Electrostatic steering and ionic tethering in the formation of thrombin-hirudin complexes: the role of the thrombin anion-binding exosite-I.

Electrostatic interactions between the thrombin anion-binding exosite-I (ABE-I) and the hirudin C-terminal tail play an important role in the formation of the thrombin-hirudin inhibitor complex and serves as a model for the interactions of thrombin with its many other ligands. The role of each solvent exposed basic residue in ABE-I (Arg(35), Lys(36), Arg(67), Arg(73), Arg(75), Arg(77a), Lys(81), Lys(109), Lys(110), and Lys(149e)) in electrostatic steering and ionic tethering in the formation of thrombin-hirudin inhibitor complexes was explored by site directed mutagenesis. The contribution to the binding energy (deltaG(degrees)b) by each residue varied from 1.9 kJ mol(-)(1) (Lys(110)) to 15.3 kJ mol(-1) (Arg(73)) and were in general agreement to their observed interactions with hirudin residues in the thrombin-hirudin crystal structure [Rydel, T. J., Tulinsky, A., Bode, W., and Huber, R. (1991) J. Mol. Biol. 221, 583-601]. Coupling energies (delta deltaG(degrees) int) were calculated for the major ion-pair interactions involved in ionic tethering using complementary hirudin mutants (h-D55N, h-E57Q, and h-E58Q). Cooperativity was seen for the h-Asp(55)/Arg(73) ion pair (2.4 kJ mol(-1)); however, low coupling energies for h-Asp(55)/Lys(149e) (deltadeltaG(degrees)int 0.6 kJ mol(-1)) and h-Glu(58)/Arg(77a) (deltadeltaG(degrees)int 0.9 kJ mol(-1)) suggest these are not major interactions, as anticipated by the crystal structure. Interestingly, high coupling energies were seen for the intermolecular ion-pair h-Glu(57)/Arg(75) (deltadeltaG(degrees)int 2.3 kJ mol(-1)) and for the solvent bridge h-Glu(57)/Arg(77a) (deltadeltaG(degrees)int 2.7 kJ mol(-1)) indicating that h-Glu(57) interacts directly with both Arg(75) and Arg(77a) in the thrombin-hirudin inhibitor complex. The remaining ABE-I residues that do not form major contacts in tethering the C-terminal tail of hirudin make small but collectively important contributions to the overall positive electrostatic field generated by ABE-I important in electrostatic steering.

The dual role of thrombin's anion-binding exosite-I in the recognition and cleavage of the protease-activated receptor 1.

The role of thrombin anion-binding exosite-I in the recognition and cleavage of the extracellular domain of the seven transmembrane domain thrombin receptor (PAR1) was determined using site-directed mutagenesis. Basic residues in anion-binding exosite-I (Arg35, Arg36, Arg67, Arg73, Arg75, Arg77A, Lys81, Lys109, Lys110 and Lys149E) were substituted with glutamines and the resultant recombinant mutant thrombins were used to determine kinetic parameters for the cleavage of a peptide (PAR38-60) based on the PAR1 extracellular domain. Compared with wild-type thrombin, replacement of Arg67 and Arg73 had a dramatic effect on the cleavage of PAR38-60 (k(cat)/K(m) = 1.8 x 10(6) and 4.6 x 10(6) vs 9.2 x 10(7) M(-1).s(-1)), whereas the remaining mutations of the anion-binding exosite-I of thrombin had a less pronounced effect, with k(cat)/K(m) values ranging from 3.3 x 10(7) M(-1). s(-1) (R77(a)Q) to 5.8 x 10(7) M(-1).s(-1) (K109Q). The ability of thrombin mutants to activate platelets paralleled that of PAR38-60 cleavage, whereas their ability to clot fibrinogen differed profoundly, as did their susceptibility to hirudin inhibition. Results are interpreted with respect to known interactions of thrombin with thrombomodulin, hirudin, rhodniin and heparin cofactor II. We conclude that the basic residues of anion-binding exosite-I contribute significantly to enhancing the rate of complex formation in two ways; the first (general) ensures electrostatic steering of ligands with complementary electrostatic fields, the second (specific) involves a combination of molecular contacts within the complex that is unique for each ligand.

