A model for fibrinogen: domains and sequence

Comparative structural and functional features of the human fibrinogen alpha C domain and the isolated alpha C fragment. Characterization using monoclonal antibodies to defined COOH-terminal A alpha chain regions

The alpha C domain of fibrinogen (A alpha-(220-610)) plays a central role in maintaining hemostasis by serving as a substrate for factor XIIIa and plasmin. Monoclonal antibodies that recognize eight distinct epitopes within the COOH-terminal two-thirds of the A alpha chain were employed as structural probes to: 1) isolate the human alpha C domain, 2) compare the topography of the eight epitopes within the alpha C domain of intact fibrinogen and in purified alpha C fragments, and 3) explore the degree to which the alpha C domain's role as a factor XIIIa substrate in intact fibrinogen is preserved within the structure of isolated alpha C fragments. Five antibodies were raised against small, synthetic peptide immunogens (A alpha-(220-230), A alpha-(425-442), A alpha-(487-498), and A alpha-(603-610)), and three were generated against larger cyanogen bromide (A) alpha chain derivatives with each epitope subsequently localized to discrete A alpha chain sequences (A alpha-(259-276), A alpha-(529-539), and A alpha-(563-578)). Human alpha C preparations were isolated from mild plasmin digests of fibrinogen by successive chromatography on concanavalin A-Sepharose, anti-A alpha-(425-442)-Sepharose, and Superdex-75 fast protein liquid chromatography. Immunochemical characterization indicated that the NH2-terminal residue of alpha C fragments was either A alpha-220 or A alpha-231 and that, although the extreme COOH-terminal region, A alpha-(603-610), was absent, all molecules were intact at least through A alpha-(563-578). Solution phase competitive assays indicated that the release of the alpha C domain from intact fibrinogen was associated with several conformational changes, e.g. in the vicinity of A alpha-(220-230), A alpha-(259-276), A alpha-(487-498), and A alpha-(529-539), but that the relative accessibility of other localized structures remained unchanged, e.g. A alpha-(425-442) and A alpha-(563-578). Immunoblotting analysis of alpha C cross-linking in vitro revealed that isolated alpha C fragments could serve as a substrate for factor XIIIa. Immunoblotting studies of the A alpha chain proteolysis that occurs during thrombolytic therapy indicated that alpha C fragments, similar in size and epitope content to those isolated from purified fibrinogen, were released in vivo early during fibrinolytic system activation. The collective findings provide new information about the fine structure of the fibrinogen alpha C domain and its functional implications and also draw attention to the as yet unexplored role of alpha C fragments in the pathophysiology of thrombosis and hemostasis.

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.

Secretion of biologically active recombinant fibrinogen by yeast

Fibrinogen (340 kDa) is a plasma protein that plays an important role in the final stages of blood clotting. Human fibrinogen is a dimer with each half-molecule composed of three different polypeptides (A alpha, 67 kDa; B beta, 57 kDa; gamma, 47 kDa). To understand the mechanism of fibrinogen chain assembly and secretion and to obtain a system capable of producing substantial amounts of fibrinogen for structure-function studies, we developed a recombinant system capable of secreting fibrinogen. An expression vector (pYES2) was constructed with individual fibrinogen chain cDNAs under the control of a Gal-1 promoter fused with mating factor F alpha 1 prepro secretion signal (SS) cascade. In addition, other constructs were prepared with combinations of cDNAs encoding two chains or all three chains in tandem. Each chain was under the control of the Gal-1 promoter. These constructs were used to transform Saccharomyces cerevisiae (INVSC1; Mat alpha his3-delta 1 leu2 trp1-289 ura3-52) in selective media. Single colonies from transformed yeast cells were grown in synthetic media with 4% raffinose to a density of 1 x 10(8) cells/ml and induced with 2% galactose for 16 h. Yeast cells expressing all three chains contained fibrinogen precursors and nascent fibrinogen and secreted about 30 micrograms/ml of fibrinogen into the culture medium. The B beta and gamma chains, but not A alpha, were glycosylated. Glycosylation of B beta and gamma chains was inhibited by treatment of transformed yeast cells with tunicamycin. Intracellular B beta and gamma chains, but not the A alpha chains in secreted fibrinogen, were cleaved by endoglycosidase H. Carbohydrate analysis indicated that secreted recombinant fibrinogen contained N-linked asialo-galactosylated biantennary oligosaccharide. Recombinant fibrinogen yielded the characteristic plasmin digestion products, fragments D and E, that were immunologically indistinct from the same fragments obtained from plasma fibrinogen. The recombinant fibrinogen was shown to be biologically active in that it could form a thrombin-induced clot, which, in the presence of factor XIIIa, could undergo gamma chain dimerization and A alpha chain polymer formation.

