EC:3.4.21.7 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.4.21.7 (plasmin)
9,023 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

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.
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PMID:Complement component C7 is a plasminogen-binding protein. 781 88

The plasminogen activation (PA) system of human Co115 colon carcinoma cells was investigated. Analysis at the levels of protein and mRNA of cultured cells and of histozymography of tumor xenografts in nude mice showed that Co115 cells produce only tissue type PA (t-PA) and no urokinase (u-PA). Also, mRNA for the u-PA receptor and for PA inhibitor type 2 (PAI-2), but not for PAI-1, were detected. We developed a quantitative degradation assay using glutaraldehyde-immobilized 125I-laminin to investigate the capacity of Co115 cells to degrade laminin. Laminin degradation by Co115 cells was completely inhibited by 100 micrograms/ml of polyclonal anti-t-PA IgG, by the plasmin inhibitors aprotinin (100 micrograms/ml) or epsilon-aminocaproic acid (EACA; at 0.3 M), but not by antibodies against u-PA or u-PAR nor by nonimmune IgG. Cycloheximide-treated Co115 cells were unable to degrade laminin but increased laminin degradation induced by conditioned medium of Co115 cells or recombinant t-PA. No potentiation was observed when Co115 cells and laminin were kept separated by Transwell inserts. Our results suggest that Co115 human colon carcinoma cells degrade laminin by potentiating t-PA-mediated plasminogen activation at the cell surface which requires close contact between tumor cells and laminin substrate.
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PMID:Human Co115 colon carcinoma cells potentiate the degradation of laminin mediated by tissue-type plasminogen activator. 796 13

It is well established that tissue-type plasminogen activator (t-PA) binds to the D region of fibrin(ogen) and that two distinct CNBr fragments of fibrinogen (FCB), FCB-2 and FCB-5, comprising parts of this region, stimulate plasminogen activation by t-PA. In the present work, ligand-binding studies were performed to characterize the interactions between t-PA and the corresponding fibrin regions using a well defined model of a fibrin surface and both FCB-2 and FCB-5 in liquid and solid phase. Binding isotherms showed a characteristic Langmuir adsorption saturation profile. The dissociation constants determined for the binding of t-PA to immobilized FCB-2 (Kd = 0.70 +/- 0.10 nM) and FCB-5 (Kd = 0.47 +/- 0.08 nM) were of the same order of magnitude as the Kd for fibrin binding (Kd = 1 +/- 0.2 nM). The specificity of the binding was demonstrated by the ability of soluble FCB-2 and FCB-5 to inhibit t-PA binding to solid-phase fibrin (Ki = 3.3 microM and 6.4 microM, respectively). The binding of t-PA to fibrin and to immobilized FCB-2 was partially inhibited by the lysine analogue 6-aminohexanoic acid (Ki = 123 +/- 47 microM and 364 microM, respectively) but was not modified by carboxypeptidase B, thus indicating involvement of internal lysine residues. Removal of lysine residues by treatment with, successively, plasmin and carboxypeptidase B, produced only a partial inhibition of t-PA binding, thus confirming the existence of both a lysine-dependent and a lysine-independent mechanism of binding of t-PA to both fibrin and FCB-2. In contrast, the binding of t-PA to FCB-5 was not significantly affected by 6-aminohexanoic acid. Altogether, these data indicate that the mechanism of binding of t-PA to fibrin involves mainly a lysine-independent interaction with the D region which is contributed by sequences present in FCB-5 and FCB-2; contribution to binding by a lysine-dependent interaction was detected only in FCB-2 and is probably of minor relevance as suggested by the limited effect of 6-aminohexanoic acid.
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PMID:Study of tissue-type plasminogen activator binding sites on fibrin using distinct fragments of fibrinogen. 811 48

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.
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PMID:Contact activation triggers stimulation of the monocyte 5-lipoxygenase pathway via plasmin. 814 60

