Modification of fibrin network ultrastructure by Fab fragments specific for different domain of fibrinogen

Kinetics of inhibition of fibrin monomer polymerization produced by Fab fragments prepared from immunochemically purified monospecific antibodies to the surface epitopes of different domains of fibrinogen molecule has been correlated with electron microscopic observations of resulting specimens. Fab fragments prepared from anti FgD antisera were the most efficient inhibitors of thrombin-catalysed conversion of fibrinogen to fibrin; polymerization of fibrin monomers as detected spectrophotometrically was abolished at 2:1 molar ratio of anti FgD Fab fragments to fibra monomer. These Fab fragments acting as a steric hindrance of polymerization sites inhibited the first stage of fibrin monomer aggregation. Interaction of Fab fragments derived from antibodies specific for alpha 239-476 with corresponding segment of fibrinogen molecule resulted in a weak inhibition of fibrin monomer polymerization. However, fibrin obtained in the presence of these Fab fragments was significantly modified and showed no periodicity. This observation may suggest that anti alpha 239-476 Fab impaired the course of the second stage of fibrin monomer polymerization, i.e. lateral association of fibrin fibrils.     

Expression of primary polymerization sites in the D domain of human fibrinogen depends on intact conformation

Fragments D1 and DD, plasmic degradation products of human fibrinogen and cross-linked fibrin, respectively, originate from the COOH-terminal domain of the parent molecule. Since a specific binding site for fibrin resides in the COOH-terminal region of the gamma chain, the primary structure of the two fragments was compared and their affinity for fibrin monomer measured. Fragments D1 and DD contained the same segments of the three fibrinogen chains, corresponding to the sequences alpha 105-206, beta 134-461, and gamma 63-411. Fragment DD had a double set of the same chain remnants. Fragments D1 and DD inhibited polymerization of fibrin monomer in a dose-dependent manner; 50% inhibition occurred at a molar ratio of fragment to monomer of 1:1 and 0.5:1, respectively. To prevent fibrin monomer polymerization and render it suitable for binding studies in the liquid phase, fibrinogen was decorated with Fab fragments isolated from rabbit antibodies to human fragment D1. Fibrinogen molecules decorated with 6 molecules of this Fab fragment did not clot after incubation with thrombin, and the decorated fibrin monomer could be used to measure binding of fragments D1 and DD in a homogeneous liquid phase. The data analyzed according to the Scatchard equation and a double-reciprocal plot gave a dissociation constant of 12 nM for fragment D1 and 38 nM for fragment DD. There were two binding sites/fibrin monomer molecule for each fragment. After denaturation in 5 M guanidine HCl, the inhibitory function on fibrin polymerization was irreversibly destroyed. Denatured fragments also lost binding affinity for immobilized fibrin monomer. The preservation of the native tertiary structure in both fragments was essential for the expression of polymerization sites in the structural D domain.     

The role of fibrinogen alpha C-domains in the fibrin assembly process

Turbidity development registration and electron microscopic observation of the assembly process of the fibrin monomer and its derivative lacking in intact alpha C-domains (monomeric X1 fragment) have shown that these domains participate in fibrin polymerization, not as structural components, but as a factor promoting the ordered process of fibrin assembly.     

Structure, stability, and interaction of fibrin αC-domain polymers

Our previous studies revealed that in fibrinogen the αC-domains are not reactive with their ligands, suggesting that their binding sites are cryptic and become exposed upon its conversion to fibrin, in which these domains form αC polymers. On the basis of this finding, we hypothesized that polymerization of the αC-domains in fibrin results in the exposure of their binding sites and that these domains adopt the physiologically active conformation only in αC-domain polymers. To test this hypothesis, we prepared a recombinant αC region (residues Aα221-610) including the αC-domain (Aα392-610), demonstrated that it forms soluble oligomers in a concentration-dependent and reversible manner, and stabilized such oligomers by covalently cross-linking them with factor XIIIa. Cross-linked Aα221-610 oligomers were stable in solution and appeared as ordered linear, branching filaments when analyzed by electron microscopy. Spectral studies revealed that the αC-domains in such oligomers were folded into compact structures of high thermal stability with a significant amount of β-sheets. These findings indicate that cross-linked Aα221-610 oligomers are highly ordered and mimic the structure of fibrin αC polymers. The oligomers also exhibited functional properties of polymeric fibrin because, in contrast to the monomeric αC-domain, they bound tPA and plasminogen and stimulated activation of the latter by the former. Altogether, the results obtained with cross-linked Aα221-610 oligomers clarify the structure of the αC-domains in fibrin αC polymers and confirm our hypothesis that their binding sites are exposed upon polymerization. Such oligomers represent a stable, soluble model of fibrin αC polymers that can be used for further structure-function studies of fibrin αC-domains.     

