Catalytic and regulatory functions of N-bromosuccinimide-modified bovine thrombin

At pH 4.1, bovine thrombin reacts rapidly with N-bromo-succinimide to yield modified enzyme containing oxidized tryptophan residue. Both fibrinogen clotting activity and esterase activity are reduced considerably when three moles of tryptophan residues per mole of thrombin are oxidized, but the Michaelis constants for synthetic substrates are not appreciably altered. Reaction of NBS also results in a decrease in the affinity of thrombin for heparin. The dissociation constant for heparin-thrombin complex is increased by 2.6-fold due to the modification of one tryptophan residue. However, the magnitude of the increase in the dissociation constant remains the same for modified enzymes containing approximately two or three oxidized tryptophan residues. The rate constant for the inactivation of thrombin by antithrombin III is increased by 2.5-fold due to the modification of a single tryptophan residue. This increase in rate constant is not further amplified when more than one tryptophan residue is oxidized. In contrast, in the presence of heparin the rate of inactivation of modified and unmodified thrombins by antithrombin III are not significantly different. Thus, the heparin-sensitized inactivation of thrombin by antithrombin III is affected by the modification of one tryptophan residue. Spectrophotometric titrations of the phenolic hydroxyl groups suggest that the structural environments of tyrosyl groups for both unmodified and modified thrombin containing one oxidized tryptophan residue, are similar. The temperature for half loss of catalytic activity of control and NBS-modified thrombin, containing one oxidized tryptophan, are 52 and 51.5 degrees C respectively. It appears that the one tryptophan residue of thrombin is situated at or close to the binding site of heparin.     

Effect of rabbit thrombomodulin on thrombin inhibition by antithrombin in the presence of heparin

Thrombomodulin acts as a cofactor for protein C activation by thrombin (PC activation cofactor activity) and inhibits thrombin-induced fibrinogen clotting (direct anticoagulant activity). In addition, rabbit thrombomodulin has been shown to promote thrombin inactivation by antithrombin (AT-dependent anticoagulant activity). However, a non-acidic form (i.e. non-retarded on ion-exchange chromatography) of thrombomodulin generated by limited proteolysis retained only the PC activation cofactor activity. The acidic form (retarded on ion-exchange chromatography) of thrombomodulin is now shown to prevent the rapid inactivation of thrombin by antithrombin in the presence of heparin, presumably by preventing the formation of the ternary thrombin-AT-heparin complex. This effect was not observed with non-acidic thrombomodulin. When submitted to chondroitinase digestion, thrombomodulin was converted into an essentially non-acidic form that lacked both the AT-dependent and the direct anticoagulant activities but showed a PC activation cofactor function indistinguishable from that of native thrombomodulin. This chondroitinase-digested form did not prevent the catalytic effect of heparin on the inhibition of thrombin by AT. It is concluded that the acidic domain of rabbit thrombomodulin, a chondroitin (dermatan) sulfate glycosaminoglycan, interacts with a site of the thrombin molecule that is not involved in the protein C activation cofactor function, but is essential to the cleavage of fibrinogen or binding of heparin.     

The amino acid sequence in fibrin responsible for high affinity thrombin binding

Human fibrin has a low affinity thrombin binding site in its E domain and a high affinity binding site in the carboxy-terminal region of its variant gamma' chain (gamma'408-427). Comparison of the gamma' amino acid sequence (VRPEHPAETEYDSLYPEDDL) with other protein sequences known to bind to thrombin exosites such as those in GPIbalpha, the platelet thrombin receptor, thrombomodulin, and hirudin suggests no homology or consensus sequences, but Glu and Asp enrichment are common to all. Tyrosine sulfation in these sequences enhances thrombin exosite binding, but this has not been uniformly investigated. The fibrinogen gamma' chain mass determined by electrospray ionization mass spectrometry, was 50,549 Da, a value 151 Da greater than predicted from its amino acid/carbohydrate sequence. Since each sulfate group increases mass by 80 Da, this indicates that both tyrosines at 418 and 422 are sulfated. A series of overlapping gamma' peptides was prepared for evaluation of their inhibition of 125I-labeled PPACK-thrombin binding to fibrin. gamma'414-427 was as effective an inhibitor as gamma'408-427 and its binding affinity was dependent on all carboxy-terminal residues. Mono Tyr-sulfated peptides were prepared by substituting non-sulfatable Phe for Tyr at gamma'418 or 422. Sulfation at either Tyr residue increased binding competition compared with non-sulfated peptides, but was less effective than doubly sulfated peptides, which had 4 to 8-fold greater affinity. The reverse gamma' peptide or the forward sequence with repositioned Tyr residues did not compete well for thrombin binding, indicating that the positions of charged residues are important for thrombin binding affinity.     

