Regulation with alpha-2-antiplasmin of Glu-plasminogen activation by tissue activator on fibrin

Interaction of tissue plasminogen activator with alpha-2-antiplasmin and its influence on tissue activator binding to fibrin was studied. Alpha-2-Antiplasmin decreases the binding of tissue activator to fibrin by 20%. The inhibitor formed a complex with tissue plasminogen activator (Kd 78.2 nM) and had no effect on amidolytic activity of the activator. The tissue activator binding to alpha-2-antiplasmin decreases by 20-35% in the presence of 6-aminohexanoic acid. It indicates that not only kringle 2 of the tissue activator molecule takes part in complex formation with alpha-2-antiplasmin, but also other activator domains. Two models were proposed to explain the alpha-2-antiplasmin effect on the Glu-plasminogen activation by tissue activator on fibrin. In the first place, the inhibitor binds to fibrin in the site where the activator complex is localized. It can create steric hindrances for the proenzyme interaction with its activator on fibrin. In the second place, alpha-2-antiplasmin in a complex with tissue plasminogen activator can bring to a change in the activator conformation and a decrease of its functional activity.     

Characterization of the kinetic pathway for fibrin promotion of alpha-thrombin-catalyzed activation of plasma factor XIII

Kinetic and thermodynamic studies are presented showing that the cofactor activity of fibrin I (polymerized des-A fibrinogen) in the alpha-thrombin-catalyzed proteolysis of activation peptide (AP) from plasma factor XIII can be attributed to formation of a fibrin I-plasma factor XIII complex (Kd = 65 nM), which is processed by alpha-thrombin more efficiently (kcat/Km = 1.2 x 10(7) M-1 s-1) than free, uncomplexed plasma factor XIII (kcat/Km = 1.4 x 10(5) M-1 s-1). The increase in the specificity constant (kcat/Km) is shown to be largely due to an increase in the apparent affinity of alpha-thrombin for the complex of plasma factor XIII and fibrin I, as reflected by the 30-fold decrease in the Michaelis constant observed for fibrin I bound plasma factor XIII relative to that for uncomplexed plasma factor XIII. Analysis of the initial rates of alpha-thrombin-catalyzed hydrolysis of fibrinopeptide B (FPB) from fibrin I polymer in the presence of plasma factor XIII indicated that alpha-thrombin bound to fibrin I in the ternary complex of alpha-thrombin, plasma factor XIII, and fibrin I polymer is competent to catalyze cleavage of both FPB from fibrin I and AP from plasma factor XIII. This observation is consistent with the view that alpha-thrombin within the ternary complex is anchored to fibrin I polymer through a binding site distinct from the active site (an exosite) and that the active site is alternatively complexed with the AP moiety of plasma factor XIII or the FPB moiety of fibrin I. This conclusion is supported by the observation that a 12-residue peptide, which binds to an exosite of alpha-thrombin and blocks the interaction of alpha-thrombin with fibrinogen and fibrin, competitively inhibits alpha-thrombin-catalyzed release of both FPB and AP from the fibrin I-plasma factor XIII complex.     

Interaction of fibrin(ogen) with fibronectin: further characterization and localization of the fibronectin-binding site

