Characterization of the binding of plasminogen to fibrin surfaces: the role of carboxy-terminal lysines.

In the present study we have quantitatively characterized the interaction of purified human Glu- and Lys-plasminogen with intact and degraded fibrin by ligand-binding experiments using a radioisotopic dilution method and antibodies against human plasminogen. A fibrinogen monolayer was covalently linked to a solid support with polyglutaraldehyde and was treated with thrombin or with thrombin and then plasmin to respectively obtain intact and degraded fibrin surfaces. Under these conditions, a well-defined surface of fibrin is obtained (410 +/- 4 fmol/cm2) and, except for a 39-kDa fragment, most of the fibrin degradation products remain bound to the support. New binding sites for plasminogen were detected on the degraded surface of fibrin. These sites were identified as carboxy-terminal lysine residues both by inhibition of the binding by the lysine analogue 6-aminohexanoic acid and by carboxy-terminal end-group digestion with carboxypeptidase B. The binding curves exhibited a characteristic Langmuir adsorption isotherm saturation profile. The data were therefore analyzed accordingly, assuming a single-site binding model to simplify the analysis. Equilibrium dissociation constants (Kd) and the maximum number of binding sites (Bmax) were derived from linearized expression of the Langmuir isotherm equation. The Kd for the binding of Glu-plasminogen to intact fibrin was 0.99 +/- 0.17 microM and for degraded fibrin was 0.66 +/- 0.22 microM. The Kd for the binding of Lys-plasminogen to intact fibrin was 0.41 +/- 0.22 microM and for degraded fibrin was 0.51 +/- 0.12 microM.(ABSTRACT TRUNCATED AT 250 WORDS)     

Functional properties of the recombinant kringle-2 domain of tissue plasminogen activator produced in Escherichia coli

The kringle-2 domain (residues 176-262) of tissue-type plasminogen activator (t-PA) was cloned and expressed in Escherichia coli. The recombinant peptide, which concentrated in cytoplasmic inclusion bodies, was isolated, solubilized, chemically refolded, and purified by affinity chromatography on lysine-Sepharose to apparent homogeneity. [35S]Cysteine-methionine-labeled polypeptide was used to study the interactions of kringle-2 with lysine, fibrin, and plasminogen activator inhibitor-1. The kringle-2 domain bound to lysine-Sepharose and to preformed fibrin with a Kd = 104 +/- 6.2 microM (0.86 +/- 0.012 binding site) and a Kd = 4.2 +/- 1.05 microM (0.80 +/- 0.081 binding site), respectively. Competition experiments and direct binding studies showed that the kringle-2 domain is required for the formation of the ternary t-PA-plasminogen-intact fibrin complex and that the association between the t-PA kringle-2 domain and fibrin does not require plasmin degradation of fibrin and exposure of new COOH-terminal lysine residues. We also observed that kringle-2 forms a complex with highly purified guanidine-activated plasminogen activator inhibitor-1, dissociable by 0.2 M epsilon-aminocaproic acid. The kringle-2 polypeptide significantly inhibited tissue plasminogen activator/plasminogen activator inhibitor-1 interaction. The kringle-2 domain bound to plasminogen activator inhibitor-1 in a specific and saturable manner with a Kd = 0.51 +/- 0.055 microM (0.35 +/- 0.026 binding site). Therefore, the t-PA kringle-2 domain is important for the interaction of t-PA not only with fibrin, but also with plasminogen activator inhibitor-1 and thus represents a key structure in the regulation of fibrinolysis.     

Lys-plasminogen is a significant intermediate in the activation of Glu-plasminogen during fibrinolysis in vitro.

