EC:3.4.21.73 - FACTA Search

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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)

Plasminogen activator and urokinase are often used as biological markers of cell activation. However, the methods currently used are cumbersome, make no discrimination between tissue-type plasminogen activator and urokinase, and do not allow expression of the results of the overall reaction in International Units. The one-step method described in this paper lacks these drawbacks. Moreover, we propose use of H-D-Val-Phe-Lys-4-nitroanilide as substrate which has a lower Km than the standard H-D-Val-Leu-Lys-4-nitroanilide which is commercially available. Low concentrations of sodium dodecyl sulfate in the reaction mixture dramatically and preferentially accelerate the reaction catalyzed by tissue-type plasminogen activators. Identical results are obtained under kinetic or fixed-time assay conditions using either a photometer or 96-well plate reader. The corresponding formulae are provided.
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PMID:Spectrophotometric method to quantify and discriminate urokinase and tissue-type plasminogen activators. 153 70

A series of new compounds, 6-amino-1-naphthalenesulfonamides (ANSN), were used as fluorescent detecting groups for substrates of amidases. These compounds have a high quantum fluorescent yield, and the sulfonyl moiety permits a large range of chemical modification. Fifteen ANSN substrates with the structure (N alpha-Z)Arg-ANSNR1R2 were synthesized and evaluated for their reactivity with 8 proteases involved in blood coagulation and fibrinolysis. Thrombin, activated protein C, and urokinase rapidly hydrolyzed substrates with monosubstituted sulfonamide moieties (R1 = H). The maximum rate of substrate homologue). The hydrolysis rates for substrates with branched substituents were slower than their linear analogues. Monosubstituted (N alpha-Z)Arg-ANSNR1R2 possessing cyclohexyl or benzyl groups in the sulfonamide moiety were hydrolyzed by these three enzymes at rates similar to that of the n-butyl homologue (except the cyclohexyl compound for u-PA). Factor Xa rapidly hydrolyzed substrates with short alkyl chains, especially when R1 = R2 = CH3 or C2H5. Lys-plasmin and rt-PA demonstrated low activity with these compounds, and the best results were accomplished for monosubstituted compounds when R2 = benzyl (for both enzymes). Factor VIIa and factor IXa beta exhibited no activity with these substrates. A series of 14 peptidyl ANSN substrates were synthesized, and their reactivity for the same 8 enzymes was evaluated. Thrombin, factor Xa, APC, and Lys-plasmin hydrolyzed all of the substrates investigated. Urokinase, rt-PA, and factor IXa beta exhibited reactivity with a more limited group of substrates, and factor VIIa hydrolyzed only one compound (MesD-LGR-ANSN(C2H5)2). The substrate ZGGRR-ANSNH (cyclo-C6H11) showed considerable specificity for APC in comparison with other enzymes (kcat/KM = 19,300 M-1 s-1 for APC, 1560 for factor IIa, and 180 for factor Xa). This kinetic advantage in substrate hydrolysis was utilized to evaluate the activation of protein C by thrombin in a continuous assay format. Substrate (D-LPR-ANSNHC3H7) was used to evaluate factor IX activation by the factor VIIa/tissue factor enzymatic complex in a discontinuous assay. A comparison between the commercially available substrate chromozyme TH (p-nitroanilide) and the ANSN substrate with the same peptide sequence (TosGPR) demonstrated that aminonaphthalenesulfonamide increased the specificity (kcat/KM) of substrate hydrolysis by thrombin more than 30 times, with respect to factor Xa substrate hydrolysis.
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PMID:Aminonaphthalenesulfonamides, a new class of modifiable fluorescent detecting groups and their use in substrates for serine protease enzymes. 160 66

