Human alpha- to zeta-thrombin cleavage occurs with neutrophil cathepsin G or chymotrypsin while fibrinogen clotting activity is retained

Human neutrophil cathepsin G or bovine chymotrypsin proteolytically cleaved human alpha-thrombin at the B-chain Trp148-Thr149 bond generating a new form, zeta-thrombin. While incubation of alpha-thrombin with cathepsin G at pH 7.4 and 37 degrees C resulted in a partial loss of fibrinogen clotting activity, 86 +/- 13% of the clotting activity and 99 +/- 16% of the active sites titratable with p-nitrophenyl p-guanidinobenzoate were retained upon controlled passage of alpha-thrombin through chymotrypsin-Sepharose 4B at pH 6.2 or 7.4 and 24 degrees C (n = 15). Kinetic parameters for H-D-hexahydrotyrosyl-Ala-Arg p-nitroanilide were Km = 1.52 +/- 0.60 vs 1.32 +/- 0.18 microM and kcat = 51.9 +/- 2.9 vs 35.8 +/- 6.4 s-1 with alpha-thrombin vs chymotrypsin-prepared zeta-thrombin (n = 4 vs 3), respectively (I = 0.15 M, pH 7.4, and 24 degrees C). Some 95% of the clotting activity was lost when zeta-thrombin was passed through trypsin-Sepharose 4B under conditions for converting alpha- to nonclotting beta- and subsequently gamma-thrombin. The resulting gamma-like thrombins eluted bimodally with 260 and 310 mM NaCl when applied to Amberlite CG-50 resin [cross-linked poly(methylacrylic acid)] developed with a linear salt gradient in 50 mM Tris at pH 7.4 and 24 degrees C. These elution peaks correspond to 240, 330, and 350 mM NaCl for gamma-, alpha-, and zeta-thrombin, respectfully, implying that the anion-binding exosite is partially destroyed in gamma-like thrombins but is intact in zeta-thrombin.(ABSTRACT TRUNCATED AT 250 WORDS)     

Allosteric changes of thrombin catalytic site induced by interaction of bothrojaracin with anion-binding exosites I and II.

Bothrojaracin, a 27-kDa C-type lectin from Bothrops jararaca venom, is a selective and potent thrombin inhibitor (K(d) = 0.6 nM) which interacts with the two thrombin anion-binding exosites (I and II) but not with its catalytic site. In the present study, we analyzed the allosteric effects produced in the catalytic site by bothrojaracin binding to thrombin exosites. Opposite effects were observed with alpha-thrombin, which possesses both exosites I and II, and with gamma-thrombin, which lacks exosite I. On the one hand, bothrojaracin altered both kinetic parameters K(m) and k(cat) of alpha-thrombin for small synthetic substrates, resulting in an increased efficiency of alpha-thrombin catalytic activity. This effect was similar to that produced by hirugen, a peptide based on the C-terminal hirudin sequence (residues 54-65) which interacts exclusively with exosite I. On the other hand, bothrojaracin decreased the amidolytic activity of gamma-thrombin toward chromogenic substrates, although this effect was observed with higher concentrations of bothrojaracin than those used with alpha-thrombin. In agreement with these observaions, bothrojaracin produced opposite effects on the fluorescence intensity of alpha- and gamma-thrombin derivatives labeled at the active site with fluorescein-Phe-Pro-Arg-chloromethylketone. These observations support the conclusion that bothrojaracin binding to thrombin produces two different structural changes in its active site, depending on whether it interacts exclusively with exosite II, as seen with gamma-thrombin, or with exosite I (or both I and II) as observed with alpha-thrombin. The ability of bothrojaracin to evoke distinct modifications in the thrombin catalytic site environment when interacting with exosites I and II make this molecule an interesting tool for the study of allosteric changes in the thrombin molecule.     