Characterization of the binding of factor Xa to fibrinogen/fibrin derivatives and localization of the factor Xa binding site on fibrinogen

The binding of human factor Xa to fibrinogen and its derivatives was characterized. Factor Xa bound to immobilized fibrin with a concentration at half-maximal binding (C50) of 100 nM. The 4-carboxyglutamic acid (Gla) domain of factor Xa is important in factor Xa binding to fibrin monomer, based on the following observations; the binding requires Ca2+; Gla-domain-lacking factor Xa could not bind to fibrin; factor Xa binding was significantly reduced by prior treatment of factor Xa with factor IX/factor-X-binding protein from the venom of Trimeresurus flavoviridis which specifically binds to the Gla domain of human factors IX and X. Factor Xa also bound to fibrinogen, fibrinogen degradation products (FDP)-D and FDP-E, with a similar affinity (C50 = 75-131 nM). In a solution-phase equilibrated binding assay, approximately 0.76 mol factor Xa bound to 1 mol fibrinogen with a dissociation constant of 180 nM. The binding of 125I-labeled factor Xa to the fibrin monomer was inhibited markedly by unlabeled factor Xa, but only slightly by thrombin, suggesting that the binding site of factor Xa on fibrin monomer differs from that of thrombin. We localized the binding site of factor Xa on fibrinogen: factor Xa bound strongly to the A alpha chain, but weakly to the B beta and gamma chains of fibrinogen. The A alpha chain was then digested with lysyl endopeptidase and separated by reverse-phase HPLC. Among resulting peptides, factor Xa bound specifically to a peptide corresponding to residues Asp82-Lys123 of the A alpha chain. This factor-Xa-binding site is located in the boundary between the central E domain and the terminal D domain of fibrinogen and is apparently distinct from the reported thrombin-binding site.

Structural and functional characterization of proteolytic fragments derived from the C-terminal regions of bovine fibrinogen

A number of new as well as previously described fragments derived from the D region of bovine fibrinogen by limited proteolysis have been characterized by sequence analysis, differential scanning calorimetry and circular dichroism. Determination of the extremities of the polypeptide chains forming individual fragments allowed the scheme of proteolysis and the borders between domains in the D region of fibrinogen to be established. It was also found that the most thermostable region of the D fragment (TSD) can be substantially reduced in size without loss of its compact structure. The alpha-helical content of the newly prepared 21-kDa TSD2 and 16-kDa TSD3 fragments were 82% and 75%, respectively, strongly supporting a coiled-coil structure for this region of the fibrinogen molecule. The DX and DZ fragments, prepared from a chymotryptic digest of the DLA fragment, were found to be similar to the DL and DY fragments, respectively, except for an internal cleavage at K393-T394 in their beta chains. This cleavage leads to destabilization of all thermolabile domains, indicating interaction between them. The DL and DY fragments, containing only one polymerization site in their beta chains, were able to inhibit fibrin polymerization at high concentration. However, these same fragments failed to bind to fibrin-Sepharose under conditions where their structural analogues, DX and DZ, were tightly bound, indicating that cleavage after K393 substantially increases the affinity of this site.

Crystallization of fragment D from human fibrinogen

Fragment D from human fibrinogen has been crystallized. The fragment, which is composed of three disulfide-linked chains (alpha' beta' gamma' = 88,000), was generated with either plasmin or mild trypsin digestion. The crystals diffracted out to 3.5 A; the space group is P2(1), unit cell dimensions a = 108 A, b = 48 A, c = 167 A, beta = 106 degrees. Fragment D was also co-crystallized with the ligand GPRP-amide, in which case the space group is consistent with P212121, unit cell dimensions a = 476 A, b = 82 A, c = 432 A.

