Review of some unusual effects of calcium binding to fibrinogen

Calcium binding curves of human and bovine fibrinogen were obtained by using a calcium sensitive electrode. The two were identical and showed 2 high, 2-3 medium and more than 15 low affinity sites. Differential scanning calorimetry at neutral pH demonstrated the presence of the D and E domains of fibrinogen; however, at pH 3.5 the D-domain was split into two. The presence of the subdomains was demonstrated also by digestion by pepsin at this pH. Combination of digestion of fibrinogen and of its fragments with different enzymes and temperatures identified up to 12 subdomains in the original molecule. Clotting of fibrinogen by thrombin at pH 7.0 was investigated also by differential scanning calorimetry. In the absence of Ca2+ clotting elicited a 40% increase in the enthalpy of thermal denaturation of the D domain of fibrinogen, but the position of the peak increased only by 0.4 degrees C. However, with clotting in the presence of 10(-3) M calcium the former increased by 70-75% and the latter by 11.0 degrees C, while these parameters of the E-domain remained unchanged. Changes of bound calcium during clotting were also measured with the calcium sensitive electrode. These had to be corrected, because the drop in free calcium was partly compensated by release of some calcium that was already bound to fibrinogen. Log of the half time of calcium uptake plotted against log thrombin concentration indicated a first order process with respect to thrombin concentration, moreover, the rate determined corresponded to that of the conformation change measured by calorimetry. The calcium uptake was correlated with release of the fibrinopeptides. Release of fibrinopeptide B follows parallel to binding of calcium and that of fibrinopeptide A is about fourfold faster. Polymerization and formation of thick bundles of fibrin is connected with release of fibrinopeptide A. Clotting with Ancrod, an enzyme that releases only fibrinopeptide A, showed only minimal binding of calcium. The polymerization inhibiting tetrapeptide Gly-Pro-Arg-Pro also depressed binding of calcium. These data suggest that a calcium-binding site must be in the proximity of the site of release of fibrinopeptide B and of a polymerization site.     

Localization of the binding site on fibrin for the secondary binding site of thrombin

Affinity chromatography of active site inhibited thrombin on immobilized fragments derived from the central (desAB-NDSK) and terminal (D1) globular domains of fibrinogen revealed that the site responsible for the binding of thrombin at its secondary fibrin binding site is located in the central domain. Chromatography of various domains of the central nodule (desAB-NDSK, fibrinogen E, and fibrin E) having nonidentical amino acid sequences showed that all of these fragments are capable of binding to PMSF-thrombin-Sepharose, suggesting that the thrombin binding site resides within the peptide regions common to all of these fragments: alpha(Gly17-Met51), beta(Val55-Met118), and gamma(Tyr1-Lys53). Competitive affinity chromatography of the same binding domains revealed that there is no detectable difference in their binding constants to PMSF-thrombin-Sepharose, indicating that the alpha(Lys52-Lys78), beta(Gly15-Lys54)/(Tyr119-Lys122), and gamma(Thr54-Met78) peptide segments do not contribute significantly to the binding of thrombin. Chromatography of the isolated chains of fibrinogen E showed that the alpha(Gly17-Lys78) peptide region itself contains a strong binding site for PMSF-thrombin-Sepharose. The location of the binding site suggests that the secondary site interaction may play an important role in determining the cleavage specificity of thrombin on fibrinogen and can affect the rate of release of the fibrinopeptides. Affinity chromatography of fragments prepared from polymerized fibrin showed that cross-linked DD (D x D) itself does not bind to thrombin, whereas the D x DE complex remained attached to the column, suggesting that the binding site on fragment E for thrombin is distinct from its binding site for D x D.(ABSTRACT TRUNCATED AT 250 WORDS)     

Differences in the clotting of lamprey fibrinogen by lamprey and bovine thrombins

1. Improved methods for the purification of lamprey thrombin and fibrinogen are presented. 2. Lamprey thrombin releases two fibrinopeptides from lamprey fibrinogen during the transformation into fibrin. Bovine thrombin releases only one of these, a peptide referred to as fibrinopeptide B. The differences in the by-products of fibrin formation are reflected in the different N-terminal amino acid compositions of the two types of fibrin. 3. The fibrinopeptide that is not removed from the lamprey fibrinogen by bovine thrombin can subsequently be released by treatment of that fibrin with lamprey thrombin. 4. Under the conditions used, lamprey thrombin releases both fibrinopeptides at about the same rate. 5. The differences in interaction among these pairs of related proteins are extreme manifestations of the phenomenon loosely referred to as `species specificity'.     

