Isolation and characterization of staphylocoagulase chymotryptic fragment. Localization of the procoagulant- and prothrombin-binding domain of this protein

Several strains of Staphylococcus aureus secrete a protein, staphylocoagulase, that binds stoichiometrically to human prothrombin, resulting in a coagulant complex designated staphylothrombin. In the present study, staphylocoagulase was digested with alpha-chymotrypsin and the resulting fragments were isolated by gel filtration. One fragment (Mr 43,000) exhibited a high affinity for human prothrombin (Kd = 1.7 X 10(-9) M), which is comparable to the affinity observed using intact staphylocoagulase (Kd = 4.6 X 10(-10) M). A complex of the Mr 43,000 fragment and prothrombin possessed both clotting and amidase activity essentially identical to that observed in a complex of intact staphylocoagulase and prothrombin. A second fragment (Mr 30,000) exhibited weaker affinity for prothrombin (Kd = 1.2 X 10(-7) M). While clotting activity was not observed with a complex of this fragment and prothrombin, it nonetheless possessed a weak amidase activity. A third fragment (Mr 20,000) was found to bind to prothrombin, but the resultant complex did not exhibit clotting or amidase activity. Amino-terminal sequence analyses of these staphylocoagulase fragments revealed that the Mr 43,000 fragment constitutes the amino-terminal portion of staphylocoagulase and also contains the Mr 30,000 and 20,000 fragments. Moreover, the amino-terminal sequence of the Mr 20,000 fragment was identical to that observed for the Mr 30,000 fragment. From these results, we conclude that the functional region of staphylocoagulase for binding and activation of human prothrombin is localized in the amino-terminal region of the intact bacterial protein.     

Staphylocoagulase-binding region in human prothrombin

A staphylocoagulase-binding region in human prothrombin was studied by utilizing several fragments prepared from prothrombin by limited proteolysis. Bovine prothrombin, prethrombin 1, prethrombin 2, and human diisopropylphosphorylated alpha-thrombin strongly inhibited formation of the complex ("staphylothrombin") between human prothrombin and staphylocoagulase, but bovine prothrombin fragment 1 and fragment 2 had no effect on the complex formation, indicating that the binding region of human prothrombin for staphylocoagulase is located in the prethrombin 2 molecule. To identify further the staphylocoagulase-binding region, human alpha-thrombin was cleaved into the NH2-terminal large fragment (Mr = 26,000) and the COOH-terminal fragment (Mr = 16,000) by porcine pancreatic elastase. Of these fragments, the COOH-terminal fragment, which includes Asn-200 to the COOH-terminal end of the alpha-thrombin molecule, partially inhibited the complex formation between staphylocoagulase and human prothrombin. In contrast, the NH2-terminal large fragment did not show any inhibitory effect on the staphylothrombin formation. These results suggest that the staphylocoagulase interacts with human prothrombin through the COOH-terminal region of alpha-thrombin B chain. Other plasma proteins, factor X, factor IX, protein C, protein S, protein Z, all of which are structurally similar to prothrombin, did not inhibit the staphylothrombin formation at all, indicating that a specific interaction site with staphylocoagulase is contained only in the prothrombin molecule.     

Enzymatic properties of staphylothrombin, an active molecular complex formed between staphylocoagulase and human prothrombin

Staphylocoagulase with a molecular weight of 64,000 and subspecies ranging in molecular weight from 36,000 to 64,000 were purified by affinity column chromatography on bovine prothrombin-Sepharose 4B from the culture filtrates of the Staphylococcus aureus strains, st-213 and 104. The samples containing all molecular species from both strains had the same NH2-terminal sequence, Ile-Val-Thr-Lys-Asp-Tyr-Ser-Lys-Glu-, implying that the molecular heterogeneity was due to proteolytic degradation to some extent of the COOH-terminal portion during cultivation or purification. Staphylocoagulase (Mr = 64,000) from strain st-213 formed an active complex, "staphylothrombin," with human prothrombin in a molar ratio of 1 to 1.1. Staphylothrombin was unstable at 37 degrees C and some portions of staphylocoagulase in the complex were rapidly degraded into small fragments, together with the fragmentation of prothrombin into prethrombin 1 and prothrombin fragment 1. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis and subsequent fluorography for the products of prothrombin activation by staphylocoagulase in the presence of [3H]diisopropylphosphofluoridate (DFP) demonstrated the formation of a DFP-sensitive active site in the prothrombin molecule, and no cleavage of the Arg-Ile bond linking the A and B chains of alpha-thrombin was found. The enzymatic properties including the pH-dependency of the activity, substrate specificity and behavior towards thrombin inhibitors of staphylothrombin differed from those of alpha-thrombin, although the active site titration of staphylothrombin with p-nitrophenyl-p'-guanidinobenzoate showed 0.95 +/- 0.2 mol of active site/mol of enzyme.     