Decorin modulates fibrin assembly and structure

Emerging evidence indicates that fibrin clotting is regulated by different external factors. We demonstrated recently that decorin, a regulator of collagen fibrillogenesis and transforming growth factor-beta activity, binds to the D regions of fibrinogen (Dugan, T.A., Yang, V. W.-C., McQuillan, D.J., and H??k, M. (2003) J. Biol. Chem. 278, 13655-13662). We now report that the decorin-fibrinogen interaction alters the assembly, structure, and clearance of fibrin fibers. Relative to fibrinogen, substoichiometric amounts of decorin core protein modulated clotting, whereas an excess of an active decorin peptide was necessary for similar activity. These concentration-dependent effects suggest that decorin bound to the D regions sterically modulates fibrin assembly. Scanning electron microscopy images of fibrin clotted in the presence of increasing concentrations of decorin core protein showed progressively decreasing fiber diameter. The sequestration of Zn(2+) ions from the N-terminal fibrinogen-binding region abrogated decorin incorporation into the fibrin network. Compared with linear thicker fibrin fibers, the curving thin fibers formed with decorin underwent accelerated tissue-type plasminogen activator-dependent fibrinolysis. Collectively, these data demonstrate that decorin can regulate fibrin organization and reveal a novel mechanism by which extracellular matrix components can participate in hemostasis, thrombosis, and wound repair.     

Volodymyr Oleksandrovych Bielitser--a gifted scientist and outstanding biochemist, a founder of the scientific school

Professor V. O. Belitser, Doctor of Science (biology), (30.09.1906, Ryazan, RF-04.03.1988 Kyiv, Ukraine), Member of the National Academy of Sciences of Ukraine, graduated from the physico-mathematical faculty of the Moscow University in speciality "physico-chemical biology". In 1934-1943 he worked at the All-Union Institute of Experimental Medicine (Moscow) where he was engaged in research of the relation between the respiratory system and glycolytic reactions in the animal tissues. V. O. Belitser established the effect of creatin on the muscular respiration on the role of creative phosphate in this process. He was the first to demonstrate that the anaerobic phosphorylation is bound to respiration. He investigated stechiometric relations between the joint phosphate binding and oxygen absorption and estimated thermodynamic importance of this process, he showed that the energy of electron transfer from the substrate to oxygen is a source of formation of three ATP molecules per one atom of absorbed oxygen. From 1944 to 1988 V. O. Belitser worked at the Institute of Biochemistry of the Academy of Sciences of the Ukr.SSR (Kyiv), where he headed the Laboratory of Enzymes (then proteins), and from 1966 he headed the Department of Protein Structure and Function; for a certain period (1969-1972) he headed the Institute as its director. Investigations of properties of native and denaturated proteins jointly with K. I. Kotkova led to the creation of blood substitute from blood serum proteins of cattle--BK-8. The school of V. O. Belitser is known by studying the molecular mechanism of one of the basic reactions of blood coagulation--fibrinogen transformation to fibrin, by finding out the organization and function of fibrinogen and fibrin. It was proved experimentally that the specific polymerization centres significance for the fibrin lattice formation are of essential significance for the fibrin lattice formation, that fibrinogen to fibrin transformation occurs in two stages--enzymatic and polymerizational ones. V. O. Belitser proposed the mechanism of fibrinogen transformation to fibrin, as soon as he had substantiated the kinetic theory of this reaction; domain structure of fibrinogen has been investigated. Such diagnostic tests as the methods of definition of the products of fibrinogen and fibrin splitting in urine (for differential diagnosis of cardiovascular diseases) were developed and put into medical practice under his guidance. V. O. Belitser and members of his school have published above 300 scientific works, prepared 5 doctors and 25 candidates of science. The selfless work of the scientists was honoured with high state awards--the Orders of Lenin, the Order of the Labour Red Banner, the Order of Oktober Revolution, that of Friendship of Peoples and with numerous medals.     

