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:3.4.21.73 (urokinase-type plasminogen activator)
10,685 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The assay of plasminogen activator activities on fibrin plates was re-evaluated with special reference to fibrinolysis inhibitors present in samples and in fibrin plates. The nature, action and stability of inhibiting material were studied in tissue with considerable differences in activator and inhibitor contents: human lung, liver and placenta. Extracts were tested for inhibitory capacity against purified human uterine tissue plasminogen activator, urokinase and plasmin of fibrin plates prepared from different grades of fibrinogen and fibrin. The tissue extracts inhibited fibrinolysis on fibrin plates to varying degrees, dependent on the sample medium, the type of fibrin plate and the kind of plasminogen activator. The influence of inhibitors in the sample and in the fibrin plate was partly abolished by the presence of 2 M KSCN in the sample. The procedure for preparing the samples as described by Astrup and Albrechtsen did not completely eliminate the inhibitory action against the added plasminogen activators. Comparison of urokinase inhibition with tissue activator inhibition by the tissue extracts as to the degree of denaturation in the Astrup and Albrechtsen procedure showed that they have much in common. Nevertheless, some differences were found which indicated the possible existence of separate urokinase and tissue activator inhibitors or of different inhibition mechanisms for these plasminogen activators.
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PMID:Interfering factors in the assay of plasminogen activators by the fibrin plate method. Occurrence of different inhibitors against tissue plasminogen activator and urokinase. 11 68

The data presented in this paper show that when rabbit plasminogen is activated to plasmin by urokinase at least two peptide bonds are cleaved in the process. Urokinase first cleaves an internal peptide bond in plasminogen, leading to two-chain disulfide-linked plasmin molecule. The plasmin heavy chain of molecular weight 66,000 to 69,000 possesses an NH2-terminal amino acid sequence identical with the original plasminogen (molecular weight 88,000 to 92,000). The plasmin light chain of molecular weight 24,000 to 26,000 is known to be derived from the COOH-terminal portion of plasminogen. The plasmin generated during the activation of plasminogen is capable, by a feedback process, of cleaving a peptide of molecular weight 6,000 to 8,000 from the NH2 terminus of the heavy chain, producing a proteolytically modified heavy chain of molecular weight 58,000 to 62,000. Plasmin also can cleave this same peptide from the original plasminogen, yielding an altered plasminogen of molecular weight 82,000 to 86,000. This plasmin-altered plasminogen and the plasmin heavy chain derived from it by urokinase activation process NH2-terminal amino acid sequences which are identical with each other and with the plasminolytic product of the original plasmin heavy chain. These studies support a mechanism of activation of plasminogen by urokinase which involves loss of a peptide located on the NH2 terminus of plasminogen. However, these same results show that this NH2-terminal peptide need not be released from rabbit plasminogen prior to the cleavage of the internal peptide bond which leads to the two-chain plasmin molecule. Furthermore, these studies show that urokinase cannot remove this peptide from either the original rabbit plasminogen molecule or from the heavy chain of the initial plasmin formed.
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PMID:The mechanism of activation of rabbit plasminogen by urokinase. 12 29

Fibrinogen, isolated from canine plasma by the successive procedures of (1) freezing and thawing, (2) fractional precipitation with 25% saturated (HN4)2SO4 and (3) Sepharose 6B gel-filtration, had a molecular weight of 282 000 by the rapid sedimentation equilibrium method. However, a molecular weight for canine fibrinogen of 332 000, which is closer to that reported for human and bovine fibrinogens (340 000 plus or minus 20 000), was obtained from the sum of the molecular weights of the Aalpha, Bbeta and gamma chains, determined from dodecylsulfate gel electrophoretic patterns of reduced fibrinogen. Canine fibrinogen, subjected to proteolysis by urokinase-activated plasminogen for 24 h, contained degradation fragments D and E which were isolated by starch block electrophoresis and Sephadex G-200 gel-filtration. The purified D and E fragments with sedimentation coefficients of 5.0 S and 2.5 S had weight average molecular weights of 89 000 and 42 000, respectively by the rapid sedimentation equilibrium method. The ratio of D to E was 2:1 per parent fibrinogen molecule. Antigenic analysis according to anti-fibrinogen antiserum showed that both D and E fragments were antigenically deficient to native fibrinogen and revealed a reaction of non-identity with each other. Upon immunoelectrophoresis at pH 8.2, D and E had different electrophoretic mobilities. Preliminary studies indicate that based on thrombin time alone, D has anticoagulant activity while E appears to be a coagulation potentiator. Canine fibrinogen apparently consist of two core fragments with dissimilar chemical characteristics in common with the fundamental structures of human and bovine fibrinogens.
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PMID:Characterization of the terminal degradation products of canine fibrinogen by plasmin. 12 81