Thrombolytic therapy frequently induces a "lytic state" associated with a decrease in plasma plasminogen concentration that could limit therapeutic efficacy. We therefore investigated the influence of soluble plasminogen concentration on in vitro lysis of retracted whole-blood clots in plasma from normal subjects and from patients undergoing thrombolytic therapy. With recombinant tissue plasminogen activator (1000 ng/ml) or two-chain urokinase plasminogen activator (250 U/ml), minimal clot lysis occurred in normal plasma depleted of plasminogen by lysine Sepharose chromatography. Clot lysis induced by two-chain urokinase plasminogen activator increased progressively in normal plasma at initial plasminogen concentrations between 0.06 to 6 U/ml, whereas maximum lysis with recombinant tissue plasminogen activator occurred between 0.5 U/ml and 1 U/ml and was less at lower and higher concentrations of plasminogen. Incubation of whole-blood clots in normal plasma with recombinant tissue plasminogen activator resulted in little change in plasminogen concentration during 6 hours, with a constant rate of clot lysis. Incubation with two-chain urokinase plasminogen activator, however, caused a rapid decrease in plasminogen concentration and a corresponding decrease in lysis rate; lysis rate was restored after repletion with purified plasminogen. The effect of in vivo activator-induced plasminogen depletion on in vitro clot lysis rates was tested with plasma obtained from patients 90 to 120 minutes after they had received 30 mg of acylated plasminogen-streptokinase activator complex that showed depletion of plasminogen to 14% +/- 2%. These plasma samples produced only 4% +/- 1% in vitro clot lysis during 4 hours but lysis increased progressively after repletion with 1, 2, and 4 U/ml plasminogen.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Depletion of plasminogen in vitro or during thrombolytic therapy limits fibrinolytic potential. 161 18

Plasminogen activation by single-chain urokinase-type plasminogen activator or pro-urokinase (pro-UK) is accompanied by the generation of two-chain urokinase (UK) by plasmin which provides a positive feedback. In the present study, the time course of the activation of Glu-plasminogen and of Lys-plasminogen (10 microM) by pro-UK (1.0 nM) was studied. In the presence of native plasminogen (Glu-plasminogen), three distinct phases with different rates of plasmin generation were observed. The initial phase was slow and corresponded to the intrinsic activity of pro-UK as reflected by the activity of a plasmin-resistant mutant (Lys158----Ala). This was followed by a second phase which had the most rapid rate. The third phase had a plasminogen activation rate which was significantly slower than the second and paralleled the rate of activation by UK (1.0 nM). The second phase coincided with the time at which there was only about 50% conversion of pro-UK to UK, whereas the final phase coincided with essentially complete conversion. In the presence of fibrin fragment E-2 (20 microM), previously shown to strongly promote plasminogen activation by pro-UK, the identical phenomenon was observed, but at one-tenth the concentration of pro-UK. The most rapid rate of plasmin generation again coincided with transitional (25-60%) pro-UK to UK conversion. To further examine this phenomenon, the rate of pro-UK to UK conversion was controlled by using kallikrein in the presence of a plasmin inhibitor. In this experiment, the activation of Glu-plasminogen bound to solid-phase fibrin was measured. A similar three-phase sequence was observed, the highest rate of plasmin generation coinciding with about 45% conversion of pro-UK to UK. A mechanism for this transitional state phenomenon was postulated based on the established significantly higher affinity of pro-UK than of UK for Glu-plasminogen. This exceptional property for a proenzyme may enable a transient activity to be generated during the transition from pro-UK to UK corresponding to the more favorable KM of pro-UK and the kcat of UK. This hypothesis was supported by the results from experiments in which Lys-plasminogen was substituted for the Glu form. No transitional state activity was observed, consistent with the relatively high KM of pro-UK against Lys-plasminogen.
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PMID:A transitional state of pro-urokinase that has a higher catalytic efficiency against glu-plasminogen than urokinase. 163 75

A novel mutant of the LLC-PK1 renal epithelial cell line, VPR1, was isolated after mutagenesis with N-methyl-N'-nitro-N-nitrosoguanidine and selection using a photoactivatable vasopressin analogue [1-(3-mercapto)propionic acid, 8-(N6-4-azidophenylamidino)lysine] vasopressin. The VPR1 mutant cell line possessed less than 5% parental V2 receptor binding for vasopressin but exhibited normal calcitonin receptor binding. In contrast to LLC-PK1 cells (wild type), VPR1 cells exhibited no response to vasopressin in terms of in vitro adenylate cyclase activation, in vivo cAMP production, or urokinase-type plasminogen activator induction. The responses of VPR1 cells to other agents, such as calcitonin, the adenylate cyclase activator forskolin, the GTP analogue guanosine 5'-[beta, gamma-imino] triphosphate, 8-bromo adenosine-3',5'-monophosphate were comparable to those of the parental cell line. Somatic cell hybrids were derived from the cell lines LLC-PK1 and VPR1 and analyzed for the dominance/recessiveness of the VPR1 mutant phenotype. Hybrids were found to possess normal vasopressin binding activity as well as functional responses to the hormone, indicating that the mutation affecting the V2 receptor in VPR1 cells is recessive. The VPR1 cell line may thus have application as a recipient for the expression of the V2 receptor gene using DNA-transfer.
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PMID:Isolation and genetic characterization of a renal epithelial cell mutant defective in vasopressin (V2) receptor binding and function. 164 58