The ultrastructure of fibrinogen-420 and the fibrin-420 clot

Fibrinogen-420 is a minor subclass of human fibrinogen that is so named because of its higher molecular weight compared to fibrinogen-340, the predominant form of circulating fibrinogen. Each of the two Aalpha chains of fibrinogen-340 is replaced in fibrinogen-420 by an Aalpha isoform termed alphaE. Such chains contain a globular C-terminal extension, alphaEC, that is homologous with the C-terminal regions of Bbeta and gamma chains in the fibrin D domain. The alphaEC domain lacks a functional fibrin polymerization pocket like those found in the D domain, but it does contain a binding site for beta2 integrins. Electron microscopy of fibrinogen-340 molecules showed the major core fibrinogen domains, D-E-D, plus globular portions of the C-terminal alphaC domains. Fibrinogen-420 molecules had two additional globular domains that were attributable to alphaEC. Turbidity measurements of thrombin-cleaved fibrinogen-420 revealed a reduced rate of fibrin polymerization and a lower maximum turbidity. Thromboelastographic measurements also showed a reduced rate of fibrin-420 polymerization (amplitude development) compared with fibrin-340. Nevertheless, the final amplitude (MA) and the calculated elastic modulus (G) for fibrin-420 were greater than those for fibrin-340. These results suggested a greater degree of fibrin-420 branching and thinner matrix fibers, and such structures were found in SEM images. In addition, fibrin-420 fibers were irregular and often showed nodular structures protruding from the fiber surface. These nodularities represented alphaEC domains, and possibly alphaC domains as well. TEM images of negatively shadowed fibrin-420 networks showed irregular fiber borders, but the fibers possessed the same 22.5-nm periodicity that characterizes all fibrin fibers. From this result, we conclude that fibrin-420 fiber assembly occurs through the same D-E interactions that drive the assembly of all fibrin fibrils, and therefore that the staggered overlapping molecular packing arrangement is the same in both types of fibrin. The alphaEC domains are arrayed on fiber surfaces, and in this location, they would very likely slow lateral fibril association, causing thinner, more branched fibers to form. However, their location on the fiber surface would facilitate cellular interactions through the integrin receptor binding site.     

Dynamic changes of fibrin architecture during fibrin formation and intrinsic fibrinolysis of fibrin-rich clots

Clotting and fibrinolysis are initiated simultaneously in vivo, and fibrinolysis usually occurs without any individualized lysis front (intrinsic fibrinolysis). We have developed a novel model to assess whether morphological changes resulting from intrinsic fibrinolysis are similar to those previously reported at the lysis front using externally applied lytic agents. Fibrin assembly and fibrinolysis were followed in real-time by confocal microscopy using gold-labeled fibrinogen molecules. An increase in fiber absorbance (30%, p < 0.01) and a decrease in fiber diameter (60%, p < 0.01) due to the ongoing accumulation and packing of fibrin molecules were the most significant detectable features occurring during fibrin assembly. Similar features with a similar magnitude were observed during fibrin dissolution, but in the reverse order and with a 3-fold increase in duration. Then, lysing fibers were progressively transected laterally, and thinner fibers were cleaved at a 2.5-fold faster rate than thicker fibers (p < 0.001). Frayed lysing fibers were seen to interact progressively with adjoining fibers (agglomeration), leading to a 76 and 88% increase in the network pore diameter (p < 0.05) and fiber diameter (p < 0.01), respectively. At the maximum decrease in fiber absorbance (46%, p < 0.05), the network suddenly collapsed with the release of large fragments that gradually vanished. Morphological changes of fibrin that occur during intrinsic fibrinolysis are similar as those observed next to the lysis front, although they are not restricted spatially to the clot/surrounding milieu interface but are observed through the entire clot.     