The interaction of fibronectin with fibrin and its incorporation into fibrin clots are thought to be important for the formation of a provisional matrix that promotes cell adhesion and migration during wound healing. However, it is still unclear whether fibronectin interacts with both fibrin and fibrinogen or fibrin only and whether fibronectin binds exclusively to the fibrin(ogen) alphaC domains. To address these questions, we studied the interaction of fibronectin with fibrinogen, fibrin, and their proteolytic and recombinant fragments. In both ELISA and surface plasmon resonance (SPR) experiments, immobilized fibrinogen did not bind fibronectin at all, but after conversion to fibrin, it bound fibronectin with high affinity. To test which regions of fibrin are involved in this binding, we studied the interaction of fibronectin with the fibrin-derived D-D:E(1) complex and a recombinant alphaC fragment (residues Aalpha221-610) corresponding to the alphaC domain that together encompass the whole fibrin(ogen) molecule. In ELISA, when fibronectin was added to the immobilized D-D:E(1) complex or the immobilized alphaC fragment, only the latter exhibited binding. Likewise, when fibronectin was immobilized and the complex or the alphaC fragment was added, only the latter was observed to bind. The selective interaction between fibronectin and the alphaC fragment was confirmed by SPR. The fibronectin-binding site was further localized to the NH(2) terminal connector region of the alphaC domain since in ELISA, the immobilized recombinant Aalpha221-391 sub-fragment bound fibronectin well while the immobilized recombinant Aalpha392-610 sub-fragment exhibited no binding. This finding was confirmed by ligand blotting analysis. Thus, the results provide direct evidence for the existence of a cryptic high-affinity fibronectin-binding site in the Aalpha221-391 region of the fibrinogen alphaC domain that is not accessible in fibrinogen but becomes exposed in fibrin.     

The interference of plasmic degradation products of human crosslinked fibrin with clot formation

The role of plasmic degradation products of human crosslinked fibrin on polymerization of fibrin monomer and clot formation was studied. Both reactions were inhibited by Fragment DD, which formed a complex with fibrin monomer in a molar ratio 1 : 1. The rate of polymerization was slightly increased by Fragment E but it was not affected by (DD)E complex and Fragment A. Approximately the same amount of fibrin was formed in the presence and absence of Fragments A, E and the complex. It was concluded that of the degradation products of crosslinked fibrin, only Fragment DD is a potent anticoagulant at physiologic pH. The (DD)E complex is inert and Fragments A and E have only marginal effects.     

The interference of plasmic degradation products of human crosslinked fibrin with clot formation.

The role of plasmic degradation products of human crosslinked fibrin on polymerization of fibrin monomer and clot formation was studied. Both reactions were inhibited by Fragment DD, which formed a complex with fibrin monomer in a molar ratio 1 : 1. The rate of polymerization was slightly increased by Fragment E but it was not affected by (DD)E complex and Fragment A. Approximately the same amount of fibrin was formed in the presence and absence of Fragments A, E and the complex. It was concluded that of the degradation products of crosslinked fibrin, only Fragment DD is a potent anticoagulant at physiologic pH. The (DD)E complex is inert and Fragments A and E have only marginal effects.     

Kinetics of the interaction of desAABB-fibrin monomer with immobilized fibrinogen

The soluble and stable fibrin monomer-fibrinogen complex (SF) is well known to be present in the circulating blood of healthy individuals and of patients with thrombotic diseases. However, its physiological role is not yet fully understood. To deepen our knowledge about this complex, a method for the quantitative analysis of interaction between soluble fibrin monomers and surface-immobilized fibrinogen has been established by means of resonant mirror (IAsys) and surface plasmon resonance (BIAcore) biosensors. The protocols have been optimized and validated by choosing appropriate immobilization procedures with regeneration steps and suitable fibrin concentrations. The highly specific binding of fibrin monomers to immobilized fibrin(ogen), or vice versa, was characterized by an affinity constant of approximately 10(-8)M, which accords better with the direct dissociation of fibrin triads (KD approximately 10(-8) -10(-9) M) (J. R. Shainoff and B. N. Dardik, Annals of the New York Academy of Science, 1983, Vol. 27, pp. 254-268) than with earlier estimations of the KD for the fibrin-fibrinogen complex (KD approximately 10(-6) M) (J. L. Usero, C. Izquierdo, F. J. Burguillo, M. G. Roig, A. del Arco, and M. A. Herraez, International Journal of Biochemistry, 1981, Vol. 13, pp. 1191-1196).     