Evolution of serpin specificity: cooperative interactions in the reactive-site loop sequence of antithrombin specifically restrict the inhibition of activated protein C.

Protease cascades and their inhibitors are a common feature of many biological regulatory systems, and the various components of such cascades have been subjected to a long and concerted evolution. We present here evidence that in the coagulation cascade, the sequence of the protease-binding reactive-site loop of antithrombin has evolved such that the majority of its residues has been acquired not for the efficient inhibition of its target proteases, thrombin and factor Xa, but to avoid the inhibition of activated protein C (APC). We substituted residues of the reactive-site loop of antithrombin into alpha(1)-antitrypsin and tested the chimeras against thrombin, factor Xa, and APC. With respect to factor Xa and thrombin, the difference in association rate between the fastest and the slowest inhibitors was 5.5- and 88-fold, respectively. However, with respect to APC the difference was 12,500-fold. While most of the variation in the inhibition rates of thrombin could be accounted for by P2 Gly-to-Pro substitutions, for APC almost every residue had an effect on inhibition. In 22 of 25 direct comparisons of antitrypsin residues with antithrombin residues, either singly or in blocs, the antithrombin residues caused a decrease in the rate of inhibition of APC. The antithrombin residue Asn393, at position P'3, emerged as particularly important for avoiding the inhibition of APC, however, its 190-fold effect was seen only when in conjunction with antithrombin P7 to P'2 residues. Cooperative effects among residues of the reactive-site loop thus emerged as critical for restricting the activity of this sequence against APC.

Role of thrombin anion-binding exosite-I in the formation of thrombin-serpin complexes.

Site-directed mutagenesis was used to investigate the role of basic residues in the thrombin anion-binding exosite-I during formation of thrombin-antithrombin III (ATIII), thrombin-protease nexin 1 (PN1), and thrombin-heparin cofactor II (HCII) inhibitor complexes, in the absence and presence of glycosaminoglycans. In the absence of glycosaminoglycan, association rate constant (kon) values for the inhibition of the mutant thrombins (R35Q, K36Q, R67Q, R73Q, R75Q, R77(a)Q, K81Q, K109Q, K110Q, and K149(e)Q) by ATIII and PN1 were similar to wild-type recombinant thrombin (rIIa), whereas kon values were decreased 2-3-fold for HCII against the majority of the exosite-I mutants. The exosite-I mutants did not have a significant effect on heparin-accelerated inhibition by ATIII with maximal kon values similar to rIIa. A small effect was seen for PN1/heparin inhibition of the exosite-I mutants R35Q, R67Q, R73Q, R75Q, and R77(a)Q, where kon values were decreased 2-4-fold, compared with rIIa. For HCII/heparin, kon values for inhibition of the exosite-I mutants (except R67Q, R73Q, and K149(e)Q) were 2-3-fold lower than rIIa. Larger decreases in kon values for HCII/heparin were found for R67Q and R73Q thrombins with 441- and 14-fold decreases, respectively, whereas K149(e)Q was unchanged. For HCII/dermatan sulfate, R67Q and R73Q had kon values reduced 720- and 48-fold, respectively, whereas the remaining mutants were decreased 3-7-fold relative to rIIa. The results suggest that ATIII has no major interaction with exosite-I of thrombin with or without heparin. PN1 bound to heparin uses exosite-I to some extent, possibly by utilizing the positive electrostatic field of exosite-I to enhance orientation and thrombin complex formation. The larger effects of the thrombin exosite-I mutants for HCII inhibition with heparin and dermatan sulfate indicate its need for exosite-I, presumably through contact of the "hirudin-like" domain of HCII with exosite-I of thrombin.

Immunolocalization of protease-activated receptor-2 in skin: receptor activation stimulates interleukin-8 secretion by keratinocytes in vitro.