Clotting of fibrinogen. 1. Scanning calorimetric study of the effect of calcium

The denaturation temperature Td and the enthalpy of thermal denaturation delta Hd of the D nodules of fibrinogen increase 12-13 degrees C and 40%, respectively, when fibrinogen is clotted by thrombin in the presence of 10(-3) M calcium ion. The rate of change of Td and delta Hd is first order in thrombin concentration. In the absence of calcium, little change in Td is observed, but the increase in delta Hd still occurs. The shift in Td as a function of logarithm of calcium concentration is sigmoid, with a half-point at 2.5 X 10(-5) M calcium for human and 6.0 X 10(-5) M calcium for bovine fibrinogens, suggesting that the shift is due to binding of calcium at the high-affinity binding sites of fibrin. The Td of the D nodule of native fibrinogen also increases, but not as much, on addition of calcium. This increase in Td is also sigmoid with log calcium, with a half-point of 1.6 X 10(-3) M calcium for human and 3.2 X 10(-3) M calcium for bovine fibrinogens, and appears to be due to binding of calcium to the low-affinity binding sites of fibrinogen. At calcium concentrations greater than 10(-4) M, traces of factor XIII in the bovine fibrinogen preparation become activated and cause cross-linking of the fibrin gel. But the changes in Td and delta Hd still occur when factor XIIIa is inactivated by iodoacetamide, and the rate of the changes is not altered by addition of large amounts of factor XIIIa.(ABSTRACT TRUNCATED AT 250 WORDS)     

Role of D and E domains in the migration of vascular smooth muscle cells into fibrin gels

The structure of fibrin plays an important role in the organization of thrombi, the development of atherosclerosis, and restenosis after PTCA. In this study, we examined the mechanisms of the migration of vascular smooth muscle cells (SMCs) into fibrin gels, using an in vitro assay system. Cultured SMCs from bovine fetal aortic media migrated into fibrin gels prepared with thrombin, which cleaves both fibrinopeptides A and B from fibrinogen, without other chemotactic stimuli. Both desA fibrin gels prepared with batroxobin, which cleaves only fibrinopeptide A, and desB fibrin gels prepared with Agkistrodon contortrix thrombin-like enzyme (ACTE), which cleaves only fibrinopeptide B, similarly induced the migration of SMCs compared to fibrin gels prepared with thrombin. These results suggest that the cleavage of fibrinopeptides is not necessary, but rather that the three-dimensional structure of the gel may be important for the migration of SMCs. Furthermore, gels prepared with protamine sulfate, which forms fibrin-like gels non-enzymatically, similarly induced the migration of SMCs compared to the gels prepared with thrombin. Both anti-fibrin(ogen) fragment D and anti-fibrin(ogen) E antibodies inhibited the migration of SMCs into fibrin gels, suggesting that both the D and E domains of fibrin(ogen) are involved in the migration of SMCs into fibrin gels. The addition of GRGDS, a synthetic RGD-containing peptide, but not that of GRGES, a control peptide, partially inhibited the migration of SMCs into fibrin gels, suggesting that the migration of SMCs into fibrin gels is at least in part dependent on the RGD-containing region of the alpha chain. The migration of SMCs into fibrin gels was also inhibited by a monoclonal antibody for integrin alpha v beta 3 and alpha 5 beta 1, indicating that migration is dependent on these integrins. Furthermore, both fibrin(ogen) fragments D and E inhibited the migration of SMCs into fibrin gels, suggesting that these fragments, generated during fibrino(geno)lysis, may be relevant in the regulation of SMC migration into fibrin gels.     