Plasminogen, the zymogen form of the fibrinolytic enzyme plasmin, is known to undergo plasmin-mediated modification in vitro. The modified form, Lys-plasminogen, is superior to the native Glu-plasminogen in fibrin binding and as a substrate for activation by tissue-type plasminogen activator (t-PA). The present study was undertaken to determine the existence and significance of the Glu- to Lys-plasminogen conversion during t-PA-mediated lysis of plasma clots in vitro. When human plasma was supplemented with exogenous Lys-plasminogen and clotted, a dose-dependent shortening of lysis time was observed. Formation of Lys-plasminogen in situ during fibrinolysis was determined using 131I-Glu-plasminogen-supplemented plasma. By the time of lysis, Lys-plasminogen had accumulated to about 20% of the initial concentration of Glu-plasminogen. Quantitation of activation of both Glu- and Lys-plasminogen as well as the conversion of Glu- to Lys-plasminogen in plasma supplemented with both 131I-Glu-plasminogen and 125I-Lys-plasminogen was accomplished by determining the flux of the isotopically labeled species along three pathways: Glu-plasminogen-->Glu-plasmin, Glu-plasminogen-->Lys-plasminogen, and Lys-plasminogen-->Lys-plasmin. After a brief lag, the Glu-plasminogen activation rate was constant until lysis was achieved, at which point activation ceased. The Lys-plasminogen activation rate also was essentially constant until lysis but was not characterized by a lag phase. The rate of conversion of Glu- to Lys-plasminogen was nonlinear and correlated directly with the rate of fibrinolysis. By the time lysis had occurred, Glu-plasminogen consumption had been distributed equally between direct activation to plasmin and conversion to Lys-plasminogen, and 45% of the plasmin which had been formed was derived from Lys-plasminogen. These results demonstrate both the formation and the subsequent activation of Lys-plasminogen during fibrinolysis. As a result of improved fibrin binding and activation of Lys-plasminogen compared to Glu-plasminogen, the formation of Lys-plasminogen within a clot constitutes a positive feedback mechanism that can further stimulate the activation of plasminogen by t-PA as fibrinolysis progresses.     

On the biological significance of the specific interaction between fibrin,plasminogen and antiplasmin

The influence of antiplasmin on the interaction between fibrin and plasminogen was studied in plasma and in a purified system. The amount of plasminogen bound to fibrin was quantitated using trace amounts of ¹²⁵I-labeled Glu-plasminogen (plasminogen with NH₂-terminal glutamic acid) or ¹²⁵I-labeled Lys-plasminogen (NH₂-terminal lysine).When whole plasma was clotted, 5.2% of Glu-plasminogen was associated with the fibrin clot. In plasma clotted in the presence of 20 mM 6-amino-hexanoic acid only 1.4% of the plasminogen was bound to fibrin, indicating that about 4% of the plasma plasminogen specifically binds to fibrin. With Lys-plasminogen these values were approximately twice as high.When antiplasmin-depleted plasma was used, only slightly higher amounts of both types of plasminogen were associated with the fibrin. The adsorbed plasminogen was not significantly eluted with plasma or with purified antiplasmin at physiological concentrations.These findings indicate that antiplasmin does not play a significant role in the inhibition of the binding of plasminogen to fibrin or the dissociation of the plasminogen · fibrin complex.These observations in conjunction with previous findings on the kinetics of the plasmin-antiplasmin reaction suggest that the lysine-binding site of plasminogen, which is responsible both for its interaction with fibrin and its interaction with antiplasmin, plays an important role in the very fast neutralization of plasmin formed in circulating blood and serves to attach plasminogen to fibrin and thereby sequestrate plasmin formed in loco from circulating antiplasmin.     

The dissociation constants and stoichiometries of the interactions of Lys-plasminogen and chloromethyl ketone derivatives of tissue plasminogen activator and the variant delta FEIX with intact fibrin

