EC:3.4.21.73 - FACTA Search

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 (0.01 seconds)

A method is described for the purification of antiactivator from bovine euglobulin-free serum by means of gelfiltration and ion exchange chromatography. The purified antiactivator has no antifibrinolytic activity. It has a molecular weight of about 115,000 and it appears to be a gamma globulin. The dissociation constant of its complex with urokinase is 1.6 x 10(-9) M and the maximum urokinase binding is close to 2000 CTA units per mg. Its concentration in bovine serum is 0.37%. Flufenamate displaces urokinase from the antiactivator at very low concentrations, about 10(-4) M. Cysteine restores its activity if lost by standing. Also an antifibrinolysin fraction is obtained free of antiactivator activity.
...
PMID:Purification and properties of an antiactivator fraction from bovine serum. 9 70

Urokinase, the plasminogen activator from human urine, produces a dose-dependent increase in blood flow in the canine superior mesenteric artery when injected intraarterially at doses from 10(-1) to 10(3) units kg-1. This vasodilation persists despite blockade of beta-adrenergic and histamine H1 and H2 receptors as well as inhibition of plasminogen activation, suggesting that these mechanisms are not involved. Infusion of urokinase at 10(2) CTA (Committee on Thrombolytic Agents) units kg-1 min-1 does not produce a sustained vasodilation, but is effective in achieving complete lysis of thrombi within 100 min in the superior mesenteric arterial circulation. Increasing the dose slightly to 125 CTA units kg-1 min-1 results in unwanted clotting abnormalities without attaining a vasodilator level. Decreasing the dose to 75 CTA units kg-1 min-1 still results in complete thrombolysis. In contrast to the results in the femoral circulation, the dose required for fibrinolysis-thrombolysis does not overlap with that for vasodilation in the superior mesenteric artery. Nevertheless, these experiments provide some basis for the use of intraarterial urokinase infusion in the treatment of nonocclusive mesenteric ischemia and, perhaps, thrombotic occlusion of the superior mesenteric artery.
...
PMID:Vasodilation, fibrinolysis, and thrombolysis with intraarterial infusion of urokinase in the canine superior mesenteric artery. 9 90

125I-fibrinogen, adsorbed to polystyrene tubes at low ionic strength and treated with thrombin, serves as a substrate for a rapid, convenient, and sensitive test tube assay for plasmin and activators and inhibitors of this enzyme. 125I-labeled digestion products released from the 125I-fibrin-polystyrene matrix are readily separated and quantitated and behave, on gel permeation, in the same manner as plasmin-generated degradation products from an unlabeled conventional fibrin clot. The 125I-fibrin, in probable non-cross-linked form, is firmly bound to the polystyrene and is resistant to nonspecific release, with control (no enzyme) values equivalent to 15.2 ng +/- 1.2 (SD) fibrin (1% of the total bound 125I-fibrin). This fact permits consistent detection of lysis of 30-50 ng 125I-fibrin, which exceeds published sensitivities (1000-5000 ng) using 125I- or fluorochrome-labeled fibrin clots as substrate. The sensitivity for plasmin (0.2 mug/ml) is tenfold greater than that of the fibrin-plate method (2.0-2.5 mug/ml), while sensitivities for streptokinase and urokinase activation of plasmin are 0.02 U/ml and 0.04 CTA U/ml, respectively (sensitivity of fibrin-plate method, 0.5 U/ml for both). The method provides a reasonable analogue of the solid-phase nature of fibrin under physiologic conditions, and the ease of preparation of large batches of tubes makes the method suitable for large-scale screening of factors modulating the plasminogen-plasmin system.
...
PMID:A rapid and sensitive 125I-fibrin solid-phase fibrinolytic assay for plasmin. 12 94