The levels of fibrinogen and of profibrinolysin (plasminogen) in urokinase-treated plasma as a function of time of incubation were measured. The profibrinolysin concentration was estimated through its complete conversion to fibrinolysin and the inhibition of the enzyme by crystalline soybean trypsin inhibitor. The dissociation constant of the FL-STI complex was determined to be 7 times 10-9 M. The average concentration of profibrinolysin in normal human citrated plasma was found to be 8 times 10-7 M. From the decrease of fibrinogen with time in the urokinase-treated plasma, the free fibrinolysin was calculated. Free fibrinolysin in normal human blood in vivo was estimated from the half-life of fibrinogen and other data obtained in this study to be present at a concentration of 1.7 times 10-10 M. The plasmakinase activity in vivo, expressed as urokinase molarity, is also about 2 times 10-10 M.
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PMID:Molar concentrations of fibrinolytic components, especially free fibrinolysin, in vivo. 12 74

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.
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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.
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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 method is described by which the heavy chain of human plasmin, obtained by partial reduction of urokinase-activated plasminogen with 2-mercaptoethanol, is adsorbed on lysine coupled to polyacrylamide. The heavy chain is recovered from the adsorbent by elution with 6-aminohexanoic acid (yield 60-65%). Sulfhydryl titrations of the heavy chain showed that the partial reduction involved primarily the cleavage of the sole interchain disulfide bridge of plasmin. Dodecylsulfate-polyacrylamide electrophoresis gave essentially a single band corresponding to a component of about 60000 molecular weight. The NH2-terminal amino acid was predominantly threonine. 6-Aminohexanoic acid at different concentrations caused significant variations of the sedimentation and diffusion constants of the heavy chain indicating inhibitor-induced conformational alterations of the protein. The present results suggest that in plasmin only the heavy chain is capable of interacting with 6-aminohexanoic acid, and it appears that it is primarily this chain which plays an important role in the inhibition of the enzyme by 6-aminohexanoic acid.
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PMID:A new method of isolation and some properties of the heavy chain of human plasmin. 12 54

Affinity chromatography forms, 1 and 2, were each isolated from human Glu- and Lys-plasminogens by gradient elution from a L-lysine-substituted Sepharose column with a linear gradient of epsilon-aminocaproic acid. Although each of the two zymogen forms contains two affinity chromatography forms, the relative concentrattions of these forms in each of the zymogen preparations depended upon the plasma sample or enriched plasma fraction used for the preparation of the zymogen. Specific analytical acrylamide gel electrophoretic systems were used for the characterization of the zymogen and enzyme forms, and their component affinity chromatography forms, 1 and 2. The four zymogen affinity chromatography forms, Glu-1-plasminogen, Glu-2-plasminogen, Lys-1-plasminogen, and Lys-2-plasmingoen, show distinct stepwise differences in their molecular size and charge. The Glu-1-form is the largest in molecular size and the most acidic, and the Lys-2-form is the smallest in molecular size and the most basic. The proteolytically altered Lys-1- and Lys-2- forms appear to be specifically df the zymogen affinity chromatography forms showed a different distribution of isoelectric forms. The major isoelectric forms isolated from Glu-plasminogen with pI values of 6.2, 6.3, 6.4, and 6.6, and the major isoelectric forms isolated from Lys-plasminogen with pI values of 6.7, 7.2, 7.5, 7.8, and 8.1, (Summaria, L., Arzadon, L., Bernabe, P., Robbins, K. C., and Barlow, G. H. (1973) J. Biol. Chem. 248, 2984-2991) were shown to be mixtures of the Glu-1- and Glu-2- forms, or the Lys-1- and Lys-2- forms, respectively. Although the sialic acid contents of the Glu- and Lys- forms appear to be similar, the isolated affinity chromatography forms show distinct differences. The sialic acid contents of the Glu-1- and Lys-1- forms are identical, and are substantially higher than the sialic acid contents of the Glu-2- and Lys-2- forms which are also identical to each other. It is possible that the charge difference between the zymogen-1- and -2- forms may be related to the differences in their sialic acid content. Each of the four zymogen affinity chromatography forms, when activated by urokinase in the presence of the plasmin inhibitor, Trasylol, was converted to an apparently unique and different enzyme form. The four enzyme forms show distinct stepwise differences in molecular size; Glu-1-plasmin is the largest in size whereas Lys-2-plasmin is the smallest in size. Each plasmin-derived carboxymethyl heavy(A) chain was found to be different in molecular size, but the two carboxymethyl light(B) chains found in each of the four enzyme forms appeared to be identical and of the same molecular sizes. The four heavy(A) chains show a stepwise difference in molecular size; the Glu-1-heavy(A) chain is the largest in size whereas the Lys-2-heavy(A) chain is the smallest in size...
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PMID:Isolation and characterization of the affinity chromatography forms of human Glu- and Lys-plasminogens and plasmins. 13 40