Thrombin generation and inactivation in the presence of antithrombin III and heparin

We have determined the rate constants of inactivation of factor Xa and thrombin by antithrombin III/heparin during the process of prothrombin activation. The second-order rate constant of inhibition of factor Xa alone by antithrombin III as determined by using the synthetic peptide substrate S-2337 was found to be 1.1 X 10(6) M-1 min-1. Factor Xa in prothrombin activation mixtures that contained prothrombin, and either saturating amounts of factor Va or phospholipid (20 mol % dioleoylphosphatidylserine/80 mol % dioleoylphosphatidylcholine, 10 microM), was inhibited by antithrombin III with a second-order rate constant that was essentially the same: 1.2 X 10(6) M-1 min-1. When both factor Va and phospholipid were present during prothrombin activation, factor Xa inhibition by antithrombin III was reduced about 10-fold, with a second-order rate constant of 1.3 X 10(5) M-1 min-1. Factor Xa in the prothrombin activation mixture that contained both factor Va and phospholipid was even more protected from inhibition by the antithrombin III-heparin complex. The first-order rate constants of these reactions at 200 nM antithrombin III and normalized to heparin at 1 microgram/mL were 0.33 and 9.5 min-1 in the presence and absence of factor Va and phospholipid, respectively. When the prothrombin concentration was varied widely around the Km for prothrombin, this had no effect on the first-order rate constants of inhibition. It is our conclusion that factor Xa when acting in prothrombinase on prothrombin is profoundly protected from inhibition by antithrombin III in the absence as well as in the presence of heparin.(ABSTRACT TRUNCATED AT 250 WORDS)     

Dissociation of thrombin from platelets by hirudin. Evidence for receptor processing.

Hirudin inhibited the binding of human 125I-alpha-thrombin to the saturable, but not the nonsaturable, sites on washed human platelets. When hirudin was added to a thrombin-platelet mixture, it caused a biphasic dissociation of bound thrombin. A partial dissociation was too rapid to measure and was followed by complete dissociation with a first order rate constant of about 10(-2) s-1. The fraction of bound thrombin in the more slowly dissociable form increased from essentially none after a 5-s preincubation of thrombin and platelets to as much as 75% of saturable binding after a 4-min preincubation. Transition to the slowly dissociable state was not accompanied by an increase in the amount bound and was not observed with active site serine-derivatized thrombin. This is the first evidence with intact platelets of a binding characteristic that depends, as does platelet stimulation, on catalytically active thrombin, suggesting that it may represent physiologically significant receptor processing.     

Characterization of bothrojaracin interaction with human prothrombin

Bothrojaracin (BJC) is a 27-kD snake venom protein from Bothrops jararaca that has been characterized as a potent thrombin inhibitor. BJC binds to exosites I and II, with a dissociation constant of 0.7 nM, and influences but does not block the proteinase catalytic site. BJC also binds prothrombin through an interaction that has not been characterized. In the present work we characterize the interaction of BJC with prothrombin quantitatively for the first time, and identify the BJC binding site on human prothrombin. Gel filtration chromatography demonstrated calcium-independent, 1:1 complex formation between fluorescein-labeled BJC ([5F]BJC) and prothrombin, whereas no interactions were observed with activation fragments 1 or 2 of prothrombin. Isothermal titration calorimetry showed that binding of BJC to prothrombin is endothermic, with a dissociation constant of 76 +/- 32 nM. The exosite I-specific ligand, hirudin(54-65) (Hir(54-65) (SO(3)(-)), displaced competitively [5F]BJC from prothrombin. Titration of the fluorescent hirudin(54-65) derivative, [5F]Hir(54-65)(SO(3)(-)), with human prothrombin showed a dissociation constant of 7.0 +/- 0.2 microM, indicating a approximately 100-fold lower binding affinity than that exhibited by BJC. Both ligands, however, displayed a similar, approximately 100-fold increase in affinity for exosite I when prothrombin was activated to thrombin. BJC efficiently displaced [5F]Hir(54-65)(SO(3)(-)) from complexes formed with thrombin or prothrombin with dissociation constants of 0.7 +/- 0.9 nM and 11 +/- 80 nM, respectively, indicating that BJC and Hir(54-65)(SO(3)(-)) compete for the same exosite on these molecules. The results indicate that BJC is a potent and specific probe of the partially exposed anion-binding exosite (proexosite I) of human prothrombin.     