Partial characterization of an autoantibody recognizing the secondary binding site(s) of thrombin in a patient with recurrent spontaneous arterial thrombosis.

A patient with an 18 year history of recurrent arterial thrombosis and no evidence of atherosclerosis or embolism of cardiac origin presented with a prolonged thrombin clotting time when performed with human thrombin. The bovine thrombin clotting time was only slightly prolonged. During 30 months of follow-up, the thrombin time fluctuated, but remained prolonged. The patient has been treated with an oral anticoagulant for the past 8 years, with no thrombotic recurrence. The inhibitor activity was due to the presence of polyclonal IgGs which bound to thrombin-Sepharose. The influence of IgGs purified from the patient's serum was compared to the influence of normal IgGs in several systems exploring the catalytic activity of thrombin and the binding of the enzyme to macromolecular substrates through secondary binding site(s). We found that the IgGs did not impair the catalytic activity toward small synthetic substrates, but inhibited the binding of thrombin to fibrinogen, thrombomodulin and heparin cofactor II. Such proteins are known to require a secondary binding site of thrombin to interact with the enzyme. The anti-thrombin antibody might have resulted from an abnormal generation of thrombin. This would be the consequence of the process favouring thrombosis. Alternatively, the autoantibody might have favoured thrombosis primarily, by impairing natural antithrombotic mechanisms triggered by thrombin.     

Oxidation of human alpha-thrombin by the myeloperoxidase-H2O2-chloride system: structural and functional effects

The myeloperoxidase-H2O2-chloride system (MPOS) is exploited by white blood cells to generate reactive oxygen species in many processes involved in the pathogenesis of inflammation and atherothrombosis. This, study investigated the biochemical and functional effects of alpha-thrombin oxidation by MPOS. This system, in the presence of 100 microM L-tyrosine, caused in the thrombin molecule loss of tryptophan and lysine residues and formation of dityrosine, chloramine and carbonyl groups. The same changes could be directly induced by thrombin incubation with reagent HOCI, but not with H2O2 alone. Exposure to either MPOS or HOCl caused major functional abnormalities in human alpha-thrombin. The interaction of oxidized (ox-)thrombin with Protein C and antithrombin III-heparin complex were most sensitive to oxidation, being the kcat/Km value for Protein C hydrolysis roughly reduced 13-fold and the affinity for the antithrombin III-heparin complex decreased approximately 15-fold. Ox-thrombin interaction with small synthetic peptides showed several changes, arising from a perturbation of the S2-S3 specificity of the enzyme. Ox-thrombin was also characterized by a 5-fold decrease of the kcat/Km value for both fibrinopeptide A and B release from fibrinogen, a 5.8-fold increase of the EC50 value for platelet activation and a 2-fold decrease of binding affinity for thrombomodulin. The above results indicate a high sensitivity of thrombin to oxidative modifications by myeloperoxidase. Perturbed interactions with Protein C and the heparin-ATIII complex were the most relevant functional abnormalities of ox-thrombin.     

Identification of critical residues on thrombin mediating its interaction with fibrin.