The protease-activated receptor-2 (PAR-2) is a seven transmembrane domain receptor related to the thrombin receptor, which is activated in vitro by cleavage by trypsin. Affinity-purified rabbit IgG raised against a peptide corresponding to the trypsin cleavage site of PAR-2 was used for an immunohistochemical study of skin. The expression of PAR-2 in epidermis was striking, with keratinocytes showing abundant intercellular and cytoplasmic staining. Basal cells showed the strongest staining intensity and the stratum corneum was negative. Staining with control IgG used at the same concentration was consistently negative. The functional expression of PAR-2 by the simian virus transformed human skin keratinocyte cell line SVK14 was demonstrated by Northern blot analysis, flow cytometric analysis and the measurement of intracellular calcium. Treatment of SVK14 with trypsin or a receptor agonist peptide (SLIGKV-NH2) caused a dose-dependent increase in the secretion of the chemokine interleukin-8 (IL-8) in vitro. The effect of the peptide was specific, since control acetylated peptide was without activity. We conclude that PAR-2 is highly expressed by epidermal keratinocytes and receptor activation in vitro leads to increased IL-8 secretion by keratinocytes. These data raise the possibility that PAR-2 may play a role in epidermal homeostasis and inflammatory conditions.

Expression and purification of the human thrombin receptor.

The human thrombin receptor has been overexpressed in Sf9 (Spodoptera frugiperda) insect cells using a baculovirus vector. Cell surface expression of the receptor was confirmed by immunocytochemistry with polyclonal antibodies raised against the extracellular domain of the receptor. The expressed receptor was functional; both thrombin and the thrombin receptor agonist peptide produced increases in intracellular calcium in transfected cells. The concentration of thrombin causing the half-maximal increase (EC50) in intracellular calcium was 3.9 nM, whereas the EC50 for the agonist peptide was 2.7 microM. However, the observed maximum increase in intracellular calcium concentration with the agonist peptide (547 nM) was twofold greater than that observed with thrombin (258 nM). The recombinant receptor was purified by immunoaffinity chromatography using a monoclonal antibody raised against the receptor extracellular domain. The purified preparation contained two species with apparent molecular masses of 48 and 90 kDa, both of which were recognized by mono- and polyclonal antibodies against the thrombin receptor. The yield of the purified receptor was 0.78 mg/liter of insect cells suspension culture (10(6) cells/ml). The purified thrombin receptor will be useful in future structural and functional studies.

Expression of the thrombin receptor in developing bone and associated tissues.

Thrombin, a serine protease with a central role in thrombosis and hemostasis, is also a specific agonist for a variety of cellular responses in osteoblasts and stimulates bone resorption in organ culture. Cultured osteoblast-like cells express the proteolytically activated thrombin receptor, but the significance of this finding in vivo remains unknown. Immunohistochemistry was used to investigate the normal tissue distribution of the proteolytically activated thrombin receptor in developing rat bones and associated tissues. In hind limbs, the receptor was first observed on embryonic day 16 and became more abundant within the limb as gestation progressed. Thrombin receptor staining was detected on osteoblasts, macrophages, muscle cells, and endothelial cells, but not osteoclasts. Similarly, osteoblasts in developing calvariae stained positively for the thrombin receptor. The pattern of receptor expression by primary osteoblast cultures and freshly isolated macrophages and osteoclasts corresponded to that observed in vivo. The observed pattern of thrombin receptor expression in bone cells supports the hypothesis that cell-mediated thrombin-induced bone resorption is mediated by osteoblasts.

Protein engineering of chimeric Serpins: an investigation into effects of the serpin scaffold and reactive centre loop length.

The exposed Serpin reactive centre loop controls the specificity of the serpin proteinase interaction. Mutations within this region have been used to generate novel potentially therapeutic inhibitors. In this study we examine the effect of the serpin scaffold and reactive centre loop length upon the generation of such inhibitors. The reactive centre loop regions, P7-P3', of alpha1-antitrypsin and alpha1-antichymotrypsin were replaced by the corresponding residues of the viral serpin, Serp1, to form AT/Serp1 and ACT/Serp1, respectively. AT/Serp1 formed SDS stable complexes with a range of proteinases with association rate constants for plasmin, tissue plasminogen activator, urokinase, thrombin and factor Xa of approximately 10(4) M(-1)s(-1) and a stoichiometry of inhibition of approximately 1 for all of them. ACT/Serp1, however, formed SDS-stable complexes with only plasmin and thrombin with association rate constant 100-fold slower than AT/Serp1 and an increased stoichiometry of inhibition. The reactive centre loop of ACT/Serp1 is four amino acid residues longer than AT/Serp1. These four additional residues (VETR) were inserted into AT/Serp1 to form AT/Serp1(VETR). AT/Serp1(VETR) formed SDS stable complexes with plasmin, thrombin and tissue plasminogen activator similar to AT/Serp1, however, the association rate constants were 10-fold slower than those observed with AT/Serp1, while the stoichiometry of inhibition remained around 1. These results suggest that the additional reactive centre loop residues effect the rate of initial complex formation by placing the reactive centre loop in a non-ideal conformation. This study demonstrates that both reactive centre loop length and serpin scaffold are important in defining the inhibitory characteristics of a serpin.

