Production, properties, and thrombin inhibitory mechanism of hirudin amino-terminal core fragments

Hirudin, a thrombin-specific inhibitor, comprises a compact amino-terminal core domain (residues 1-52) and a disordered acidic carboxyl-terminal tail (residues 53-65). An array of core fragments were prepared from intact recombinant hirudin by deletion of various lengths of its carboxyl-terminal tail on selective enzymatic cleavage. Hir1-56 and Hir1-53 were produced by pepsin digestion at Phe56-Glu57 and Asp53-Gly54. Hir1-52 was generated by Asp-N cleavage at Asn52-Asp53. Hir1-49 was prepared by cleavage of Gln49-Ser50 by chymotrypsin, elastase, and thermolysin. In addition, Hir1-62 (containing part of the carboxyl-terminal tail) was derived from Hir1-65 by selective removal of the three carboxyl-terminal amino acids using carboxypeptidase A. Hirudin amino-terminal core fragments were stable at extreme pH (1.47 and 12.6), high temperature (95 degrees C), and resistant to attack by various proteinases. For instance, following 24-h incubation with an equal weight of pepsin, the covalent structure of Hir1-52 remained intact and its anticoagulant activity unaffected. Unlike intact hirudin (Hir1-65) the inhibitory potency of which is a consequence of concerted binding of its amino-terminal and carboxyl-terminal domains to the active site and the fibrinogen recognition site of thrombin, the core fragments block only the active site of thrombin with binding constants of 19 nM (Hir1-56), 35 nM (Hir1-52), and 72 nM (Hir1-49). As an anticoagulant Hir1-56 is about 2-, 4-, and 30-fold more potent (on a molar basis) than Hir1-52, Hir1-49, and Hir1-43, respectively. Hir1-56 was also about 15-fold more effective than the most potent carboxyl-terminal fragment of hirudin, sulfated-Hir54-65, although they bind to independent sites on thrombin. The potential advantages of hirudin core fragments as antithrombotic agents are discussed in this report.     

Deciphering the structural elements of hirudin C-terminal peptide that bind to the fibrinogen recognition site of alpha-thrombin

The C-terminal peptide of a hirudin acts as an anticoagulant by binding specifically to a noncatalytic (fibrinogen recognition) site of thrombin. This binding has been shown to shield five spatially distant lysines of the thrombin B-chain (Lys21, Lys65, Lys77, Lys106, and Lys107). It was also demonstrated that modification of the sequence of the hirudin C-terminal peptide invariably diminished its anticoagulant activity. The major object of this study is to investigate how the decreased activity of the modified hirudin C-terminal peptide is reflected by the change of its binding properties to these five lysines of thrombin. A synthetic peptide representing the last 12 C-terminal amino acids of hirudin (Hir54-65) was (1) truncated from both its N-terminal and its C-terminal ends, or (2) substituted with Gly along residues 57-62, or (3) chemically modified to add (sulfation at Tyr63) or abolish (Asp and Glu modification with carbodiimide/glycinamide) its negatively charged side chains. The binding characteristics of these peptides to thrombin were investigated by chemical methods, and their corresponding anticoagulant activities were studied. Our results demonstrated the following: (1) the anticoagulant activities of hirudin C-terminal peptides were quantitatively related to their abilities to shield the five identified lysines of thrombin. The most potent peptide was sulfated Hir54-65 (S-Hir54-65) with an average binding affinity to the five lysines of 120 nM. A heptapeptide (Hir54-60) also displayed anticoagulant activity and thrombin binding ability at micromolar concentrations. (2) All active hirudin C-terminal peptides regardless of their sizes and potencies were shown to be capable of shielding the five lysines of thrombin.(ABSTRACT TRUNCATED AT 250 WORDS)     

Inhibition of thrombin by synthetic hirudin peptides

To investigate the role of different regions of hirudin in the interaction with the proteinase thrombin, segments of hirudin containing 15-51 residues were synthesized. The C-terminal segment 40-65 inhibited the fibrinogen clotting activity of thrombin but not amidolysis of tosyl-Gly-Pro-Arg-p-nitroanilide. Central peptide 15–42 was insoluble at pH 7, but peptide 15-65 inhibited fibrinogen clotting and amidolysis to an equal extent. The N-terminal loop peptide 1-15 had no inhibitory activity and did not affect the potency of peptide 15-65. These data suggest that the central region inhibits catalysis.     