Interaction of a peptide inhibitor with two forms of monomeric fibrin differing in the degree of activation

The study is devoted to the interaction of peptide inhibitor of fibrin self-assemblage with two forms of fibrin monomer: deprived of fibrinopeptides A and preserving fibrinopeptides B (desAA-monomer) and fully activated (desAABB-monomer). It is shown that peptide inhibitor hinders the coagulative conversion of fibrinogen by thrombin, limiting the enzymic and nonenzymic stages of the process. The indispensible condition for the formation of inhibitor-monomeric fibrin associates is a preliminary modification of fibrinogen by thrombin.     

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.     

Preparation of fibrin des-AA by thrombin

The active thrombin is formed in the blood stream when the blood coagulation system is activated. It attacks fibrinogen, splits off two fibrinopeptides A and fibrinogen is transformed into des-AA fibrin which is able to polymerize spontaneously forming protofibrils. At high thrombin concentration the enzyme splits off two fibrinopeptides B and des-AA fibrin units are transformed into des-AABB fibrin. These two forms of fibrin are widely used in the biological experiments. However des-AA fibrin is obtained usually from fibrinogen using the snake poisons (such as reptilase). Des-AA fibrin was obtained also by physiological enzyme thrombin, but that des-AA fibrin samples had the contamination of des-AABB fibrin. At the present paper we have described the method of the des-AA fibrin preparation by thrombin without any contamination of des-AABB fibrin.     

Effects of fibrinopeptide cleavage on the plasmic degradation pathways of human cross-linked fibrin

The presence of fibrinopeptide B in human fibrin has a significant effect on plasmic degradation pathways of cross-linked clots. Two types of fibrin were obtained from fibrinogen by incubation either with thrombin, to remove both fibrinopeptides A and B, or with batroxobin, to cleave fibrinopepitde A only. Fibrins obtained after various incubation times were characterized by the determination of the NH2-terminal amino acids, the content of fibrinopeptides, and the extent of cross-linking. The fibrins were digested by plasmin and were analyzed by polyacrylamide gel electrophoresis. The presence and concentration of the (DD)E complex, as well as fragments E1 and E2, in the digests were dependent upon the loss of fibrinopeptide B from cross-linked fibrin. These degradation products, and also fragment DD, appear to be useful molecular markers of fibrinolysis.     

Fibrin assembly after fibrinopeptide A release in model systems and human plasma studied with magnetic birefringence.

Magnetically induced birefringence was used to monitor fibrin polymerization after the release of the small negatively charged A fibrinopeptides from human fibrinogen by the action of the snake-venom-derived enzymes reptilase and ancrod. A range of conditions was investigated. Fibrin polymerization in solutions of purified fibrinogen shows a distinct break near the gelation point. On addition of Ca2+ or albumin the lag period is shortened, fibre thickness is increased and the break in assembly almost vanishes, probably because both of these additives promote lateral aggregation. There are minor differences in the kinetics, depending on the venom enzyme used. The kinetics of fibrin assembly in model systems containing either Ca2+ or albumin and in human plasma with a largely dormant coagulation cascade are very similar. Therefore in the latter condition there is no significant alteration in the assembly process due to interaction between fibrin or the venom enzymes and any of the plasma proteins. When the cascade is activated, the polymerization progress curves have a character that resembles a combination of the reactions observed when the venom enzymes and endogenously generated thrombin separately induce coagulation, except for a region near gelation where, paradoxically, polymerization appears to be slower on activation. The low-angle neutron-diffraction patterns from oriented gels made with thrombin or reptilase are identical. Therefore at low resolution the packing of the monomers within fibres is the same when fibrinopeptide A only or both fibrinopeptides A and B are removed.     