Thrombin binding to fibrin may be important in localizing thrombin to the site of vascular injury. However, fibrin-bound thrombin retains its catalytic activity toward fibrinogen, and may be prothrombotic under certain conditions. A collection of 52 purified thrombin mutants was used to identify those residues mediating the thrombin-fibrin interaction. Comparison of fibrinogen clotting activity with fibrin binding activity identified twenty residues involved in fibrinogen recognition with four of these residues important in fibrin binding (Lys65, His66, Tyr71, Arg73). No mutant was identified with normal clotting activity and deficient fibrin binding, suggesting that these two properties are not readily dissociable. A DNA thrombin aptamer that binds to these residues was able to inhibit the thrombin-fibrin interaction, and displace thrombin that was already bound. Mapping of these fibrin-binding residues on thrombin revealed that they are localized within exosite I, and comprise a subset of the residues important in fibrinogen recognition.     

Factor XI dependent and independent activation of thrombin activatable fibrinolysis inhibitor (TAFI) in plasma associated with clot formation

Thrombin Activatable Fibrinolysis Inhibitor (TAFI) also known as plasma procarboxypeptidase B is activated by relatively high concentrations of thrombin in a reaction stimulated by thrombomodulin. In plasma an intact factor XI-dependent feed back loop via the intrinsic pathway is necessary to generate sufficient thrombin for TAFI activation. This thrombin generation takes place after clot formation with consequent down-regulation of fibrinolysis. We developed a specific and sensitive assay for activated TAFI (TAFIa) and studied its factor XI-dependent generation during clot formation. In the absence of thrombomodulin, addition of 20 nM thrombin to normal plasma generated 5-10% of the amount of TAFIa generated by 20 nM thrombin in the presence of 8 nM thrombomodulin. Minimal activation of TAFI was detected in factor II deficient plasma when clotting was initiated by 20 nM thrombin. Addition of 320-640 nM of thrombin to factor II deficient plasma resulted in the same amount of TAFIa as in normal plasma, suggesting that approximately 50% of factor II has to be converted to thrombin for extensive activation of TAFI. A Mab that neutralizes activated factor XII had no effect on TAFI activation indicating that an intact contact system is not necessary for the activation of TAFI. The dependency of TAFI activation of factor XI was tested using a Mab that neutralizes activated factor XI. When plasmas from 13 healthy individuals were tested, this Mab reduced TAFI activation by 65% (range 35-89%). Our results indicate that activation of TAFI in serum after clot formation can be quantitated and that it takes place in both factor XI-dependent and factor XI-independent mechanisms.     

Thrombin binding properties of insoluble modified polystyrene: Part II

Antithrombin III (AT III) inhibits thrombin via an arginine-serine interaction. Insoluble polystyrene resins grafted with arginyl methyl ester have been synthesized, and their interaction with thrombin tested. One of these resins was selected for its high affinity for thrombin. In this paper we report the characteristics of this thrombin resin interaction. Using this substituted polystyrene resin as a support for affinity chromatography, we have compared the binding of thrombin with that of other proteins (prothrombin, Factor IXa, trypsin and AT III). It was found that 0.7 mg of highly purified human thrombin (2,100 U/mg) was bound to 1 g of resin. This could only be eluted at high ionic strength (1.5 M) and the amidolytic and clotting activities of the eluted thrombin remained unchanged. The binding of thrombin to the resin involves the active site of the enzyme but also other residues since, when DIP thrombin was used, the inactive enzyme could be eluted at lower ionic strength (1.0 M). This resin seems to be specific for thrombin because it does not bind the other serine-proteases (trypsin or Factor IXa), prothrombin (the inactive precursor of thrombin) or AT III. The arginyl residues of the resin are important for the specificity of the interaction with Factor IIa since prolyl residues are totally ineffective. Chromatography performed on such a resin is a very efficient method of purifying thrombin, and may be very useful for the removal of thrombin as a contaminant of plasma protein fractions.     

