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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)
Enzyme kinetic plots relating the initial rate of activation of pro-
urokinase
to
urokinase
by plasmin, according to the concentration of substrate, were smooth downward curves and indicated that an apparent decrease in binding affinity occurred with increase in the concentration of pro-
urokinase
. Such nonlinear plots were obtained with plasmin 1 and also plasmin 2. Over sections of each curve it was possible to estimate apparent kinetic constants. At the uppermost concentrations of substrate tested, these were Km 2.9 microM and kcat 35.5 min-1 for plasmin 1, and at the lowermost concentrations, Km 9.5 nM and kcat 2.0 min-1. Linear plots were obtained when the single proteolytic cleavage was made by K5-plasmin or undegraded plasmin in the presence of 1.0 mM
6-aminohexanoic acid
(6-AHa). Constants were estimated for catalysis of this reaction by K5 plasmin to be Km 6.0 microM and kcat 38 min-1 (r = 0.987). The catalytic efficiency of plasmin, at the lowermost concentrations of pro-
urokinase
tested, was therefore 33-fold higher than that of K5-plasmin. Plotting of data for the cleavage of pro-
urokinase
by plasmin 1 (in the absence of 6-AHa) according to the model of Hill, gave a slope of 0.5 at the lowermost concentrations of pro-
urokinase
increasing to 1.0 at higher concentrations (greater than 0.3 microM); such a profile is characteristic of negative cooperativity. The rates of formation of plasmin and
urokinase
in a mixture containing a low concentration of plasminogen and pro-
urokinase
were measured and compared to those predicted by a computer program designed to calculate theoretical rates using available kinetic data. The observed rates of generation of both plasmin and
urokinase
coincided to those predicted from the negative cooperativity model. The mechanism of the negative cooperativity may reside in a conformational change induced by binding of pro-
urokinase
to the kringle structure of plasmin. This property may be of significance in controlling the fibrinolytic properties of the
urokinase-type plasminogen activator
system.
...
PMID:Activation of pro-urokinase by plasmin: non-Michaelian kinetics indicates a mechanism of negative cooperativity. 252 53
The binding of
urokinase
-type plasminogen activators (u-PA) to receptors on various cell types has been proposed to be an important feature of many cellular processes requiring extracellular proteolysis. We have investigated the effect of single-chain u-PA binding to the monocyte-like cell line U937 on plasminogen activation. A 16-fold acceleration of the activation of plasminogen was observed at optimal concentrations of single-chain u-PA. This potentiation was abolished by the addition of either
6-aminohexanoic acid
or the amino-terminal fragment of u-PA, thus demonstrating the requirement for specific binding of both single-chain u-PA and plasminogen to the cells. The mechanism of the enhancement of plasmin generation appears to be due primarily to an increase in the rate of feedback activation of single-chain u-PA to the more active two-chain u-PA by cell-bound plasmin, initially generated by single-chain u-PA. This increased activity of the plasminogen activation system in the presence of U937 cells provides a mechanism whereby u-PAs may exert their influence in a variety of cell-associated proteolytic events.
...
PMID:Plasminogen activation initiated by single-chain urokinase-type plasminogen activator. Potentiation by U937 monocytes. 252 25
Activation of human Glu-plasminogen, Lys-plasminogen and low-Mr plasminogen (lacking lysine-binding sites) by pro-
urokinase
(pro-UK), obtained from a human lung adenocarcinoma cell line (Calu-3, ATCC), obeys Michaelis-Menten kinetics. Activation occurs with a comparable affinity (Km 0.40-0.77 microM), while the catalytic rate constant (kcat) is comparable for Glu-plasminogen (0.0022s-1) and low-Mr plasminogen (0.0034 s-1), but is somewhat higher for Lys-plasminogen (0.0106 s-1). The rate of activation of plasminogen by pro-UK is not significantly influenced by the presence of
6-aminohexanoic acid
, purified fragments LBS I or LBS II or histidine-rich glycoprotein, indicating that the high affinity of pro-UK for plasminogen is not mediated via the high-affinity lysine-binding site of plasminogen located in kringles 1-3 (LBS I) nor via the low-affinity lysine-binding site comprised within kringle 4 (LBS II). The site(s) in plasminogen involved in the high-affinity interaction with pro-UK thus appear to be located within the low-Mr plasminogen moiety.
...
