Crystal structure of thrombin in a self-inhibited conformation

The activating effect of Na(+) on thrombin is allosteric and depends on the conformational transition from a low activity Na(+)-free (slow) form to a high activity Na(+)-bound (fast) form. The structures of these active forms have been solved. Recent structures of thrombin obtained in the absence of Na(+) have also documented inactive conformations that presumably exist in equilibrium with the active slow form. The validity of these inactive slow form structures, however, is called into question by the presence of packing interactions involving the Na(+) site and the active site regions. Here, we report a 1.87A resolution structure of thrombin in the absence of inhibitors and salts with a single molecule in the asymmetric unit and devoid of significant packing interactions in regions involved in the allosteric slow --> fast transition. The structure shows an unprecedented self-inhibited conformation where Trp-215 and Arg-221a relocate >10A to occlude the active site and the primary specificity pocket, and the guanidinium group of Arg-187 penetrates the protein core to fill the empty Na(+)-binding site. The extreme mobility of Trp-215 was investigated further with the W215P mutation. Remarkably, the mutation significantly compromises cleavage of the anticoagulant protein C but has no effect on the hydrolysis of fibrinogen and PAR1. These findings demonstrate that thrombin may assume an inactive conformation in the absence of Na(+) and that its procoagulant and anticoagulant activities are closely linked to the mobility of residue 215.     

How Na+ activates thrombin--a review of the functional and structural data

Thrombin is the ultimate coagulation factor; it is the final protease generated in the blood coagulation cascade and is the effector of clot formation. Regulation of thrombin activity is thus of great relevance to determining the correct haemostatic balance, with dysregulation leading to bleeding or thrombosis. One of the most enigmatic and controversial regulators of thrombin activity is the monovalent cation Na+. When bound to Na+, thrombin adopts a 'fast' conformation which cleaves all procoagulant substrates more rapidly, and when free of Na+, thrombin reverts to a 'slow' state which preferentially activates the protein C anticoagulant pathway. Thus, Na+-binding allosterically modulates the activity of thrombin and helps determine the haemostatic balance. Over the last 30 years, there has been much research investigating the structural basis of thrombin allostery. Biochemical and mutagenesis studies established which regions and residues are involved in the slow-->fast conformational change, and recently several crystal structures of the putative slow form have been solved. In this article, the biochemical and crystallographic data are reviewed to see if we are any closer to understanding the conformational basis of the Na+ activation of thrombin.     

Formation of soluble fibrin oligomers in purified systems and in plasma.

The kinetic parameters for release of fibrinopeptide A (FPA) from human fibrinogen by thrombin are: Km = 2.3 X 10(-6)M and Vmax. = 1.1 X 10(-10)mol of FPA/s per unit of thrombin; for fibrin formation, Km is similar to that for FPA release, but, the conditions of the present study, Vmax. was approximately half of that for FPA release. The formation of fibrin polymer before the sol-gel transition was studied by gel-permeation chromatography combined with effluent analysis for fibrinogen antigen and residual FPA. Polymer formation in purified fibrinogen incubated with thrombin proceeded as a bimolecular association of exposed sites in a manner predicted by probability calculations and assuming random FPA cleavage. Each oligomer consisted of n molecules of fibrin monomer and two fibrinogen molecules, each of the latter lacking one FPA molecule, i.e. each oligomer, regardless of molecular size, retains two FPA molecules. The addition of 5 mM-CaCl2 to the reaction mixture changed the rate of polymer formation, so that dimer was no longer the prevalent oligomer; in the presence of Ca2+, the trimer was the oligomer in highest concentration. The polymers formed in the presence of calcium were similar in composition to those without, i.e. 2 mol of FPA/mol of oligomer. EDTA-treated plasma samples incubated for short periods of time, 30s or less, with thrombin ranging in concentration up to 1 N.I.H. unit/ml did not form clots during the 10-15 min period of observation until they were applied to the column, though a large proportion of the available FPA was cleaved (maximum 45%). The soluble polymers in plasma were mostly of the high-Mr variety (tetramer and greater); these high-Mr polymers contained less than 2 mol of FPA/mol of polymer, whereas dimer and trimer in plasma were similar to those in the purified systems, i.e. 2 mol of FPA/mol.     