Identification of potential activators of proteinase-activated receptor-2.

In order to identify physiological activators of proteinase-activated receptor-2 (PAR-2), a peptide chloromethane inhibitor (biotinyl-Ser-Lys-Gly-Arg-CH2Cl) based on the cleavage site for activation of PAR-2 was synthesised and tested with 12 trypsin-like serine proteinases. The second-order rate constant (ki/Ki) for the formation of the covalent proteinase-inhibitor complex varied by 2 x 10(5)-fold between the proteinases. Biotinyl-Ser-Lys-Gly-Arg-CH2Cl reacted very rapidly with trypsin, acrosin from sperm and tryptase from mast cells: the ki/Ki values with these proteinases were greater than 10(5) M(-1) x s(-1). Thus, the specificity of these proteinases matched the sequence of the activation site of PAR-2 and it can be concluded that these proteinases are potential physiological activators of PAR-2.

The thrombin E192Q-BPTI complex reveals gross structural rearrangements: implications for the interaction with antithrombin and thrombomodulin.

Previous crystal structures of thrombin indicate that the 60-insertion loop is a rigid moiety that partially occludes the active site, suggesting that this structural feature plays a decisive role in restricting thrombin's specificity. This restricted specificity is typified by the experimental observation that thrombin is not inhibited by micromolar concentrations of basic pancreatic trypsin inhibitor (BPTI). Surprisingly, a single atom mutation in thrombin (E192Q) results in a 10(-8) M affinity for BPTI. The crystal structure of human thrombin mutant E192Q has been solved in complex with BPTI at 2.3 A resolution. Binding of the Kunitz inhibitor is accompanied by gross structural rearrangements in thrombin. In particular, thrombin's 60-loop is found in a significantly different conformation. Concomitant reorganization of other surface loops that surround the active site, i.e. the 37-loop, the 148-loop and the 99-loop, is observed. Thrombin can therefore undergo major structural reorganization upon strong ligand binding. Implications for the interaction of thrombin with antithrombin and thrombomodulin are discussed.

Intrinsic specificity of the reactive site loop of alpha1-antitrypsin, alpha1-antichymotrypsin, antithrombin III, and protease nexin I.

Members of the serpin (serine protease inhibitor) family share a similar backbone structure but expose a variable reactive-site loop, which binds to the catalytic groove of the target protease. Specificity originates in part from the sequence of this loop and also from secondary binding sites that contribute to the inhibitor function. To clarify the intrinsic contribution of the reactive-site loop, alpha1-antichymotrypsin has been utilized as a scaffold to construct chimeras carrying the loop of antithrombin III, protease nexin 1, or alpha1-antitrypsin. Reactive-site loops not only vary in sequence but also in length; therefore, the length of the reactive-site loop was also varied in the chimeras. The efficacy of the specificity transfer was evaluated by measuring the stoichiometry of the reaction, the ability to form an SDS-stable complex, and the association rate constant with a number of potential targets (chymotrypsin, neutrophil elastase, trypsin, thrombin, factor Xa, activated protein C, and urokinase). Overall, substitution of a reactive-site loop was not sufficient to transfer the specificity of a given serpin to alpha1-antichymotrypsin. Specificity of the chimera partly matched that of the loop donor and partly that of the acceptor, whereas the behavior as an inhibitor or a substrate depended upon the targeted protease. Results suggest that, aside from the contributions of the loop sequence and the framework-specific secondary binding sites, an intramolecular control may be essential for productive interaction.