When human plasminogen (Glu-Pga) is activated by urokinase in the presence of pancreatic trypsin inhibitor, the plasmin produced (Glu-Pma) exclusively contains a heavy chain (Glu-Ha) derived intact from the original NH2 terminus of Glu-Pga. Similar activations, utilizing a low molecular weight synthetic plasmin acylating agent, p-nitrophenyl-p-(pyridiniummethyl) benzoate, still result in a plasmin molecule with approximately 50% of the plasmin heavy chain containing the intact NH2 terminus of the original Glu-Pga. Activations performed at high levels of urokinase in the absence of any inhibitors initially produce Glu-Pma. However, the final stable plasmin, Lys-Pmb, which is obtained contains a heavy chain (Lys-Hb) which arises by plasminolysis of a small peptide from the NH2 terminus of Glu-Ha. Alternatively, Lys-Pmb can be formed in a separate series of reactions initially involving plasminolysis of Glu-Pga to yield Lys-Pgb. The peptide removed in this step is identical to the peptide removed in the Glu-Ha to Lys-Hb reaction. Next, urokinase catalyzes the conversion of Lys-Pgb to Lys-Pmb without further loss of peptide material. This latter pathway involving Lys-Pgb is probably the major pathway for human Lys-Pmb generation. These studies support a mechanism of activation of human plasminogen which involves at least two bond cleavages in Glu-Pga. However, these same studies strongly indicate that the Nh2-terminal peptide need not be released from Glu-Pga prior to plasmin formation. Further, we feel that plasmin and not urokinase catalyzes cleavage of the NH2-terminal peptide bond from Glu-Pga and the Glu-Ha heavy chain of Glu-Pma.
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PMID:Mechanism of the urokinase-catalyzed activation of human plasminogen. 13 42

Fresh plasma was seeded with trace amounts of highly purified biologically intact iodine-labelled plasminogen and the plasmin-inhibitor complexes formed after activation with streptokinase or urokinase separated by gel filtration. Two radioactive peaks were observed, the first one eluted in the void volume and the second one just before the 7-S globulin peak. In incompletely activated samples, the second peak was always predominant over the first one. Both components were purified with high yield by a combination of affinity chromatography on lysine-agarose and gel filtration, and investigated by dodecylsulphate-polyacrylamide gel electrophoresis and immunoelectrophoresis. Neither component reacted with antisera against alpha1-antitrypsin, antithrombin III, C1-esterase inhibitor, inter-alpha-trypsin inhibitor or alpha1-antichymotrypsin. The component of the first peak appeared to be a complex between plasmin and alpha2-macroglobulin which reacted with antisera against human plasminogen and against alpha2-macroglobulin. The component of the second peak had a molecular weight (Mr) of 120000-140000 by dodecyl-sulphate-polyacrylamide gel electrophoresis and lpon reduction displayed a doublet band with an Mr of 65000-70000 and a band with Mr 11000. It reacted with antisera against plasminogen and with antisera raised against this complex and absorbed with purified plasminogen. The latter antisera reacted with a single component in plasma which is different from the above-mentioned plasma protease inhibitors. Specific removal of this component from plasma by immuno-absorption resulted in disappearance of the fast-reacting antiplasmin activity whereas alpha2-macroglobulin was found to represent the slower-reacting plasmin-neutralizing activity. In the presence of normal plasma levels of these proteins, the specific removal or absence of alpha1-antitrypsin, antithrombin III or C1-esterase inhibitor did not alter the inactivation rate of plasmin when added to plasma in quimolar amounts to that of plasminogen. It is concluded that only two plasma proteins are important in the binding of plasmin generated by activation of the plasma plasminogen, namely a fast-reacting inhibitor which is different from the known plasma protease inhibitors and which we have provisionally named antiplasmin, and alpha2-macroglobulin, which reacts more slowly.
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PMID:Identification and some properties of a new fast-reacting plasmin inhibitor in human plasma. 13 45


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