Thrombin-induced fibrinopeptide release from a fibrinogen variant (fibrinogen Sydney I) with an Aalpha Arg-16----His substitution

Fibrinogen, purified from a recently identified case of dysfibrinogenaemia, fibrinogen Sydney I, was shown by thrombin digestion, high-performance liquid chromatography (HPLC) and amino acid analysis to be a heterozygous case of an A alpha Arg-16----His substitution. Kinetic studies have been carried out on the thrombin-induced release of fibrinopeptide A (FPA), fibrinopeptide B (FPB) and the variant peptide [His16]FPA. When thrombin was added to fibrinogen Sydney I at a concentration of 0.2 U/ml release of FPA was rapid and there was a 79-fold reduced rate of release of [His16]FPA, but the rate of release of FPB was not appreciably reduced. In contrast, at lower thrombin concentrations the rate of FPB release was reduced in proportion to the rate of total FPA release, supporting the view that release of fibrinopeptides is a sequential process. The second-order kinetic constant kcat/Km for hydrolysis of the abnormal A alpha chain by thrombin was calculated from Lineweaver-Burk plots to be 16-30-fold less than that for the normal A alpha chain. Molecular modelling studies, using a refined model of the trypsin-pancreatic-trypsin-inhibitor complex have been used to suggest how the histidine at the P1 site can be accommodated within the enzyme hydrophobic active-site pocket.     

Probing the hirudin-thrombin interaction by incorporation of noncoded amino acids and molecular dynamics simulation

Thrombin is a primary target for the development of novel anticoagulants, since it plays two important and opposite roles in hemostasis: procoagulant and anticoagulant. All thrombin functions are influenced by Na+ binding, which triggers the transition of this enzyme from an anticoagulant (slow) form to a procoagulant (fast) form. In previous studies, we have conveniently produced by chemical synthesis analogues of the N-terminal fragment 1-47 of hirudin HM2 containing noncoded amino acids and displaying up to approximately 2700-fold more potent antithrombin activity, comparable to that of full-length hirudin. In the work presented here, we have exploited the versatility of chemical synthesis to probe the structural and energetic properties of the S3 site of thrombin through perturbations introduced in the structure of hirudin fragment 1-47. In particular, we have investigated the effects of systematic replacement of Tyr3 with noncoded amino acids retaining the aromatic nucleus of Tyr, as well as similar hydrophobic and steric properties, but possessing different electronic (e.g., p-fluoro-, p-iodo-, or p-nitro-Phe), charge (p-aminomethyl-Phe), or conformational (homo-Phe) properties. Our results indicate that the affinity of fragment 1-47 for thrombin is proportional to the desolvation free energy change upon complex formation, and is inversely related to the electric dipole moment of the amino acid side chain at position 3 of hirudin. In this study, we have also identified the key features that are responsible for the preferential binding of hirudin to the procoagulant (fast) form of thrombin. Strikingly, shaving at position 3, by Tyr --> Ala exchange, abolishes the differences in the affinity for thrombin allosteric forms, whereas a bulkier side chain (e.g., beta-naphthylalanine) improves binding preferentially to the fast form. These results provide strong, albeit indirect, evidence that the procoagulant (fast) form of thrombin is in a more open and accessible conformation with respect to the less forgiving structure it acquires in the slow form. This view is also supported by the results of molecular dynamics simulations conducted for 18 ns on free thrombin in full explicit water, showing that after approximately 5 ns thrombin undergoes a significant conformational transition, from a more open conformation (which we propose can be related to the fast form) to a more compact and closed one (which we propose can be related to the slow form). This transition mainly involves the Trp148 and Trp60D loop, the S3 site, and the fibrinogen binding site, whereas the S1 site, the Na+-binding site, and the catalytic pocket remain essentially unchanged. In particular, our data indicate that the S3 site of the enzyme is less accessible to water in the putative slow form. This structural picture provides a reasonable molecular explanation for the fact that physiological substrates related to the procoagulant activity of thrombin (fibrinogen, thrombin receptor 1, and factor XIII) orient a bulky side chain into the S3 site of the enzyme. Taken together, our results can have important implications for the design of novel thrombin inhibitors, of practical utility in the treatment of coagulative disorders.     

