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

Modifications of urokinase by substances possessing useful therapeutic activity permit combined action preparations to be obtained. Here an attempt was made to develop a complex having combined action for therapeutic activity. The possibility of repeatedly modified urokinase with antithrombin-III-methyldopa-prostaglandin E1 had been experimentally demonstrated. The complex was immobilized on albuminated substrate, which showed fibrinolytic, anticoagulant, and antiplatelet effects simultaneously, in addition to the normal antihypertensive action of methyldopa. The complex immobilized substrate also demonstrated an increase in albumin-surface attachment and a reduction in fibrinogen binding. This may be one of the parameters for a reduced platelet-surface attachment, which may also improve the blood compatibility of the substrate. The approaches suggested indicate the possible new ways of creating nonthrombogenic surfaces with wider applications. A better understanding of the mechanism of these complexes are needed in in vivo conditions to correlate these findings.
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PMID:The preparation of a urokinase-AT-III-PGE1-methyldopa complex, and its effects on platelet adhesion, coagulation times, protein adsorption, and fibrinolysis. 276 62

We have used purified protease nexin-I (PN-I) from human fibroblasts to develop a polyclonal antibody that specifically blocks the PN-I-mediated cellular binding of thrombin and urokinase. Anti-PN-I IgG did not inhibit the binding of 125I-epidermal growth factor-binding protein to fibroblasts, which is mediated by protease nexin-II, another cell-secreted, serine protease inhibitor that is distinct from PN-I. This furthers the belief that the protease nexins are distinct from one another. In addition, while anti-PN-I IgG immunoprecipitated PN-I X thrombin complexes, it did not do so with antithrombin-III X thrombin. Metabolically labeled PN-I was also immunoprecipitated by IgG, indicating that the protein can be labeled in vivo. The antibody also recognized primarily one band on Western transfers of conditioned medium from fibroblast cultures. These results suggest that anti-PN-I will be useful in probing the physiological role of PN-I as well as its biosynthesis.
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PMID:Human protease nexin-I. Further characterization using a highly specific polyclonal antibody. 394 Oct 97

A method is described for distinguishing coagulation from fibrinolysis by three estimates of fibrinogen. This "fibrinogen series" together with plasma antithrombin and urinary urokinase have been compared in pregnant patients with venous thrombosis and pre-eclampsia. Evidence is presented for active coagulation during deterioration of the pre-eclampsia state and for enhanced fibrinolysis during improvement.
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PMID:Assessment of coagulation and fibrinolysis in pre-eclampsia. 459 83

The digestion of fibrinogen with various concentrations of trypsin results in the formation of a variety of degradation products. Degradation products formed in this way have been purified by DEAE cellulose column chromatography and their effects on platelet aggregation investigated.TWO METHODS HAVE BEEN USED TO STUDY PLATELET AGGREGATION: a turbidimetric method which assesses platelet aggregation by the ability of adenosine diphosphate (ADP) to clump platelets and a method which assesses platelet adhesiveness by their ability to adhere to glass and to each other (modified Hellem technique, 1960). Three breakdown products produced by trypsin-digested fibrinogen were studied and all showed ;antithrombin' activity: two inhibited platelet aggregation, but one accelerated aggregation in both systems. Another product prepared by digestion of fibrinogen with urokinase-activated plasminogen has been shown to possess the ability to enhance ADP-induced platelet aggregation.
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PMID:McNicol GP,+MACNICOL GP, Douglas AS: Effect of fibrinogen degradation products on platelet aggregation. 575 42

The variations of different antiplasmins were studied in a group of patients suffering from thromboembolic conditions and receiving three different regimens of thrombolytic treatment with streptokinase and urokinase. The evaluation of the antiproteases was carried out by chromogenic substrate and radial immunodiffusion. The different administration patterns of the fibrinolytic agents were followed by a clear drop in fast antiplasmin and alpha 2-macroglobulin, while alpha 1-antitrypsin was increased. Antithrombin-III activity was reduced while its protein rose in the intermittent treatment with streptokinase. In the conventional treatment with streptokinase, both the activity and the protein of antithrombin-III increased. With urokinase both the protein and the activity of antithrombin-III were slightly reduced. Plasminogen and fibrinogen decreased in the different regimens of thrombolytic treatment, being more evident in continuous administration of streptokinase.
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PMID:Plasmin inhibitors in different fibrinolytic treatment patterns. 616 21