Role of the alpha C domains of fibrin in clot formation

The role of the carboxyl-terminal portion of the alpha chains of fibrin (alpha C domains) in clot formation was investigated by transmission and scanning electron microscopy and turbidity studies of clots made from preparations of molecules missing one or both of these domains. Highly purified and entirely clottable preparations of bovine fragment X monomer, one containing primarily molecules missing a single alpha C domain (fragment X1) and the other consisting of molecules missing both alpha C domains (fragment X2), were used for these experiments. These preparations were characterized by various methods, including the complete determination of the amino- and carboxyl-termini of all peptides and fragments. These preparations formed clots on dilution to neutral pH. In all cases, clots observed by either scanning or transmission electron microscopy were made up of a branched network of fibers, similar to those formed by thrombin treatment of intact fibrinogen, suggesting that the alpha C domains are not necessary for protofibril and fiber formation or branching. However, both the fiber and clot structure varied with the different fractions, indicating that the alpha C domains do participate in polymerization. The rate of assembly, as indicated by the lag period and maximum rate of turbidity increase, as well as the final turbidity, was decreased with removal of the alpha C domains, suggesting that they accelerate polymerization. preparations of isolated alpha C fragment added to fibrin monomer have striking effects on the turbidity curves, showing a decrease in the rate of polymerization in a dose-dependent manner but not complete inhibition. Electron microscopy of fibrin monomer desA molecules at neutral pH showed that most of the alpha C domains, like those in fibrinogen, remain associated with the central region. Thus, it appears that normally with thrombin cleavage of fibrinogen the effects of the interactions of alpha C domains observed here will be most significant for lateral aggregation.

Fib420: a normal human variant of fibrinogen with two extended alpha chains

In fibrinogen, alpha E chains form a subpopulation of alpha subunits that are distinguished by a carboxyl extension homologous to the C termini of the other two constituent chains: beta and gamma. The molecular mass of alpha E is > 50% greater than that of the common alpha subunit, due in part to an extra 236 amino acids. These residues are encoded by exon VI, a recently discovered extension of the fibrinogen alpha gene. Additional mass is contributed by posttranslational processing, including N-glycosylation, which, based on experiments with the inhibitor tunicamycin, was found to account in large measure for alpha E migration on SDS/PAGE at approximately 110 kDa rather than at its calculated mass of 92,843 Da. An antibody specific for the exon VI-encoded domain of alpha E (anti-VI) and capable of recognizing alpha E-containing fibrinogen in both native and denatured form was generated using a recombinant protein as immunogen. Its use in Western blot analysis of fractions of normal human blood (plasma and preparations of fibrinogen) revealed a single, sharp, alpha E-containing band migrating behind the position of the broad, predominant fibrinogen band, (alpha beta gamma)2. Designation of the upper band as Fib420, an approximately 420-kDa homodimer of the formula (alpha E beta gamma)2, is based on the overwhelming proportion of alpha E subunits (> 80% of the total alpha chains) found in anti-VI-immunoprecipitable material from hepatoma cell medium. Several lines of evidence suggest that the alpha E subunit, alone or incorporated into fibrinogen, is more stable than the common alpha chain, a feature of potential clinical importance.

Functional motifs of delta antigen essential for RNA binding and replication of hepatitis delta virus

The functions of delta antigens (HDAgs) in the replication of hepatitis delta virus (HDV) have been identified previously. The small HDAg acts as a transactivator, whereas the large HDAg has a negative effect on replication. To understand the molecular mechanisms involved in the control of HDV replication, we have established a replication system in Huh-7 cells by cotransfecting a monomeric cDNA genome of HDV and a plasmid encoding the small HDAg. We demonstrate that a leucine repeat in the middle domain of the small HDAg is involved in binding to the HDV genome and transactivation of HDV replication. When the leucine repeat was disrupted by a substitution of valine for leucine at position 115, both RNA-binding and transactivation activity of the small HDAg were abolished. In contrast, the binding and transactivation activities were not affected when Leu-37 and Leu-44 of the small HDAg were replaced by valines. In addition, small and large HDAgs can interact with each other to form protein complexes in vitro. The complex formation that may lead to the trans-dominant negative regulation of large HDAg in HDV replication is mediated by a cryptic signal located between amino acid residues 35 and 65 other than the putative N-terminal leucine zipper motif. Furthermore, an extra 21-amino-acid extension near the N terminus converts the small HDAg into a pseudo-large HDAg with negative regulation activity of HDV replication even though the extreme C-terminal residue is unchanged.