Human alpha-thrombin binding to nonpolymerized fibrin-Sepharose: evidence for an anionic binding region

In order to investigate ligand binding sites in alpha-thrombin that interact with nonpolymerized fibrin, fibrinogen was conjugated (with CNBr) to Sepharose 4B and converted to the nonpolymerized fibrin resin with alpha-thrombin. Human alpha-thrombin was bound to the resin at 22 degrees C and eluted with a linear NaCl gradient [50-300 mM in 50 mM tris(hydroxymethyl)aminomethane hydrochloride, pH 7.6] with midpeak elution occurring at an ionic strength that corresponds to 170 +/- 5 mM NaCl. Among various ligands examined, ATP and its analogues caused alpha-thrombin to elute with 125 mM or less salt. Apparent dissociation constants were estimated by the dependence of elution volume on ligand concentration. The most potent ligands for desorption from the column were anionic (e.g., adenine nucleotides), which also inhibit thrombin esterolytic/amidolytic and clotting activity [Conery, B. G., & Berliner, L. J. (1983) Biochemistry 22, 369-375]. The desorption series was at 10 mM concentrations: ATP = ADP greater than pyrophosphate greater than citrate greater than oxalate greater than PO4(3-). Contrastingly, serotonin and related apolar compounds did not cause dissociation of alpha-thrombin from the fibrin resin, even though several of these substances inhibit fibrinogen clotting and esterolytic/amidolytic activities of the enzyme. These data imply that independent sites for apolar and anionic binding in alpha-thrombin are required for converting fibrinogen into clottable fibrin and that alpha-thrombin-fibrin binding involves an anionic site.     

Alpha-thrombin-catalyzed hydrolysis of fibrin I. Alternative binding modes and the accessibility of the active site in fibrin I-bound alpha-thrombin

Steady-state kinetic parameters were determined for the action of human alpha-thrombin on human fibrin I polymer, an intermediate in the alpha-thrombin-catalyzed conversion of fibrinogen to the fibrin matrix of blood clots during the terminal phase of the blood clotting cascade. Values of 49 s-1 and 7.5 microM were determined (at 37 degrees C, pH 7.4, gamma/2 0.17) for kcat and Km, respectively. Studies of the effect of fibrin I on alpha-thrombin-catalyzed hydrolysis of the fluorogenic substrate N-p-Tos-Gly-L-Pro-L-Arg-7-amido-4-methylcoumarin (tos-GPR-amc) and the effect of fibrin I on the reaction of alpha-thrombin with antithrombin III (AT) were presented which indicate that the active site of alpha-thrombin is accessible while it is bound to its substrate fibrin I. Fibrin I inhibited alpha-thrombin-catalyzed hydrolysis of tos-GPR-amc in a manner inconsistent with the pure competitive inhibition expected for an alternative substrate, whereas fibrinogen, an alpha-thrombin substrate, behaved as a pure competitive inhibitor of the alpha-thrombin-catalyzed hydrolysis of tos-GPR-amc. The effect of fibrin I on alpha-thrombin-catalyzed hydrolysis of tos-GPR-amc was shown to be consistent with alpha-thrombin binding to fibrin I in alternative orientations. In one orientation both the active site and a site distinct from the active site (an exosite) of alpha-thrombin are occupied by fibrin I. In the other orientation only the exosite of alpha-thrombin is occupied and the active site is freely accessible to other substrates. The values of both kcat (21 s-1) and Km (less than 0.23 microM) determined for fibrin I-bound alpha-thrombin acting on tos-GPR-amc were decreased relative to the values of kcat (180 s-1) and Km (7.3 microM) observed for the action of uncomplexed alpha-thrombin on tos-GPR-amc. This observation suggests that the active site of alpha-thrombin is altered in fibrin I-bound alpha-thrombin. Studies of the effect of fibrin I on the reaction of AT with alpha-thrombin (at 37 degrees C, pH 7.4, gamma/2 0.17) indicated that when alpha-thrombin is bound to fibrin I in an orientation where the active site of alpha-thrombin is accessible, AT reacts with alpha-thrombin with a rate constant (greater than 4.2 x 10(4) M-1 s-1) that is greater than the rate constant (1.5 x 10(4) M-1 s-1) for reaction of AT with the free enzyme.(ABSTRACT TRUNCATED AT 400 WORDS)     

Characterization of the kinetic pathway for fibrin promotion of alpha-thrombin-catalyzed activation of plasma factor XIII