Electron microscopic study of the products from dissolving unstabilized fibrin with complex heparin compounds

Effects of some heparin complex compounds (heparin-urea, adrenaline-heparin, fibrinogen-heparin complexes and secondary complex adrenalin-heparin-fibrinogen) on factor XIIIa unstabilized fibrin were studied using electron microscopy. Fibrillar network of unstabilized fibrin destroys with the formation of globular molecular particles similar to fibrinogen molecule or fibrin monomer ultrastructure. A mechanism of fibrinolytic action of all the complexes mentioned is probably the same, since under dissolving of unstabilized fibrin, structures are found, which are similar to those forming under dissolving of unstabilized fibrin with urea.     

Conversion of fibrinogen to fibrin: mechanism of exposure of tPA- and plasminogen-binding sites

Conversion of fibrinogen into fibrin results in the exposure of cryptic interaction sites and modulation of various activities. To elucidate the mechanism of this exposure, we tested the accessibility of the Aalpha148-160 and gamma312-324 fibrin-specific epitopes that are involved in binding of plasminogen and its activator tPA, in several fragments derived from fibrinogen (fragment D and its subfragments) and fibrin (cross-linked D-D fragment and its noncovalent complex with the E(1) fragment, D-D. E(1)). Neither D nor D-D bound tPA, plasminogen, or anti-Aalpha148-160 and anti-gamma312-324 monoclonal antibodies, indicating that their fibrin-specific epitopes were inaccessible. The Aalpha148-160 epitope became exposed only upon proteolytic removal of the beta- and gamma-modules from D. At the same time, both epitopes were accessible in the D-D.E(1) complex, indicating that the DD.E interaction resulted in their exposure. This exposure was reversible since the dissociation of the D-D.E(1) complex made the sites unavailable, while reconstitution of the complex made them exposed. The results indicate that upon fibrin assembly, driven primarily by the interaction between complementary sites of the D and E regions, the D regions undergo conformational changes that cause the exposure of their plasminogen- and tPA-binding sites. These changes may be involved in the regulation of fibrin assembly and fibrinolysis.     

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.     

Complexes of the N-terminal disulfide branch point of fibrin with fibrinogen

Investigation of fibrin N-terminal disulphide knot (N-DSK) binding with fibrinogen (F) showed, that the F-N-DSK-complex represents growing polymer structure which is soluble at early polymerization stage and forms a solid phase during the further growth. This complex is characterized by constant stoichiometry expressed by formula F (N-DSK)2. A model of the complex structure as a regular copolymer of fibrinogen and N-DSK is proposed, in which neighbouring fibrinogen molecules are clamped with two N-DSK molecules. Such copolymer was never described. Since its formation is caused by specific D-E interdomain binding, it may be considered as a peculiar analogue of fibrin polymer.     

Anticoagulant effects of the heparin-proline complex

In the present work, the formation of the proline-heparin complex has been established. The way to synthesize the complex in vitro has been developed. The complex synthesized with the molar ratio of proline to heparin of 3: 1 extended the time of formation of a fibrin clot, reduced platelet aggregation, and showed a lytic effect towards nonstabilized fibrin in vitro conditions. Ten minutes after intravenous administration of the proline-heparin complex, there was an increase in levels of fibrin-depolymerization, anticoagulant, antifibrin-stabilizing and antiplatelet activity in blood of animals, whereas its components, proline and heparin, did not have such effects.     

Formation of a ternary complex between thrombin, fibrin monomer, and heparin influences the action of thrombin on its substrates