A detailed consideration of a principal domain of vertebrate fibrinogen and its relatives

Vertebrate fibrinogen is a complex multidomained protein, the structure of which has been inferred mainly from electron microscopy and amino acid sequence studies. Among its most prominent features are two terminal globules, moieties that are mostly composed of the carboxyl-terminal two-thirds of the beta and gamma chains. Sequences homologous to the latter segments are found in several other animal proteins, always as the carboxyl-terminal contributions. An alignment of 15 amino acid sequences from various fibrinogens and related proteins has been used to make judgments about secondary structure. The nature of amino acids at each position in the alignment was used to distinguish alpha helices and beta structure on the one hand from loops and turns on the other, and the resulting assignments compared with predictions of secondary structure by other methods. Additionally, constraints imposed by the locations of cystines, carbohydrate attachment residues, and proteinase-sensitive points provided further insights into the general organization of the postulated secondary structures. Other ancillary data, including the effects of bound calcium and the locations of labeled or variant residues, were also considered. An intriguing similarity to a portion of the recently reported structure of a calcium-dependent lectin is noted.

Role of fibrinogen alpha and gamma chain sites in platelet aggregation

Fibrinogen (Fbg) mediates platelet aggregation by its interaction with the platelet glycoprotein IIb-IIIa (integrin alpha IIb beta 3). Peptides containing the amino acid sequence RGD derived from the alpha chain (residues alpha 95-97 and residues alpha 572-574) and the sequence HHLGGAKQAGDV derived from the carboxyl terminus of the gamma chain of Fbg (residues gamma 400-411) inhibit these interactions. To determine the role of these sequences in intact Fbg, recombinant human Fbg (rFbg), mutant rFbgs with an RGD-->RGE substitution at either position alpha 97 or alpha 574, and a rFbg gamma'-containing variant that has a carboxyl-terminal interruption in the HHLGGAKQAGDV sequence have been expressed in transfected BHK cells. Purified rFbg and the two RGE mutant Fbgs were similar to plasma Fbg in platelet aggregation assays. In contrast, the gamma' variant Fbg was markedly defective in platelet aggregation. These data support the proposals that the carboxyl-terminal region of the gamma chain of Fbg is essential for optimal platelet aggregation and that the alpha-chain RGD sequences are neither necessary nor sufficient for platelet aggregation.

Fibrinogen structure in projection at 18 A resolution. Electron density by co-ordinated cryo-electron microscopy and X-ray crystallography

Electron microscope images of frozen-hydrated crystals of a proteolytically modified fibrinogen show excellent preservation of the structure. An electron density map of the key centric projection of the crystal at 18 A resolution has been obtained by combining the phases derived from cryo-electron microscopy with X-ray amplitudes. Simulation methods developed in earlier studies have been used to interpret the map. In contrast to the earlier images, the map allows us to visualize the coiled-coil region of the molecule and possible substructure in the beta domains. The map also shows that there is a marked difference in density in the two regions corresponding to the molecular ends where the gamma domains interact. A possible interpretation of this finding is provided by assuming substructure in the gamma domains and the breaking of molecular symmetry where these domains interact. Some additional constraints useful for the determination of the three-dimensional structure were obtained from cryo-electron micrographs of a perpendicular view at 25 A resolution. Implications of this working model for the molecular length and contacts in the filaments in both the crystal and fibrin are described. The data used here will be valuable as a starting point for obtaining the three-dimensional structure.