Anticoagulant activity of synthetic hirudin peptides

Synthetic peptides based on the COOH-terminal 21 residues of hirudin were prepared in order to 1) evaluate the role of this segment in hirudin action toward thrombin, 2) define the shortest peptide derivative with anticoagulant activity, and 3) investigate the role of tyrosine sulfation in the peptides' inhibitory activities. A hirudin derivative of 20 amino acids, Hir45-64 (derived from residues 45-64 of the hirudin polypeptide), was found to effect a dose-dependent increase in the activated partial thromboplastin time (APTT) of normal human plasma but to have no measurable inhibitory activity toward thrombin cleavage of a tripeptidyl p-nitroanilide substrate. Anticoagulant activity in hirudin derivatives was comparable in peptides of 20, 16, and 12 residues truncated from the NH2 terminus. Additional truncated peptides prepared by synthesis and carboxypeptidase treatment reveal that the minimal sequence of a hirudin peptide fragment with maximal anticoagulant activity is contained within the sequence: NH2-Asn-Gly-Asp-Phe-Glu-Glu-Ile-Pro-Glu-Glu-Tyr-Leu-COOH. The 12-residue derivative thus identified was reacted with dicyclohexylcarbodiimide in the presence of sulfuric acid to yield a Tyr-sulfated peptide, S-Hir53-64. By comparison to unsulfated peptide, S-Hir53-64 was found to contain a specific inhibitory activity enhanced by one order of magnitude toward increase in APTT and to effect a dose-dependent increase in thrombin time of normal human plasma to yield a 4-fold increase in thrombin time with 2.5 micrograms/ml peptide using 0.8 units/ml alpha-thrombin. Comparison of S-Hir53-64 to hirudin in thrombin time and APTT assays reveals a 50-fold difference in molar specific activities toward inhibition of thrombin. Comparison of antithrombin activities of S-Hir53-64 using a variety of animal thrombins demonstrates greatest inhibitory activity toward murine, rat, and human enzymes and a 10-fold reduced activity toward bovine thrombin.     

Antithrombin properties of C-terminus of hirudin using synthetic unsulfated N alpha-acetyl-hirudin45-65

Unsulfated N alpha-acetyl-hirudin45-65 (MDL 27 589), which corresponds to the C-terminus of hirudin1-65, was synthesized by solid-phase methods. The synthetic peptide was able to inhibit fibrin formation and the release of fibrinopeptide A from fibrinogen by thrombin. The catalytic site of thrombin was not perturbed by the synthetic peptide as H-D-Phe-Pip-Arg-pNA hydrolysis (amidase activity) was not affected. The binding of synthetic peptide and thrombin was assessed by isolation of the complex on gel-filtration chromatography. A single binding site with a binding affinity (Ka) of approx. 1.0 X 10(5) M-1 was observed for thrombin-hirudin45-65 interaction. The data suggest that the C-terminal residues 45-65 of hirudin contain a binding domain which recognizes thrombin and yet does not bind to the catalytic site of the enzyme.     

The region of the thrombin receptor resembling hirudin binds to thrombin and alters enzyme specificity.