The consequences of the combined effects of fibrin II monomer (FnIIm) and heparin (H) on the hydrolysis of peptidyl p-nitroanilide substrates by thrombin (IIa), the cleavage of prothrombin by thrombin and the thrombin-catalyzed release of fibrinopeptides from fibrinogen have been studied at pH 7.4 and I 0.15. The effects of fibrin II monomer and heparin on chromogenic substrate hydrolysis can be described by a hyperbolic mixed inhibition model in which substrate can interact with four possible enzyme species (IIa, IIa.H, IIa.FnIIm, and IIa.FnIIm.H) that arise as a result of random formation of a ternary complex among thrombin, fibrin II monomer, and heparin (Hogg, P. J. and Jackson, C. M. (1990) J. Biol. Chem. 265, 241-247). The formation of the ternary IIa.FnIIm.H complex results in an increase in the Km values of 7.03 +/- 1.17-fold (1.37-9.65 microM) and 1.94 +/- 0.60-fold (38.1-73.9 microM) for H-D-Ile-Pro-Arg-pNA and Cbz-Gly-Pro-Arg-pNA hydrolysis, respectively, and a decrease in the kc values of 0.45 +/- 0.08-fold (49.5-22.3 s-1) and 0.52 +/- 0.05-fold (93.1-48.4 s-1). Fibrin II monomer and heparin in combination also decrease the efficiency (kc/Km) with which thrombin cleaves prothrombin to produce Fragment 1 and Prethrombin 1 by 2.3-fold from 607 +/- 30 to 264 +/- 13 M-1 s-1. In contrast to the effects of fibrin II monomer and heparin on thrombin hydrolysis of chromogenic substrates, its proteolysis of prothrombin and its inactivation by antithrombin III (Hogg, P. J., and Jackson, C. M. (1989) Proc. Natl. Acad. Sci. U. S. A. 86, 3619-3623), these components have no discernible influence on the ability of thrombin to cleave fibrinogen. These observations indicate that the substrate specificity of thrombin is altered when it is bound in a complex with fibrin II monomer and heparin and suggest that the catalytic efficiency of thrombin for its physiological substrates will be affected differentially by these interactions. Such ternary complex formation involving thrombin, fibrin II monomer, and heparin may provide a mechanism for selectively regulating thrombin action.     

The Non-catalytic B Subunit of Coagulation Factor XIII Accelerates Fibrin Cross-linking

Covalent cross-linking of fibrin chains is required for stable blood clot formation, which is catalyzed by coagulation factor XIII (FXIII), a proenzyme of plasma transglutaminase consisting of catalytic A (FXIII-A) and non-catalytic B subunits (FXIII-B). Herein, we demonstrate that FXIII-B accelerates fibrin cross-linking. Depletion of FXIII-B from normal plasma supplemented with a physiological level of recombinant FXIII-A resulted in delayed fibrin cross-linking, reduced incorporation of FXIII-A into fibrin clots, and impaired activation peptide cleavage by thrombin; the addition of recombinant FXIII-B restored normal fibrin cross-linking, FXIII-A incorporation into fibrin clots, and activation peptide cleavage by thrombin. Immunoprecipitation with an anti-fibrinogen antibody revealed an interaction between the FXIII heterotetramer and fibrinogen mediated by FXIII-B and not FXIII-A. FXIII-B probably binds the γ-chain of fibrinogen with its D-domain, which is near the fibrin polymerization pockets, and dissociates from fibrin during or after cross-linking between γ-chains. Thus, FXIII-B plays important roles in the formation of a ternary complex between proenzyme FXIII, prosubstrate fibrinogen, and activator thrombin. Accordingly, congenital or acquired FXIII-B deficiency may result in increased bleeding tendency through impaired fibrin stabilization due to decreased FXIII-A activation by thrombin and secondary FXIII-A deficiency arising from enhanced circulatory clearance.     

Electronmicroscopic study on the molecular shape of non-stabilized fibrin break-down products produced by complex heparin compounds

Experimental data indicate that products develop from non-stabilized fibrin because of nonfermentative splitting by complex heparin connections. These products have a globular form with a diameter of 10-250 A and are similar to morphological fibrinogen molecules. The identified products show no marked lytic effect towards non-stabilized fibrin. The application of S35 labelled heparin in combination with preparative ultracentrifugation and electron microscopy enabled the determination to be established that heparin complexes will combine with particles of fibrinomeres, thus causing their transfer from the fibrillary to the globular condition. The destruction of the connections of heparin complexes with their globular molecule structures of fibrinmonomere, e.g. by protamine sulfate, guarantees their development and primary polymerization. With factor XIIIa being present, the structurally reconstructed fibrin will form a stabilized coagulum of full value which is similar in its ultrastructure to fibrin obtained in control tests.     

