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.     

The role of complementary E2 and D2 centers in the reaction between fibrin and fibrinogen

The effect of fibrinogen on the two steps of polymerization of two fibrin forms differing in the set of polymerization sites (fibrin-desAA and fibrin-desAABB) was studied. It was shown that fibrinogen inhibited the protofibril growth and fibril formation at the stage of lateral aggregation more effectively with fibrin-desAABB than with fibrin desAA. When the fibrinogen D2-site was blocked by tetrapeptide Gly-His-Arg-Pro, the key structure of the E2-site, the inhibitory activity of fibrinogen diminished. A conclusion is drawn that the high susceptibility of fibrin-desAABB to fibrinogen is due to the interaction of the E2-active site with the D2-site of the fibrinogen molecule. The concentration dependence of the tetrapeptide Gly-His-Arg-Pro-induced inactivation of fibrinogen and the effects of temperature and Ca2+ on the tetrapeptide interaction with fibrinogen were investigated.     

Interaction of fibrinogen and fibrin with protamine sulfate

Fibrinogen and fibrin sedimentation by different protamine sulphate preparations have been studied. Ionic strength and protamine sulphate concentration are found to influence the sedimentation reaction (paracoagulation). High sedimentation activity is inherent in protamine sulphate preparations with the lower electrophoretic mobility, that is with the higher molecular weight. The protamine sulphate reaction with fibrinogen and fibrin is of electrostatic character as the long polycationic chain of protamine is coupled with the negatively charged loci either of fibrin or of fibrinogen molecules, thus evoking aggregation. In this case the fibrin molecules being brought together favour the specific mutual binding due to the active sites of polymerization, specific fibres or gel being formed.     

Interaction of fibrinogen and its derivatives with fibrin

The binding between complementary polymerization sites of fibrin monomers plays an essential role in the formation of the fibrin clot. One set of polymerization sites involved in the interaction of fibrin monomers is believed to pre-exist in fibrinogen, while the complementary set of binding sites is exposed after the cleavage of fibrinopeptides from fibrinogen. The polymerization sites present in fibrinogen and its derivatives mediate their binding to fibrin. Although the binding of fibrinogen and its derivatives to fibrin have been qualitatively studied, there has been no systematic, quantitative investigation of their interaction with forming or preformed clots. In the present study, the binding of fibrinogen and fragments DD, D1, and E1 was measured using a sonicated suspension of plasminogen- and thrombin-free human cross-linked fibrin as a model of a preformed clot. Dissociation constants of 0.056, 0.19, and 2.44 microM, and the number of binding sites corresponding to 0.10, 0.21, and 0.13/fibrin monomer unit of fibrin polymer were found for fibrinogen, fragment DD, and fragment D1, respectively. Fragment E1 did not bind to sonicated noncross-linked or cross-linked fibrin suspensions. However, it was bound to forming fibrin clots as well as to fibrin-Celite, suggesting that the binding sites on fibrin involved in the interaction with fragment E1 may have been altered upon sonication. Affinity chromatography of various fibrinogen derivatives on a fibrin-Celite column showed that only part of the bound fragment DD was displaced by arginine, whereas fragments D1 and E1 were completely eluted under the same conditions. The results indicate that interaction of fibrinogen with the preformed fibrin clots is characterized by affinity in the nanomolar range and that binding between fibrin monomers, in the process of clot formation, could be characterized by even a higher affinity.     

Evidence that catalytically-inactivated thrombin forms non-covalently linked dimers that bridge between fibrin/fibrinogen fibers and enhance fibrin polymerization