A thrombin receptor has recently been cloned and the sequence deduced. The sequence reveals a thrombin cleavage site that accounts for receptor activation. The receptor also has an acidic region with some similarities to the carboxyl-terminal region of the leech thrombin inhibitor, hirudin. Synthetic peptides corresponding to the receptor cleavage site (residues 38-45), the hirudin-like domain (residues 52-69), and the covalently associated domains (residues 38-64) were evaluated for their ability to bind to thrombin. Peptides 38-45 and 38-64 were competitive inhibitors of thrombin's chromogenic substrate activity (Ki = 0.96 mM and 0.6 microM, respectively. Residues 52-69 altered the chromogenic substrate specificity, resulting in accelerated cleavage of some substrates and inhibited cleavage of others. The same peptide binds to thrombin and alters the fluorescence emission intensity of 5-dimethylaminonaphthalene-1-sulfonyl (dansyl)-thrombin in which the dansyl is attached directly to the active site serine (Kd = 32 +/- 7 microM). Residues 52-69 displace the carboxyl-terminal peptide of hirudin, indicating that they share a common binding site in the anion exosite of thrombin. These data suggest that the thrombin receptor has high affinity for thrombin due to the presence of the hirudin-like domain and that this domain alters the specificity of thrombin. This change in specificity may account for the ability of the receptor to serve as an excellent thrombin substrate despite the presence of an Asp residue in the P3 site, which is normally inhibitory to thrombin activity.     

Bifunctional thrombin inhibitors based on the sequence of hirudin45-65

The interaction of alpha-thrombin with the hirudin (HV1) fragment N alpha-acetyl desulfo hirudin45-65 (P51) was investigated. Kinetic analysis revealed that P51 inhibits the proteolysis of a tripeptidyl substrate with Ki = 0.72 +/- 0.13 and 0.11 +/- 0.03 microM for bovine and human alpha-thrombins, respectively. The inhibition was partially competitive, affecting substrate binding to the enzyme-inhibitor complex by a factor alpha = 2 (bovine) and alpha = 4 (human) characteristic of hyperbolic inhibitors. P51 also inhibited thrombin-induced fibrin clot formation with IC50 values of 0.94 +/- 0.20 and 0.058 +/- 0.006 microM for bovine and human alpha-thrombins, respectively. The enhanced antithrombin activity for human thrombin could be attributed to species variations in the putative auxiliary "anion" exosite since N alpha-acetyl desulfo hirudin55-65 displayed the same rank order of potency shift in a clotting assay without inhibiting the amidolytic activity of either enzyme. From these observations, a potent thrombin inhibitor was designed having modified residues corresponding to the P1 and P3 recognition sites. N alpha-Acetyl[D-Phe45, Arg47] hirudin45-65 (P53) emerged as a pure competitive inhibitor with a Ki = 2.8 +/- 0.9 nM and IC50 = 4.0 +/- 0.8 nM (human alpha-thrombin) and is designated as a "bifunctional" inhibitor. Its enhanced potency could be explained by a cooperative intramolecular interaction between the COOH-terminal domain of the inhibitor and the auxiliary exosite of thrombin on the one hand, and the modified NH2-terminal residues with the catalytic site on the other.     

The structure of a complex of bovine alpha-thrombin and recombinant hirudin at 2.8-A resolution.

Crystals of the complex of bovine alpha-thrombin with recombinant hirudin variant 1 have space group C222(1) with cell constants a = 59.11, b = 102.62, and c = 143.26 A. The orientation and position of the thrombin component was determined by molecular replacement and the hirudin molecule was fit in 2 magnitude of Fo - magnitude of Fc electron density maps. The structure was refined by restrained least squares and simulated annealing to R = 0.161 at 2.8-A resolution. The binding of hirudin to thrombin is generally similar to that observed in the crystals of human thrombin-hirudin. Several differences in the interactions of the COOH-terminal polypeptide of hirudin, specifically of residues Asp-55h, Phe-56h, Glu-57h, and Glu-58h, and a few differences in the interactions of the hirudin core, specifically of residues Asp-5h, Ser-19h, and Asn-20h, with thrombin from human thrombin-hirudin suggest that there is some flexibility in the binding of these 2 molecules. Most of the residues in the 9 subsites that bind fibrinopeptide A7-16 to thrombin also interact with the NH2-terminal domain of hirudin. The S1 subsite is a notable exception in that only 1 of its 6 residues, namely Ser-214, interacts with hirudin. The only difference between human and bovine thrombins that appears to influence the binding of hirudin is the replacement of Lys-149E by an acidic glutamate in the bovine enzyme.     