Crystal structure of the anticoagulant slow form of thrombin

Using the thrombin mutant R77aA devoid of the site of autoproteolytic degradation at exosite I, we have solved for the first time the structure of thrombin free of any inhibitors and effector molecules and stabilized in the Na(+)-free slow form. The slow form shows subtle differences compared with the currently available structures of the Na(+)-bound fast form that carry inhibitors at the active site or exosite I. The most notable differences are the displacement of Asp-189 in the S1 specificity pocket, a downward shift of the 190-193 strand, a rearrangement of the side chain of Glu-192, and a significant shift in the position of the catalytic Ser-195 that is no longer within H-bonding distance from His-57. The structure of the slow form explains the reduced specificity toward synthetic and natural substrates and suggests a molecular basis for its anticoagulant properties.     

The polymerization and thrombin-binding properties of des-(B beta 1-42)-fibrin

Multiple factors affect the thrombin-catalyzed conversion of fibrinogen to fibrin, including: fibrinopeptide (FPA and FPB) release leading to exposure of two types of polymerization domains ("A" and "B," respectively) in the central portion of the molecule, and exposure of a noncatalytic "secondary" thrombin-binding site in fibrin. Fibrinogen containing the FPA sequence but lacking the B beta 1-42 sequence ("des-(B beta 1-42)-fibrinogen"), was compared to native fibrinogen (containing both FPA and FPB) to investigate the role played by B beta 1-42 in the polymerization of alpha-fibrin (i.e. fibrin lacking FPA), to compare reptilase and thrombin cleavage of FPA from fibrinogen, and to explore the location and function of the secondary thrombin-binding site. Electron microscopy of evolving polymer structures (mu, 0.14; pH 7.4) plus turbidity measurements, showed that early thin fibril formation as well as subsequent lateral fibril associations were impaired in des-(B beta 1-42)-alpha-fibrin, thus indicating that the B beta 1-42 sequence contributes to the A polymerization site. Reptilase-activated des-(B beta 1-42)-alpha-fibrin polymerized even more slowly than thrombin-activated des-(B beta 1-42)-alpha-fibrin, differences that disappeared when repolymerization of preformed fibrin monomers was carried out. Since existing data indicate that thrombin releases FPA in a concerted manner, resulting in relatively rapid evolution of fully functional divalent alpha-fibrin monomers, it can be inferred that delayed fibrin assembly of reptilase fibrin is due to slower formation of divalent alpha-fibrin monomers. Thrombin-activated des-(B beta 1-42)-alpha-fibrin polymerized more rapidly at low ionic strength (mu, 0.04) than did native alpha,beta-fibrin, a reversal of their behavior at physiological ionic strength (mu, 0.14). Concomitant measurement of FPA release revealed modest slowing of release at low ionic strength from des-(B beta 1-42)-fibrinogen (t1/2, 36.5 versus 21.5 min) and marked slowing from native fibrinogen (t1/2, 138 versus 22.2 min). This behavior correlated with increased thrombin binding to native alpha,beta-fibrin at low ionic strength, coupled with weak thrombin binding to des-(B beta 1-42)-alpha-fibrin, and indicates that secondary thrombin binding plays an important role in regulating thrombin diffusion and catalytic activity. Des-(B beta 1-42)-fibrinogen lacks or has a markedly defective secondary thrombin-binding site, from which we conclude that the B beta 15-42 sequence in fibrin plays a major role in forming or providing this site.     