Fibrin-fragment D-protector equilibrium system. Quantitative determination of protector activity

Equilibrium distribution of fibrin between clot fibres and liquid phase was studied as affected by the protector fraction of fibrinogen tryptic hydrolyzate in the presence of fragment D. It was found that in such a system the protector counteracting the solubilizing fibrin-effect of fragment D evokes an increase in the content of the fibrin solid phase. The effect is suggested to be used as a quantitative index of the protector activity. The presence of equilibrium between the protector--fragment D complex and products of its dissociation is shown. This equilibrium is a part of a more complex fibrin--fragment D-protector equilibrium system.     

Molecular basis for the susceptibility of fibrin-bound thrombin to inactivation by heparin cofactor ii in the presence of dermatan sulfate but not heparin

Although fibrin-bound thrombin is resistant to inactivation by heparin.antithrombin and heparin.heparin cofactor II complexes, indirect studies in plasma systems suggest that the dermatan sulfate.heparin cofactor II complex can inhibit fibrin-bound thrombin. Herein we demonstrate that fibrin monomer produces a 240-fold decrease in the heparin-catalyzed rate of thrombin inhibition by heparin cofactor II but reduces the dermatan sulfate-catalyzed rate only 3-fold. The protection of fibrin-bound thrombin from inhibition by heparin.heparin cofactor II reflects heparin-mediated bridging of thrombin to fibrin that results in the formation of a ternary heparin.thrombin.fibrin complex. This complex, formed as a result of three binary interactions (thrombin.fibrin, thrombin.heparin, and heparin.fibrin), limits accessibility of heparin-catalyzed inhibitors to thrombin and induces conformational changes at the active site of the enzyme. In contrast, dermatan sulfate binds to thrombin but does not bind to fibrin. Although a ternary dermatan sulfate. thrombin.fibrin complex forms, without dermatan sulfate-mediated bridging of thrombin to fibrin, only two binary interactions exist (thrombin.fibrin and thrombin. dermatan sulfate). Consequently, thrombin remains susceptible to inactivation by heparin cofactor II. This study explains why fibrin-bound thrombin is susceptible to inactivation by heparin cofactor II in the presence of dermatan sulfate but not heparin.     

Conformational and structural modulation of the NH2-terminal regions of fibrinogen and fibrin associated with plasmin cleavage.

Conformational and structural modulations of the NH2-terminal region of fibrinogen and fibrin associated with plasmin cleavage have been examined utilizing specific antibody probes. The E region derived from the NH2-terminal aspects of fibrinogen undergoes complex structural and conformational changes throughout the cleavage process as indicated by differences in the quantitative and qualitative expression of antigenic determinants by the E region of each isolated cleavage fragment. When the range of antigenic determinants recognized by the antibody probe is limited to a specific molecular marker on the gamma chain within the E region, fg-E-neo, evidence for a systematic and progressive modulation of this site during plasmin cleavage is observed. Fg-E-neo undergoes progressive exposure as the cleavage of fibrinogen proceeds from X to Y to D:E complex. Separation of the D:E complex into its constituent, D and E fragments, is associated with further exposure of fg-E-neo determinants. The sequential cleavage of fibrin by plasmin also leads to progressive exposure of the fg-E-neo site; however, comparison of corresponding fragments derived from fibrinogen and fibrin reveals significant differences in the character of fg-E-neo expression. Immunochemical differences between fibrin and fibrinogen E fragments are not abolished by further exposure of the fragments to plasmin, are apparently not due to the presence or absence of fibrinopeptides, and are maintained following denaturation and renaturation of the fragments. These results suggest that the differential expression of fg-E-neo by the E fragments may be primarily dependent upon differences in amino acid compositions of the fragments.     