Phe-pro-arg-chloromethyl ketone-inhibited alpha-thrombin [FPR alpha-thr] retains its fibrinogen recognition site (exosite 1), augments fibrin/fibrinogen [fibrin(ogen)] polymerization, and increases the incorporation of fibrin into clots. There are two 'low-affinity' thrombin-binding sites in each central E domain of fibrin, plus a non-substrate 'high affinity' gamma' chain thrombin-binding site on heterodimeric 'fibrin(ogen) 2' molecules (gamma(A), gamma'). 'Fibrin(ogen) 1' (gamma(A), gamma(A)) containing only low-affinity thrombin-binding sites, showed concentration-dependent FPR alpha-thr enhancement of polymerization, thus indicating that low-affinity sites are sufficient for enhancing polymerization. FPR gamma-thr, whose exosite 1 is non-functional, did not enhance polymerization of either fibrin(ogen)s 1 or 2 and DNA aptamer HD-1, which binds specifically to exosite 1, blocked FPR alpha-thr enhanced polymerization of both types of fibrin(ogen) (1>2). These results showed that exosite 1 is the critical element in thrombin that mediates enhanced fibrin polymerization. Des B beta 1-42 fibrin(ogen) 1, containing defective 'low-affinity' binding sites, was subdued in its FPR alpha-thr-mediated reactivity, whereas des B beta 1-42 fibrin(ogen) 2 (gamma(A), gamma') was more reactive. Thus, the gamma' chain thrombin-binding site contributes to enhanced FPR alpha-thr mediated polymerization and acts through a site on thrombin that is different from exosite 1, possibly exosite 2. Overall, the results suggest that during fibrin clot formation, catalytically-inactivated FPR alpha-thr molecules form non-covalently linked thrombin dimers, which serve to enhance fibrin polymerization by bridging between fibrin(ogen) molecules, mainly through their low affinity sites.     

纤维蛋白单体D区与E区聚合后E区结构的变化

应用纤维蛋白单克隆抗体IF 5 3,观察当纤维蛋白的“A”位点与另一纤维蛋白D区域的“a”位点结合后纤维蛋白E区的变化 .纤维蛋白原Aα链经赖氨酰肽链内切酶消化后 ,应用反相HPLC分离纯化 ;通过ELISA法检测单克隆抗体IF 5 3与纤维蛋白原及其衍生物的反应情况 ;应用放射免疫法检测RGD合成肽抑制纤维蛋白单体与IF 5 3反应的情况 .发现IF 5 3能与纤维蛋白原Aα链的一个片段反应 ,该片段经氨基酸序列分析显示为纤维蛋白原Aα链氨基末端 (1～ 2 9) .该抗体能与酸溶解的纤维蛋白单体和可溶性纤维蛋白及XDP反应 ,但不能与酸化纤维蛋白原或GPRP反应 ,因此IF 5 3的抗原决定簇在Aα 2 0～ 2 9,与凝血酶作用于纤维蛋白肽A ,暴露出的聚合位点“A”(Aα17～19)紧邻 .当GPRP存在于纤维蛋白原溶液时 ,经凝血酶作用产生这种纤维蛋白单体不能与IF 5 3反应 .Aα(93～ 99) (ILRGDFS)合成肽部分抑制纤维蛋白单体与IF 5 3的反应 .实验结果提示 ,当纤维蛋白单体相互聚合 ,或纤维蛋白单体与纤维蛋白原聚合时 ,纤维蛋白单体结构会发生变化 ,其中Aα2 0～ 2 9片段成为新抗原暴露于E区表面 ,并且Aα2 0～ 2 9与纤维蛋白原细胞粘附区域RGD1片段邻近     

A re-examination of the cleavage of fibrinogen and fibrin by plasmin.