Electron microscope investigation of the early stages of fibrin assembly. Twisted protofibrils and fibers

Structures formed during the early stages of clot formation have been produced in a controlled manner by polymerization of soluble fibrin monomers prepared from dissolved normal clots that had been formed upon addition of thrombin to fibrinogen. In agreement with other studies using different approaches, electron microscopy of negatively contrasted or rotary-shadowed specimens of these preparations reveal two-stranded protofibrils, as well as shorter oligomers and fibrin monomers. Individual fibrin molecules are similar in appearance to fibrinogen, suggesting that no large-scale changes in conformation occur on removal of the fibrinopeptides. Moreover, these micrographs show details of the protofibril structure not previously seen. The visualization of clear cross-over points of the filaments making up the protofibril indicate that these structures are twisted. Diffraction patterns of electron micrographs of both protofibrils and fibers and computer modeling of protofibrils also suggest that these structures are twisted but not precisely ordered.

Electron microscopy of platelet interactions with heme-octapeptide-labeled fibrinogen

Binding of fibrinogen to ADP-activated platelets was visualized by labeling the molecule with heme-octapeptide (microperoxidase) for direct cytochemical staining. Transmission electron microscopy of the platelet aggregates showed most of the fibrinogen distributed widely over the platelet surface in nonbridging rims of 7- to 9-nm thickness. Short peroxidase-positive bridges (less than 25 nm) were found in clusters in regions of close contact between the platelets, but 50-nm bridging corresponding to the length of the molecule was not seen by this method. Thus the fibrinogen appeared to be binding in a predominantly prone rather then upright orientation on the platelets. Abundant 50-nm bridging seen by nonspecific staining appeared unrelated to the length of the fibrinogen molecule because the bridging did not change when the length of the fibrinogen was more than doubled by end-to-end cross-linking with factor XIIIa. It is suggested that the observed binding and bridging of fibrinogen in a prone orientation is promoted by the existence of multiple platelet-binding domains on the molecule.

Deep-etch visualization of proteins involved in clathrin assembly

Assembly proteins were extracted from bovine brain clathrin-coated vesicles with 0.5 M Tris and purified by clathrin-Sepharose affinity chromatography, then adsorbed to mica and examined by freeze-etch electron microscopy. The fraction possessing maximal ability to promote clathrin polymerization, termed AP-2, was found to be a tripartite structure composed of a relatively large central mass flanked by two smaller mirror-symmetric appendages. Elastase treatment quantitatively removed the appendages and clipped 35 kD from the molecule's major approximately 105-kD polypeptides, indicating that the appendages are made from portions of these polypeptides. The remaining central masses no longer promote clathrin polymerization, suggesting that the appendages are somehow involved in the clathrin assembly reaction. The central masses are themselves relatively compact and brick-shaped, and are sufficiently large to contain two copies of the molecule's other major polypeptides (16- and 50-kD), as well as two copies of the approximately 70-kD protease-resistant portions of the major approximately 105-kD polypeptides. Thus the native molecule seems to be a dimeric, bilaterally symmetrical entity. Direct visualization of AP-2 binding to clathrin was accomplished by preparing mixtures of the two molecules in buffers that marginally inhibit AP-2 aggregation and cage assembly. This revealed numerous examples of AP-2 molecules binding to the so-called terminal domains of clathrin triskelions, consistent with earlier electron microscopic evidence that in fully assembled cages, the AP's attach centrally to inwardly-directed terminal domains of the clathrin molecule. This would place AP-2s between the clathrin coat and the enclosed membrane in whole coated vesicles. AP-2s linked to the membrane were also visualized by enzymatically removing the clathrin from brain coated vesicles, using purified 70 kD, uncoating ATPase plus ATP. This revealed several brick-shaped molecules attached to the vesicle membrane by short stalks. The exact stoichiometry of APs to clathrin in such vesicles, before and after uncoating, remains to be determined.

Characterization of the fibrin polymer structure that accelerates thrombin cleavage of plasma factor XIII

The effect of plasmin-derived fibrin(ogen) degradation products on alpha-thrombin cleavage of plasma Factor XIII was studied to identify the fibrin polymer structure that promotes Factor XIIIa formation. Fibrin polymers derived from fibrinogen and Fragment X enhanced the rate of thrombin cleavage of plasma Factor XIII in plasma or buffered solutions. The concentrations of fibrinogen and Fragment X that promoted half-maximal rates of Factor XIIIa formation were 5 and 40 micrograms/ml, respectively. Fragments Y, D, E, D-dimer, and photooxidized fibrinogen did not enhance thrombin cleavage of Factor XIII. Although purified Fragment D1 inhibited fibrin gelation, the soluble protofibrils promoted thrombin activation of Factor XIII. Noncrosslinked fibrin fibers failed to enhance thrombin cleavage of Factor XIII. In conclusion, soluble fibrin oligomers function to promote thrombin cleavage of plasma Factor XIII during blood clotting.