The effect of a cadaver-derived vascular plasminogen activator (VA) on the degradation of fibrinogen, soluble fibrin monomer, and fibrin was studied and compared with the effect of equivalent fibrinolytic potencies of streptokinase (SK), urokinase (UK), and plasmin. The proteolytic activity of the three activators and plasmin was determined by a standard fibrin plate assay and was expressed in CTA units from a UK reference curve. Fibrinogen degradation was measured by clottable protein determinations and by an electrophoretic technique sensitive to small changes in the molecular weight of fibrinogen. When VA was incubated in plasma, no degradation of fibrinogen occurred, whereas rapid fibrinolysis took place after the plasma was clotted. By contrast, equivalent potencies of SK, UK, and plasmin caused extensive fibrinogenolysis. Since the plasmin added and that formed by the three activators had equivalent fibrinolytic activity, the failure of VA to induce fibrinogen degradation was attributed to antiactivators rather than antiplasmins. VA activity in plasma was consumed by clotting, whereas the antiactivator activity remained in the serum, suggesting dissociation of the VA-antiactivator complex on the fibrin clot. Fibrinogen and its soluble derivatives resisted degradation by VA in plasma because a solid phase appeared necessary for the complex to dissociate. The findings indicated that the degradation of fibrinogen or soluble fibrin in blood as a result of plasminogen activation by VA was unlikely to occur due to a large excess of antiactivator activity. Alternative pathways for their catabolism are discussed.
...
PMID:The resistance of fibrinogen and soluble fibrin monomer in blood to degradation by a potent plasminogen activator derived from cadaver limbs. 12 95

A simple plasminogen determination method is presented. It is based upon the conversion of plasminogen into activator by large and constant amounts of streptokinase. The activator contained in a standard coagulum consisting of bovine fibrin, streptokinase, and a 1:40 dilution of human plasma converts the plasminogen adsorbed on bovine fibrin into plasmin. Lysis of the test coagulum is hereby induced. The speed of such lysis is limited by the concentration of the activator incorporated in the test coagulum. The variable component of the activator being human plasminogen, the speed of lysis is directly dependent upon the concentration of human plasminogen in the standard coagulum. Using the thromboelastograph according to Hartert in recording the test clot lysis times, this method of plasminogen determination was shown to be a simple and quick procedure. The standard deviation ranged from +/- 13,2 tp 68%, depending upon the plasminogen value to be measured (lower rates of error were attached to high, and higher rates of error to low, plasminogen concentrations). The biological variation of plasminogen values in a group of 26 men aged from 40 to 65 years was calculated to be +/- 21%. Both plasminogen and plasmin, its activated form, were exchangeable in the test, i.e. plasminogen determinations performed by activator assay did not differentiate between plasminogen and plasmin. There was no influence by varying anti-SK titers in the plasma up to a circulating antibody content of 2 million. Furthermore, plasma antiplasmins did not affect the plasminogen measuring system. Plasminogen tested by activator assay displayed values closely related to those achieved by immunochemical methods. Plasminogen measurements were performed in patients undergoing streptokinase and urokinase infusion treatment. 5,000 u streptokinase per hour, as well as 270,000 CTA-u urokinase per hour, infused over a period of 2 days produced a fall in plasminogen down to 30-60% of normal. In contrast, 100,000 u streptokinase per hour lowered the plasminogen concentration down to values of below 1%. The foregoing data indicate that plasminogen measurement, according to the principles outlined here (activator assay), may be regarded as a valuable and reliable method for the routine control of streptokinase and urokinase therapy.
...
PMID:On the reliability of plasminogen measurement employing the proactivator-activator converting method. 13 61