Three Fragment D species (D1, D2, D3) were isolated with time from a plasmin digest of fibrinogen and had molecular weights of 92,999, 86,000 and 82,000 by summation of subunit molecular weights from sodium dodecyl sulfate polyacrylamide gel electrophoresis. Their molecular weights by sedimentation equilibrium ultracentrifugation were 94,000 t87,000, 88,000 to 82, 000, and 76,000 to 70,000 depending on the values calculated for the partial specific volumes. Each of the Fragment D species contained three disulfide-linked subunits derived from the Aalpha, Bbeta, and gamma chains of fibrinogen and differed only in the extent of COOH-terminal degradation of their gamma chain derivatives. Plasmin cleaved Fragment D1 to release the cross-link sites from its gamma' subunit of 38,000 molecular weight; however, the beta' subunit of 42,000 molecular weight and the alpha' subunit of 12,000 molecular weight were resistant to further digestion by plasmin. Fragment D isolated from highly cross-linked fibrin had a dimeric structure due to cross-link formation between the gamma' subunits of two fibrinogen Fragment D species. The molecular weight of fibrin Fragment D was 184,000 by summation of subunit molecular weights and 190,000 to 175,000 by sedimentation equilibrium. Cross-linking the gamma chain, as well as incorporating the site-specific fluorescent label monodansyl cadaverine into the gamma chain cross-link acceptor site, prevented its COOH-terminal degradation by plasmin. Therefore, only one species of fibrin Fragment D, as well as only one species of monodansyl cadaverine-labeled fibrin Fragment D monomer, was generated during plasmin digestion. These results show unequivocally that each fibrinogen Fragment D contains only three subunit chains and therefore the digestion of fibrinogen by plasmin must result in the production of two Fragment D molecules from each fibrinogen molecule. The recently proposed model of fibrinogen cleavage that postulates the generation of a single Fragment D with three pairs of subunit chains from each fibrinogen molecule is incorrect. Incorporation of monodansyl cadaverine into the cross-link acceptor sites of the alpha chain did not alter its cleavage by plasmin detectably. A series of monodansyl cadaverine-labeled peptides, which ranged in molecular weight from 40,000 to 23,000, were cleaved from the alpha chain of monodansyl cadaverine-labeled fibrin monomer during the early stages of plasmin digestion. These peptides were degraded progressively to a brightly fluorescent plasmin-resistant peptide of 21,000 molecular weight and a weakly fluorescent peptide of 2,500 molecular weight. Thus both alpha chain cross-link acceptor sites are contained within a peptide segment of 23,000 molecular weight.     

Position of gamma-chain carboxy-terminal regions in fibrinogen/fibrin cross-linking mixtures

There are conflicting ideas regarding the location of the carboxyl-terminal regions of cross-linked gamma-chain dimers in double-stranded fibrin fibrils. Some investigators believe that the chains are always oriented longitudinally along each fibril strand and traverse the contacting ends of abutting fibrin D domains ("DD-long" cross-linking). Other investigations have indicated instead that the chains are situated transversely between adjacent D domains in opposing fibril strands (transverse cross-linking). To distinguish between these two possibilities, the gamma dimer composition of factor XIIIa-cross-linked fibrin/fibrinogen complexes that had been formed through noncovalent D/E interactions between fibrinogen D domains and fibrin E domains was examined. Two factor XIIIa-mediated cross-linking conditions were employed. In the first, fibrin/fibrinogen complexes were formed between (125)I-labeled fibrinogen 2 ("peak 2" fibrinogen), each heterodimeric molecule containing one gamma(A) and one larger gamma' chain, and nonlabeled fibrin 1 molecules ("peak 1" fibrin), each containing two gamma(A) chains. If DD-long cross-linking occurred, (125)I-labeled gamma(A)-gamma(A), gamma(A)-gamma', and gamma'-gamma'dimers in a 1:2:1 ratio would result. Transverse cross-linking would yield a 1:1 mixture of (125)I-labeled gamma(A)-gamma(A) and gamma(A)-gamma' dimers, without any gamma'-gamma' dimers. Autoradiographic analyses of reduced SDS-PAGE gels from protocol 1 revealed (125)I-labeled gamma(A)-gamma(A) and gamma(A)-gamma' dimers at a ratio of approximately 1:1. No labeled gamma'-gamma' dimers were detected. Protocol 2 used a converse mixture, (125)I-fibrin 2 and nonlabeled fibrinogen 1. DD-long cross-linking of this mixture would yield only nonradioactive gamma(A)-gamma(A) dimers, whereas transverse cross-linking would yield a 1:1 mixture of (125)I-labeled gamma(A)-gamma(A) and gamma(A)-gamma' dimers. Autoradiographic analyses of this mixture yielded (125)I-labeled gamma(A)-gamma(A) and gamma(A)-gamma' dimers in a 1:1 ratio. These findings provide no evidence that longitudinal (DD-long) gamma chain positioning occurs in cross-linked fibrin and indicate instead that most, if not all, gamma-chain positioning in an assembled fibrin polymer is transverse.     