Domain structure of the myosin head in correlation-averaged images of shadowed molecules

Electron microscope images of rotary shadowed myosin heads and subfragment-1 (S1) have been computationally aligned and averaged using correlation methods. Average images show reproducible detail within the 'pear-shaped' envelope of the head; the major features are invariant in S1 and in intact heads, in two mirror-related views of the head, and in the presence and absence of ATP. The averages support the view that the head contains two main structural domains separated by a cleft, and that the region of the neck close to the head-rod junction is flexible. They also reveal the inadequacy of the conventional method of correcting the measured dimensions of shadowed particles for the supposed thickness of the 'metal coat'.

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.

Molecular morphology of fibrin monomers and early oligomers during fibrin polymerization

The structural features of early fibrin oligomers produced during the initial stages of polymerization were investigated by rotatory shadowing after cryotechnical preparation. The building blocks of polymerization, namely fibrin monomer units (in analogy to fibrinogen itself), were found to exhibit a high degree of flexibility which is independent of fibrinopeptide A and B removal. Early polymers exhibited directed longitudinal growth and were frequently branched. Along the main oligomer axis, fibrin monomer units were randomly orientated. Within early oligomers, a given fibrin monomer unit was found to establish a single contact with each of its two neighbors, suggesting that during the early stages of polymerization, only one polymerization and one binding site are activated per fibrinogen molecule (becoming an AB2 fibrin monomer unit). This morphological feature was corroborated by the finding that early oligomer fractions are deficient in only 50% of releasable fibrinopeptide A. Early associations between AB2 fibrin monomer units were demonstrated to be reversible and to occur in the absence of direct domainal contact; interactions thus presumably occur via fine molecular protrusions on either D or E domains. The arrangement of AB2 fibrin monomer units within early oligomers suggests that, with respect to their structural organization, fibrinogen molecules are radially symmetrical through the E domain (implying an antiparallel organization of polymerization and binding sites). This pattern is inconsistent with a "top-bottom" model, and thus with "half-staggered double-stranded" polymer growth. The methodological problems responsible for the apparent conflict with previous morphological findings are discussed.

Twisting of fibrin fibers limits their radial growth

Electron microscopy of freeze-dried, shadowed fibrin fibers has demonstrated that these structures are twisted. The pitch and radius of many fibers were measured from the micrographs. Although there is some variability, the average pitch of 1930 +/- 280 (SD) nm is independent of radius. The distribution of observed radii of fibers assembled in vitro is highly skewed, suggesting that individual fibers grow to a maximum radius of about 50 nm, except when both pH and ionic strength are high; fibers aggregate to form thicker fiber bundles under some conditions. The observed twisting may be responsible for limiting the lateral growth of individual fibers. Protofibrils near the surface of a twisted fiber are stretched relative to those near the center. Consequently, the degree to which a protofibril can be stretched limits the radius of a fiber; protofibrils can be added to a growing fiber until the energy required to stretch an added protofibril exceeds the energy of binding. These properties of assembly arise directly from the intrinsic twist of the fibrinogen molecule determined from structural evidence. Simple geometric considerations lead to conclusions regarding the locations of the binding sites for assembly of the protofibril and the flexibility of the fibrin molecule.

Fibrinogen-induced erythrocyte aggregation: erythrocyte-binding site in the fibrinogen molecule