Since the introduction of synthetic chromogenic and fluorogenic peptide substrates from serine proteases, the testing of coagulation has undergone a dramatic conceptual and methodological change. The concept of coagulation profiling has emerged and automated methodologies are being introduced. Synthetic substrate methods for the evaluation of antithrombin-III; progressive antithrombin; plasminogen; antiplasmin; prekallikrein; antikallikrein ; alpha 1-antitrypsin; prothrombin; heparin; platelet factor IV; urokinase; tissue activator of plasminogen; factor assays; amidolytic equivalents of prothrombin time; and partial thromboplastin time have been developed. Studies on antithrombin-III indicate that immunological methods evaluate the total immunoreactive-antithrombin-III (antigenic) level and do not discriminate between functionally active forms and the AT-III serine protease complex. The clinical significance of AT-III measured by immunological methods is highly questionable. The coagulant assays for the measurement of AT-III require purified alpha-thrombin preparations. The noncoagulant forms of thrombin (beta- and gamma-) result in falsely low antithrombin-III quantitation. The molecular heterogeneity in a given thrombin preparation if standardized in terms of its amidolytic activity does not produce any errors in the quantitation of AT-III levels with synthetic peptide methods. None of the immunological methods provide clinically relevant information except in normal plasma where the immunological and functional activities are identical. Analysis of pathologic plasma samples using laser nephelometry, radial immunodiffusion and radioimmunoassay methods revealed that the functional activity of various serine protease inhibitors is greatly reduced but the reduction in the immunological quantities is minimal. Since coagulation proteins are functional, a ratio between their functional activity and absolute protein levels may be a useful parameter. Employing human and bovine thrombin; bovine and human Xa with their respective substrates, the absolute quantitation of heparin is satisfactorily carried out, however, these assays only measure heparin concentrations and do not reflect the overall anticoagulant effect of heparin. Using the synthetic substrates, the value of measuring absolute concentrations of heparin in a patient on heparin therapy is questionable. With the introduction of fluorogenic substrates, the presence of activated coagulation factors may be demonstrated in patients with thrombotic disorders.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Synthetic peptide substrates in hemostatic testing. 637 39

We examined in patients with acute myocardial infarction (AMI) the pharmacokinetics of saruplase, an unglycosylated, single chain, urokinase-type plasminogen activator (rscu-PA) by measuring urokinase-type plasminogen activator (u-PA) antigen and total u-PA activity, its conversion to active two-chain urokinase-type plasminogen activator (tcu-PA) and evaluated its effect on haemostatic parameters. Twelve patients were studied during and after administration of 20 mg bolus plus 60 mg continuous 1 h i.v. infusion of saruplase. For u-PA antigen and total u-PA activity (expressed as protein equivalents), where 234 U corresponds to 1 microgram, respectively, steady state plasma concentrations were 2.75 +/- 8.3 and 2.50 +/- 7.0 micrograms/ml (mean +/- standard deviation) and were reached within 20 min, t1/2 lambda 1 was 9.1 +/- 1.8 and 7.8 +/- 1.3 min, t1/2 lambda 2 1.2 +/- 0.2 and 1.9 +/- 0.5 h, and the total clearance was 393 +/- 110 and 427 +/- 113 ml/min. Inactivation of saruplase in plasma was negligible. After 15 min, tcu-PA was detected in plasma. From the ratio of the areas under the curve of tcu-PA and total u-PA activities it was calculated that 28 +/- 9.3% of the saruplase dose is converted into active tcu-PA. Systemic plasminaemia occurs as shown by a decrease in alpha 2-antiplasmin and fibrinogen and an increase in fibrinogen degradation products. Thrombin-antithrombin complex formation indicated activation of the clotting system. Saruplase is eliminated rapidly from plasma in AMI patients.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Pharmacokinetics and pharmacodynamics of saruplase, an unglycosylated single-chain urokinase-type plasminogen activator, in patients with acute myocardial infarction. 753 46