Localization of the domains of fibrin involved in binding to platelets

The molecular basis of platelet-fibrin interactions has been investigated by using synthetic peptides as potential inhibitors of fibrin protofibril and fibrinogen binding to ADP-stimulated platelets, adhesion of fibrin fibers to the platelet surface, and platelet-mediated clot retraction. Synthetic peptides of sequence RGDS and HHLGGAKQAGDV, corresponding to regions of the fibrinogen alpha- and gamma-chains previously identified as platelet recognition sites, inhibited the binding of radiolabelled soluble fibrin oligomers to ADP-stimulated platelets with IC50 values of 10 and 40 microM, respectively. Synthetic GPRP and GHRP, corresponding to the N-terminal tripeptide sequence of the fibrin alpha-chains and the tetrapeptide sequence of the beta-chains, respectively, were minimally effective in blocking soluble fibrin polymer binding to ADP-stimulated platelets. Platelet functions which are unique to the three-dimensional fibrin network were examined by measurements of the extent of adhesion of fluorophore-labelled fibrin to platelets with a microfluorimetric technique and by light scattering measurements of the time course of clot retraction. Inhibition of fibrin-platelet adhesion by RGDS, HHLGGAKQAGDV and GHRP exhibited a similar, linear dependence reaching 1/2 maximum at about 200 microM, suggesting nonspecific effects. GPRP inhibited fibrin assembly but did not appear to have specific effects on fibrin-platelet adhesion. Only RGDS effected clot retraction, causing a 4-6-fold decrease in rate at 230 microM. These results indicate that fibrinogen and fibrin protofibrils, which are obligatory intermediates on the fibrin assembly pathway, share a set of common platelet recognition sites located at specific regions of the alpha- and gamma-chains of the multinodular fibrin(ogen) molecules. The RGDS site is also involved in mediating interactions between the three-dimensional fibrin network and stimulated platelets.     

alphaC domains of fibrinogen molecules as the structures accelerating fibrin assembly

Preparation of monomeric fibrin lacking intact alpha C-domains (monomeric X1-fragment), but fully clottable, is described. The assembly process of both monomeric fibrin and monomeric X1-fragment has been studied by electron microscopy and light scattering methods. It was shown that both proteins form similar fibrils with characteristic cross-banding. Upon dilution a sharp elevation of the differences between the assembly rates of monomeric X1-fragment and monomeric fibrin was revealed. The results obtained show that alpha C-domains take part in fibrin clot formation not as structural components but as the factor accelerating the ordered assembly of complex fibrin structure. The possible mechanism of alpha C-domains participation in fibrin clot formation are regarded.     

The effect of fibrin structure on fibrinolysis.

Fibrin structure contributes to the regulation of the fibrinolytic rate. As the fibrin fiber size is decreased, the fibrinolytic rate also decreases. Fibrin structure was altered by either changing the ratio of thrombin to fibrinogen, i.e. altering the assembly rate or by adding a fibrin assembly inhibitor, iopamidol. Changes in the fibrinolytic rate were followed by measuring the time dependence of the decrease in the fiber mass/length ratio during fibrinolysis. A measure of the overall fibrinolytic rate was determined from the decrease in the mass/length ratio versus time. An 8-fold reduction in the fibrinolytic rate was seen on decreasing the mass/length ratio from 2.7 x 10(12) daltons/cm to 0.5 x 10(12) daltons/cm. It is shown that thin fibrin fibers have a decreased rate of conversion of plasminogen to plasmin by tissue plasminogen activator and that thin fibrin fibers are lysed more slowly than thick fibrin fibers.     

Interaction between complementary polymerization sites in the structural D and E domains of human fibrin.