The effect of fibrinogen and fibrinogen-derived products on the velocity of rouleau formation of human erythrocytes was quantitatively examined with a rheoscope combined with a video-camera, an image analyzer and a computer. (i) The velocity of rouleau formation by naturally occurring low-molecular-weight fibrinogen of 305 kDa and by desialylated fibrinogen was the same as that by native fibrinogen of 340 kDa. (ii) Concerning fibrinogen degradation products by plasmin, the velocity of rouleau formation decreased upon going from fibrinogen greater than fragment X greater than fragment Y (the ratio of molar concentration of fibrinogen, fragment X and fragment Y for giving a certain velocity of rouleau formation was approx. 1:2:5). The effect of fragments X and Y on the fibrinogen-induced rouleau formation was additive. (iii) Fragments D and E could not induce rouleau formation and did not affect the fibrinogen-, fragment X- and fragment Y-induced rouleau formation. (iv) Fibrinopeptides A and B and artificial tetrapeptides (Gly-Pro-Arg-Pro and Gly-His-Arg-Pro) did not affect the fibrinogen-induced rouleau formation. (v) The possible erythrocyte-binding site in fibrinogen molecule for leading to rouleaux was proposed to be in A alpha-chain (probably, around residues No. 207-303) near the terminal domain of the trinodular structure of fibrinogen.

Involvement of the COOH-terminal portion of the alpha-chain of fibrin in the branching of fibers to form a clot

A modified fibrinogen molecule which is missing the COOH-terminal portion of the A alpha chain has been used in structural investigations of the mechanism of assembly of the fibrin clot. Brief plasmin digestion of human fibrinogen, followed by ammonium sulfate fractionation and column chromatography, yielded a highly clottable fragment X-like preparation. Molecules in this preparation contain mostly intact B beta and gamma chains, but are missing the COOH-terminal two-thirds of the A alpha chain. Clots formed by addition of thrombin to this fragment were mechanically unstable and easily dispersed. Electron microscopy showed that the clots consist mainly of a suspension of individual fibers, in contrast to clots made from native fibrinogen, which are highly branched. It appears, therefore, that a part of the COOH-terminal two-thirds of the alpha chain is necessary for branching of fibers to form a stable three-dimensional gel. Intermolecular interactions of this portion of the alpha chain are consistent with certain of its unusual features, such as its apparent existence, in part, as a single polypeptide chain and its involvement in Factor XIIIa-mediated ligation between molecules.

Protein structure probed by polarization spectroscopy. II. A time-resolved fluorescence study of human fibrinogen

Human fibrinogen in solution was studied by monitoring the time-resolved depolarization of the fluorescence emitted by two spectroscopic labels of which the fluorescence lifetimes differ by an order of magnitude. Contrary to a long-held view, no evidence of molecular flexibility was found in the 10-1000 ns range. In addition, from the rate of the overall rotation, it is proposed that a prolate and symmetric ellipsoid of 47 X 10.5 nm may represent the time-averaged hydrodynamic size and shape of the protein in solution. This rigid and highly hydrated structure (4 g water/g protein) accommodates the latest nodular models obtained from electron microscopy, explains the singular hydrodynamics of fibrinogen and, apparently, it would perform the two main functions of the protein in haemostasis, blood coagulation and platelet aggregation, more efficiently than the flexible molecule.

The role of fibronectin fragments and cell-attached transamidase on the binding of soluble fibrin to macrophages

Proteolytic fragments from the N-terminus of the fibronectin subunit chains were shown to mediate the binding of 125-I-fibrin to macrophages. With increasing molecular weight of the fragments, binding activity decreased and intact plasma fibronectin was inactive. Fibrin binding to macrophages was a time dependent reaction and proceeded considerably faster than binding of fibrinogen. The binding reaction was inhibited by putrescine suggesting the involvement of a transamidase. Pericellular transamidase was demonstrated on macrophages by incorporation of 14-C-putrescine into fibronectin 30 kD-fragment. Expression of this enzyme appeared to be rate-limiting for the binding reaction which was accelerated after loading the cells with placental transamidase.

Fibrin assembly. Lateral aggregation and the role of the two pairs of fibrinopeptides