A new method is presented for estimating the activator (plasminogen-streptokinase complex) concentration in native plasma of patients undergoing streptokinase infusion. The principle of the method is based on clot lysis time as recorded by the thromboelastograph. The test clot constituents were bovine fibrinogen, bovine plasminogen, EDTA, human plasma (with unknown activator concentrations), and thrombin. In order to obtain a standardization line, urokinase dissolved in NaCl solution was substituted for patients' plasma. Thus, each lysis time could easily be converted into urokinase equivalent (CTA-u/ml). Streptokinase and plasminogen molecules in undiluted patients' plasma were found to exist both in an activator-bound (equimolar plasminogen-streptokinase complex) and in a freely circulating form. This result is in agreement with earlier findings where the activator complex was demonstrated to be a widely dissociated complex in highly diluted plasma of patients, thus displaying an ample proportion of free streptokinase and plasminogen and molecules. Streptokinase treatment using dosage schemes of 100,000 u SK/h, and 200,000 u/h were monitored by quantitative activator, streptokinase, and plasminogen measurements. An average activator concentration of 50-100 CTA-u/ml and a SK-concentration of 7-16 u/ml were recorded during streptokinase infusion. Plasminogen values averaged 0.25%, independent of the amount of streptokinase infused. Each drop in streptokinase was accompanied by a drop in activator during the infusion, and each rise in streptokinase by a rise in activator. There was a strong correlation between streptokinase and activator concentrations in that, on the average, 1 u streptokinase equalled 8.4 CTA-u/ml activator (correlation coefficient r = 0.9) It is concluded that the activator concentration in the plasma of patients undergoing fibrinolytic treatment can easily be adjusted by regulating the hourly streptokinase influx.
...
PMID:Studies on activator formation in human plasma with streptokinase. III. Investigation of activator kinetics in undiluted plasma in terms of urokinase equivalents. 13 62

A chromogenic tripeptide - H-D-Val-Leu-Lys-p-nitroanilide-substrate of plasmin, can be used to follow plasminogen activation by an activator such as urokinase or the activator secreted by mouse peritoneal macrophages (thioglycolate-elicited). The acceleration of p-nitroaniline production is proportional to the initial rate of plasmin formation from plasminogen. Thus, at a given plasminogen concentration, this acceleration is proportional to the activator concentration. The acceleration can be evaluated from the spectrophotometer trace recording at 405 nm the appearance of p-nitroaniline, either by means of a computer program or by a plot of delta A405 vs.t2. The sensitivity of this assay allows detection of 0.003 CTA units of urokinase. Thioglycollate-elicited mouse peritoneal macrophages secrete plasminogen activator into the extracellular medium during in vitro cultivation only after a contact with serum.
...
PMID:Regulation of plasminogen activator secretion in mouse peritoneal macrophages. I. - Role of serum studied by a new spectrophotometric assay for plasminogen activators. 48 77

Secretion of large quantities of urokinase by cultured renal cells suggested tissue culture as a means of production to meet demand for the material and to obtain guidelines for optimization of production. Rates of secretion and overall yields of urokinase from confluent cultures of renal cells have been studied in relation to species differences, effects of passage of cells, inoculum density, and volume of maintenance media. Added in part by an advantage gained through addition of glycine to maintenance media, it is now possible to harvest urokinase at concentrations of the order of 800 CTA units per ml. Such concentrations are of the order of 10(2) times that occurring in human male urine.
...
PMID:Plasminogen activator (urokinase) from cultured cells. 50 4

The term "effective activator" of plasminogen is proposed, to denote the resultant of activator-antiactivator interaction, and a method for the determination of the level of these activators is described. By adding axcess plasminogen to the euglobulin fraction of plasma the influence of the level of endogenous plasminogen and of the antiplasmin is eliminated. It is shown that the level of fibrinogen has very little bearing on the results. An effective activator unit is defined as equal to 1 CTA unit of urokinase activity on a fibrinogen-plasminogen substrate.
...
PMID:A new method for the determination of plasma activators fibrinolysis. 57 25

Toxicity of intravitreal urokinase was studied by injection of various doses of urokinase in primate eyes. Doses of 22,500 CTA units or less produced no toxic effects on the eye. Higher doses caused retinal degeneration, transient lens opacities, and cloudy vitreous. Urokinase was ineffective in clearing experimentally induced vitreous hemorrhage if injected as early as 24 hours after the intravitreal blood or as late as six months thereafter.
...
PMID:Urokinase in experimental vitreous hemorrhage. 81 Jul 55

1 2 3 Next >>