Effect of methylmercuric chloride (MMC) on fibrin polymerization

Methylmercuric chloride (MMC) in concentrations 0.1–10μM reduces the amount of fibrinopeptides released from thrombinactivated human fibrinogen. However, the fibrin clot formation is not discriminated and the turbidity of the fibrin gel is even augmented. MMC does not cause such changes in the process of repolymerization of fibrin monomers. The addition of fibrinopeptides to the fibrin monomers results in a similar increase of turbidity of the repolymerizing sample in the presence of MMC as in the case of fibrinogen clotting. These experiments indicate that MMC modifies the structure of fibrin in the presence of fibrinopeptides.     

Fibrinogen and fibrin interaction with concanavalin a dimer and its influence on coagulation

Concanavalin A dimer interacts with fibrinogen and soluble fibrin at pH 5.2 Analysis of the binding data shows that there are in both cases four binding sites per molecule and that the dissociation constant does not change by removal of fibrinopeptides A and B. Ultracentrifugal studies shows that no aggregates of fibrinogen or fibrin are formed through concanavalin A binding and that up to four molecules of concanavalin A dimer can be bind to one molecule of fibrinogen or fibrin. These results imply that the four carbohydrate chains in the molecule are accessible to concanavalin A dimer. There is a diminution in the coagulation of fibrinogen by thrombin at low relative lectin concentrations and an increase at high concentrations. However, the lectin always favours the aggregation of fibrin monomers and does not have any inhibitory effect on the release of fibrinopeptides. We conclude that the electric charge in the neighbourhood of the carbohydrate in both chains, Bβ and γ plays an important role in the attraction between monomeric fibrin and fibrinogen-monomeric fibrin. The different effect of concanavalin A on the coagulation, depending on the relative concentration of the lectin, would be the result of the screening of this electric charge favouring either the interaction of fibrinogen-monomeric fibrin or the polymerization of monomeric fibrin.     

Polymerization and gelation of fibrinogen in D2O

The solution properties of fibrinogen and the thrombin-induced activation and gelation of fibrinogen in 95% D2O at pH 7.4 were compared to those in H2O under similar conditions. The initial release rates of fibrinopeptides A and B in D2O were slightly slower than those in H2O. However, the values of the Michaelis-Menten parameters Km and V for the release of the two peptides in D2O and H2O in the presence of 0.5 M NaCl were about the same. From turbidity measurements at 450 nm it is obvious that fibrinogen is soluble in a slightly more narrow range of NaCl concentration and that the fibrin gels have a higher degree of lateral aggregation in D2O than in H2O. The variation of fibrinogen concentration, thrombin concentration, pH and ionic a strength have a similar dependence on the final gel structure and clotting time in D2O and H2O. SDS-gel electrophoresis on fibrin samples, which were cross-linked by factor XIII, yielded results where the cross-linking of the gamma-chain appeared to be the same in D2O and H2O. The alpha-chain cross-linking was somewhat faster in D2O than in H2O. When fibrinogen solutions in 95% D2O were incubated at 20 mM CaCl2, a slow gelation of fibrinogen was observed, which was found to be induced by trace amounts of factor XIII. The final gel turbidity appeared to be about the same for this gelation as for that induced by thrombin. The differences in solubility for fibrinogen, kinetics for the enzyme reaction and optical properties for the fibrin gels in D2O and H2O may be explained by differences in electrostatic interactions, hydrogen bonding and hydration of fibrinogen in these two media.     

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

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

Gold labeling of thrombin and ultrastructural studies of thrombin-gold conjugate binding by fibrin