Control of thrombin mediated cleavage of protein S

Thrombin has been shown to cleave the vitamin K dependent cofactor protein S with subsequent loss of its cofactor activity. This study examines the control mechanisms for thrombin cleavage of protein S. The anticoagulant activity of activated protein C (APC) is enhanced fourteen fold by the addition of protein S. Thrombin cleaved protein S is seven fold less efficient than the native protein, and this loss of activity is due to reduced affinity of cleaved protein S for APC or the lipid surface compared to the intact protein. In the absence of Ca++, protein S is very sensitive to minimal concentrations of thrombin. As little as 1.5 nM thrombin results in complete cleavage of 20 nM protein S in 10 min and loss of cofactor activity. Ca++, in concentrations greater than 0.5 mM, will inhibit this cleavage and in the presence of physiological Ca++ concentrations, no cleavage of protein S could be demonstrated in spite of high concentrations of thrombin (up to 1 microM) and prolonged incubations (up to two hours). The endothelial surface protein thrombomodulin is very efficient in inhibiting the cleavage of protein S by thrombin suggesting that any thrombin formed on the endothelial cell surface is unlikely to cleave protein S, thus allowing the intact protein to act as a cofactor to APC. We conclude that the inhibitory effects of Ca++ and thrombomodulin on thrombin mediated cleavage of protein S imply that this event, by itself, is unlikely to represent a physiological control of the activity of protein S.     

Enzymic activity of thrombin with partially reduced disulfide bonds

Partial reduction of thrombin disulfide bridges with dithiothreitol in the absence of denaturants inhibits the fibrinogen clotting but not the esterase activity of the enzyme. The clotting activity reappears on spontaneous air reoxidation of thrombin. As a result of the reaction with dithiothreitol, two disulfide bonds are cleaved in thrombin molecule inducing a small decrease of β-sheets in the secondary structure of thrombin. It may be concluded that this modification does not affect the catalytic site of thrombin but has influence upon the fibrinogen binding (recognition) site.     

Effect of the hirudin carboxy-terminal peptide 54-65 on the interaction of thrombin with platelets.

The carboxy-terminal region of hirudin (residues 54-65) has previously been shown to inhibit thrombin clotting activity without binding to the catalytic site of the enzyme. In the present study, the effect of hirudin 54-65 on thrombin interaction with specified platelet proteins has been investigated. Hirudin 54-65 was found to inhibit thrombin-induced platelet aggregation and secretion in a dose-dependent manner. Substitution of either Phe56, Glu57, Ile59, Pro60 or Leu64 showed that these residues were critical for inhibition of thrombin-induced platelet activation whereas sulfation of Tyr63 increased the inhibitory potency of the peptide. Hydrolysis of glycoprotein V, a platelet membrane substrate for thrombin, was only partially inhibited by hirudin 54-65. Although hirudin 54-65 did not decrease the amount of thrombin bound to platelets during cross-linking experiments, it was found to inhibit the specific binding of thrombin to platelet glycoprotein Ib. Since the carboxy-terminal region of hirudin has previously been reported to bind near the trypsin-catalyzed beta cleavage site, we have analyzed the consequences of alpha to beta-thrombin conversion on both thrombin-hirudin 54-65 interaction and thrombin activity toward platelets. The beta cleavage induced a decrease in the affinity of thrombin for both glycoprotein Ib and hirudin 54-65. Altogether, our results indicate that thrombin recognition sites for hirudin 54-65 and platelet membrane glycoprotein Ib share common structures located near the beta cleavage site at Arg 73 on the thrombin B chain.     

Monoclonal antibodies directed against human alpha-thrombin and the thrombin-antithrombin III complex

Human alpha-thrombin was poorly immunogenic in Balb/c mice. Nevertheless, following fusion of spleen cells from a responding mouse with NS-1 cells, 8 mouse monoclonal antibodies against alpha-thrombin were isolated, and 6 were characterised. Five of these were isotype IgG2a, and one was IgG1. One, EST 1, bound thrombin only minimally, and was directed against a neoantigen on the thrombin-ATIII (T-AT) complex. This antibody also recognised a site on prothrombin, though with much lower affinity. Its binding was markedly temperature-dependent, indicating a requirement for molecular mobility. A second antibody, EST 4, would not bind the T-AT complex. It inhibited both the clotting and amidase activities of thrombin, and modification of the active site histidine, but not the active site serine, reduced the affinity constant of binding to EST 4. This antibody appears to be directed against an epitope in the vicinity of the enzyme active site. The epitopes for EST 1 and EST 4 were both remote from those of the other monoclonal antibodies, EST 2, 6, 7 and 8. These four competed with each other for binding to thrombin, and all inhibited clotting but not amidase activity. Thrombin binding was not affected by modification of the active site, though formation of the T-AT complex reduced the affinity of binding to EST 6 and EST 8. These monoclonals recognise epitopes in the region of the fibrinogen binding site.     