Catalytic competence of human alpha- and gamma-thrombin in the activation of fibrinogen and factor XIII

Steady-state kinetic parameters were compared for the action of alpha- and gamma-thrombin on the physiologically important thrombin substrates fibrinogen and factor XIII at 37 degrees C, pH 7.4, and 0.14 M NaCl. gamma-Thrombin, an alpha-thrombin derivative proteolytically cleaved at R-B73 and K-B154, was observed to catalyze the release of fibrinopeptide A (FPA) from fibrinogen with a specificity constant (kcat/Km) of 5 X 10(3) M-1 s-1. This value was approximately 2400-fold lower than the specificity constant for the corresponding alpha-thrombin-catalyzed reaction. The low specificity constant was attributed to an increase in Km and a decrease in kcat for gamma-thrombin-catalyzed release of FPA from fibrinogen. Conversion of alpha-thrombin to gamma-thrombin also resulted in an approximately 800-fold reduction in the specificity constant for thrombin-catalyzed release of fibrinopeptide B (FPB) from fibrin I, as well as a loss in discriminatory power. Whereas alpha-thrombin preferentially released FPA from intact fibrinogen, gamma-thrombin released FPA and FPB from intact fibrinogen at similar rates. In contrast to the large difference in specificity constants observed for alpha- and gamma-thrombin catalysis with fibrin(ogen) as substrate, the specificity constant (2.6 X 10(4) M-1 s-1) observed for gamma-thrombin-catalyzed release of activation peptide from factor XIII was only 5-fold lower than the corresponding value for the alpha-thrombin-catalyzed reaction. Additionally, the promotion of factor XIII activation by fibrin characteristic of the alpha-thrombin-catalyzed reaction did not occur in the gamma-thrombin-catalyzed reaction.(ABSTRACT TRUNCATED AT 250 WORDS)     

Hereditary dysfibrinogenaemia: structural and functional studies on three fibrinogen variants

Dysfunctional fibrinogens occurring in three unrelated families were studied. Fibrinogen Erfurt I consists of B beta chains with a slightly lower molecular mass than normal. The same structural abnormality was also detected in fibrin beta chains. The variant is present in platelets too. Fibrinogen Erfurt II is characterized by the absent thrombin-induced release of FPA. With fibrinogen Berlin cleavage of the B beta chains by thrombin is slow but complete. All carriers of the three abnormal fibrinogens seem to be heterozygous for the underlying mutant gene.     

Crystal structure of the thrombin mutant D221A/D222K: the Asp222:Arg187 ion-pair stabilizes the fast form

The thrombin mutant D221A/D222K (ARK) does not bind Na+ and has interesting functional properties intermediate between those of the slow and fast forms of wild type. We solved the X-ray crystal structure of ARK bound at exosite I with a fragment of hirudin at 2.4-A resolution. The structure shows a slight collapse of the 186 and 220 loops into the Na+ binding site due to disruption of the Asp222:Arg187 ion-pair. The backbone O atoms of Arg221a and Lys224 are shifted into conformations that eliminate optimal interaction with Na+. A paucity of solvent molecules in the Na+ binding site is also noted, by analogy to what is seen in the structure of the slow form. These findings reinforce the crucial role of the Asp222:Arg187 ion-pair in stabilizing the fast form of thrombin.     

Murine thrombin lacks Na+ activation but retains high catalytic activity

Human thrombin utilizes Na+ as a driving force for the cleavage of substrates mediating its procoagulant, prothrombotic, and signaling functions. Murine thrombin has Asp-222 in the Na+ binding site of the human enzyme replaced by Lys. The charge reversal substitution abrogates Na+ activation, which is partially restored with the K222D mutation, and ensures high activity even in the absence of Na+. This property makes the murine enzyme more resistant to the effect of mutations that destabilize Na+ binding and shift thrombin to its anticoagulant slow form. Compared with the human enzyme, murine thrombin cleaves fibrinogen and protein C with similar k(cat)/K(m) values but activates PAR1 and PAR4 with k(cat)/K(m) values 4- and 26-fold higher, respectively. The significantly higher specificity constant toward PAR4 accounts for the dominant role of this receptor in platelet activation in the mouse. Murine thrombin can also cleave substrates carrying Phe at P1, which potentially broadens the repertoire of molecular targets available to the enzyme in vivo.     