Human endothelial cells (EC) assemble plasmin-generating proteins on their surface. We have previously identified an EC membrane protein (Mr approximately 40,000) which specifically binds tissue plasminogen activator (t-PA) but not urokinase (Hajjar, K.A., and Hamel, N. M. (1990) J. Biol. Chem. 265, 2908-2916). In the present study, t-PA receptor protein (t-PA-R) was purified to apparent homogeneity from a detergent extract of human placental tissue by diisopropyl fluorophosphate-t-PA affinity chromatography and preparative gel electrophoresis. In a solid phase binding assay wells coated with t-PA-R bound both 125I-t-PA and 125I-Lys-plasminogen (PLG), but not 125I-urokinase in a specific, reversible, and noncompetitive fashion. Binding of 125I-Lys-PLG, but not 125I-t-PA, to t-PA-R was 80% inhibited by a 20-100-fold molar excess of the PLG-like lipoprotein(a), or by the lysine analog, epsilon-aminocaproic acid (50 mM). A polyclonal anti-t-PA-R antibody inhibited 66 and 79% of the specific 125I-t-PA and 125I-Lys-PLG binding, respectively, to EC monolayers. Biosynthetically labeled 40-kDa protein coprecipitated with t-PA- or Lys-PLG-Sepharose beads, but not with unconjugated Sepharose. In a functional assay, t-PA associated with immobilized t-PA-R generated 6.4 times more plasmin than an equivalent amount of t-PA in the fluid phase. These results suggest that t-PA-R can bind both t-PA and Lys-PLG in a manner that mimics the EC surface. This protein may play a role in modulating plasmin generation on cell surfaces.
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PMID:The endothelial cell tissue plasminogen activator receptor. Specific interaction with plasminogen. 165 83

In order to analyze the mechanism of the intramolecular binding of the N-terminal peptide of Glu-plasminogen (Glu-plg) to its kringles, which results in its tight conformation, we synthesized peptides of the N-terminal portion of Glu-plg molecules and analyzed their effects on the activation of Glu-plg and its conversion to Lys-plasminogen (Lys-plg) by plasmin. Three peptides of Ala44-Lys50, Ala44-Glu51 and Ala44-Ser49 were synthesized in order to examine the effect of lysine residue in the peptide. Ala44-Lys50 and Ala44-Glu51 enhanced the activation of Glu-plg by urokinase, whereas the activation of Lys-plasminogen (Lys-plg) was slightly inhibited. The conversion of Glu-plg to Lys-plg by plasmin was also enhanced by these peptides. The results suggest that Ala44-Lys50 and Ala44-Glu51 worked on Glu-plg in a similar manner as lysine analogues by making its conformation looser. The third peptide Ala44-Ser49 did not have any effect on the activation of Glu-plg by urokinase or the conversion of Glu-plg to Lys-plg by plasmin. Ala44-Lys50 residue of Glu-plg is, therefore, strongly implicated as a candidate for the responsible site of the intramolecular binding in Glu-plg.
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PMID:Effects of N-terminal peptide of Glu-plasminogen on the activation of Glu-plasminogen and its conversion to Lys-plasminogen. 167 46