Kinetic and thermodynamic studies are presented showing that the cofactor activity of fibrin I (polymerized des-A fibrinogen) in the alpha-thrombin-catalyzed proteolysis of activation peptide (AP) from plasma factor XIII can be attributed to formation of a fibrin I-plasma factor XIII complex (Kd = 65 nM), which is processed by alpha-thrombin more efficiently (kcat/Km = 1.2 x 10(7) M-1 s-1) than free, uncomplexed plasma factor XIII (kcat/Km = 1.4 x 10(5) M-1 s-1). The increase in the specificity constant (kcat/Km) is shown to be largely due to an increase in the apparent affinity of alpha-thrombin for the complex of plasma factor XIII and fibrin I, as reflected by the 30-fold decrease in the Michaelis constant observed for fibrin I bound plasma factor XIII relative to that for uncomplexed plasma factor XIII. Analysis of the initial rates of alpha-thrombin-catalyzed hydrolysis of fibrinopeptide B (FPB) from fibrin I polymer in the presence of plasma factor XIII indicated that alpha-thrombin bound to fibrin I in the ternary complex of alpha-thrombin, plasma factor XIII, and fibrin I polymer is competent to catalyze cleavage of both FPB from fibrin I and AP from plasma factor XIII. This observation is consistent with the view that alpha-thrombin within the ternary complex is anchored to fibrin I polymer through a binding site distinct from the active site (an exosite) and that the active site is alternatively complexed with the AP moiety of plasma factor XIII or the FPB moiety of fibrin I. This conclusion is supported by the observation that a 12-residue peptide, which binds to an exosite of alpha-thrombin and blocks the interaction of alpha-thrombin with fibrinogen and fibrin, competitively inhibits alpha-thrombin-catalyzed release of both FPB and AP from the fibrin I-plasma factor XIII complex.     

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)     

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 COOH-terminal domain of hirudin. An exosite-directed competitive inhibitor of the action of alpha-thrombin on fibrinogen

Hirudin, a potent 65-residue polypeptide inhibitor of alpha-thrombin found in the saliva of the leech Hirudo medicinalis, and fragments thereof are potentially useful as antithrombotic agents. Hirugen, the synthetic N-acetylated COOH-terminal dodecapeptide (Ac-Asn-Gly-Asp-Phe-Glu-Glu-Ile-Pro-Glu-Glu-Tyr(SO3)-Leu) of hirudin was shown in the present study to behave as a pure competitive inhibitor (Ki = 0.54 microM) of human alpha-thrombin-catalyzed release of fibrinopeptide A from human fibrinogen. In contrast to this inhibitory activity, hirugen slightly enhanced (increased kcat/Km 1.6-fold) alpha-thrombin-catalyzed hydrolysis of the fluorogenic tripeptide substrate N-p-Tosyl-Gly-Pro-Arg-7-amino-4-methylcoumarin. These observations indicate that hirugen binds to alpha-thrombin at an exosite distinct from the active site, and that interaction with this exosite is a major determinant of the competence of alpha-thrombin to bind fibrinogen. Consistent with this view, hirugen blocked binding of fibrin II to alpha-thrombin. Studies of the effect of hirugen on the rate of inactivation of alpha-thrombin by antithrombin III (AT), the major plasma inhibitor of alpha-thrombin, indicated that binding of hirugen to alpha-thrombin results in less than a 2.5-fold decrease in the rate of inactivation of alpha-thrombin by AT, both in the absence and presence of heparin. This behavior is distinct from that of active site-directed competitive inhibitors of alpha-thrombin which bind to alpha-thrombin and block both conversion of fibrinogen to fibrin and inactivation of alpha-thrombin by AT. Hirugen, an exosite-directed competitive inhibitor, blocks the interaction of alpha-thrombin with fibrinogen while leaving alpha-thrombin competent to react with AT. Thus, unlike active site-directed competitive inhibitors, hirugen should act in concert with AT and heparin to reduce the amount of fibrinogen that is processed during the lifetime of alpha-thrombin in plasma.     

Role of exosites 1 and 2 in thrombin reaction with plasminogen activator inhibitor-1 in the absence and presence of cofactors.