Inhibition of fibrin-bound thrombin by a covalent antithrombin-heparin complex

Numerous studies have shown that fibrin-bound thrombin (IIa) is protected from inhibition by antithrombin (AT) + heparin (H) due to the formation of a ternary fibrin.IIa.H complex. We investigated factors affecting the inhibition of fibrin.IIa by a covalent complex of AT and H (ATH). The rate of IIa reaction with ATH was decreased 2-3-fold by fibrin monomer as compared to 57-fold for AT + heparin with high AT affinity. Furthermore, although the reaction of AT + H with a IIa mutant with decreased H binding (RA-IIa) was inhibited 2-3-fold in the presence of fibrin, reaction rates of ATH + RA-IIa were not reduced by fibrin. The relative difference in the effect of fibrin on the ATH reaction with RA-IIa compared to that for reactions of AT + H with RA-IIa is consistent with the fact that, in the absence of fibrin, the rate of the ATH reaction with RA-IIa relative to IIa was much less reduced (8-fold) compared to the corresponding reactions of AT + H (decreased 306 fold). Similarly, the addition of excess H in the absence of fibrin gave only a small decrease in rate of ATH + IIa reaction. However, in the presence of fibrin, the addition of 40-fold excess H decreased the rate of ATH inhibition of IIa by 1 order of magnitude. Experiments with ATH containing low molecular weight heparin chains with low AT affinity showed that IIa inhibition requires ATH with long chains that activate the AT moiety. Finally, electrophoresis of fibrin +/- ((125)I-)IIa +/- ((125)I-)ATH on native and denaturing gels showed that ATH forms ATH-IIa complexes that remain bound to fibrin through the ATH component. Thus, ATH is a potent inhibitor of fibrin-bound IIa, likely due to the formation of fibrin.ATH-IIa as opposed to fibrin.IIa.H ternary complexes.     

Reversible cross-linking of alpha 2-plasmin inhibitor to fibrinogen by fibrin-stabilizing factor

alpha 2-Plasmin inhibitor, a primary inhibitor of fibrinolysis, is cross-linked to fibrin by plasma transglutaminase (glutaminyl-peptide:amine gamma-glutamyltransferase, EC 2.3.2.13, activated fibrin-stabilizing factor) when blood coagulation takes place. alpha 2-Plasmin inhibitor was found also to be cross-linked to fibrinogen by plasma transglutaminase. The inhibitor was corss-linked exclusively to the A alpha-chain of fibrinogen, and the cross-linking reaction proceeded very rapidly. The reaction was almost completed before the formation of the gamma-chain dimers of fibrinogen which precedes cross-linking polymerization of the A alpha-chain of fibrinogen. The maximum level of inhibitor cross-linking achieved was approx. 30% of the inhibitor present at the start of the reaction. The level of cross-linking of the inhibitor was not changed when the cross-linking reaction was preceded by dimerization of fibrinogen. The cross-linking reaction was found to be a reversible one, since the cross-linked complex of the inhibitor and fibrinogen was partly dissociated to each of its components when the complex was incubated with plasma transglutaminase. These results suggest that the self-limiting nature of the cross-linking reaction between alpha 2-plasmin inhibitor and fibrin(ogen) is due to the reaction equilibrium favoring dissociation of the complex, and not due to the development of structural hindrance in polymerizing fibrin(ogen).     

Fibrin membrane endowed with biological function. V. Multienzyme complex of uricase,catalase, allantoinase and allantoicase

The enzymes (uricase (EC 1.7.3.3), allantoinase (EC 3.5.3.4), and allantoicase (EC 3.5.2.5) which participate in degradation of purine bases, were embedded separately in fibrin membranes formed by fibrinogen-fibrin conversion with thrombin. All of these enzymes together with catalase were also embedded in a single fibrin membrane to make an immobilized multienzyme complex. The multienzyme complex in fibrin membrane thus prepared had an ability of degradation of uric acid to urea and glyoxylic acid via allantoin and allantoic acid. The stability of immobilized uricase or catalse embedded in fibrin membrane upon lyophilization was also tested in a comparison with non-immobilized enzymes.