PMID:Characterization of the high-affinity interaction between human plasminogen and pro-urokinase. 392 92
The catalytic efficiency (kcat/Km) of high-molecular-mass
urokinase
for the activation of Glu-plasminogen is increased about 10-fold in the presence of CNBr-digested fibrinogen. This stimulation is similar to that observed with
6-aminohexanoic acid
, and yields kinetic parameters comparable to those for the activation of Lys-plasminogen by
urokinase
. The increase of the activation rate of Glu-plasminogen by
urokinase
in the presence of CNBr-Fg can thus be explained by a conformational change in the plasminogen molecule similar to that observed upon conversion of Glu-plasminogen to Lys-plasminogen and upon binding of
6-aminohexanoic acid
to Glu-plasminogen. Stabilization of the Michaelis complex between
urokinase
and plasminogen by formation of a cyclic ternary complex with CNBr-Fg, which has been invoked to explain the dramatic stimulatory effect of CNBr-Fg on the activation of plasminogen by tissue-type plasminogen activator, does not appear to play a significant role in the increased activation rate.
...
PMID:Influence of cyanogen-bromide-digested fibrinogen on the kinetics of plasminogen activation by urokinase. 648 41
Ab deposition, whether by reaction with the specific Ag or by preformed immune complexes, is followed by activation and deposition of complement components. Tissue destruction is observed in the Ab- and complement-induced lesions. The proteolytic enzyme plasmin is thought to participate in the Ab- and complement-mediated organ pathology. Plasmin is generated from plasma-derived plasminogen by cell-derived plasminogen activators (PAs). Two types of PAs are known,
urokinase
-type PA (uPA) and tissue-type PA (tPA). We investigated whether the PA system and the complement system can interact to promote local plasmin generation. Among the terminal complement components C5b6, C7, C8, and C9, the nonenzymatic component C7 is a plasminogen-binding protein. Radioligand binding studies revealed that the isolated component, as well as C7 after its incorporation into the terminal complement complex C5b-9, can bind plasminogen. Binding was inhibited by the lysine analogues
6-aminohexanoic acid
and tranexamic acid, implicating the lysine binding sites of plasminogen into the binding interaction. tPA-mediated plasminogen activation was enhanced in the presence of C7. Based on these findings, an interaction is proposed between the complement system and the plasminogen activator system; a mechanism that may focus plasmin activity to structures that have been tagged by Ab and complement deposition.
...
PMID:Complement component C7 is a plasminogen-binding protein. 781 88
The purpose of this study was to characterize the stimulus that activates the 5-lipoxygenase pathway in human peripheral monocytes (PM) during the process of contact activation. Incubation of PM, but not of polymorphonuclear leukocytes (PMN), in contact-activated, recalcified plasma induced a time-dependent release of leukotrienes (LT). The presence of platelets was required for the generation of cysteinyl-LT, but LTB4 formation also proceeded in their absence, although to a lesser extent. Plasmin, presumably generated via the intrinsic fibrinolytic pathway, was liable for the 5-lipoxygenase stimulation during contact activation inasmuch as (1) the 5-lipoxygenase pathway in PM was stimulated by contact-activated, recalcified, autologous or homologous plasma, but not by factor XII-deficient or prekallikrein-deficient plasma; (2) lysine analogs such as N alpha-acetyl-L-lysine,
6-aminohexanoic acid
(6-AHA), or trans-4- (aminomethyl)cyclohexane-1-carboxylic acid (t-AMCA), which inhibit plasmin(ogen) binding to PM plasmin(ogen) binding sites, concentration-dependently reduced the cysteinyl-LT release; (3) plasminogen activators such as
urokinase
or streptokinase concentration-dependently enhanced the cysteinyl-LT release up to 10 and 1,000 IU/mL, respectively, while higher concentrations were less effective leading to bell-shaped concentration-response curves; (4) plasmin inhibitors such as aprotinin or alpha 2-antiplasmin concentration-dependently inhibited the cysteinyl-LT release; and (5) preincubation of plasma with monoclonal antibodies directed against plasminogen and capable of preventing plasminogen activation blocked the contact-mediated 5-lipoxygenase stimulation. Moreover, incubation of PM with plasmin, but not with plasma kallikrein, in Hanks' balanced salt solution (HBSS)-bovine serum albumin (BSA) 0.4% triggered a concentration-dependent release of LTB4 up to 0.1 caseinolytic units (CU)/mL, with higher concentrations being less effective. By contrast, release of cyclooxygenase metabolites such as thromboxane (TX) B2 and prostaglandin (PG) E2 was not stimulated by plasmin, indicating specificity for the 5-lipoxygenase pathway. With plasmin as a hitherto unknown stimulus of the 5-lipoxygenase pathway in PM, a novel link between contact activation and inflammation has been established.