Chimeric antithrombin peptide. Characterization of an Arg-Gly-Asp (RGD)- and hirudin carboxyl terminus-containing synthetic peptides

We investigated the properties of an artificial chimeric peptide that contains an Arg-Gly-Asp (RGD)-tripeptide, the versatile cell recognition signal of extracellular matrix protein components, coupled to a carboxyl-terminal fragment of the highly specific alpha-thrombin inhibitor, hirudin (residues 53-64): WGRGDSANGDFEEIPEEYL (RGD-hirudin53-64). Hirudin53-64 and RGD-hirudin53-64 inhibited the fibrinogen clotting activity of alpha-thrombin and prolonged the activated partial thromboplastin time of human plasma. In addition, both peptides afforded total protection to thrombin from trypsionolysis. Neither hirudin53-64 nor RGD-hirudin53-64 dramatically interfered with the thrombin-antithrombin inhibition reaction either in the absence or presence of added heparin. alpha-Thrombin-induced platelet aggregation was effectively inhibited by hirudin53-64 and RGD-hirudin53-64. Unlike hirudin53-64, RGD-hirudin53-64 in solution inhibited integrin-mediated endothelial cell and fibroblast cell attachment to polystyrene wells in the presence of fetal bovine serum. Collectively, our results demonstrate that RGD-hirudin53-64 has anticoagulant/antiplatelet aggregation activity attributable to its hirudin sequence and integrin-directed cell attachment activity due to its RGD site. Our results suggest that this chimeric motif may serve as a prototype for a new class of anticoagulants where an integrin-specific sequence "targets" the peptide to a cell (ultimately through the platelet integrin alpha IIb beta 3) trapped amid a thrombus with ensuing proteinase inhibition.     

Characterization of the interactions of a bifunctional inhibitor with alpha-thrombin by molecular modelling and peptide synthesis.

A potent thrombin inhibitor, [D-Phe45, Arg47] hirudin 45-65, that contains an active site-directed sequence D-Phe-Pro-Arg-Pro, an exosite specific fragment hirudin 55-65 (H55-65) and a linker portion hirudin 49-54, was designed based on the hirudin sequence [DiMaio et al. (1990) J. Biol. Chem., 265, 21698-21798]. A three-dimensional model of the complex between the B-chain of human thrombin and the inhibitor [D-Phe45, Arg47] hirudin 45-65 was constructed using molecular modelling starting from the X-ray C alpha coordinates of the thrombin-hirudin complex and the NMR-derived structure of the thrombin-bound hirudin 55-65. The contribution of the H49-54 fragment to the thrombin-inhibitor interaction was deduced by examining a series of analogs containing single glycine substitution and analogs with reduced number of residues within the linker. The results were consistent with the molecular modelling observations i.e. the H49-54 fragment serves the role of a spacer in the binding interaction and could be replaced by four glycine residues. The studies on the interaction of the exosite-directed portion of the inhibitor with thrombin using a series of synthetic H55-65 analogs demonstrated that residues AspH55 to ProH60 play a major role in binding to human thrombin where the side chains of PheH56, IleH59 and GluH57 showed critical contributions. Molecular modelling suggested that these side chains may contribute to inter- and intramolecular hydrophobic and electrostatic interactions, respectively.     