Proteinase-activated receptor-2: expression by human neutrophils.

Neutrophils were shown to express the proteinase-activated receptor-2 (PAR-2), a seven transmembrane domain receptor, which is activated by cleavage by trypsin. Granulocytes from 14 donors stained positively for PAR-2 with affinity-purified rabbit antibodies raised against a peptide corresponding to the trypsin cleavage site of human PAR-2. Neutrophil activation in response to a receptor activating peptide (RAP) varied between donors. RAP (Ser-Leu-Ile-Gly-Lys-Val-NH2) alone induced an increase in the forward and side light scatter after 5-10 minutes and a small increase in the expression of the activation molecule CD11b. The increased expression of CD11b induced by RAP was markedly enhanced by priming the neutrophils with a low concentration (1 nM) of formyl-Leu-Met-Phe. Trypsin and RAP also induced an increase in intracellular calcium, but there were large variations in the magnitude of responses between donors also in this assay. The effects of RAP in the different assays were specific; acetylated RAP was completely without activity.

Inhibitory mechanism of serpins. Mobility of the C-terminal region of the reactive-site loop.

The reactive-site loops of serpins are characterized by a defined mobility where the loop adopts a new secondary structure as an essential part of the inhibitory process. While the importance of mobility in the N-terminal region of the reactive-site loop has been well studied, the role of mobility in the C-terminal portion has not been investigated. The requirements for mobility of the C-terminal portion of the reactive-site loop of alpha1-antitrypsin were investigated by creating a disulfide bridge between the P'3 residue and residue 283 near the top of strand 2C; this disulfide would restrict the mobility of the C-terminal portion of the reactive-site loop by locking together strands 1 and 2 of the C beta-sheet. The engineered disulfide bond had no effect on the inhibitory activity of alpha1-antitrypsin, indicating that there is no requirement for mobility in this region of the molecule. Moreover, these results, coupled with those from molecular modeling, indicate that insertion into the A beta-sheet of the intact reactive-loop beyond P12 is not rate-limiting for the formation of the stable complex. The engineered disulfide bond should also prove useful in the creation of more stable serpin variants; for example, such a bond in plasminogen activator inhibitor-1 would prevent it from becoming latent by locking strand 1C onto the C beta-sheet.

Inhibitory mechanism of serpins. Identification of steps involving the active-site serine residue of the protease.

The role of the protease active-site serine residue in the formation of protease-serpin complexes has been investigated by using a mutant of thrombin in which Ser195 was mutated to alanine (S195A). The structural integrity of S195A was established by examining the kinetics of its interaction with the inhibitor hirudin, which does not have substantial interactions with Ser195. The affinity of S195A for hirudin was only tenfold less than that of thrombin and the kinetic constants for the formation of the S195A-hirudin complex were very similar to those observed with thrombin. In contrast to hirudin, the dissociation constants (Ki) for S195A with serpins (antithrombin, protease nexin-1 and alpha1-antitrypsin with a P1 arginine) were 2 x 10(3) to 2 x 10(5)-fold higher than those observed with thrombin. These results indicate a critical role for interactions with Ser195 in stabilizing the thrombin-serpin complexes. The cofactor heparin compensated partially for the loss of interactions with Ser195; it increased the affinity of S195A for protease nexin-1 and antithrombin by 140-fold and 1000-fold, respectively. In the case of heparin/antithrombin, the increase in affinity could be attributed mainly to interactions outside the active site of S195A. Kinetic studies with antithrombin and protease nexin-1 in the presence of heparin indicated that Ser195 was not involved in any rate-limiting process in the formation of protease-serpin complexes. Interactions with Ser195 increased the stability of the complex by markedly reducing its rate of breakdown rather than by increasing its rate of formation. Overall, the results of the kinetic studies were consistent with a mechanism in which the binding of the protease induces a rate-limiting conformational change in the serpin and interactions with the protease's active-site serine residue, occurring in a subsequent faster step, greatly stabilize the complex.

Allosteric modulation of the activity of thrombin.