The cofactors heparin, vitronectin (VN), and thrombomodulin (TM) modulate the reactivity of alpha-thrombin with plasminogen activator inhibitor (PAI-1). While heparin and VN accelerate the reaction by approximately 2 orders of magnitude, TM protects alpha-thrombin from rapid inactivation by PAI-1 in the presence of VN. To understand how these cofactors function, we studied the kinetics of PAI-1 inactivation of alpha-thrombin, the exosite 1 variant gamma-thrombin, the exosite 2 mutant R93,97,101A thrombin, and recombinant meizothrombin in both the absence and presence of these cofactors. Heparin and VN accelerated the second-order association rate constant [k(2) = (7.9 +/- 0.5) x 10(2) M(-)(1) s(-)(1)] of alpha-thrombin with PAI-1 approximately 200- and approximately 240-fold, respectively. The k(2) value for gamma-thrombin [(7.9 +/- 0.7) x 10(1) M(-)(1) s(-)(1)] was impaired 10-fold, but was enhanced by heparin and VN approximately 280- and approximately 75-fold, respectively. Similar to inactivation of gamma-thrombin, PAI-1 inactivation of alpha-thrombin in complex with the epidermal growth factor-like domains 4-6 of TM (TM4-6) was impaired approximately 10-fold. The exosite 2 mutant R93,97,101A thrombin, which was previously shown not to bind heparin, and meizothrombin, in which exosite 2 is masked, reacted with PAI-1 at similar rates in both the absence and presence of heparin [k(2) = (1.3-1.5) x 10(3) M(-)(1) s(-)(1) for R93,97,101A thrombin and k(2) = (3.6-5.1) x 10(2) M(-)(1) s(-)(1) for meizothrombin]. Unlike heparin, however, VN enhanced the k(2) of R93,97,101A thrombin and meizothrombin inactivation approximately 80- and approximately 30-fold, respectively. Continuous kinetic analysis as well as competition kinetic studies in the presence of S195A thrombin suggested that the accelerating effect of VN or heparin occurs primarily by lowering the dissociation constant (K(d)) for formation of a noncovalent, Michaelis-type complex. Analysis of these results suggest that (1) heparin binds to exosite 2 of alpha-thrombin to accelerate the reaction by a template mechanism, (2) VN accelerates PAI-1 inactivation of alpha-thrombin by lowering the K(d) for initial complex formation by an unknown mechanism that does not require binding to either exosite 1 or exosite 2 of alpha-thrombin, (3) alpha-thrombin may have a binding site for PAI-1 within or near exosite 1, and (4) TM occupancy of exosite 1 partially accounts for the protection of thrombin from rapid inactivation by PAI-1 in the presence of vitronectin.     

Platelet glycoprotein Ib alpha binds to thrombin anion-binding exosite II inducing allosteric changes in the activity of thrombin

The glycoprotein (GP) Ib-IX complex is a platelet surface receptor that binds thrombin as one of its ligands, although the biological significance of thrombin interaction remains unclear. In this study we have used several approaches to investigate the GPIb alpha-thrombin interaction in more detail and to study its effect on the thrombin-induced elaboration of fibrin. We found that both glycocalicin and the amino-terminal fragment of GPIb alpha reduced the release of fibrinopeptide A from fibrinogen by about 50% by a noncompetitive allosteric mechanism. Similarly, GPIb alpha caused in thrombin an allosteric reduction in the rate of turnover of the small peptide substrate d-Phe-Pro-Arg-pNA. The K(d) for the glycocalicin-thrombin interaction was 1 microm at physiological ionic strength but was highly salt-dependent, decreasing to 0.19 microm at 100 mm NaCl (Gamma(salt) = -4.2). The salt dependence was characteristic of other thrombin ligands that bind to exosite II of this enzyme, and we confirmed this as the GPIb alpha-binding site on thrombin by using thrombin mutants and by competition binding studies. R68E or R70E mutations in exosite I of thrombin had little effect on its interaction with GPIb alpha. Both the allosteric inhibition of fibrinogen turnover caused by GPIb alpha binding to these mutants, and the K(d) values for their interactions with GPIb alpha were similar to those of wild-type thrombin. In contrast, R89E and K248E mutations in exosite II of thrombin markedly increased the K(d) values for the interactions of these thrombin mutants with GPIb alpha by 10- and 25-fold, respectively. Finally, we demonstrated that low molecular weight heparin (which binds to thrombin exosite II) but not hirugen (residues 54-65 of hirudin, which binds to exosite I of thrombin) inhibited thrombin binding to GPIb alpha. These data demonstrate that GPIb alpha binds to thrombin exosite II and in so doing causes a conformational change in the active site of thrombin by an allosteric mechanism that alters the accessibility of both its natural substrate, fibrinogen, and the small peptidyl substrate d-Phe-Pro-Arg-pNA.     