Regions of apoprotein(a) of lipoprotein(a) [Lp(a)] exhibit striking primary sequence homology to the kringles of plasminogen. The kringles of plasminogen are lysine binding structures and mediate interactions of plasmin(ogen) with substrates and inhibitors. In the current study, the lysine binding properties of Lp(a) have been compared to those of plasminogen and isolated kringle 4 of plasminogen (K4). An analytical assay was implemented to quantitate the interaction of kringle-containing molecules with lysine-Sepharose beads. Radioiodinated ligands, Lp(a), plasminogen, and K4, bound to the beads, and their interactions were inhibited by lysine analogues in a dose-dependent fashion. A series of omega-aminocarboxylic acids inhibited Lp(a), plasminogen, and K4 binding to the lysine-Sepharose beads, but marked differences in the effectiveness of these compounds were observed with each ligand. In this series of compounds, 6-aminohexanoic acid was the most potent inhibitor of binding to lysine-Sepharose for all three ligands. The pH had little effect on the inhibition of plasminogen binding by these compounds. For Lp(a), a low pH caused a marked decrease in inhibition by the 5-carbon and 4-carbon omega-amino acids. In addition, tranexamic acid was 750-fold more potent than lysine in inhibiting plasminogen and 55-fold more potent for K4 binding to the beads. In contrast, the differential potency of these compounds on Lp(a) binding was only 3-fold. These results suggest that the kringles of Lp(a) possess lysine binding functions which are similar, but not identical, to those of plasminogen and its K4.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Comparison of the lysine binding functions of lipoprotein(a) and plasminogen. 825 2

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.
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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.
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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

The plasminogen kringle 2 (K2HPg) and kringle 3 (K3HPg) modules occur in tandem within the polypeptide segment that affords the heavy chain of plasmin. The K2HPg and K3HPg are unique among the plasminogen kringle domains in that they also are linked to each other via the Cys169-Cys297 (Cys4 of K2HPg to Cys43 of K3HPg, kringle numbering convention) disulfide bridge, thus generating a K2HPg-K3HPg "supermodule". The kringle (2 + 3) sequence of human plasminogen (r-EE[K2HPgK3HPg]DS) was expressed in Escherichia coli, using an expression vector containing the phage T5 promoter/operator N250PSN250P29 and the codons for an N-terminal hexahistidine tag to ensure the isolation of the recombinant protein by affinity chromatography on Ni(2+)-nitrilotriacetic acid/agarose under denaturing and reducing conditions. Kringle (2 + 3) was refolded in the presence of glutathione redox buffer. By taking advantage of the lysine affinity of kringle 2, the protein was purified by affinity chromatography on lysine-Bio-Gel. Recombinant kringle (2 + 3) was identified by amino acid composition, N-terminal sequence and mass determination. The 1H NMR spectrum shows that the intact r-K2HPgK3HPg is properly folded. By reference to spectra of the individual kringles, r-K2HPg and r-K3HPg, resonances of the K2HPg and K3HPg components in the spectrum of the intact r-K2HPgK3HPg can be readily distinguished. The strictly conserved Leu46 residue (kringle residue number convention) yields delta-methyl signals that are characteristic for K2HPg and K3HPg, exhibiting chemical shifts of -0.87 and -0.94 ppm, respectively, which are distinct from those of K1HPg, K4HPg, and K5HPg, (-1.04 to -1.05 ppm). Thus, the high-field Leu46 signals from K2HPg and K3HPg are well resolved from those of other kringles and can be identified unambiguously in spectra of the K1HPgK2HPgK3HPg elastolytic fragment of plasminogen as well as in spectra of Glu-plasminogen. Overall, r-K2HPgK3HPg exhibits broader resonance line widths than does the K1HPg component, consistent with a lesser mobility of the K2HPgK3HPg segment within the K1HPgK2HPgK3HPg fragment, a reflection of the extra structural constraint imposed by the disulfide bridge linking K2HPg to K3HPg. The ligand 6-aminohexanoic acid (6-AHA), which is known to interact with r-K2HPg but not with r-K3HPg, selectively perturbs K2 aromatic signals in the intact r-K2HPgK3HPg spectrum while leaving K3 resonances largely unaffected. Association constant (K(a)) values for 6-AHA determined from 1H NMR ligand titration experiments yield K(a) approximately 2.2 +/- 0.3 mM(-1) for the intact r-K2HPgK3HPg, comparable to K(a) approximately 2.3 +/- 0.2 mM(-1) determined for the isolated r-K2HPg, which demonstrates that the interactions of 6-AHA with the K2HPg ligand-binding site are not significantly affected by the neighboring K3HPg domain within the intact r-K2HPgK3HPg supermodule.
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PMID:Recombinant gene expression and 1H NMR characteristics of the kringle (2 + 3) supermodule: spectroscopic/functional individuality of plasminogen kringle domains. 865 77