Substrates containing a P3 aspartic residue are in general cleaved poorly by thrombin. This may be partly due to an unfavourable interaction between the P3 aspartate and Glu192 in the active site of thrombin. In Protein C activation and perhaps also thrombin receptor cleavage, binding of ligands at the anion-binding exosite of thrombin seems to improve the activity of thrombin with substrates containing a P3 aspartate. To investigate the importance of Glu192 and exosite-binding in modulating thrombin's interactions with a P3 aspartate, peptidyl chloromethanes based on the sequence of the thrombin receptor (containing a P3 aspartate) have been synthesized and the kinetics of their inactivation of alpha-thrombin and the mutant Glu192-->Gln determined. The values of the inactivation rate constant (ki) for the chloromethanes containing a P3 aspartate were about two-fold higher with the Glu192-->Gln mutant. A peptide based on the sequence of hirudin (rhir52 65), which binds to the anion-binding exosite of thrombin, was an allosteric modulator of the amidolytic activity of the Glu192-->Gln mutant; a 5-fold decrease in the K(m) value for the substrate D-Phe-pipecolyl-Arg-p-nitroanilide was observed in the presence of saturating concentrations of rhir52-65. This exosite-binding peptide also increased the ki values of chloromethanes containing a P3 aspartate with both alpha-thrombin and the Glu192-->Gln mutant. However, the increases in the ki values were greater with the Glu192-->Gln mutant (5-fold compared with 2-fold for alpha-thrombin). Thus exosite binding does not seem to mitigate putative unfavourable interactions between Glu192 and the P3 aspartate. Moreover, increases in the ki caused by exosite binding were not unique to chloromethanes containing a P3 aspartate; increases of the same magnitude were also observed when the P3 position was occupied by the favourable D-phenylalanine in place of the unfavourable aspartate. The results obtained were consistent with exosite binding's causing changes in the conformation of the S2 and/or S1 site of thrombin.

Cleavage of the thrombin receptor: identification of potential activators and inactivators.

The kinetic parameters were determined for the hydrolysis of a peptide based on the activation site of the thrombin receptor (residues 38-60) by thrombin and 12 other proteases. The kcat and Km values for the cleavage of this peptide (TR39-40) by thrombin were 107 s-1 and 1.3 microM; the kcat/Km of TR39-40 is among the highest observed for thrombin. A model is presented that reconciles the parameters for cleavage of the peptide with the concentration dependence of cellular responses to thrombin. Cleavage of TR39-40 was not specific for thrombin. The pancreatic proteases trypsin and chymotrypsin hydrolysed TR39-40 efficiently (kcat/Km > 10(6) M-1.s-1). Whereas trypsin cleaved TR39-40 at the thrombin activation site (Arg41-Ser42), chymotrypsin hydrolysed the peptide after Phe43. This chymotryptic cleavage would result in inactivation of the receptor. The efficient cleavage of TR39-40 by chymotrypsin (kcat/Km approximately 10(6) M-1.s-1) was predominantly due to a low Km value (2.8 microM). The proteases factor Xa, plasmin, plasma kallikrein, activated protein C and granzyme A also hydrolysed TR39-40 at the Arg41-Ser43 bond, but exhibited kcat/Km values that were at least 10(3)-fold lower than that observed with thrombin. Both tissue and urokinase plasminogen activators as well as granzyme B and neutrophil elastase were unable to cleave TR39-60 at appreciable rates. However, neutrophil cathepsin G hydrolysed the receptor peptide after Phe55. Like the chymotryptic cleavage, this cleavage would lead to inactivation of the receptor, but the cathepsin G reaction was markedly less efficient; the kcat/K(m) value was almost four orders of magnitude lower than that for thrombin. In addition to the above cleavage sites, a secondary site for thrombin and other arginine-specific proteases was identified at Arg46, but the cleavage at this site only occurred at very low rates and is unlikely to be significant in vivo.

Role of the P2 residue in determining the specificity of serpins.