Thrombolytic agents are widely used for the treatment of acute thromboembolic diseases, especially acute myocardial infarction (AMI). These compounds include streptokinase, anistreplase, alteplase, urokinase and, although not commercially available yet, saruplase (prourokinase). The therapeutic window of these compounds is relatively small and subtherapeutic or toxic plasma concentrations may have serious clinical implications (insufficient thrombolysis, reocclusion and bleeding). Among the factors that affect the pharmacokinetics and pharmacodynamics of thrombolytic agents, comedication is especially relevant since these drug interactions are partly predictable and sometimes preventable. Based on knowledge of the pharmacology of thrombolytic agents and general mechanisms by which pharmacokinetic drug interactions occur, interactions with alteplase and saruplase are expected. The clearance of alteplase is dependent on hepatic blood flow (HBF), and scientific evidence is emerging that saruplase is also a high-clearance compound. Each pharmacological agent that alters HBF and is given concurrently with one of these agents can change the plasma concentrations of those thrombolytics. Although there are no published data confirming drug-induced changes in the metabolism of alteplase or saruplase by this mechanism in humans, indirect supportive evidence (clinical observations and animal experiments) is available. An overview is presented of the anticipated effects of compounds that are frequently coadministered with thrombolytic agents on the pharmacokinetics of the thrombolytics with high-clearance properties. Since the clearance of these thrombolytics may be strongly affected by hypoperfusion of the liver as a result of cardiogenic haemodynamic failure, the role of circulatory changes in potential drug-drug interactions is also discussed. Pharmacodynamic drug interactions are highly relevant in the treatment of acute thrombotic lesions and are still being evaluated to further optimise treatment strategies. As most of these treatments exist as combinations of thrombolytic, antithrombin and antiplatelet compounds, beneficial effects are partly offset by bleeding complications. Changes in the pharmacokinetics and/or pharmacodynamics of thrombolytic agents may have serious consequences. It becomes imperative for the practising physician to be aware of benefits and risks of interactions with thrombolytic agents and especially of the fact that the principal way by which the pharmacokinetics of alteplase and, presumably, saruplase can be affected is by drug- and/or haemodynamic failure-induced changes of HBF.
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PMID:Drug interactions with thrombolytic agents. Current perspectives. 764 59

Endothelial release of tissue plasminogen activator (t-PA) may initiate fibrinolysis. Fibrinolysis and coagulation were investigated in 12 patients undergoing elective coronary artery bypass surgery. Cardiopulmonary bypass (CPB) was 108 +/- 7 min (mean +/- SEM), the time of cold, crystalloid, retrograde cardioplegia 53 +/- 5 min. Arterial and coronary sinus blood were sampled concomitantly before cardioplegia and after release of the aortic cross-clamp, for measurement of t-PA antigen (Ag) and activity, plasminogen activator inhibitor (PAI-1) Ag and activity, t-PA/PAI-1 complex, single chain urokinase (sc-uPA) and urokinase (uPA) plasminogen activators, the fibrin split product D-dimer, thrombin-antithrombin complex (TAT), and the prothrombin split product F 1 + 2. Cardiopulmonary bypass significantly increased t-PA Ag and activity, t-PA/PAI complex, D-dimer, TAT, and F 1 + 2, and decreased PAI-1 Ag and activity in arterial blood; uPA and sc-uPA were unchanged. The tissue plasminogen activator antigen was higher in coronary sinus than arterial blood after 1 (39 +/- 5 vs 24 +/- 4 ng/ml, P < 0.003), 4 (P < 0.003), and 10 min (P < 0.004) reperfusion. Tissue plasminogen activator activity and t-PA/PAI complex increased, PAI-1 activity decreased, while all other parameters were unchanged across the coronary circulation. In conclusion, CPB induces fibrinolysis and coagulation. Cold cardioplegia induces t-PA release in the coronary circulation, denoting a postischemic antithrombotic function of the coronary endothelium. Tissue plasminogen activator may be used to evaluate endothelial stimulation or injury induced by CPB, or by different regimens of myocardial protection.
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PMID:Fibrinolysis during cardiac surgery. Release of tissue plasminogen activator in arterial and coronary sinus blood. 808 78

Thrombolytic therapy paradoxically induces the formation of fibrinopeptide A, fibrin degradation products and thrombin-antithrombin complexes, indicating thrombin generation. Part of the mechanism of this thrombin generation under the influence of thrombolytic agents was unraveled in this study. We measured thrombin with a chromogenic substrate at several time intervals after recalcification of citrated plasma which had been preincubated with urokinase, streptokinase, recombinant tissue plasminogen activator (rt-PA) or recombinant single-chain urokinase-type plasminogen activator (rscu-PA). Thrombin generation induced by the addition of thromboplastin together with calcium (extrinsic pathway) was greatly accelerated in the presence of streptokinase (from about 7 to 2 min), and to a lesser extent in the presence of urokinase, rt-PA or rscu-PA. Similar effects were seen after the addition of calcium to the plasma containing the thrombolytic agent and preincubated with partial thromboplastin (intrinsic pathway). Hirudin quenched the conversion of the chromogenic substrate completely, confirming that thrombin was the active enzyme. Aprotinine did not affect the results, and the effect of streptokinase was also observed in plasminogen-depleted plasma. We conclude that streptokinase, and to a lesser extent other thrombolytic agents, activate the prothrombinase complex directly or indirectly through a calcium-dependent mechanism, independently of plasminogen, with a resulting acceleration of thrombin generation.
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PMID:Thrombin generation induced by the intrinsic or extrinsic coagulation pathway is accelerated by streptokinase, independently of plasminogen. 816 24


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