Several human melanoma cell lines produced tissue-type plasminogen activator (t-PA), as detected by zymography and immunocapture assay of culture media and cell lysates. Urokinase (u-PA) was found at only less than or equal to 1% the level of t-PA. Acid eluates of the cell surface indicated that the melanoma cells had t-PA bound on their surface, but no u-PA, and also had a very low capacity to bind exogenous u-PA. After incubation of the melanoma cells with 10% plasminogen-depleted fetal calf serum and human plasminogen, bound plasmin activity could be eluted from the cell surface with tranexamic acid, an analogue of lysine. This indicated that plasminogen was activated on the cell surface. The cell-surface plasmin formation was inhibited by an anti-catalytic monoclonal antibody to human t-PA, and not by an anti-catalytic antibody to u-PA. The melanoma cells also synthesized and secreted alpha 2-macroglobulin (alpha 2M), as shown by alpha 2M-specific mRNA in Northern blotting and detection of alpha 2M protein in conditioned cell culture media. The media were found to inhibit u-PA but not t-PA. This inhibition was related to their alpha 2M content, and immunoabsorption of alpha 2M removed the inhibitory activity. These studies suggest that t-PA can bind to the surface of melanoma cells and generate surface-bound plasmin. Because t-PA and cell-bound plasmin are unaffected by alpha 2M, t-PA may, in the case of melanoma cells, serve an analogous function to u-PA in supporting tumor cell invasion.
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PMID:Plasminogen activation by t-PA on the surface of human melanoma cells in the presence of alpha 2-macroglobulin secretion. 171 33

The pathogenesis of Hailey-Hailey disease and Darier's disease was investigated using immunocytological and explant-tissue-culture techniques. There was breakdown of the intercellular adhesions between keratinocytes in explants from clinically uninvolved skin of patients with Hailey-Hailey disease or Darier's disease. The major desmosomal components were present in the cultures and were expressed in a punctate peripheral pattern at cell-cell contact sites, but there was diffuse staining of acantholytic cells. Plasminogen, which is expressed by basal keratinocytes in normal skin, was detected in association with suprabasal acantholytic cells in skin biopsies from these diseases. Plasminogen was reversibly displaced from the cells by 6-aminohexanoic acid, suggesting that binding is mediated by a reaction with the lysine receptor on the plasminogen molecule. Plasminogen was also detected in separating cells in explant cultures and there was cytoplasmic expression of the plasminogen activator urokinase by these cells. These abnormalities are not unique to either disease and do not account for the phenotypic differences between Darier's disease and Hailey-Hailey disease, but plasmin generation may have a role in perpetuating cell separation.
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PMID:Cell adhesion in Hailey-Hailey disease and Darier's disease: immunocytological and explant-tissue-culture studies. 175 48

When single-chain pro-UK is activated by plasmin or kallikrein, the Lys158-Ile159 bond is cleaved, leaving a C-terminal lysine on the A-chain (Lys-UK). Two-chain, high molecular weight urokinase (UK) purified from urine, however, has been shown to contain a phenylalanine residue as the C-terminal of the A-chain (Phe-UK). Since C-terminal lysine residues have a strong binding affinity for plasminogen that may promote its activation, we undertook kinetic studies comparing plasminogen activation by Lys- and Phe-UK. A two-stage method was employed in order to minimize factors known to interfere with plasminogen activation and plasmin determination. The Lys-UK was prepared by plasmin activation of pro-UK purified from human fetal kidney cell culture medium. The Phe-UK was prepared by carboxypeptidase B (CpB) treatment of Lys-UK. Removal of the C-terminal lysine of Lys-UK by CpB produced small but significant increases in the Michaelis constants for the activation of both Glu- and Lys-plasminogen. The apparent Michaelis constants for Glu-plasminogen activation by Lys- and Phe-UK were 3.7 microM +/- .36 microM and 5.9 microM +/- .70 microM, respectively and the Michaelis constants for Lys-plasminogen activation by Lys- and Phe-UK were 5.4 microM +/- .72 microM and 15.2 microM +/- 1.4 microM, respectively. The catalytic efficiency (kcat/Km) of Lys-UK was approximately 2-fold greater than that of Phe-UK for the activation of either Glu- or Lys-plasminogen. When the fibrinolytic activities of Lys- and Phe-UK were compared in a plasma milieu no significant differences were detected. In conclusion, the findings indicate that the C terminal lysine on the A-chain of UK significantly promotes the catalysis of plasminogen in a purified system. However, the higher catalytic efficiency of Lys-UK was not found to induce significant acceleration of clot lysis at pharmacological concentrations in plasma.
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PMID:The effect of the carboxy-terminal lysine of urokinase on the catalysis of plasminogen activation. 177 40

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