The C-terminal binding domain of hirullin P18. Antithrombin activity and comparison to hirudin peptides

Hirullin P18 is a 61-amino acid hirudin-related protein having potent antithrombin activity. Similar to hirudin, it contains a highly acidic C-terminus, but has a significantly different sequence from any other known hirudin variant. The present study demonstrates that the C-terminal fragment acetyl-hirullin P18(41-62) [corrected] possesses an antithrombin potency similar to that of acetyl-desulfatohirudin(45-65). Additionally, like the hirudin fragment analog, it inhibits fibrin-clot formation by binding to a non-catalytic site on thrombin. Sequential shortening of the hirullin P18 C-terminal fragment demonstrates the critical nature of Phe51, which corresponds to the important Phe56 residue of hirudin. Although the sequences of hirullin P18(54-61) and hirudin(59-65) have substantial differences, the C-terminal functional domain represented by hirullin P18(50-61) appears to be comparable to hirudin(55-65) in terms of its functional role in antithrombin activity.     

Thrombin-bound conformation of the C-terminal fragments of hirudin determined by transferred nuclear Overhauser effects

The interaction of the C-terminal fragments (residues 52-65 and 55-65) of the thrombin-specific inhibitor hirudin with bovine thrombin was studied by use of one- and two-dimensional NMR techniques in aqueous solution. Thrombin induces specific line broadening of the proton resonances of residues Asp(55) to Gln(65) of the synthetic hirudin fragments H-Asn-Asp-Gly-Asp(55)-Phe-Glu-Glu-Ile-Pro-Glu-Glu-Tyr(63)-Leu-Gln-COOH and acetyl-Asp(55)-Phe-Glu-Glu-Ile-Pro-Glu-Glu-Tyr(63)-Leu-Gln-COOH. This demonstrates that residues 55-65 are the predominant binding site of hirudin fragments with thrombin. Hirudin fragments take on a well-defined structure when bound to thrombin as indicated by several long-range transferred NOEs between the backbone and side-chain protons of the peptides, but they are not structured when free in solution. Particularly, transferred NOEs exist between the alpha CH proton of Glu(61) and the NH proton of Leu(64) [d alpha N(i,i+3)], between the alpha CH proton of Glu(61) and the beta CH2 protons of Leu(64) [d alpha beta(i,i+3)], and between the alpha CH proton of Glu(62) and the gamma CH2 protons of Gln(65) [d alpha gamma(i,i+3)]. These NOEs are characteristic of an alpha-helical structure involving residues Glu(61) to Gln(65). There are also NOEs between the side-chain protons of residues Phe(56), Ile(59), Pro(60), Tyr(63), and Leu(64). Distance geometry calculations suggest that in the structure of the thrombin-bound hirudin peptides all the charged residues lie on the opposite side of a hydrophobic cluster formed by the nonpolar side chains of residues Phe(56), Ile(59), Pro(60), Tyr(63), and Leu(64).     

Use of fragments of hirudin to investigate thrombin-hirudin interaction

Site-directed mutagenesis was used to create hirudin in which Asn52 was replaced by methionine. Cyanogen bromide cleavage at this unique methionine resulted in two fragments. These fragments have been used to study the kinetic mechanism of the inhibition of thrombin by hirudin and to identify areas of the two molecules which interact with each other. The binding of the C-terminal fragment (residues 53-65) to thrombin resulted in a decrease in the Michaelis constant for the substrate D-phenylalanylpipecolylarginyl-p-nitroanilide (DPhe-Pip-Arg-NH-Ph). The N-terminal fragment (residues 1-52) was a competitive inhibitor of thrombin. There was a small amount of cooperativity in the binding of the two fragments. Whereas hirudin and its C-terminal fragment protected alpha-thrombin against cleavage by trypsin, the N-terminal fragment did not. Hirudin and the N-terminal fragment completely prevented the cleavage of alpha-thrombin by pancreatic elastase while the C-terminal fragment afforded a lesser degree of protection. The results of these experiments with trypsin and elastase are discussed in terms of interaction areas on thrombin and hirudin.     