Plasmic degradation products of human fibrin, fragments DD, D, and E, bind to fibrin. It has been inferred from this observation that the binding occurs by attraction of complementary sites located in the NH2- and COOH-terminal domains of the fibrin molecule. The interaction between fragments D1 and E1 has been investigated in this work since it represents the first step in the process of fibrin clot formation. Fragment D1, that was initially as active as fragment DD, lost most of its anticoagulant activity after purification by cation-exchange chromatography. The lability of fragment D1 function explained the previous unsuccessful attempts to form a complex between fragments D1 and E1. The loss of fragment D1 anticoagulant activity was not associated with the cleavage of the gamma 63-85 chain segment, since fragments D1A and D1 identically inhibited the fibrin monomer polymerization rate. In order to demonstrate the formation of a complex between fragments D1 and E1, three lines of experiments were advanced. First, the anticoagulant activity of fragment D1 was neutralized by fragment E1 in a dose-dependent manner, demonstrating that the association between these fragments involved polymerization sites. Second, two products, D1.E1 and D1.E1.D1, were stabilized in a reaction with bifunctional cross-linking reagents, proving the formation of D.E complexes in aqueous solution. Third, immobilized fragment D1 bound fragments E1 and E2, but not fragment E3, showing that fragments E1 and E2 attached via a polymerization site to the complementary one in fragment D1, since this association was disrupted by fibrin polymerization inhibitory peptide GPRP. These results provided direct evidence for specific binding between the structural D and E domains of fibrin mediated through complementary polymerization sites. Thus, the initial formation of fibrin clot fibers appears to be driven by specific association of these sites.     

Interactions of bovine fibrinogen and thrombin. Early events in the development of clot structure.

Interactions which determine the rate of conversion of fibrinogen into monomer fibrin and the retention of monomer fibrin in a noncompactible form through interaction with residual fibrinogen (solution stabilization) were examined through the kinetics of formation of equilibrium compactible network at pH 7 and ionic strength 0.15. For studies of conversion, reactions with thrombin were at 29 or 2 °C, hirudin was added at successive times to inhibit thrombin, and compactible network was equilibrated at 2 °C, where solution stabilization is negligible. A substrate dependency of initial rate is interpreted on the basis of inactive complex formation between thrombin and both fibrinogen and monomer fibrin. At 29 or 2 °C specific rate constants are 32 or 2.9 × 10⁶ liter/mol, and association constants for inactive complex formation are 5.2 or 2.0 × 10⁵ liter/mol. The second peptide-A is removed from fibrinogen ~ 40-fold as rapidly as the first.With equilibration at 29 °C, compactible network does not appear until the solution stabilization ratio of residual fibrinogen/monomer fibrin is four. Thereafter, increasing amounts of compactible network appear. However, the stabilization ratio progressively decreases to approximately two, a situation which indicates the complexity of the stabilization mechanism.The thrombin-hirudin association constant is estimated to be 4.9 or 17 × 10¹¹ liter/mol at 29 or 2 °C.     

Fibrinogen Dusart: electron microscopy of molecules, fibers and clots, and viscoelastic properties of clots.

Ultrastructural perturbations resulting from defects in polymerization of fibrinogen Dusart, a congenital dysfibrinogenemia with the amino acid substitution A alpha 554 arginine to cysteine, were investigated by a variety of electron microscope studies. Polymerization of this mutant fibrinogen on addition of thrombin is impaired, producing clots with decreased porosity and increased resistance to fibrinolysis, resulting in thrombotic complications in the family members with this dysfibrinogenemia. Electron microscopy of rotary-shadowed individual molecules revealed that, in contrast to control fibrinogen, most of the alpha C domains of fibrinogen or fibrin Dusart appeared to be free-swimming appendages that do not exhibit intra- or intermolecular interactions either with each other or with the central domains. The location of albumin on the alpha C domains was demonstrated by electron microscopy using anti-albumin antibodies. Electron microscopy of negatively contrasted fibrin Dusart fibers indicated that they were less ordered than control fibers and had additional mass visible. Electron microscopy of freeze-dried, unidirectionally shadowed fibers showed that they were twisted with a shorter pitch. Scanning electron microscopy revealed that intact clots were made up of thin fibers with many branch points and very small pore sizes. The viscoelastic properties of Dusart fibrin clots measured with a torsion pendulum indicated a marked increase in stiffness consistent with the structural observations.     

