbit thrombomodulin. 50% inactivation of scu-PA occurred in 45 min at 160 ng/ml thrombin in the absence of thrombomodulin and at 4.6 ng/ml thrombin in the presence of thrombomodulin. No difference was found in either the absence or the presence of thrombomodulin between the inactivation rates of high molecular weight scu-PA, and a low molecular weight scu-PA which lacked the growth factor and kringle domains. Enzyme kinetic experiments with varying concentrations of scu-PA showed that thrombomodulin decreased the Km of thrombin for scu-PA from 7.8 to 0.43 microM and increased the kcat from 0.30 to 1.2 s-1, corresponding to a 70-fold increase in the second-order rate constant kcat/Km. SDS-polyacrylamide gel electrophoresis showed that scu-PA was cleaved into two chains upon inactivation by thrombin, and confirmed the acceleration effect of thrombomodulin on inactivation of scu-PA. Thrombomodulin thus not only has anticoagulant properties but is also antifibrinolytic. The acceleration may imply a new mechanism for the regulation of local plasminogen activator activity on the cell surface.
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PMID:Acceleration of the thrombin inactivation of single chain urokinase-type plasminogen activator (pro-urokinase) by thrombomodulin. 165 49

Thrombomodulin (TM), a membrane proteoglycan on endothelial cells, binds thrombin in a 1:1 complex, accelerates the protein C activation by thrombin, promotes the thrombin inactivation by antithrombin III and inhibits the procoagulant properties of thrombin. The inactivation of single-chain urokinase-type plasminogen activator (scu-PA) by thrombin is accelerated about 70-fold by TM [De Munk, Groeneveld and Rijken (1991) J. Clin. Invest. 88, 1680-1684]. The present study investigates the role of the O-linked glycosaminoglycan moiety of TM in the latter reaction. In the presence of an excess of a fully-glycosylated soluble recombinant human TM mutant (high-Mr rec-TM), 0.11 nM thrombin inactivated 50% of 4.4 nM scu-PA in 45 min at 37 degrees C. In the presence of a soluble recombinant TM mutant lacking the glycosaminoglycans (low-Mr rec-TM), 1.9 nM thrombin was needed to inactivate 50% scu-PA, as compared with 4.7 nM thrombin in the absence of TM. Using the scu-PA inactivation assay the dissociation constant for the thrombin-TM interaction was found to be 0.4 nM for high-Mr rec-TM and 14 nM for low-Mr rec-TM. Treatment of high-Mr rec-TM with chondroitinase ABC to digest the glycosaminoglycans decreased the accelerating effect to the level of low-Mr rec-TM. A similar decrease was observed after treatment of solubilized rabbit TM with chondroitinase ABC. As expected, chondroitinase ABC had no influence on the accelerating effect of low-Mr rec-TM. The free glycosaminoglycans obtained by alkaline treatment of TM or chondroitin sulphate A also accelerated the inactivation of scu-PA by thrombin, but about 1000-fold higher concentrations than with TM were needed to obtain the same acceleration. It is concluded that the major glycosaminoglycan of TM plays a pivotal role in the inactivation of scu-PA by the TM-thrombin complex, both in the formation and in the activity of the complex.
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PMID:Role of the glycosaminoglycan component of thrombomodulin in its acceleration of the inactivation of single-chain urokinase-type plasminogen activator by thrombin. 838 42

Thrombomodulin (TM) expressed on endothelial cells binds thrombin and initiates anticoagulant pathways. Soluble functional proteolytic fragments of TM are also present in circulating plasma. Recently, it was reported that TM accelerated thrombin-dependent plasma procarboxypeptidase B (pro-pCPB) activation in a purified system and suggested that TM may inhibit fibrinolysis in crude plasma. The aim of present study was to evaluate any functional role of soluble TM fragments in plasma or purified TM added into plasma to the regulation of coagulation and fibrinolysis. Addition of rabbit TM (1-200 ng/ml) to plasma resulted in a concentration-dependent prolongation of urokinase (UK)- or tissue plasminogen activator (t-PA)-induced clot lysis time. The concentration of TM required for the inhibition of fibrinolysis was lower than that required for the inhibition of coagulation. Addition of anti-rabbit TM IgG or anti-human TM IgG into plasma reduced UK- or t-PA-induced clot lysis time without affecting clotting times, indicating that exogenous TM or soluble TM fragments in normal human plasma participated in regulation of fibrinolysis. Moreover, the TM-dependent inhibition of fibrinolysis was observed only in the presence of thrombin and blocked by addition of carboxypeptidase B inhibitors, but not mediated by protein C activation or direct inhibition of UK, t-PA or plasmin. Analysis of various substrates and inhibitors indicated that TM accelerated thrombin-dependent pro-pCPB activation in plasma. The present results indicate that TM, including soluble TM fragments in plasma, inhibit fibrinolysis via activation of pro-pCPB in plasma.
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PMID:Thrombomodulin in human plasma contributes to inhibit fibrinolysis through acceleration of thrombin-dependent activation of plasma procarboxypeptidase B. 949 93