Evidence that both exosites on thrombin participate in its high affinity interaction with fibrin

Exosite 1 on thrombin mediates low affinity binding to sites on the NH2 termini of the alpha- and beta-chains of fibrin. A subpopulation of fibrin molecules (gammaA/gamma'-fibrin) has an alternate COOH terminus of the normal gamma-chain (gammaA/gammaA-fibrin) that binds thrombin with high affinity. To determine the roles of exosites 1 and 2 in the high affinity interaction of thrombin with gammaA/gamma'-fibrin, binding studies were done with thrombin variants and exosite 1- or 2-directed ligands. alpha-Thrombin bound gammaA/gamma'-fibrin via high and low affinity binding sites. A peptide analog of the COOH terminus of the gamma'-chain that binds alpha-thrombin via exosite 2 blocked the high affinity binding of alpha-thrombin to gammaA/gamma'-fibrin, suggesting that the interaction of alpha-thrombin with the gamma'-chain is exosite 2-mediated. In support of this concept, (a) gamma-thrombin, which lacks a functional exosite 1, bound to gammaA/gamma'-fibrin, but not to gammaA/gammaA-fibrin; (b) thrombin R93A/R97A/R101A, an exosite 2-defective variant, bound only to gammaA/gamma'-fibrin via low affinity sites; and (c) exosite 2-directed ligands reduced alpha-thrombin binding to gammaA/gamma'-fibrin. However, several lines of evidence indicate that exosite 1 contributes to the high affinity interaction of thrombin with gammaA/gamma'-fibrin. First, the affinity of gamma-thrombin for gammaA/gamma'-fibrin was lower than that of alpha-thrombin. Second, removal of a low affinity binding site on the beta-chain of gammaA/gamma'-fibrin reduced its affinity for alpha-thrombin. Third, exosite 1-directed ligands reduced alpha-thrombin binding to gammaA/gamma'-fibrin. Taken together, these data suggest that, although exosite 2 mediates the interaction of thrombin with the gamma'-chain of gammaA/gamma'-fibrin, simultaneous ligation of exosite 1 by low affinity binding sites is essential for the high affinity interaction of thrombin with gammaA/gamma'-fibrin.     

Anophelin: kinetics and mechanism of thrombin inhibition

Anophelin is a 6.5-kDa peptide isolated from the salivary gland of Anopheles albimanus that behaves as an alpha-thrombin inhibitor. In this paper, kinetic analyses and the study of mechanism of alpha-thrombin inhibition by anophelin were performed. Anophelin was determined to be a reversible, slow, tight-binding inhibitor of alpha-thrombin, displaying a competitive type of inhibition. The binding of anophelin to alpha-thrombin is stoichiometric with a dissociation constant (K(i)) of 5.87 +/- 1.46 pM, a calculated association rate constant (k(1)) of 2.11 +/- 0.06 x 10(8) M(-1) s(-1), and a dissociation rate constant (k(-1)) of 4.05 +/- 0.97 x 10(-4) s(-1). In the presence of 0.15 and 0.4 M NaCl, a 17.6- and 207-fold increase in the K(i) of anophelin-alpha-thrombin complex was observed, respectively, indicating that ionic interactions are important in anophelin-alpha-thrombin complex formation. Incubation of alpha-thrombin with C-terminal hirudin fragment 54-65 that binds to alpha-thrombin anion binding exosite 1 (TABE1) attenuates alpha-thrombin inhibition by anophelin; anophelin also blocks TABE1-dependent trypsin-mediated proteolysis of alpha-thrombin. Using gamma-thrombin, an alpha-thrombin derivative where the anion binding exosite has been disrupted, anophelin behaves as a fast and classical competitive inhibitor of gamma-thrombin hydrolysis of small chromogenic substrate (K(i) = 0. 694 +/- 0.063 nM). In addition, anophelin-gamma-thrombin complex formation is prevented by treatment of the enzyme with D-Phe-Pro-Arg-chloromethyl ketone (PPACK), a reagent that irreversibly blocks the catalytic site of thrombin. It is concluded that anophelin is a potent dual inhibitor of alpha-thrombin because it binds both to TABE1 and to the catalytic site, optimal binding being dependent on the availability of both domains. Finally, anophelin inhibits clot-bound alpha-thrombin with an IC(50) of 45 nM and increases the lag phase that precedes explosive in vitro alpha-thrombin generation after activation of intrinsic pathway of blood coagulation. Because of its unique primary sequence, anophelin may be used as a novel reagent to study the structure and function of alpha-thrombin.     