Identification of regions of alpha-thrombin involved in its interaction with hirudin

The contributions of various regions of human alpha-thrombin to the formation of the tight complex with hirudin have been assessed by using derivatives of thrombin. alpha-Thrombin in which the active-site serine was modified with diisopropyl fluorophosphate was able to bind hirudin, but its affinity for hirudin was decreased by 10(3)-fold compared to unmodified alpha-thrombin. Modification of the active-site histidine with D-Phe-Pro-Arg-CH2Cl resulted in a form of thrombin with a 10(6)-fold reduced affinity for hirudin. gamma-Thrombin is produced by proteolytic cleavage of alpha-thrombin in two surface loops corresponding to residues 65-83 and 146-150 in alpha-chymotrypsin [Berliner, L. J. (1984) Mol. Cell. Biochem. 61, 159-172; Birktoft, J. J., & Blow, D. M. (1972) J. Mol. Biol. 68, 187-240]. The gamma-thrombin-hirudin complex had a dissociation constant that was 10(6)-fold higher than that of alpha-thrombin. Treatment of alpha-thrombin with pancreatic elastase resulted in a form of thrombin only cleaved in the loop corresponding to residues 146-150 in alpha-chymotrypsin, and this form of thrombin had only a slightly reduced affinity for hirudin. By using limited proteolysis with trypsin, it was possible to isolate beta-thrombin which contained a single cleavage in the loop corresponding to residues 65-83 in alpha-chymotrypsin. This form of thrombin had a 100-fold decrease in affinity for hirudin. Kinetic analysis of the binding of hirudin to beta-thrombin indicated that the 100-fold decrease in affinity was predominantly due to a decrease in the rate of association of the two molecules.(ABSTRACT TRUNCATED AT 250 WORDS)     

Systematic study of the substituted active C-terminus of hirudin.

Hirudin, a potent clinical thrombin inhibitor from Hirudo medicinalis, consists of 65 amino acids in a single chain. In this paper, we systematically synthesize a series of C-terminal (desulfo hirudin45-65) peptides substituted by 20 natural L-amino acids via the Multipin method. The resulting peptide library is subsequently screened using an alpha-thrombin-mediated fibrinogen clotting assay and alpha-thrombin-induced amidolytic hydrolysis assay.     

Analysis of the secondary structure of hirudin and the mechanism of its interaction with thrombin

Highly purified hirudin with a specific activity of 13,950 antithrombin units/mg was isolated from a commercial preparation by reversed-phase chromatography. The circular dichroism (CD) spectrum of hirudin was investigated and it was found that the spectrum cannot be accounted for solely in terms of the traditional three components of peptide backbone. It was also found that the CD spectrum of the thrombin-hirudin complex was not additive with respect to the individual spectra of thrombin and hirudin. This deviation from additivity was significant between 210 and 225 nm, indicating alterations in the secondary structures of the proteins during complex formation. When thrombin was titrated with hirudin, the spectral deviation from additivity was sigmoidal, suggesting the cooperative nature of the binding process. Gel filtration of the thrombin-hirudin mixture showed no molecular species greater than a 1:1 complex (Mr 45,500), but gel filtration of free hirudin showed a multimeric form (Mr 51,300) under the same experimental conditions. It is concluded that the cooperative nature of the binding process is due to the binding of thrombin molecules to the multimeric form of hirudin. This initial binding occurs with little or no change in the CD spectrum. In the second step, the multiple complex dissociates to form 1:1 complexes, resulting in larger conformational changes and a considerable increase in binding affinity.     

The functional domain of hirudin, a thrombin-specific inhibitor

Hirudin is a thrombin-specific inhibitor of Mr 8000 (65 amino acid residues). Native hirudin contains 3 disulfide linkages within the first 39 amino-terminal residues, and a highly acidic C-terminal segment which is freely accessible to enzyme digestion by both endo- and exo-peptidases. Removal of the acidic C-terminal amino acids of native hirudin by both chemical and enzymatic methods resulted in a concomitant loss of hirudin inhibition activity. It is concluded that this acidic C-terminal segment of hirudin is essential for hirudin-thrombin interaction. The implication of the hirudin-thrombin interaction for the enzymatic specificity of thrombin is also discussed.     