Mechanism of functioning of specific sites of interdomain D-E binding of fibrin molecules: interaction of fibrinogen with the N-terminal disulfide node of fibrin

The intermolecular noncovalent binding of complementary fibrin polymerization sites localized in fibrin domains D and E was investigated in the model system. In this system fibrinogen molecules represent the active D domains and the N-terminal disulphide knot of fibrin (N-DSK) represents the active E domain. Quantitative definition of insoluble fibrinogen and N-DSK copolymer and light scattering data of their mixtures before the appearance of visible precipitate show that complexing of these structures decreases with an increase of the temperature and ionic strength. The character of this dependence permits certain conclusions to be made on the functioning mechanism for two types of the D-E binding sites. These conclusions are based on an idea of their different affinity. The interdomain binding is primarily realized by D1-E1 sites which are characterized by a high affinity and work mainly on the basis of electrostatic forces. This binding directs the D2-E2 binding which is characterized by lower affinity and which determines the final degree of fibrinogen and N-DSK complexing. These sites function mainly by the H-binding.     

On the mechanism of αC polymer formation in fibrin

Our previous studies revealed that the fibrinogen αC-domains undergo conformational changes and adopt a physiologically active conformation upon their self-association into αC polymers in fibrin. In the present study, we analyzed the mechanism of αC polymer formation and tested our hypothesis that self-association of the αC-domains occurs through the interaction between their N-terminal subdomains and may include β-hairpin swapping. Our binding experiments performed by size-exclusion chromatography and optical trap-based force spectroscopy revealed that the αC-domains self-associate exclusively through their N-terminal subdomains, while their C-terminal subdomains were found to interact with the αC-connectors that tether the αC-domains to the bulk of the molecule. This interaction should reinforce the structure of αC polymers and provide the proper orientation of their reactive residues for efficient cross-linking by factor XIIIa. Molecular modeling of self-association of the N-terminal subdomains confirmed that the hypothesized β-hairpin swapping does not impose any steric hindrance. To "freeze" the conformation of the N-terminal subdomain and prevent the hypothesized β-hairpin swapping, we introduced by site-directed mutagenesis an extra disulfide bond between two β-hairpins of the bovine Aα406-483 fragment corresponding to this subdomain. The experiments performed by circular dichroism revealed that Aα406-483 mutant containing Lys429Cys/Thr463Cys mutations preserved its β-sheet structure. However, in contrast to wild-type Aα406-483, this mutant had lower tendency for oligomerization, and its structure was not stabilized upon oligomerization, in agreement with the above hypothesis. On the basis of the results obtained and our previous findings, we propose a model of fibrin αC polymer structure and molecular mechanism of assembly.     

可溶性血纤蛋白促进细胞伸展及其作用机制

可溶性血纤蛋白（ｓｏｌｕｂｌｅｆｉｂｒｉｎ,ＳＦ）为血纤蛋白单体和血纤蛋白原１∶２的复合物．现已知在血液凝固系统被激活的病理状态下,存在于循环血液中,然而它的生理作用仍然不明．首次发现细胞能在固定的ＳＦ上伸展,并能被外源性ＳＦ及精氨酸－甘氨酸－天冬氨酸（ＲＧＤ）合成肽所抑制,但不能被血纤蛋白原和血纤蛋白单体所抑制,提示ＳＦ形成后其结构变化是引起细胞伸展的关键．片段Ｘ（缺乏ＲＧＤ２序列的血纤蛋白原片段）与血纤蛋白单体形成的复合物,使细胞伸展活性明显减低,提示在ＳＦ结构中,血纤蛋白原的ＲＧＤ２序列在细胞伸展中起重要作用．同时发现ＤＩＣ患者血浆中的ＳＦ也具有细胞伸展活性．ＳＦ作为一个粘附分子在体内血栓形成过程中起重要调节作用     