Prothrombin Salakta : An abnormal prothrombin characterized by a defect in the active site of thrombin

An abnormal prothrombin has been detected in a 17 yr-old female originating from Tunisia. There was no history of excessive bleeding. Prothrombin time and activated partial thromboplastin time were moderately prolonged. Prothrombin activity was 15–18 % when measured using either the classical one-stage and two-stage assays, or assays with Echis carinatus venom or staphylocoagulase, whereas prothrombin antigen was 100 %. In keeping with current nomenclature practices, the abnormal molecule has been designated prothrombin Salakta. The electrophoretic behaviour and calcium binding properties of the abnormal prothrombin did not differ significantly from normal, as assessed by crossed immunoelectro-phoresis. Prothrombin Salakta was isolated by chromatography on DEAE-Sephadex and Dextran sulphate sepharose. Electrophoretic migration of purified prothrombin Salakta on SDS polyacrylamide gels or alkaline disc gels was normal. Upon activation by either bovine factor Xa or Echis carinatus venom, thrombin activity produced by prothrombin Salakta was only 15 % of normal, even when the incubation period was prolonged for 24 hours. The pattern of factor Xa-catalyzed proteolysis of prothrombin Salakta, investigated by SOS polyacrylamide gel electrophoresis, was found to be normal. These results indicated that prothrombin Salakta was characterized by a defective thrombin enzymatic activity. Thrombin Salakta was therefore isolated by heparin-sepharose chromatography. Affinity for heparin and molecular weight of thrombin Salakta were found to be normal. Biological activity of thrombin Salakta, determined by clotting assay, was 535 u/mg versus 3 200 u/mg for normal thrombin. Amidolytic activity of thrombin Salakta parallelled its clotting activity, suggesting that the defect resides either in the catalytic site or in the residues adjacent to the catalytic site and implicated as contact residues, rather than in the fibrinogen recognition site.     

Thrombin induced platelet reactions: Effect of substrates and inhibitors on binding of thrombin and serotonin release

Binding of ¹²⁵I-thrombin to platelets and subsequent serotonin release were confirmed. The binding of unaltered thrombin to platelets was also measured by a new technique using a chromogenic substrate (S-2238). As compared to ¹²⁵I-thrombin, this method gave similar constants for binding to the high affinity binding site, but lower for binding to the low affinity binding site. Furthermore, the results suggest that the platelets have two classes of independent binding sites. Substrates and inhibitors of thrombin inhibited thrombin induced serotonin release, suggesting that the release reaction depends on the proteolytic activity of thrombin. The serotonin release was more inhibited than the binding of thrombin, suggesting that the platelet binding site and the active site of thrombin are located in different parts of the thrombin molecule.     

Hemophilia B with mutations at glycine-48 of factor IX exhibited delayed activation by the factor VIIa-tissue factor complex