Structural and functional properties of human alpha-thrombin, phosphopyridoxylated alpha-thrombin, and gamma T-thrombin. Identification of lysyl residues in alpha-thrombin that are critical for heparin and fibrin(ogen) interactions

alpha-Thrombin derivatives obtained either by site-specific modification at lysyl residues (phosphopyridoxylated) or by limited trypsinolysis (gamma T-thrombin) were compared to correlate structural modifications with the functional reactivity toward fibrin(ogen) and heparin. alpha-Thrombin phosphopyridoxylated in the absence of heparin (unprotected) showed approximately 2 mol of label incorporated/mol of thrombin, but only 1 mol of label incorporated/mol of proteinase when modified in the presence of added heparin (protected). In contrast to native alpha-thrombin, both phosphopyridoxylated alpha-thrombin derivatives failed to interact with a fibrin monomer-agarose column and had reduced fibrinogen clotting activity, which is very similar to gamma T-thrombin. Heparin accelerated the rate of antithrombin III inhibition of alpha-thrombin, heparin-protected modified-alpha-thrombin, and gamma T-thrombin in a manner consistent with a template mechanism but was without effect on unprotected modified alpha-thrombin. In a heparin-catalyzed antithrombin III inhibition assay of alpha-thrombin, we found that D-Phe-Pro-Arg chloromethyl ketone-active site-inactivated gamma T-thrombin competed for heparin binding. It has been shown that limited proteolysis/autolysis of the B-chain of alpha-thrombin in the area around Arg-B73 (in beta T/beta- and gamma T/gamma-thrombin), but not that around Lys-B154 (in gamma T/gamma-thrombin), diminishes specific interactions with fibrinogen (Hofsteenge, J., Braun, P. J., and Stone , S. R. (1988) Biochemistry 27, 2144-2151). In unprotected modified alpha-thrombin, lysyl residues B21, B65, B174, and B252 were phosphopyridoxylated. In heparin-protected modified alpha-thrombin, only lysyl residues B21 and B65 were phosphopyridoxylated. These observations suggest that lysyl residues 21/65 of the B-chain of alpha-thrombin are involved in fibrin(ogen) interactions, and lysyl residues 174/252 of the B-chain are important in heparin interactions.     

Thrombin's enzymatic activity increases permeability of endothelial cell monolayers

Human alpha-thrombin increases the permeability of bovine pulmonary artery endothelial cell (CCL-209) monolayers. To determine if this increase is via an enzymatic or receptor-mediated mechanism, enzymatically active forms of alpha-thrombin and enzymatically inactive forms with cell binding activity were incubated with the monolayers. Enzymatic forms included alpha-thrombin and two digestion products, zeta-thrombin (chymotryptic product with 89% clotting activity) and gamma-thrombin (tryptic product). Enzymatically inactive forms included D-Phe-Pro-Arg-chloromethylketone-(PPACK) alpha-thrombin and diisopropylphosphorofluoridate-(DIP) alpha-thrombin. Cell binding activity of alpha- and PPACK-alpha-thrombin was demonstrated to be similar to each other and comparable to that cited in the literature for DIP-alpha-thrombin. gamma-Thrombin, on the other hand, did not compete for binding of 125I-labeled alpha-thrombin. All enzymatic forms of alpha-thrombin increased endothelial permeability as assessed by the clearance of 125I-albumin across the monolayers. Coincubation of PPACK, an enzymatic site inhibitor, with alpha- or gamma-thrombin prevented the increase in permeability, further indicating that alpha-thrombin increased permeability by its enzymatic activity. Both enzymatically inactive forms of alpha-thrombin with high-affinity binding activity had no effect on permeability. To further examine whether cell binding activity of alpha-thrombin contributed to the increased permeability, a sulfated COOH-terminal fragment of hirudin (hirugen) that binds to the anion-binding site of alpha-thrombin but, unlike hirudin, does not interact with the catalytic site was coincubated with alpha-thrombin.(ABSTRACT TRUNCATED AT 250 WORDS)     

The interaction of thrombin with fibrinogen. A structural basis for its specificity.