Hirudin binding reveals key determinants of thrombin allostery

Thrombin exists in two allosteric forms, slow (S) and fast (F), that recognize natural substrates and inhibitors with significantly different affinities. Because under physiologic conditions the two forms are almost equally populated, investigation of thrombin function must address the contribution from the S and F forms and the molecular origin of their differential recognition of ligands. Using a panel of 79 Ala mutants, we have mapped for the first time the epitopes of thrombin recognizing a macromolecular ligand, hirudin, in the S and F forms. Hirudin binding is a relevant model for the interaction of thrombin with fibrinogen and PAR1 and is likewise influenced by the allosteric S-->F transition. The epitopes are nearly identical and encompass two hot spots, one in exosite I and the other in the Na+ site at the opposite end of the protein. The higher affinity of the F form is due to the preferential interaction of hirudin with Lys-36, Leu-65, Thr-74, and Arg-75 in exosite I; Gly-193 in the oxyanion hole; and Asp-221 and Asp-222 in the Na+ site. Remarkably, no correlation is found between the energetic and structural involvements of thrombin residues in hirudin recognition, which invites caution in the analysis of protein-protein interactions in general.     

Fibrinogen and the early stages of polymerization to fibrin as studied by dynamic laser light scattering

Human fibrinogen and the polymerization of fibrin after activation by the enzymes, thrombin and Batroxobin, were studied by means of dynamic laser light scattering (DLS). The apparent diffusion constant, D, for fibrinogen was measured and has a value of (1.80 +/- 0.42) X 10(-7) cm2 X s-1. D was found to contain contributions from the translational diffusion constant (Dt) as well as from the rotational diffusion constant (Dr). A comparison between experimental and calculated values of Dr and Dt suggests that fibrinogen in the absence of added Ca2+ expresses a certain degree of flexibility, while it is straightened in the presence of added Ca2+. The time dependence of D showed periodic oscillations, while the average D values decreased with time. Thrombin and Batroxobin caused similar behaviour of D. The period length was related to the enzyme concentration, clotting time (Ct) and the rate of release of fibrinopeptide A (FPA). No periodic oscillations were observed in experiments where the enzyme was replaced by saline, or in experiments using a dysfunctional fibrinogen (fibrinogen Aarhus) which displayed slow rates of FPA-release and polymerization. We propose that the periodic oscillations in a system far from equilibrium may be explained by conformational changes occurring in the fibrinogen molecule during enzyme activation and polymerization.     

Crystal structure of anticoagulant thrombin variant E217K provides insights into thrombin allostery

Thrombin is the ultimate protease of the blood clotting cascade and plays a major role in its own regulation. The ability of thrombin to exhibit both pro- and anti-coagulant properties has spawned efforts to turn thrombin into an anticoagulant for therapeutic purposes. This quest culminated in the identification of the E217K variant through scanning and saturation mutagenesis. The antithrombotic properties of E217K thrombin are derived from its inability to convert fibrinogen to a fibrin clot while maintaining its thrombomodulin-dependent ability to activate the anticoagulant protein C pathway. Here we describe the 2.5-A crystal structure of human E217K thrombin, which displays a dramatic restructuring of the geometry of the active site. Of particular interest is the repositioning of Glu-192, which hydrogen bonds to the catalytic Ser-195 and which results in the complete occlusion of the active site and the destruction of the oxyanion hole. Substrate binding pockets are further blocked by residues previously implicated in thrombin allostery. We have concluded that the E217K mutation causes the allosteric inactivation of thrombin by destabilizing the Na(+) binding site and that the structure thus may represent the Na(+)-free, catalytically inert "slow" form.     