...
PMID:Contact activation triggers stimulation of the monocyte 5-lipoxygenase pathway via plasmin. 814 60
The characteristics of plasminogen activation by glycosylphosphatidylinositol (GPI)-anchored
urokinase
were evaluated and compared with those reported previously for receptor-bound
urokinase
. When expressed in cultured bovine aortic endothelial cells, GPI anchoring of single-chain
urokinase plasminogen activator
(scu-PA) potentiated plasmin generation as compared with GPI-anchored scu-PA that had been released into solution from the cell surface by enzymatic cleavage of the GPI anchor ("released" scu-PA). The potentiation of plasmin generation by GPI-anchored scu-PA was inhibited in a dose-dependent manner by
6-aminohexanoic acid
, a lysine analog, suggesting that the augmentation of plasmin generation by GPI-anchored scu-PA was dependent on simultaneous binding of plasminogen to the cell surface. GPI-anchored two-chain
urokinase
(tcu)-PA cleaved a peptide substrate at a rate equivalent to that of released
urokinase
. However, at a plasminogen concentration of 0.5 microM, GPI-anchored tcu-PA activated plasminogen less rapidly than did released
urokinase
. Modeling of kinetics of individual reactions revealed that cell-associated plasminogen activation by GPI-anchored tcu-PA was characterized by a Km of approximately 0.15 microM. This value of Km was 70-fold below that for activation of solution plasminogen by GPI-anchored
urokinase
. There was a concomitant decrease in Vmax for plasminogen activation by anchored tcu-PA. These alterations in kinetic parameters are similar to those reported previously for the activation of plasminogen by receptor-bound tcu-PA. In addition, GPI-anchored tcu-PA exhibited a modest resistance to plasminogen activator inhibitor 1 inactivation. The enzymatic characteristics of GPI-anchored
urokinase
reported here resemble closely those reported previously for receptor-bound
urokinase
. These data suggest that the
urokinase
receptor may regulate plasmin generation through a relatively nonspecific localization of
urokinase
to the cell surface rather than through any intrinsic property of the
urokinase
receptor.
...
PMID:Characterization of plasminogen activation by glycosylphosphatidylinositol-anchored urokinase. 830 May 67
We have observed that a murine IgG1 monoclonal antibody directed against human
urokinase-type plasminogen activator
(
uPA
) greatly potentiates pro-
uPA
-mediated plasminogen activation. This effect was dependent on the interaction between the immunoglobulin and the kringle domain of pro-
uPA
and could be competed efficiently by kringle-containing proteolytic fragments of
uPA
. In addition, the potentiation could also be competed by the lysine analog
6-aminohexanoic acid
, an antagonist of plasminogen binding. This unexpected plasminogen binding dependence was found to be due to a carboxyl-terminal lysine residue on the immunoglobulin gamma chain, which by analogy with other proteins represents a potential binding site for plasminogen. Removal of this residue with carboxypeptidase B resulted in a complete abolition of the potentiation. It appears therefore that the potentiatory effect involves a novel mechanism with the antibody acting to provide a specific template for the assembly of a ternary complex involving pro-
uPA
/
uPA
and plasminogen, enabling them to interact in a catalytically favorable manner. This interpretation was confirmed by studying the kinetics of plasminogen activation by the complex between active, two-chain
uPA
and the antibody, which resulted in an overall 50-fold increase in reaction efficiency (kcat/Km), primarily due to a reduction in Km from 20 to 0.1 microM. Pro-
uPA
activation by plasmin was also accelerated, although to a lesser extent. The potentiation due to complex formation also provides a mechanism for the initiation of this system, dependent only on the low intrinsic proteolytic activity of the zymogen forms. The effects observed here, mediated by ternary complex formation, simulate the effects we have previously observed on assembly of the
uPA
receptor-mediated cellular plasminogen activation system and may therefore represent a mechanistic model for both its activity and initiation.
...