The structure of the ternary complex of human alpha-thrombin with a covalently bound analogue of fibrinopeptide A and a C-terminal hirudin peptide has been determined by X-ray diffraction methods at 0.25 nm resolution. Fibrinopeptide A folds in a compact manner, bringing together hydrophobic residues that slot into the apolar binding site of human alpha-thrombin. Fibrinogen residue Phe8 occupies the aryl-binding site of thrombin, adjacent to fibrinogen residues Leu9 and Val15 in the S2 subsite. The species diversity of fibrinopeptide A is analysed with respect to its conformation and its interaction with thrombin. The non-covalently attached peptide fragment hirudin(54-65) exhibits an identical conformation to that observed in the hirudin-thrombin complex. The occupancy of the secondary fibrinogen-recognition exosite by this peptide imposes restrictions on the manner of fibrinogen binding. The surface topology of the thrombin molecule indicates positions P1'-P3', differ from those of the canonical serine-proteinase inhibitors, suggesting a mechanical model for the switching of thrombin activity from fibrinogen cleavage to protein-C activation on thrombomodulin complex formation. The multiple interactions between thrombin and fibrinogen provide an explanation for the narrow specificity of thrombin. Structural grounds can be put forward for certain congenital clotting disorders.     

Thymosin alpha(1)--an endogenous modulator of alpha-thrombin recognition site]

Thymosin alpha 1-inhibited fibrinogen clotting activity of alpha-thrombin, but not amidolysis of H-D-Phe-Pip-Arg-pNA. Modulation of thrombin interaction with rat peritoneal mast cells (RPMC) by suppressors of additional recognition binding site (thymosin and heparin) was studied. Thrombin-induced pHi changes of RPMC were controlled with pH-sensitive fluorescent dye, BCECF. Thrombin caused a biphasic changes in pHi: rapid cell acidification (0.02) followed by slow alkalinization (0.06 above baseline for 18 min). Thymosin suppressed thrombin-induced pHi increase above resting level. Similar changes in pHi were observed after modification of additional recognition binding site by heparin. Beta/gamma-thrombin with disrupted additional binding site was shown to induce only a decrease of pHi. It is concluded that thymosin alpha 1 is endogenous modulator of alpha-thrombin activity.     

Antithrombin reactions with alpha- and gamma-thrombins.

Human alpha-thrombin with high clotting activity and its proteolyzed derivative gamma-thrombin with virtually no clotting activity reacted in an essentially identical manner with antithrombin. The two enzyme forms bound proflavin with similar constants and showed identical behavior with small substrates. No significant differences were found for the antithrombin reactions (measured by proflavin displacement or active site titration) with respect to kinetics, extent of reaction, or effect of added heparin. The enzyme--antithrombin complexes could not be dissociated with sodium dodecyl sulfate (NaDodSO4) but the NaDodSO4-denatured complexes were dissociated by hydroxylamine treatment. The gamma-thrombin-antithrombin complex has an approximate molecular weight of 75 000 by disc gel electrophoresis as compared with 100 000 for the alpha-complex, consistent with the polypeptide structures of the two proteins. The gamma-thrombin--antithrombin complex did not inhibit clotting catalyzed by alpha-thrombin. In addition, fibrinogen did not affect the reaction of gamma-thrombin with antithrombin or antithrombin--heparin. Thus, the antithrombin and antithrombin--heparin reactions do not involve the fibrinogen recognition sites which are destroyed by proteolytic conversion of alpha-thrombin to the noncoagulant gamma form.     

Enzymic and nonenzymic properties of human beta-thrombin

Autolysis or tryptic hydrolysis converts human alpha-thrombin to its beta-derivative and subsequently to gamma-thrombin. Human beta-thrombin was obtained by tryptic digestion of alpha-thrombin and isolated by BioRex chromatography. The kinetic parameters for human alpha- and beta-thrombins with H-D-phenylalanyl-L-pipecolyl-L-arginine-para-nitroanilide were similar, as well as the rate of inactivation by tosyl-lysine chloromethyl ketone. By contrast, the rate of inactivation by diisopropyl fluorophosphate was reduced by half, and the inhibition constant for benzamidine was increased 2.5-fold. Moreover, the beta cleavages induced a drastic reduction in reactivity toward protein C, affinity for thrombomodulin, and fibrinogen clotting activity. Unlike alpha-thrombin, beta-thrombin was not protected from inhibition by diisopropyl fluorophosphate in the presence of fibrinogen and failed to bind to fibrin-Sepharose. Our results indicate that the beta cleavages induce multiple defects in the functions of human thrombin. Although the three catalytic residues remain in an active configuration, subtle changes are induced in the microenvironment of the active serine. However, the drastic reduction of fibrinogen clotting activity should rather be ascribed to major alterations observed in both the fibrinopeptide groove and the fibrin recognition site. These observations provide further evidence for a double-site mechanism in the interaction of fibrinogen with thrombin.     