The importance of the P2 residue in determining serpin specificity was examined by making a series of substitutions in the P2 position of recombinant alpha 1-antichymotrypsin that contained an arginine P1 residue. The importance of the P2 residue in governing the association rate constant (Kon) of the serpin varied with the protease examined. For trypsin, the P2 residue played a relatively minor role, whereas the nature of this residue markedly influenced the rates of inhibition of thrombin, factor Xa, and APC. A 1000-fold difference in Kon values was observed between the fastest (P2 proline) and the slowest (P2 threonine) inhibitors of thrombin. Similar differences were observed with factor Xa; the best inhibitor (P2 glycine) displayed a 200-fold higher Kon value than the poorest (P2 threonine). The nature of the P2 residue also affected whether the interaction of the serpin with the protease resulted in inhibition of the protease or cleavage of the serpin; a P2 proline residue increased the rate of cleavage of alpha 1-antichymotrypsin by trypsin. By using mutants of thrombin, it was possible to show that the B-insertion loop, which partially occludes the active site, is important in determining the P2 specificity of this enzyme. Deletion of three amino acids from this loop yielded a protease (des-PPW) that became more like trypsin in its specificity. In addition, it was shown that Glu192 dramatically restricts thrombin's ability to accommodate a threonine in the P2 position. Taken together, the results demonstrated the importance of complementary interactions between the P2 residue of the serpin and the S2 binding site of the protease in regulating the specific interaction between serpin and protease.

Characterization of the P2' and P3' specificities of thrombin using fluorescence-quenched substrates and mapping of the subsites by mutagenesis.

The importance of substrate residues P2' and P3' on thrombin catalysis has been investigated by comparing the hydrolysis of a series of fluorescence-quenched substrates. Each consisted of a 10-residue peptide, carrying a 2-aminobenzoyl (Abz) group at the N-terminus, and a penultimate 2,4-dinitrophenyl (Dnp) derivatized lysine. Cleavage of such a peptide relieves the intramolecularly-quenched fluorescence, allowing determination of the kinetic parameters. The nature of the P2' residue was found to have a major influence on the rate of cleavage: the Kcat/Km value for the hydrolysis of the Arg-Ser bond in Abz-Val-Gly-Pro-Arg-Ser-Phe-Leu-Leu-Lys(Dnp)-Asp-OH was nearly 3 orders of magnitude higher than that for the hydrolysis of the same substrate with aspartate instead of phenylalanine at the P2' position. Comparatively, the P3' side chain was less important: the kcat/Km value for the substrate with the least effective residue (aspartate) was only 33 times lower than that of the substrate with the most favorable amino acid (lysine). The role of thrombin residues Arg35, Lys36, Glu39 and Lys60f in the putative P2' and P3' binding sites was also examined. Replacement of Lys60f by glutamine improved the rate of cleavage for peptides with P2' lysine or leucine. Compared with thrombin, mutants E39K and E39Q hydrolyzed faster substrates with an acidic residue in P2' or P3', but slightly slower those with a lysine at either position. Mutations R35Q and K36Q only improved the hydrolysis of substrates with an acidic P2' residue. Overall, thrombin prefers bulky hydrophobic side chains in subsite S2' and positively charged residues in S3', whereas acidic residues are markedly antagonistic to both subsites.

Analysis of the platelet-type thrombin receptor in 20 cases of large granular lymphocyte proliferations.

The platelet-type thrombin receptor was expressed by large granular lymphocytes (LGLs) in a variety of proliferative diseases. Twenty patients with LGL proliferative disease were examined, including five T cell clones and a variety of polyclonal proliferations, some secondary to rheumatoid arthritis and Felty's syndrome; 17/20 showed high number of CD3+, CD8+, and CD57+ lymphocytes and 9/20 also had high numbers of CD16+ or CD 56+ positive lymphocytes. The thrombin receptor was present on more than 20% of the LGLs in 13/20 patients. The clonal T cell expansions showed the highest receptor expression with greater than 75% cells positive. Regression analysis of all 20 cases showed striking and highly statistically significant positive Spearman rank correlation between the proportion of thrombin receptor and CD57-positive LGLs (r = 0.56, P = 0.009). A negative correlation with CD56 was also found (r = -0.46, P= 0.043). Dual antibody flow cytometry showed the receptor was more often co-expressed with CD57 (64%) than with CD16 (19%) or CD56 (11%). The expression of the platelet-type thrombin receptor by LGLs of this phenotype raises the possibility of a functional role for thrombin in the pathogenesis of LGL proliferative diseases.