Rapid kinetics of Na+ binding to thrombin

The kinetic mechanism of Na(+) binding to thrombin was resolved by stopped-flow measurements of intrinsic fluorescence. Na(+) binds to thrombin in a two-step mechanism with a rapid phase occurring within the dead time of the spectrometer (<0.5 ms) followed by a single-exponential slow phase whose k(obs) decreases hyperbolically with increasing [Na(+)]. The rapid phase is due to Na(+) binding to the enzyme E to generate the E:Na(+) form. The slow phase is due to the interconversion between E(*) and E, where E(*) is a form that cannot bind Na(+). Temperature studies in the range from 5 to 35 degrees C show significant enthalpy, entropy, and heat capacity changes associated with both Na(+) binding and the E to E(*) transition. As a result, under conditions of physiologic temperature and salt concentrations, the E(*) form is negligibly populated (<1%) and thrombin is almost equally partitioned between the E (40%) and E:Na(+) (60%) forms. Single-site Phe mutations of all nine Trp residues of thrombin enabled assignment of the fluorescence changes induced by Na(+) binding mainly to Trp-141 and Trp-215, and to a lesser extent to Trp-148, Trp-207, and Trp-237. However, the fast phase of fluorescence increase is influenced to different extents by all Trp residues. The distribution of these residues over the entire thrombin surface demonstrates that Na(+) binding induces long-range effects on the structure of the enzyme as a whole, contrary to the conclusions drawn from recent structural studies. These findings elucidate the mechanism of Na(+) binding to thrombin and are relevant to other clotting factors and enzymes allosterically activated by monovalent cations.     

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.     

Inhibitors of Na+/H+ exchange block stimulus-provoked arachidonic acid release in human platelets. Selective effects on platelet activation by epinephrine, ADP, and lower concentrations of thrombin

We have observed previously that removal of extraplatelet Na+ blocks platelet secretion of dense granule contents in response to epinephrine, ADP, and 0.004 unit/ml thrombin, all agents which must mobilize arachidonic acid for its subsequent conversion to cyclooxygenase products in order to elicit platelet secretion. The present studies demonstrate that removal of extraplatelet Na+ blocks arachidonic acid mobilization in response to epinephrine, ADP, and 0.004 unit/ml thrombin without altering arachidonic acid conversion to thromboxane A2. The data also provide several lines of evidence which suggest that the blockade of arachidonic acid release due to removal of extraplatelet Na+ is a manifestation of blockade of Na+/H+ exchange system. 1) There is a concentration-dependent effect of extraplatelet Na+ (EC50 congruent to 55 mM) on [3H]arachidonic acid release such that mobilization is observed when [Na+]o greater than [Na+]i. 2) Increasing extraplatelet [H+] (i.e. decreasing extraplatelet pH from pH 7.35 to 6.8) causes a concentration-dependent decline in stimulus-provoked [3H]arachidonic acid release. 3) Ethylisopropylamiloride and other potent 5-amino analogs of amiloride block [3H]arachidonic acid release with a potency that parallels their effects on Na+/H+ exchange in other cellular systems. None of the above manipulations alter primary aggregation induced by epinephrine, ADP, or 0.004 unit/ml thrombin, indicating that stimulus-receptor binding, subsequent exposure of fibrinogen receptors, and fibrinogen-mediated platelet-platelet cross-linking are not significantly inhibited by [3H]arachidonic acid release in response to greater than 0.1 unit/ml thrombin, a stimulus that can elicit platelet secretion in the absence of products of the cyclooxygenase pathway. Therefore, Na+/H+ exchange may selectively modulate arachidonic acid mobilization in response to the so-called "weak agonists," agonists that require this mobilization to effect vigorous platelet aggregation and dense granule secretion.     