The structural basis of the wide variability of the physical properties of fibrin clots and the process of assembly of the clot were investigated by electron microscopy of fibers formed under various ionic conditions. In addition, highly specific proteolytic enzymes from different snake venoms were used to remove selectively only the A (batroxobin) or the B (venzyme) fibrinopeptides from fibrinogen, in contrast to thrombin, which removes both pairs. Fibers produced by cleavage of only the B fibrinopeptides displayed a characteristic band pattern indistinguishable from that of fibers formed upon removal of either the A fibrinopeptides alone or of both pairs. Computer modeling studies suggest that there is a unique molecular packing that gives rise to this fibrin band pattern. These findings imply that the release of either fibrinopeptide triggers similar modes of aggregation; the intermolecular binding sites can be localized to particular molecular domains. The diameters of fibers formed with each condition of enzyme, pH, salt concentration, and temperature were measured from electron micrographs. All fibers, except for those produced at both high ionic strength and pH, had about the same average diameter of 85 +/- 13 nm. The degree of lateral aggregation of the fibers themselves varied greatly, however; fibers aggregated more readily with cleavage of both pairs of fibrinopeptides and at lower pH and salt concentrations. The formation of such thick fiber bundles increases the stability of the clot and its resistance to proteolytic dissolution.

Gly-Pro-Arg-Pro modifies the glutamine residues in the alpha- and gamma-chains of fibrinogen: inhibition of transglutaminase cross-linking

During blood clotting Factor XIIIa, a transglutaminase, catalyzes the formation of covalent bonds between the epsilon-amino group of lysine and the gamma-carboxamide group of peptide-bound glutamine residues between fibrin molecules. We report that glycyl-L-prolyl-L-arginyl-L-proline (GPRP), a tetrapeptide that binds to the fibrin polymerization sites (D-domain) in fibrin(ogen), inhibits transglutaminase cross-linking by modifying the glutamine residues in the alpha- and gamma-chains of fibrinogen. Purified platelet Factor XIIIa, and tissue transglutaminase from adult bovine aortic endothelial cells were used for the cross-linking studies. Gly-Pro (GP) and Gly-Pro-Gly-Gly (GPGG), peptides which do not bind to fibrinogen, had no effect on transglutaminase cross-linking. GPRP inhibited platelet Factor XIIIa-catalyzed cross-linking between the gamma-chains of the following fibrin(ogen) derivatives: fibrin monomers, fibrinogen and polymerized fibrin fibers. GPRP functioned as a reversible, noncompetitive inhibitor of Factor XIIIa-catalyzed incorporation of [3H]putrescine and [14C]methylamine into fibrinogen and Fragment D1. GPRP did not inhibit 125I-Factor XIIIa binding to polymerized fibrin, demonstrating that the Factor XIIIa binding sites on fibrin were not modified. GPRP also had no effect on Factor XIIIa cross-linking of [3H]putrescine to casein. This demonstrates that GPRP specifically modified the glutamine cross-linking sites in fibrinogen, and had no effect on either Factor XIIIa or the lysine residues in fibrinogen. GPRP also inhibited [14C]putrescine incorporation into the alpha- and gamma-chains of fibrinogen without inhibiting beta-chain incorporation, suggesting that the intermolecular cross-linking sites were selectively affected. Furthermore, GPRP inhibited tissue transglutaminase-catalyzed incorporation of [3H]putrescine into both fibrinogen and Fragment D1, without modifying [3H]putrescine incorporation into casein. GPRP also inhibited intermolecular alpha-alpha-chain cross-linking catalyzed by tissue transglutaminase. This demonstrates that the glutamine residues in the alpha-chains involved in intermolecular cross-linking are modified by GPRP. This is the first demonstration that a molecule binding to the fibrin polymerization sites on the D-domain of fibrinogen modifies the glutamine cross-linking sites on the alpha- and gamma-chains of fibrinogen.

The electron microscope band pattern of human fibrin: various stains, lateral order, and carbohydrate localization

Human fibrin negatively contrasted with a variety of heavy metal compounds and examined by electron microscopy displays a distinctive, nonpolar band pattern with a repeat of 22.5 nm. These results together with a reversal of contrast observed in images of positively stained fibrin, indicate that the striations reflect the protein density along the fiber. All major features of the band pattern can be accounted for directly in terms of a model for the structure of fibrinogen. Optical and computed diffraction patterns of micrographs of fibrin show that most specimens are highly ordered along the fiber axis but have only diffuse equatorial reflections arising from the average spacing of the protofibrils, although occasional fibers have discrete reflections at about 19 nm. Finally, the resulting change in negative staining pattern upon binding of lectins to the carbohydrate moieties is distinctive and allows the carbohydrate-containing beta domain of the molecule to be localized.