Conformational stability of a thrombin-binding peptide derived from the hirudin C-terminus.

The COOH-terminal region of hirudin represents an independent functional domain that binds to an anion-binding exosite of thrombin and inhibits the interaction of thrombin with fibrinogen and regulatory proteins in blood coagulation. The thrombin-bound structure of the peptide fragment, hirudin 55-65, has been determined by use of transferred NOE spectroscopy [Ni, F., Konishi, Y., & Scheraga, H. A. (1990) Biochemistry 29, 4479-4489]. The stability of the thrombin-bound conformation has been characterized further by a combined NMR and theoretical analysis of the conformational ensemble accessible by the hirudin peptide. Medium- and long-range NOE's were found for the free hirudin peptide in aqueous solution and in a mixture of dimethyl sulfoxide and water at both ambient (25 degrees C) and low (0 degrees C) temperatures, suggesting that ordered conformations are highly populated in solution. The global folding of these conformations is similar to that in the thrombin-bound state, as indicated by NOE's involving the side-chain protons of residues Phe(56), Ile(59), Pro(60), Tyr(63), and Leu(64). Residues Glu(61), Glu(62), Tyr(63), and Leu(64) all contain approximately 50% of helical conformations calculated from the ratio of the sequential dNN and d alpha N NOE's. Among the helical ensemble, active 3(10)-helical conformations were found by an analysis of the medium-range [(i,i+2) and (i,i+3)] NOE's involving the last six residues of the peptide. An analysis of the side-chain rotamers revealed that, upon binding to thrombin, there may be a rotation around the alpha CH-beta CH bond of Ile(59) such that Ile(59) adopts a gauche- (chi 1 = +60) conformation in contrast to the highly populated trans (chi 1 = -60) found for Ile(59) in the free peptide. However, the thrombin-bound conformation of the hirudin peptide is still an intrinsically stable conformer, and the preferred conformational ensemble of the peptide contains a large population of the active conformation. The apparent preference for a gauche- (chi 1 = +60) side-chain conformation of Ile(59) in the bound state may be explained by the existence of a positively charged arginine residue among the hydrophobic residues in the thrombin exosite.     

The structural elements of hirudin which bind to the fibrinogen recognition site of thrombin are exclusively located within its acidic C-terminal tail

Six lysyl residues of human thrombin (LysB21, LysB52, LysB65, LysB106, LysB107 and LysB154) have been previously shown to participate in the binding site of hirudin, a thrombin-specific inhibitor [(1989) J. Biol. Chem. 264, 7141-7146]. In this report, we attempted to delineate the region of hirudin which binds to these basic amino acids of thrombin. Using the N-terminal core domains (r-Hir1-43 and r-Hir1-52) derived from recombinant hirudins and synthetic C-terminal peptides (Hir40-65 and Hir52-65)--all fragments form complexes with thrombin--we are able to demonstrate that the structural elements of hirudin which account for the shielding of these 6 lysyl residues are exclusively located within the acidic C-terminal region. Since hirudin C-terminal peptides were shown to bind to a non-catalytic site of thrombin and inhibit its interaction with fibrinogen [(1987) FEBS Lett. 211, 10-16], our data consequently imply that these 6 lysyl residues are constituents of the fibrinogen recognition site of thrombin.     

Influence of chain shortening on the inhibitor properties of hirudin and eglin c

To find out minimal sizes of the proteinase inhibitor proteins hirudin and eglin necessary for their biological activity the inhibitors were incubated with exopeptidases. From the incubation mixtures shortened derivatives were isolated and characterized. Eglin c can be N-terminally shortened by up to 6 amino-acid residues without any loss of affinity towards chymotrypsin. The complex of thrombin with hirudin lacking 3 C-terminal amino-acid residues showed a 15-20-fold increased Ki value as found previously for desulfato-hirudin and desulfato-hirudin shortened by 2 amino-acid residues. Obviously, the C-terminal part of the hirudin molecule has a positive influence on its affinity to thrombin.