Gly-48 is in the conserved DGDQC sequence (residues 47-51 of human factor IX) of the first EGF (EGF-1)-like domain of factor IX. The importance of the Gly-48 is manifested by two hemophilia B patients; factor IXTainan and factor IXMalmo27, with Gly-48 replaced by arginine (designated IXG48R) and valine (IXG48V), respectively. Both patients were CRM+ exhibiting mild hemophilic episodes with 25% (former) and 19% (latter) normal clotting activities. We characterize both factor IX variants to show the roles of Gly-48 and the conservation of the DGDQC sequence in factor IX. Purified plasma and recombinant factor IX variants exhibited approximately 26%-27% normal factor IX's clotting activities with G48R or G48V mutation. Both variants depicted normal quenching of the intrinsic fluorescence by increasing concentrations of calcium ions and Tb3+, indicating that arginine and valine substitution for Gly-48 did not perturb the calcium site in the EGF-1 domain. Activation of both mutants by factor XIa appeared normal. The reduced clotting activity of factors IXG48R and IXG48V was attributed to the failure of both mutants to cleavage factor X: in the presence of only phospholipids and calcium ions, both mutants showed a 4 to approximately 7-fold elevation in Km, and by adding factor VIIIa to the system, although factor VIIIa potentiated the activation of factor X by the mutants factor IXaG48R and factor IXaG48V, a 2 to approximately 3-fold decrease in the catalytic function was observed with the mutant factor IXa's, despite that they bound factor VIIIa on the phospholipid vesicles with only slightly reduced affinity when compared to wild-type factor IXa. The apparent Kd for factor VIIIa binding was 0.83 nM for normal factor IXa, 1.74 nM for IXaG48R and 1.4 nM for IXaG48V. Strikingly, when interaction with the factor VIIa-TF complex was examined, both mutations were barely activated by the VIIa-TF complex and they also showed abnormal interaction with VIIa-TF in bovine thromboplastin-based PT assays. Taken together, our results suggest that mutations at Gly-48 altered the interaction of factor IX with its extrinsic pathway activator (VIIa-TF complex), its macromolecular substrate (factor X), and its cofactor (factor VIIIa).     

Comparative study of the iodination of tyrosines in the amino terminal domain of fibrinogen and in N-DSK and fibrin-N-DSK

Lactoperoxidase catalyzed iodination has been used to probe for differences in surface orientation of tyrosine residues in the amino-terminal disulfide knot (N-DSK) domain of fibrinogen, in N-DSK and in Fb-N-DSK prepared from fibrin. The central region of N-DSK containing the beta chain Tyr 41 and gamma chain Tyr 18 and 32 are much more susceptible to iodination than when an integral part of the fibrinogen molecule. Cleavage of the N-DSK domain from fibrinogen "loosens" up the tertiary structure of N-DSK and allows iodination of its central region. The iodination pattern of comparable tyrosine residues did not change between N-DSK and Fb-N-DSK. This result implies that no significant change occurs in the tertiary structure of N-DSK upon thrombin activation. These results favor the concept that removal of the fibrinopeptides removes a steric hindrance or exposes a binding site for polymerization.     

Location of the multimerin 1 binding site in coagulation factor V: an update

Activated coagulation factor V (FVa) is an important cofactor that accelerates thrombin production. In human blood, 25% of the factor V (FV) is stored in platelets, complexed to the polymeric, FV binding protein multimerin 1 (MMRN1). The light chain of FV is required for MMRN1 binding, and its C2 domain contains a MMRN1 binding site that overlaps phospholipid binding residues essential for FVa procoagulant function. The homologous structures and roles of the FVa light chain C1 and C2 domains led us to investigate if the C1 domain also contains a MMRN1 binding site. The MMRN1 binding properties of FV constructs were tested by modified enzyme-linked immunoassays, before and after thrombin activation. The constructs tested included the combined C1 and C2 domain deleted FV, and B-domain deleted forms of FV containing C1 domain point mutations or combined C1 and C2 domain phospholipid binding site mutations. The MMRN1 binding site in FV/FVa was mapped to a large region that included the C1 domain phospholipid binding residues Y1956 and L1957. The FV construct with combined C1 and C2 domain phospholipid binding site mutations had no MMRN1 binding, highlighting the critical role of the FV C1 and C2 domain phospholipid binding residues in MMRN1 binding. Our data update the information on the structural features of FV and FVa important for MMRN1 binding, and suggest that the extended MMRN1 binding site in the C1 and C2 domains is important for the storage of FV-MMRN1 complexes in platelets.     