Active-site-blocked, fluorescent derivatives of tPA (Activase) and a variant (delta FEIX) which lacks the finger and epidermal growth factor-like domains and possesses Asn to Gln and Val to Met mutations at residues 117 and 245, respectively, were prepared. The binding of these to fibrin was studied by adding them at systematically varying concentrations to fibrinogen, at a fixed concentration, inducing clotting with thrombin, separating free and bound tPA or delta FEIX by centrifugation, and measuring the concentration of unbound material by extrinsic fluorescence. Similar studies were performed with Glu and Lys-plasminogen, using intrinsic fluorescence. epsilon-amino caproic acid (EACA) was utilized to distinguish kringle-dependent from finger-dependent binding. In the absence of EACA, delta FEIX-bound fibrin through a single class of sites with Kd = 0.69 microM and n = 1.34 delta FEIX/fibrin. The binding of delta FEIX was completely inhibited by EACA and 50% displacement occurred at [EACA] = 300 microM. Fibrin-bound tPA was only partially displaced with EACA. In the presence of 30 mM EACA, tPA binding reflected a single class of sites with Kd = 0.26 microM and n = 0.60 tPA/fibrin. In the absence of EACA, tPA binding was complex, typified by downwardly curved Scatchard plots, and was consistent with interactions of the two classes of sites, characterized by Kd = 0.13 microM, n = 0.60 and Kd = 0.61 microM, n = 1.23. These were attributed to finger and kringle-dependent interactions, respectively. Under the experimental conditions employed, Glu-plasminogen exhibited no binding to fibrin, whereas Lys-plasminogen bound to a single class of sites with Kd = 0.25 microM and n = 1.02 plasminogen/fibrin. This binding was completely inhibited by EACA and 50% displacement occurred at [EACA] = 28 microM. Competition experiments indicated that Lys-plasminogen does not displace either tPA or delta FEIX from fibrin. From these results the conclusions are drawn that tPA can interact with intact fibrin by two different and independent modes, involving, respectively, the finger and kringle 2 domains, and neither of these modes are competitive with the kringle-dependent binding of Lys-plasminogen.     

On the specific interaction between the lysine-binding sites in plasmin and complementary sites in alpha2-antiplasmin and in fibrinogen.

Plasminogen and plasminogen derivatives which contain lysine-binding sites were found to decrease the reaction rate between plasmin and alpha2-antiplasmin by competing with plasmin for the complementary site(s) in alpha2-antiplasmin. The dissocwation constant Kd for the interaction between intact plasminogen (Glu-plasminogen) and alpha2-antiplasmin is 4.0 microM but those for Lys-plasminogen or TLCK-plasmin are about 10-fold lower indicating a stronger interaction. The lysine-binding site(s) which is situated in triple-loops 1--3 in the plasmin A-chain is mainly responsible for the interaction with alpha2-antiplasmin. The interaction between Glu-plasminogen and alpha2-antiplasmin furthermore enhances the activation of Glu-plasminogen by urokinase to a comparable extent as 6-aminohexanoic acid, suggesting that similar conformational changes occur in the proenzyme after complex formation. Fibrinogen, fibrinogen digested with plasmin, purified fragment E and purified fragment D interfere with the reaction between plasmin and alpha2-antiplasmin by competing with alpha2-antiplasmin for the lysine-binding site(s) in the plasmin A-chain. The Kd obtained for these interactions varied between 0.2 microM and 1.4 microM; fragment E being the most effective. Thus the fibrinogen molecule contains several complementary sites to the lysine-binding sites located both in its NH2-terminal and COOH-terminal regions; these sites are to a large extent.     

Features of the interaction of Glu- and Lys-forms of plasminogen with native and partially hydrolyzed fibrin]

Glu- and Lys-plasminogen interaction with native and desAABB-fibrin obtained from fibrinogen partially hydrolyzed by plasmin was studied. It was found that native fibrin adsorbs 6 times more Lys-plasminogen as compared to the native form of the proenzyme. The range of the Lys-plasminogen binding does not change, if part of the fibrinogen molecules hydrolyze down to X-fragments. At the same time, the appearance in the system of 1% Xi-fragments leads to a 6-fold increase in the Glu-plasminogen binding. The amount of adsorbed Glu-plasminogen reaches the level of Lys-plasminogen adsorption both in the native and partially hydrolyzed fibrin. It was found that kringle K 1-3 or 6-aminohexanoic acid at saturating for high-affinity lysine-binding sites concentrations do not influence the Glu-plasminogen binding to native fibrin but inhibit it when the partially purified form is used. It is assumed that the manyfold increase of the Glu-plasminogen binding to partially hydrolyzed fibrin is due to the alteration of the proenzyme conformation at the initial steps of fibrin hydrolysis during the formation of Xi fragments.     