PMID:Potentiation of plasminogen activation by an anti-urokinase monoclonal antibody due to ternary complex formation. A mechanistic model for receptor-mediated plasminogen activation. 844 57
A series of chimeric
urokinase-type plasminogen activator
(
uPA
) genes, which contain combinations of kringle domains of human plasminogen (HPg) in place of the
uPA
kringle (KuPA), has been constructed and expressed. Some of the resulting recombinant (r) variant
uPA
chimeras contain modules that potentially mediate the macroscopic binding of HPg to its activation effectors, fibrin(ogen) and
6-aminohexanoic acid
(EACA). Such binding sites are not possessed by KuPA, but are present in certain of the HPg kringles, viz., kringle 1 (K1HPg), kringle 4 (K4HPg), and kringle 5 (K5HPg). The recombinant (r) chimeras constructed included molecules with replacements of KuPA with K1HPg (r-[KuPA-->K1HPg]
uPA
), and with KuPA replaced by double kringle combinations of K1HPgK4HPg (r-[KuPA-->K1HPgK4HPg]
uPA
), K2HPgK3HPg (r-[KuPA-->K2HPgK3HPg]
uPA
), and K4HPgK5HPg (r-[KuPA-->K4HPgK5HPg]
uPA
). All of these variant genes, along with their wild-type (wt) r-
uPA
counterparts, were expressed in human kidney 293 cells. In cases wherein EACA-binding kringles from HPg have been placed in
uPA
, this property has been retained in the chimeric molecule and employed as an essential part of the purification procedures for the variants. The steady state amidolytic activity of two-chain (tc) wtr-
uPA
toward the chromogenic substrate, H-D-pyroglutamyl-Gly-L-Arg-p-nitroanilide (S2444), is characterized by a kcat/KM (pH 7.4, 37 degrees C) of 120 s-1 mM-1. This value ranges from 92 s-1 mM-1 (tcr-[KuPA-->K1HPg]
uPA
) to 166 s-1 mM-1 (tcr-[KuPA-->K1HPgK4HPg]
uPA
) for each of the variants, demonstrating that the catalytic efficiency of the active site is altered only in a small way by changes in the noncatalytic domain of
uPA
. Small differences are also observed in the abilities of these tcr variants to interact with the fast-acting plasma inhibitor of
uPA
, viz., plasminogen activator inhibitor-1 (PAI-1). The second-order rate constant for the interaction of PAI-1 with tcr-
uPA
, 0.46 x 10(7) M-1s-1 (pH 7.4, 10 degrees C), ranges from 0.29 x 10(7) M-1s-1 (tcr-[KuPA-->K1HPgK4HPg]
uPA
) to 1.08 x 10(7) M-1s-1 (tcr-[KuPA-->K4HPgK5HPg]
uPA
), for the tcr-chimeric variants. Neither wtr-
uPA
nor any of its chimeric r-variants interacted macroscopically with a fibrin clot under conditions that allowed binding of 74% of single-chain r-tissue-type plasminogen activator. However, the tcr-chimeric
uPA
variants provided HPg-enriched clot lysis times between 0.2 (r-[KuPA-->K1HPgK4HPg]
uPA
) and 2.4 (r-[KuPA-->K2HPgK3HPg]
uPA
) relative to that of wtr-
uPA
.(ABSTRACT TRUNCATED AT 400 WORDS)
...
PMID:The construction and expression of chimeric urokinase-type plasminogen activator genes containing kringle domains of human plasminogen. 851 11
Fucoidan [sulfated poly (L-fucopyranose)] was compared with
6-aminohexanoic acid
(6-AH) or CNBr-cleaved fibrinogen (CNBr-Fbg) alone or in combination in enhancing the activation of glutamic plasminogen (Glu-Plg) or lysine plasminogen (Lys-Plg) by two-chain tissue plasminogen activator (t-PA) or LMwt-
urokinase
or by streptokinase. Fucoidan enhanced the t-PA activation of Glu-Plg or Lys-Plg at Plg concentrations greater than 75nM, while stimulation by CNBr-Fbg of t-PA activation followed saturation kinetics of Michaelis-Menton. During t-PA activation of Glu-Plg, a high degree of synergism was observed between 6-AH and fucoidan while the enhancement by CNBr-Fbg was not influenced by fucoidan and was reversed by 6-AH. Fucoidan alone at higher concentrations was effective in enhancing the activation of Glu-Plg by
urokinase
while the combination of fucoidan and 6-AH showed additive effect in enhancing the activation of Lys-Plg. The activation of Glu-Plg by streptokinase was reversed by fucoidan in a manner similar to that reported for 6-AH. The results are interpreted to suggest that CNBr-Fbg and 6-AH compete with each other for the same lysine binding sites (LBS) on the Plg molecule while fucoidan acted synergistically with 6-AH in enhancing the t-PA activation of Glu-Plg by a different mechanism. The double reciprocal plot for the interaction of Glu-Plg and
urokinase
also showed a significantly higher affinity between the two in presence of fucoidan.
...
PMID:Effect of fucoidan during activation of human plasminogen. 853 20
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