The effects of human thrombomodulin on the inactivation of thrombin by its serum inhibitors

Thrombomodulin is an endothelial cell protein which accelerates thrombin-dependent protein C activation by over 1000 fold. In this study, the effect of thrombomodulin on the inactivation of thrombin by its serum inhibitors was evaluated. 125I-thrombin was incubated at 37 degrees C with serum and the resulting complexes separated by SDS-PAGE. Antithrombin III was the major complex formed with some 125I-thrombin bound to heparin cofactor II and higher molecular weight fractions. Inclusion of thrombomodulin at increasing concentrations inhibited 125I-thrombin binding to antithrombin III and the higher molecular weight fractions but had little effect on thrombin-heparin cofactor II complex formation. Similar results were obtained using a purified antithrombin III/heparin cofactor II system. Kinetic studies, using purified antithrombin III, revealed that thrombomodulin acts as a weak competitive inhibitor towards antithrombin III (Ki = 39 nM). We postulate that in the microcirculation, where the ratio of thrombomodulin to antithrombin III is relatively high, thrombin bound to thrombomodulin may be protected from inactivation by antithrombin III and can thus promote efficient activation of protein C.     

Inhibition of thrombin generation in plasma by fibrin formation (Antithrombin I)

The adsorption of thrombin to fibrin during clotting defines "Antithrombin I" activity. We confirmed that thrombin generation in afibrinogenemic or in Reptilase defibrinated normal plasma was higher than in normal plasma. Repletion of these fibrinogen-deficient plasmas with fibrinogen 1 (gamma A/gamma A), whose fibrin has two "low affinity" non-substrate thrombin binding sites, resulted in moderately reduced thrombin generation by 29-37%. Repletion with fibrinogen 2 (gamma'/gamma A), which in addition to low affinity thrombin-binding sites in fibrin, has a "high affinity" non-substrate thrombin binding site in the carboxy-terminal region of its gamma' chain, was even more effective and reduced thrombin generation by 57-67%. Adding peptides that compete for thrombin binding to fibrin [S-Hir53-64 (hirugen) or gamma'414-427] caused a transient delay in the onset of otherwise robust thrombin generation, indicating that fibrin formation is necessary for full expression of Antithrombin I activity. Considered together, 1) the increased thrombin generation in afibrinogenemic or fibrinogen-depleted normal plasma that is mitigated by fibrinogen replacement; 2) evidence that prothrombin activation is increased in afibrinogenemia and normalized by fibrinogen replacement; 3) the severe thrombophilia that is associated with defective thrombin-binding in dysfibrinogenemias Naples I and New York I, and 4) the association of afibrinogenemia or hypofibrinogenemia with venous or arterial thromboembolism, indicate that Antithrombin I (fibrin) modulates thromboembolic potential by inhibiting thrombin generation in blood.     

Different vulnerability of fibrinogen subunits to oxidative/nitrative modifications induced by peroxynitrite: functional consequences

Based on previous studies suggesting that fibrinogen (Fg) might be a potential target for peroxynitrite (PN) action in plasma, we investigated the effects of PN on structure and hemostatic function of Fg in vitro. Using fluorescence and spectrophotometric methods, we estimated that about 0.5, 2 and 8 tyrosine residues per molecule were nitrated following the reaction of Fg at concentration 5.88 muM with 10, 100 and 1000 muM PN, respectively. At the same molar ratios of Fg to PN, about 0.01, 0.19 and 0.34 of tyrosine residues per molecule were oxidized to dityrosine and the amount of carbonyl groups in Fg increased 1.3-, 2,3- and 3.6-fold when compared to control Fg. SDS-PAGE analysis of PN-modified Fg suggests that inter- and intramolecular dityrosine cross-links occur between A alpha chains of Fg. Vulnerability of Fg subunits to oxidative/nitrative modifications induced by PN was different. Within the Fg molecule, mainly alpha C domains as well as D domains (contrary to E domain) undergo the majority of the modifications. Low extent of nitration and oxidation of Fg molecule (induced by 10 microM PN) did not affect its clotting activity and susceptibility to degradation by plasmin. Modification of Fg induced by higher PN concentrations decreased these properties.