Thrombin cleaves single-chain urokinase-type plasminogen activator (scu-PA) into a virtually inactive two-chain form (tcu-PA/T), a process which may contribute to the maintenance of a fresh blood clot. We have examined the inactivation of scu-PA by thrombin in a plasma milieu to get more insight in the physiological relevance of this phenomenon. Citrated pooled normal plasma was treated with thrombin in the absence and presence of thrombomodulin. After an incubation period of 30 min the concentrations of scu-PA and tcu-PA/T were measured using specific bioimmunoassays. The inactivation of scu-PA in citrated plasma was found to be stimulated fourfold by thrombomodulin. Kinetic experiments showed that the inactivation of scu-PA by thrombin in the absence and presence of thrombomodulin occurred rapidly and declined within 1 min as a result of rapid inhibition by antithrombin III (ATIII) and other possible inhibitors. Calcium had no direct effect on the inactivation of scu-PA by exogenously added thrombin in the absence and presence of thrombomodulin. However, recalcification of plasma induced significant inactivation of scu-PA in plasma as a result of endogenous thrombin generation through the contact activation system. This calcium-induced inactivation of scu-PA was completely abolished in the presence of thrombomodulin, most likely as a result of activation of protein C by the complex formed between thrombomodulin and endogenously generated thrombin. Thrombomodulin thus appeared to play a dual role both by stimulating the inactivation of scu-PA by thrombin, and by inhibiting calcium-induced inactivation of scu-PA in plasma. In the plasma from a patient heterozygous for protein C deficiency, thrombomodulin could not prevent calcium-induced generation of tcu-PA/T, whereas the stimulating effect of thrombomodulin predominated instead. This result implied that disturbance of the protein C pathway may lead to the inactivation of substantial amounts of scu-PA in plasma under (patho)physiological circumstances and may provide an additional explanation for the association found between thromboembolism and deficiencies in the protein C pathway. This study shows that the amount of scu-PA that is inactivated in plasma depends mainly on the generation of thrombin and on thrombomodulin. We conclude that the inhibition of scu-PA-induced fibrinolysis appears to be regulated by activation of the coagulation system, providing a link between coagulation and fibrinolysis.
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PMID:The inactivation of single-chain urokinase-type plasminogen activator by thrombin in a plasma milieu: effect of thrombomodulin. 971 90

During normal pregnancy the hemostatic balance changes in the direction of hypercoagulability, thus decreasing bleeding complications in connection with delivery. The most important initial factor for acute hemostasis at delivery is, however, uterine muscle contractions, which interrupt blood flow. Global tests such as Sonoclot signature, the Thromboelastogram, and a new method analyzing overall plasma hemostasis, all show changes representative of hypercoagulability during pregnancy. Increased endogenous thrombin generation, acquired activated protein C resistance, slightly decreased activated partial thromboplastin time (aPTT) and increased prothrombin complex level (PT) measured as international normalized ratio (INR) of less than 0.9 have been reported as well. In normal pregnancy, the platelet count is within normal range except during the third trimester when benign gestational thrombocytopenia, 80 to 150 x 10 9/L, can be observed. Platelet turnover is usually normal. Activation of platelets and release of beta-thromboglobulin and platelet factor 4 are reported. The bleeding time is unchanged during normal pregnancy. Most blood coagulation factors and fibrinogen increase during pregnancy. Factor (F) XI is the only blood coagulation factor that decreases. Blood coagulation inhibitors are mainly unchanged but the level of free protein S decreases markedly and the level of tissue factor pathway inhibitor increases. Thrombomodulin levels increase during pregnancy. Fibrinolytic capacity is diminished during pregnancy, mainly because of markedly increased levels of plasminogen activator inhibitor-1 (PAI-1) from endothelial cells and plasminogen activator inhibitor-2 (PAI-2) from the placenta. Thrombin-activated fibrinolysis inhibitor is reported to be unaffected. The total hemostatic balance has been studied by analyses of prothrombin fragment 1+2, thrombin-antithrombin complex, fibrinopeptide A, soluble fibrin, D-dimer, and plasmin-antiplasmin complex. There is activation of blood coagulation and a simultaneous increase in fibrinolysis without signs of organ dysfunction during normal pregnancy. These changes increase as pregnancy progresses. During delivery, there is consumption of platelets and blood coagulation factors, including fibrinogen. Fibrinolysis improves and increases fast following childbirth and expulsion of the placenta, resulting in increased D-dimer levels. These changes are self-limiting at normal delivery. The hemostatic changes, noted during pregnancy, normalize after delivery within 4 to 6 weeks. Platelet count and free protein S, however, can be abnormal longer. Hemostasis should not be tested earlier than 3 months following delivery and after terminating lactation to rule out influences of pregnancy. PAI-1 and PAI-2 levels decrease fast postpartum, but PAI 2 has been detected up to 8 weeks postpartum. alpha 2 -antiplasmin, urokinase, and kallikrein inhibitor levels have been reported to be increased 6 weeks postpartum.
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PMID:Hemostasis during normal pregnancy and puerperium. 1270 15