Monodispersed thrombin-gold (T-Au) conjugates were prepared by the absorption of a monolayer (3.8 nm thick) of human alpha-thrombin around individual monodispersed colloidal gold particles (16.5 +/- 1.8 nm). Like free molecular thrombin, T-Au conjugates can cause platelet aggregation, plasma clotting, and the release of fibrinopeptides A and B from fibrinogen. At the same thrombin concentration, T-Au conjugates have only one-tenth the fibrinogen-clotting activity of free thrombin and one-third the amidolytic activity of free thrombin. Hirudin can completely inhibit the fibrinogen-clotting activity of both T-Au conjugates and free thrombin, but can inhibit only half of the amidolytic activity of the conjugates. Diisopropyl fluorophosphonate can completely inhibit the fibrinogen-clotting activity and the amidolytic activity of both T-Au conjugates and free thrombin. T-Au conjugates were further characterized by studying the mechanism of their binding to fibrin and the location of the binding site on fibrin. The results of electron microscopic studies showed that T-Au conjugates, but not albumin-Au conjugates, are bound by fibrin. Increasing T-Au conjugate concentrations are associated with an increase in the number of T-Au conjugates binding to fibrin. At 0.1 microM thrombin, 73% of the T-Au conjugates are bound to branch points of the fibrin network with 27% of the T-Au conjugates present in the fibrin strands. At higher thrombin concentration (e.g., 0.5 microM) the percentage of T-Au conjugates bound to locations other than branch points increases to 62%.(ABSTRACT TRUNCATED AT 250 WORDS)     

Interaction of fibrinogen with two forms of fibrin differing in the degree of activation by thrombin

The inhibitory effect of fibrinogen in the clotting of two fibrin monomer species--f-desAA and f-desAABB--was studied. The concentration dependence of this effect for two fibrin forms was found to be of the same character. This fact indicates that the modifying influence of fibrinogen proposed earlier in relation to f-desAABB also takes place in the case of f-desAA. However, an equal inhibitory effect is achieved for f-desAA at much higher fibrinogen concentrations than that for f-desAABB. The inhibitory effect of fibrinogen is greater at higher ionic strengths for both fibrin forms, but in the case of f-desAA this effect is more pronounced. The role of fibrin polymerization sites formed after fibrinopeptides B removal in initial fibrin polymerization and in F-f-desAABB interaction is discussed.     

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.     

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.     

The thrombin-fibrinogen interaction

The thrombin-catalyzed conversion of fibrinogen (F) to fibrin consists of three reversible steps, with thrombin (T) being involved in only the first step which is a limited proteolysis to release fibrinopeptides (FpA and FpB) from fibrinogen to produce fibrin monomer. In the second step, fibrin monomers form intermediate polymers through noncovalent interactions. In the third step, the intermediate polymers aggregate to form the fibrin clot. The molecular mechanisms of the first two steps are elucidated.     

Fibronectin and fibrin gel structure

Plasma fibronectin is covalently incorporated into alpha-chains of fibrin gels in the presence of Factor XIII activated by thrombin (FXIIIaT) but not by Factor XIII activated by the snake venom enzyme batroxobin (FXIIIaB). FXIIIaB catalyzes introduction of gamma-gamma cross-links in fibrin but cross-linked alpha-chains are not formed. In the presence of FXIIIaT, fibrin gels formed by batroxobin incorporated fibronectin and the alpha-chains are cross-linked indicating that FXIIIaB has a different substrate specificity from FXIIIaT. In the presence of FXIIIaT the incorporation of fibronectin approaches 1 mol/340 kDa unit weight of fibrin. Fibronectin when present in a fibrinogen thrombin mixture containing FXIII does not influence the clotting time of the system nor the release of fibrinopeptides. Incorporation of fibronectin is not appreciable before the gel point. This indicates that the polymerization and gelation of fibrinogen is essentially not perturbed by the presence of fibronectin and that fibrin in the gel matrix rather than the fibrin polymers formed prior to gel point is the preferred structure for fibronectin incorporation. Incorporation of fibronectin into fibrin gels during formation leads to an increase in turbidity and a small decrease in Ks (permeability coefficient). This suggests that the width of the strands in the gel increases as a result of fibronectin incorporation. Fibronectin is also incorporated into preformed gels having completely cross-linked gamma- and alpha-chains perhaps indicating that the sites in fibrin involved in fibronectin incorporation are different from those involved in fibrin cross-linking. FXIIIaT appeared to be adsorbed to fibrin gel matrix in the presence but not in the absence of calcium ions.