High-affinity binding sites for human Glu-plasminogen unveiled by limited plasmic degradation of human fibrin

The binding of human 125I-Glu-plasminogen to human plasmin-degraded fibrin was studied. Treatment of preformed and polymerized fibrin with 0.01 IU plasmin/ml resulted in an increased binding of 125I-Glu-plasminogen depending upon the length of time of preincubation of fibrin with plasmin. Binding reached a plateau of 30% of total added radioactivity after 60 min. At this time, less than 10% of fibrin had been digested. Polyacrylamide/urea/acetic acid gel electrophoresis revealed that the radioiodinated plasminogen bound to plasmin-degraded fibrin was of the Glu form. Computerized non-linear regression analysis of the binding experiments revealed that limited plasmic degradation of fibrin progressively generates high-affinity binding sites (Kd approximately equal to 0.3 microM) for Glu-plasminogen. At the time of maximal Glu-plasminogen binding approximately 5 high-affinity binding sites per 100 molecules of fibrin had been generated. The low-affinity type of binding sites were also identified. These observations describe a new mechanism which exquisitely modulates the plasmic breakdown of fibrin by a continuous renewal of high-affinity binding sites for Glu-plasminogen on the surface of the fibrin gel during the fibrinolytic process.     

Tissue-type plasminogen activator and its substrate Glu-plasminogen share common binding sites in limited plasmin-digested fibrin

The enzyme tissue-type plasminogen activator (t-PA) and its substrate Glu-plasminogen can both bind to fibrin. The assembly of these three components results in about a 1000-fold acceleration of the conversion of Glu-plasminogen into plasmin. Fibrin binding of t-PA is mediated both by its finger (F) domain and its kringle-2 domain. Fibrin binding of Glu-plasminogen involves its kringle structures (K1-K5). It has been suggested that particular kringles contain lysine-binding sites and/or aminohexyl-binding sites, exhibiting affinity for specific carboxyl-terminal lysines and intrachain lysines, respectively. We investigated the possibility that t-PA and Glu-plasminogen kringles share common binding sites in fibrin, limitedly digested with plasmin. For that purpose we performed competition experiments, using conditions that exclude plasmin formation, with Glu-plasminogen and either t-PA or two deletion mutants, lacking the F domain (t-PA del.F) or lacking the K2 domain (t-PA del.K2). Our data show that fibrin binding of t-PA, mediated by the F domain, is independent of Glu-plasminogen binding. In contrast, partial inhibition by Glu-plasminogen of t-PA K2 domain-mediated fibrin binding is observed that is dependent on carboxyl-terminal lysines, exposed in fibrin upon limited plasmin digestion. Half-maximal competition of fibrin binding of both t-PA and t-PA del.F is obtained at 3.3 microM Glu-plasminogen. The difference between this value and the apparent dissociation constant of Glu-plasminogen binding to limitedly digested fibrin (12.1 microM) under these conditions is attributed to multiple, simultaneous interactions, each having a separate affinity. It is concluded that t-PA and Glu-plasminogen can bind to the same carboxyl-terminal lysines in limitedly digested fibrin, whereas binding sites composed of intrachain lysines are unique both for the K2 domain of t-PA and the Glu-plasminogen kringles.     

Plasminogen activator inhibitor-1 binds to fibrin and inhibits tissue-type plasminogen activator-mediated fibrin dissolution.

Plasminogen activator inhibitor-1 (PAI-1) accumulates within thrombi and forming whole blood clots. To explore this phenomenon at the molecular level, PAI-1 binding to fibrin was examined. The experiments were performed by adding 125I-PAI-1, which retains its complete tissue-type plasminogen (t-PA) inhibitory activity, to fibrin matrices formed in 2-cm2 tissue culture wells. Guanidine HCl-activated PAI-1 binding was reversible and was inhibited in the presence of excess, unlabeled PAI-1. Activated 125I-PAI-1 recognized 2 sites on fibrin: a very small number of high affinity sites (Kd less than 1 nM) and principally a large number of low affinity sites with an approximate Kd of 3.8 microM. Latent PAI-1 bound to fibrin at a site indistinguishable from the lower affinity site recognized by activated PAI-1. Fibrin, pretreated with activated PAI-1, was protected from t-PA-mediated plasmin degradation in a PAI-1 dose-responsive manner (IC50 = 12.3 nM). Clot protection correlated with partial occupancy of the low affinity PAI-1 binding site on fibrin and was due to the formation of sodium dodecyl sulfate-stable, PAI-1.t-PA complexes. Latent PAI-1 (27 nM) did not protect the fibrin from dissolution. The localization of PAI-1 to a thrombus by virtue of its fibrin binding potential could result in significant protection of the thrombus from the degradative effects of the fibrinolytic system.