Structural transformations of fibrin oligomers

The morphology of equilibrium of soluble fibrin oligomers at different stages of assembly was studied. Results of Rauleigh's light scattering, analytical ultracentrifugation and viscosimetry show that fibrin-polymers throughout the entire homology range present rigid, rod-like structures dispersed by weight and dimensions. It was shown, that along with the traditional double-stranded chain protofibrills, where the monomer molecules are connected "end-to-center", there is an alternative variant, which is a result of single-stranded chain dimerization, where the monomers are formed up in an "end-to-end" fashion. Identity of physicochemical features of fibrin oligomers obtained by means of different enzyme activation of fibrinogen indicates that E1 and E2 sites interact with the complementary D1 and D2 sites only at the stage of protofibrill formation. It is suggested that the lateral aggregation is initiated by other sites that exist in fibrinogen and fibrin-monomer molecules in an accessible state. Thermodynamic reasons for the cooperative ability of protofibrill aggregation processes and gel-formation are discussed.     

Substitution of the human αC region with the analogous chicken domain generates a fibrinogen with severely impaired lateral aggregation: fibrin monomers assemble into protofibrils but protofibrils do not assemble into fibers

Fibrin polymerization occurs in two steps: the assembly of fibrin monomers into protofibrils and the lateral aggregation of protofibrils into fibers. Here we describe a novel fibrinogen that apparently impairs only lateral aggregation. This variant is a hybrid, where the human αC region has been replaced with the homologous chicken region. Several experiments indicate this hybrid human-chicken (HC) fibrinogen has an overall structure similar to normal. Thrombin-catalyzed fibrinopeptide release from HC fibrinogen was normal. Plasmin digests of HC fibrinogen produced fragments that were similar to normal D and E; further, as with normal fibrinogen, the knob 'A' peptide, GPRP, reversed the plasmin cleavage associated with addition of EDTA. Dynamic light scattering and turbidity studies with HC fibrinogen showed polymerization was not normal. Whereas early small increases in hydrodynamic radius and absorbance paralleled the increases seen during the assembly of normal protofibrils, HC fibrinogen showed no dramatic increase in scattering as observed with normal lateral aggregation. To determine whether HC and normal fibrinogen could form a copolymer, we examined mixtures of these. Polymerization of normal fibrinogen was markedly changed by HC fibrinogen, as expected for mixed polymers. When the mixture contained 0.45 μM normal and 0.15 μM HC fibrinogen, the initiation of lateral aggregation was delayed and the final fiber size was reduced relative to normal fibrinogen at 0.45 μM. Considered altogether, our data suggest that HC fibrin monomers can assemble into protofibrils or protofibril-like structures, but these either cannot assemble into fibers or assemble into very thin fibers.     

Plasminogen-binding centers of molecules of fibrinogen, fibrin and products of their proteolysis

Using affinity chromatography, the binding of Lys-plasminogen to fibrinogen, fibrin and the consecutively formed products of their proteolysis was studied. The optimal conditions for this binding were elaborated, and the quantitative parameters of Lys-plasminogen binding to fibrinogen-Sepharose were determined. It was found that the interaction of Lys-plasminogen with fibrinogen- and fibrin-Sepharose is provided for by the lysine-binding sites of the proenzyme molecule. After partial hydrolysis of fibrinogen by plasmin, the amount of adsorbed plasminogen increases and the type of binding changes; part of the proenzyme molecules bind in the presence of 0.003 M 6-aminohexanoic acid, i.e., when lysine-binding sites appear to be blocked. A comparative study of plasminogen binding to fibrinogen fragments was carried out. The resistance of the complexes formed to the effect of 6-aminohexanoic acid and arginine competing for the binding sites was determined. The data obtained testify to the appearance of additional plasminogen-binding sites in the fibrinogen molecule during proteolysis. These sites are complementary for both lysine-and arginine-binding sites of the plasminogen molecule and are localized in the peripheral domains of the fibrinogen molecule.