Hepatitis C virus (HCV) infects hepatocytes and utilizes the hepatocyte to replicate. In so doing, many hepatocyte activities are shifted from their native state to one reflecting liver cell stress. Thrombomodulin and tissue factor are endothelial cell proteins that are expressed as a result of tissue injury or stress. Urokinase is a serine protease, which has been implicated in a number of physiologic and pathologic processes related to cellular stress and or injury. Nitric oxide is produced by cells in response to injury and functions both as a vasodilator and as an activator of a large number of cytokine cascades. NFkappaB is a transcription factor that forms one of the first lines of cellular defense against infection and hepatocellular stress. The levels of these four factors in plasma, hepatocyte cytosol and hepatocyte nuclear extracts provide a precise panoramic measure of cellular stress. Plasma, hepatocyte cytosol and nuclear extracts of hepatocytes were assayed for these four factors in 17 patients treated with alphaIFN for chronic hepatitis C. Five of the 17 were responders while 12 were nonresponders. Ten normal controls and 1 normal control liver were assayed also for each parameter. Nonresponders had 2x the plasma urokinase levels of responders and normals. The cytosol prepared from hepatocytes of nonresponders had a urokinase level 15-fold that of the controls and responders to IFN therapy. Plasma thrombomodulin levels in nonresponders were sixfold greater than those of responders and controls. The levels of all of the other measures in plasma, cytosol and nuclear extracts of liver tissue varied minimally between responders and nonresponders and the normal controls. These data demonstrate that: (i) urokinase levels in plasma and more clearly in cytosol are greater in nonresponders than responders, and (ii) plasma thrombomodulin levels in nonresponders are sixfold greater than those of responders and controls. These data suggest that urokinase and thrombomodulin may be unique markers of cellular and endothelial stress present in individuals with chronic hepatitis C. These markers might be useful during the clinical course of chronic hepatitis C, as a means of gauging the tissue response to therapy.
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PMID:Plasma and hepatic tissue levels of thrombomodulin, tissue factor, NFkappaB and nitric oxide in responders and nonresponders to IFNalpha therapy. 1296 88

Endothelial cells are the main sensors of changes in the biomechanical flow environment and play a pivotal role in vascular homeostasis. An in vitro perfusion model was developed to study the regulatory effect on gene expression by different flow and pressure profiles. Human umbilical vein endothelial cells were grown to confluence inside capillary microslides or silicone tubes. Thereafter, they were exposed to different levels of shear stress or different levels of static or pulsatile pressure. Genes representing various hemostasis functions of the endothelial cells were analyzed. Shear stress was a more effortful stimulus than static or pulsatile tensile stress. Although shear stress affected mRNA expression of all six studied genes (tissue-type plasminogen activator [t-PA], plasminogen activator inhibitor [PAI]-1, Thrombomodulin [TM], urokinase-type plasminogen activator [u-PA], vascular cell adhesion molecule [VCAM-1], and endothelial nitric oxide synthase [eNOS]), none of the genes was found regulated by pressure. Shear stress down-regulated t-PA and VCAM-1 in a dose response-dependent way, and up-regulated TM. u-PA, eNOS, and PAI-1 were up-regulated by shear stress, but there was no obvious dose-response effect for these genes. These findings suggest that shear stress has a more powerful gene regulatory effect on endothelial gene expression than tensile stress. Low shear stress induced a more proatherogenic endothelial surface but preserved t-PA gene expression levels compared to high shear stress.
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PMID:Effects of two complex hemodynamic stimulation profiles on hemostatic genes in a vessel-like environment. 1906 14