The fibrinogen anion-binding exosite of thrombin is necessary for induction of rises in intracellular calcium and prostacyclin production in endothelial cells.

Thrombin stimulation of prostacyclin (PGI2) synthesis by cultured human umbilical vein endothelial cells (HUVEC) requires the active site of thrombin and involves rapid and transient rises in cytoplasmic free calcium [Ca2+]i. In this study, we investigated whether or not the anion-binding exosite for fibrinogen recognition of thrombin (which confers certain substrate specificities) is also necessary for the induction of rises in [Ca2+]i and PGI2 production. Thrombin variants which lack either the catalytic site (DIP-alpha-thrombin) or anion-binding exosite (gamma-thrombin) either alone or in combination failed to induce rises in [Ca2+]i or PGI2 production in HUVEC. To further study the role of the anion-binding exosite of thrombin in the activation of HUVEC, COOH-terminal fragments of hirudin were used. This portion of hirudin interacts with the anion-binding exosite of thrombin and inhibits thrombin-induced fibrinogen coagulation while leaving the catalytic activity of thrombin intact. A 21-amino acid COOH-terminal peptide of hirudin (N alpha-acetyldesulfato-hirudin45-65 or Hir45-65) inhibited thrombin-induced (0.5 U/ml) rises in [Ca2+]i and PGI2 production with IC50 of 0.13 and 0.71 microM, respectively. Similar results were obtained using shorter hirudin-derived peptides. Thus, the fibrinogen anion-binding exosite of thrombin is required for alpha-thrombin-induced rises in [Ca2+]i and PGI2 production in HUVEC.     

The N-terminal acidic domain of heparin cofactor II mediates the inhibition of alpha-thrombin in the presence of glycosaminoglycans

Heparin cofactor II (HCII) is a glycoprotein in human plasma that inhibits thrombin and chymotrypsin. Inhibition occurs when the protease attacks the reactive site peptide bond in HCII (Leu444-Ser445) and becomes trapped as a covalent 1:1 complex. Dermatan sulfate and heparin increase the rate of inhibition of thrombin, but not of chymotrypsin, greater than 1000-fold. The N-terminal portion of HCII contains two acidic repeats (Glu56-Asp-Asp-Asp-Tyr-Leu-Asp and Glu69-Asp-Asp-Asp-Tyr-Ile-Asp) that may bind to anion-binding exosite I of thrombin to facilitate covalent complex formation. To examine the importance of the acidic domain, we have constructed a series of 5' deletions in the HCII cDNA and expressed the recombinant HCII (rHCII) in Escherichia coli. Apparent second-order rate constants (k2) for inhibition of alpha-thrombin and chymotrypsin by each variant were determined. Deletion of amino acid residues 1-74 had no effect on the rate of inhibition of alpha-thrombin or chymotrypsin in the absence of a glycosaminoglycan. Similarly, the rate of inhibition of alpha-thrombin in the presence of a glycosaminoglycan was unaffected by deletion of residues 1-52. However, deletion of residues 1-67 (first acidic repeat) or 1-74 (first and second acidic repeats) greatly decreased the rate of inhibition of alpha-thrombin in the presence of heparin, dermatan sulfate, or a dermatan sulfate hexasaccharide that comprises the minimum high-affinity binding site for HCII. Deletion of one or both of the acidic repeats increased the apparent affinity of rHCII for heparin-Sepharose, suggesting that the acidic domain may interact with the glycosaminoglycan-binding site of native rHCII. The stimulatory effect of glycosaminoglycans on native rHCII was decreased by a C-terminal hirudin peptide which binds to anion-binding exosite I of alpha-thrombin. Furthermore, the ability of native rHCII to inhibit gamma-thrombin, which lacks the binding site for hirudin, was stimulated weakly by glycosaminoglycans. These results support a model in which the stimulatory effect of glycosaminoglycans on the inhibition of alpha-thrombin is mediated, in part, by the N-terminal acidic domain of HCII.