Characteristics of D-domain-containing specific inhibitors of polymerization on the fibrin self-assembly process

The inhibitory effect of D- and DD-fragments and their mixture on plasma blood coagulation process under the action of thrombin has been studied. The significant increase of total efficiency of the inhibitory action has been shown. The inhibitors have influence on a lag-phase and lateral association of protofibrills of fibrin polymerization carried out by turbidimetry method in the model systems in vitro. The concentration of fragments which are close to parameters of fibrinogen/fibrin degradation products in pathological conditions was used. It is shown, that the covalent cross-link of D-dimer gamma-gamma-chains affects the inhibitory features and mechanism of interaction with fibrin monomer molecules. D-fragments inhibit the both phases of polymerization, whereas DD-fragments effectively inhibit the lateral association of protofibrill.     

Sites of D-domain interaction in fibrin-derived D dimer

We have examined the plasmic digestion products of fibrin formed in the presence of dansylcadaverine, the fluorescent D dimer, to determine whether they are held together not only by the cross-link region on the gamma chain but also by other interactions on the D domain. Antibodies to the D dimer reacted 8X more strongly with sites on the D dimer (purified or in the presence of E) than with sites on fibrinogen or plasmin-digested fibrinogen. The reactivity of this surface site was lost when the gamma chain was cleaved by plasmin after the molecule had been destabilized by the removal of calcium ions, thus breaking the covalent linkage of the homodimer. The noncovalent D dimer retained its dimeric structure by the criteria of molar volume, measured by fluorescence polarization, and molecular sieving. The noncovalently attached, cross-link-containing peptide bound tightly to the parent molecules at higher temperatures but rotated more freely below 15 degrees C, and could be lost from the parent molecules without destroying the dimeric structure. We therefore propose that the forces maintaining the dimeric structure of the noncovalently joined molecule are not solely located at the gamma-chain cross-link region. These other sites on the D domain are therefore candidates for the initial fibrinogen polymerization site and may also have a role in fibrinogen half-molecule assembly.     

Characterization of the inhibition of fibrin assembly by fibrinogen fragment D.

Fragment D (Mr 100 000) prepared from a terminal plasmin digest of fibrinogen was isolated and used to study its effect on fibrin formation. Increasing amounts of fragment D added to a solution of fibrinogen and thrombin decrease the rigidity of the resultant gel (10% of control at 2 mol of fragment D/mol of fibrinogen). Half-maximal inhibition is achieved at 1 mol of fragment D/mol of fibrinogen for non-cross-linked clots and at 1/2 mol of fragment D/mol of fibrinogen for cross-linked clots. "Clottability' decreases concomitantly with the rigidity. Only small amounts of fragment D (less than 10% for non-cross-linked gels) are incorporated into the gel. Light-scattering shows an increase in the final fibre thickness at fragment D concentrations up to 2 mol of fragment D/mol of fibrinogen, from 60 molecules/cross-section for the control to 120 molecules/cross-section. Higher fragment D concentrations lead to a decrease in the final fibre thickness. The limit fibre thickness is 8 nm, with a length of 80 nm, which is equivalent to a fibrin trimer. On the basis of results of synthetic-substrate and fibrinopeptide-release assays, it is clear that thrombin inactivation is not responsible for this effect. These data suggest that fragment D may inhibit fibrin formation by blocking the bimolecular polymerization of activated fibrin monomer molecules to form protofibrils, although additional effects on subsequent assembly steps may also be involved.     

Effect of peptides--structural analogs of NH2-terminal sites of fibrin alpha- and beta-chains--on specific binding of the NH2-terminal disulfide bond of fibrin with fibrinogen

Peptides Gly-Pro-Arg-Pro and Gly-His-Arg-Pro (fibrin alpha- and beta-chain NH2-terminal analogs, respectively) are studied for their effect on fibrinogen (F) and fibrin NH2-terminal disulphide knot (N-DSK) specific binding. Both peptides are found to inhibit the formation of soluble and insoluble F-N-DSK-complexes through inhibition of the interdomain D-E-binding. Gly-Pro-Arg-Pro is much more potent inhibitor than Gly-His-Arg-Pro. Lowering the insoluble F-N-DSK-copolymer quantity by concentration-dependent way these peptides do not change its composition described by the formula [F(N-DSK)2]n. Invariability of fibrinogen and N-DSK copolymer structure is asserted. In this structure neighbouring fibrinogen molecules are bound by two N-DSK molecules via the D1-E1 and D2-E2 binding sites.     