The impact of delayed fibrinopeptide-A release on fibrin structure. Studies of an abnormal fibrinogen

The impact of delayed fibrinopeptide-A release on polymerization and structure of fibrin gels was studied utilizing a heterozygously transmitted variant fibrinogen. An arginine to histidine substitution at position 16 of the alpha chain of the abnormal fibrinogen delayed release of an abnormal fibrinopeptide-A (A) by thrombin and completely blocked release of A by reptilase. When clotted with thrombin, patient fibrin formed more slowly than normal fibrin, but clottability was normal and gel fiber mass/length ratios were decreased less than 10%. Gels formed with reptilase clotted slowly, demonstrated reduced clottability, but had normal fiber mass/length ratios. Reptilase clotted the normal but not the variant component of the patient fibrinogen. Thrombin-induced cleavage of fibrinopeptide-B prior to A occurred in these experiments, but polymerization of this species beyond trimers has been reported to be minimal under the conditions used. With time, A is removed by thrombin resulting in the slow production of normal fibrin monomer from the abnormal component. These monomers subsequently polymerize. The minimal change in gel fiber size caused by slow A release implies that fibrin fiber size is primarily a function of ionic environment and not of the sequence of peptide release.     

Sodium ions as the effector of catalytic action of alpha-thrombin

A process of thrombin interaction with synthetic and natural substrates in the presence of Na+ ions has been analyzed in the survey. Molecular bases of this interaction have been presented, interrelation between the structure and function of thrombin has been noted; the nature of the unique site of its active centre which determines high thrombin affinity for the substrates and increase of its catalytic activity defined by the term of "specificity to univalent cations" have been considered in detail. Na+ ions play the role of allosteric effector in realization of two informational states of thrombin which penform, respectively, two fundamental and competing functions in the process of hemostasis. The molecular basis of the process of Na+ binding with thrombin is rather simple and depends only on the single site which importance for the enzyme function is marked by numerous investigations of a number of authors, and it is shown that Na(+)-binding site is distributed in the other zone of thrombin molecule as compared to exosites I and II, which do not take part in Na(+)-binding and allosteric transduction. Considerable attention was given to conformational conversions of a thrombin molecule caused by Na+ ions binding. It was shown that the transition slow <--> fast of the enzyme forms leads to formation of the ion pair Arg-187: Asp-222, optimal orientation of Asp-189 and Ser-195 for binding of substrates and considerable shift of the lateral chain Glu-192 determined by the disturbance of the lattice of water molecules which connects Na(+)-binding site with aminoacid Ser-195 of the active centre of the enzyme. New data have been presented which indicate that the changes in the lattice of water molecules and allosteric nucleus of Na(+)-binding site of the enzyme are the basic link of raising the affinity between the thrombin and substrate and mechanism of the enzyme activation by Na(+)-ions. The survey touches some problems of creation of allosteric inhibitors of thrombin which can take essential effect on Na(+)-binding site and favor stabilization of the anticoagulant slow-form of thrombin, and of enzyme rational mutants with selective specificity in respect of protein C which display effective and safe anticoagulant and antithrombotic effects in vivo.     

Inhibition of the enzymatic activity of thrombin by concanavalin A

Concanavalin A, a carbohydrate lectin derived from the jack bean, prolongs the thrombin clotting time of human plasma or purified fibrinogen. Prolongation is due to delay in peptide release from fibrinogen. The rate of fibrin monomer polymerization is not affected. Hydrolysis of protamine sulfate by thrombin is inhibited by concanavalin A. All inhibitory effects are prevented by α-methyl-D-mannoside. Concanavalin A does not delay clotting of fibrinogen by reptilase (releases fibrinopeptide A only) or by Ancistrodon contortrix contortrix (releases fibrinopeptide B initially followed by a small amount of A). It is concluded that concanavalin A binds to a carbohydrate on the thrombin molecule thus inhibiting its enzymatic activity.