Surface-associated plasmin(ogen) may contribute to the invasive properties of various cells. Analysis of plasmin(ogen)-binding surface proteins is therefore of interest. The N-terminal variable regions of M-like (ML) proteins from five different group A streptococcal serotypes (33, 41, 52, 53 and 56) exhibiting the plasminogen-binding phenotype were cloned and expressed in Escherichia coli. The recombinant proteins all bound plasminogen with high affinity. The binding involved the kringle domains of plasminogen and was blocked by a lysine analogue, 6-aminohexanoic acid, indicating that lysine residues in the M-like proteins participate in the interaction. Sequence analysis revealed that the proteins contain common 13-16-amino-acid tandem repeats, each with a single central lysine residue. Experiments with fusion proteins and a 30-amino-acid synthetic peptide demonstrated that these repeats harbour the major plasminogen-binding site in the ML53 protein, as well as a binding site for the tissue-type plasminogen activator. Replacement of the lysine in the first repeat with alanine reduced the plasminogen-binding capacity of the ML53 protein by 80%. The results precisely localize the binding domain in a plasminogen surface receptor, thereby providing a unique ligand for the analysis of interactions between kringles and proteins with internal kringle-binding determinants.
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PMID:Identification of a plasminogen-binding motif in PAM, a bacterial surface protein. 874 39

Staphylokinase obtains plasminogen activating activity by forming a complex with plasminogen. Although the enzymatic activity of staphylokinase is enhanced by fibrin, how fibrin enhances enzymatic activity has not been determined yet. The effects of fibrin, or fibrinogen fragments, on the activation of plasminogen by staphylokinase was investigated using CNBr-digested fibrinogen fragments (FCB-2 and FCB-5) and plasmin-degraded cross-linked fibrin fragments ((DD)E complex, DD fragments and E fragments). Kinetic analysis of the activity of staphylokinase revealed that its plasminogen activating activity, which was expressed as kcat/Km, was enhanced by FCB-2 (10-fold) and FCB-5 (5-fold). These fibrin fragments caused 38-, 30-, and 8.5-fold increases in activity for the DD fragment, (DD)E complex and E fragment, respectively. Although alpha2-antiplasmin inhibited the activation of plasminogen by staphylokinase, FCB-2 abolished its inhibitory effects, and the plasminogen activating activity of staphylokinase was restored. The inhibitory effects of alpha2-antiplasmin on the activation of mini-plasminogen by staphylokinase were less than for Glu- or Lys-plasminogen, and the inhibitory effect of alpha2-antiplasmin was not altered by fibrin or EACA. These findings indicate that the staphylokinase/plasmin(ogen) complex reacts with fibrin even in the presence of alpha2-antiplasmin, and efficient plasminogen activation takes place on the surface of fibrin.
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PMID:Effects of fibrin and alpha2-antiplasmin on plasminogen activation by staphylokinase. 889 84

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