Interaction of heavy and light chains of plasmin with fibrinogen E and D fragments

It was demonstrated that plasminogen and the plasmin heavy chain form a complex with an immobilized fibrinogen fragment E. The E-fragment interacts, in its turn, with the immobilized heavy chain; this interaction is provided for by the lysin binding sites of the plasminogen molecule. The plasmin light chain having no lysin binding sites is specifically absorbed on the immobilized fragment D, whereas the D-fragment--on the immobilized light chain. The elution is caused by arginine or benzamidine; 6-aminohexanoic acid does not affect this interaction. It is assumed that the interaction of plasminogen and plasmin with fibrin is provided for not only by the lysine binding but also by the benzamidine binding sites of the plasminogen molecule.     

Fibrinogen beta-chain tyrosine nitration is a prothrombotic risk factor

Elevated levels of circulating fibrinogen are associated with an increased risk of atherothrombotic diseases although a causative correlation between high levels of fibrinogen and cardiovascular complications has not been established. We hypothesized that a potential mechanism for an increased prothrombotic state is the post-translational modification of fibrinogen by tyrosine nitration. Mass spectrometry identified tyrosine residues 292 and 422 at the carboxyl terminus of the beta-chain as the principal sites of fibrinogen nitration in vivo. Immunoelectron microscopy confirmed the incorporation of nitrated fibrinogen molecules in fibrin fibers. The nitration of fibrinogen in vivo resulted in four distinct functional consequences: increased initial velocity of fibrin clot formation, altered fibrin clot architecture, increased fibrin clot stiffness, and reduced rate of clot lysis. The rate of fibrin clot formation and clot architecture was restored upon depletion of the tyrosine-nitrated fibrinogen molecules. An enhanced response to the knob "B" mimetic peptides Gly-His-Arg-Pro(am) and Ala-His-Arg-Pro(am) suggests that incorporation of nitrated fibrinogen molecules accelerates fibrin lateral aggregation. The data provide a novel biochemical risk factor that could explain epidemiological associations of oxidative stress and inflammation with thrombotic complications.     

Localization of a fibrin polymerization site

The formation of a fibrin clot is initiated after the proteolytic cleavage of fibrinogen by thrombin. The enzyme removes fibrinopeptides A and B and generates fibrin monomer which spontaneously polymerizes. Polymerization appears to occur though the interaction of complementary binding sites on the NH2-terminal and COOH-terminal (Fragment D) regions of the molecule. A peptide has been isolated from the gamma chain remnant of fibrinogen Fragment D1 which has the ability to bind to the NH2-terminal region of fibrinogen as well as to inhibit fibrin monomer polymerization. The peptide reduces the maximum rate and extent of the polymerization of thrombin or batroxobin fibrin monomer and increases the lag time. The D1 peptide does not interact with disulfide knot, fibrinogen, or Fragment D1, but it binds to thrombin-treated disulfide knot with a Kd of 1.45 X 10(-6) M at approximately two binding sites per molecule of disulfide knot. Fibrin monomer formed either by thrombin or batroxobin binds approximately two molecules of D1 peptide per molecule of fibrin monomer, indicating that the complementary site is revealed by the loss of fibrinopeptide A. The NH2-terminal sequence (Thr-Arg-Trp) and COOH-terminal sequence (Ala-Gly-Asp-Val) of the D1 peptide were determined. Therefore the gamma 373-410 region of fibrinogen contains a polymerization site which is complementary to the thrombin-activated site on the NH2-terminal region of fibrinogen.     

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.     

Interactions mediated by the N-terminus of fibrinogen's Bbeta chain

Specific molecular interactions mediated by the N-terminus of fibrinogen's Bbeta chain were revealed using laser tweezers-based force spectroscopy. We examined interactions between fibrinogen fragments representing the center of the molecule, NDSK, desA-NDSK, and desAB-NDSK, and two recombinant fibrinogens, gammaD364H and gammaD364A, which have nonfunctional gamma-chain polymerization sites to prevent the dominant knob-hole binding. Interactions between desA-NDSK, where the N-terminus of the Bbeta chain is present, and the fibrinogen variants showed a complex spectrum of rupture forces which disappeared with desAB-NDSK, lacking both FpA and FpB. The interactions between desA-NDSK and gammaD364H or gammaD364A were inhibited by addition of soluble FpB, but not FpA or the polymerization inhibitor peptides GPRP and GHRP. When gammaD364H fibrinogen was replaced with its X-fragment lacking alphaC- domains or with fragment D, the strongest component of the rupture force spectrum disappeared, suggesting interactions between the uncleaved FpB and the alphaC-domain. Electron microscopy confirmed the binding of desA-NDSK to either D or E regions of fibrinogen as well as to alphaC-domains. The data demonstrate the existence of weak transient interactions within and between fibrin molecules mediated by the N-terminus of the fibrinogen Bbeta chain.     

Department of Protein Structure and Function--Volodimir Oleksandrovich Bielitser School of the Ukrainian Academy of Sciences. Studies on structure of fibrin fiber structure and mechanism (1975-1987

In this short historical review the records about foundation and research activity of the Department of Structure and Function of Protein--school of V. A. Belitser, Member of the National Academy of Sciences of Ukraine are presented. V. A. Belitser was the founder and indispensable chief of the department since the date of its creation (1944) till 1987. The main research interests (1975-1987) of the department were focused at the investigation of structure, biological function of the fibrinogen-fibrin system, mechanisms of the network assembly and of the fibrin fibers structure. Studying the molecular mechanisms of the fibrin fiber assembly, it was shown that the specificity of the building structure was shown is determined by the specific reactive sites with strong affinity of the molecules. The activity of the sites was investigated on protein molecules as well as the fragments. The physical nature of the bonds created by the active sites, that appearing during in the process of fibrinogen activation by thrombin, was revealed. Examination of the fibrin assembly in cooperation with electronmicroscopists and studies of the complex formation between active fragments and fibrin monomer were summarized. Both the fibrin monomer polymerization and protofibril lateral association are presented as two stages in the assembly of the fibrin network. In the research of the domain fibrinogen structure the specific sites of the fibrin assembly in each of the domains were found. COOH-terminal regions of the A alpha-chains play independent part in the fibrinogen and fibrin. That is why it is relevant to consider them as alpha C-domains. In the free fibrinogen molecules (in solution) these domains are responsible for globular shape, they are linked to domains D intramolecularly. When fibrin assembly takes place, alpha C-domains play significant carriage role in fibrin molecules interaction, linking to domains D intermolecularly. The model of the fibrinogen molecule structure and the general scheme of the fibrin fibers network formation were proposed. Physico-chemical basics of a biological structure assembly were elucidated using the process of the fibrin self-assembly as an example. Much attention was devoted to the problems of practical medicine. The quantitative methods of fibrinogen, soluble fibrin and active fibrin/fibrinogen fragments estimation in blood plasma were developed.     

Interaction of an analog of the E1 site of tetrapeptide Gly-Pro-Arg-Pro with the D1 site of two forms of monomeric fibrin

Two monomeric fibrin forms differing in a set of polymerization sites (fibrin desAA and fibrin-desAABB) are inhibited to a different extent by tetrapeptide Gly-Pro-Arg-Pro which simulates a moiety of polymerization site E1. The lesser sensitivity of fibrin-desAABB polymerization to the inhibiting tetrapeptide is due to the presence of active site E2 in it. A shape of the concentration dependence curve of the inhibitory effect of tetrapeptide Gly-Pro-Arg-Pro on the polymerization of both fibrin types is similar to the previously found curve for fibrinogen and its fragments--specific inhibitors of polymerization. Ca2+ intensifies inhibition of fibrin-desAABB polymerization by tetrapeptide Gly-Pro-Arg-Pro twice as much as that of fibrin-desAA evidently due to the peptide blockage of sites D2. An increase of the ionic strength from 0.15 to 0.3 enhances the inhibitory effect of the tetrapeptide on polymerization of two monomeric fibrin forms.