Structure and function relationship of staphylocoagulase

The bacterial protein staphylocoagulase binds stoichiometrically to human prothrombin, resulting in a coagulant complex, staphylothrombin. The enzymatic properties of staphylothrombin differ from those of -thrombin in their substrate specificities toward natural and synthetic substrates, in addition to their interaction with protease inhibitors. In order to obtain information about the region of staphylocoagulase that interacts with human prothrombin, staphylocoagulase was cleaved by -chymotrypsin. Limited -chymotryptic cleavage of staphylocoagulase yielded three large fragments, of 43, 30, and 20 kD. The 43-kD fragment exhibited a high affinity for human prothrombin (K_d=1.7 nM), which is comparable to the affinity observed using intact staphylocoagulase (K_d=0.46 nM). A complex of the 43-kD fragment and prothrombin possessed both clotting and amidase activity essentially identical to that observed in a complex of intact staphylocoagulase and prothrombin. The 30-kD fragment exhibited weaker affinity for prothrombin (K_d=120 nM.) While clotting activity was not observed with a complex of this fragment and prothrombin, it nonetheless possessed a weak amidase activity. The 20-kD fragment was found only to bind to prothrombin. The NH₂-terminal sequence analyses of these fragments revealed that the 43-kD fragment constitutes the NH₂-terminal portion of staphylocoagulase, and contains the 30-kD and 20-kD fragments. It is therefore concluded that the functional region of staphylocoagulase for binding and activation of prothrombin is localized in the NH₂-terminal region of the intact protein. The 43-kD fragment contained 324 amino acids with a molecular weight of 38,098. The 43-kD fragment had an unusual amino acid composition based on a sequence in which the sum of Asp (28 residues), Asn (22), Glu (35), Gln (9), and Lys (52) residues accounted for more than 45% of the total. A comparison of the amino acid sequence of the 43-kD fragment with that of streptokinase did not reveal any obvious sequence homology. There was also no sequence homology with that of trypsin, -chymotrypsin, and elastase.This article was presented during the proceedings of the International Conference on Macromolecular Structure and Function, held at the National Defence Medical College, Tokorozawa, Japan, December 1985.     

Role of procoagulant lipids in human prothrombin activation. 1. Prothrombin activation by factor X(a) in the absence of factor V(a) and in the absence and presence of membranes.

Activation of prothrombin by factor X(a) requires proteolysis of two bonds and is commonly assumed to occur via by two parallel, sequential pathways. Hydrolysis of Arg(322)-Ile(323) produces meizothrombin (MzII(a)) as an intermediate, while hydrolysis of Arg(273)-Thr(274) produces prethrombin 2-fragment 1.2 (Pre2-F1.2). Activation by human factor X(a) of human prothrombin was examined in the absence of factor V(a) and in the absence and presence of bovine phosphatidylserine (PS)/palmitoyloleoylphosphatidylcholine (25:75) membranes. Four sets of data were collected: fluorescence of an active site probe (DAPA) was sensitive to thrombin, MzII(a), and Pre2-F1.2; a synthetic substrate (S-2238) detected thrombin or MzII(a) active site formation; and SDS-PAGE detected both intermediates and thrombin. The fluorescence data provided an internal check on the active site and SDS-PAGE measurements. Kinetic constants for conversion of intermediates to thrombin were measured directly in the absence of membranes. Both MzII(a) and Pre2-F1.2 were consumed rapidly in the presence of membranes, so kinetic constants for these reactions had to be estimated as adjustable parameters by fitting three data sets (thrombin and MzII(a) active site formation and Pre2 appearance) simultaneously to the parallel-sequential model. In the absence of membranes, this model successfully described the data and yielded a rate constant, 44 M(-1) s(-1), for the rate of MzII(a) formation. By contrast, the parallel-sequential model could not describe prothrombin activation in the presence of optimal concentrations of PS-containing membranes without assuming that a pathway existed for converting prothrombin directly to thrombin without release from the membrane-enzyme complex. The data suggest that PS membranes (1) regulate factor X(a), (2) alter the substrate specificity of factor X(a) to favor the meizothrombin intermediate, and (3) "channel" intermediate (MzII(a) or Pre2-F1.2) back to the active site of factor X(a) for rapid conversion to thrombin.     

Glial-derived neurite-promoting factor is a slow-binding inhibitor of trypsin, thrombin, and urokinase

Glial-derived neurite-promoting factor was found to be a slow-binding inhibitor of trypsin, urokinase, and thrombin. The kinetic mechanism of the inhibition differs among the three proteases. With trypsin and urokinase, an initial protease-factor complex formed which isomerized to a tighter complex. For thrombin, however, no initial complex was kinetically observed. The dissociation constants of the equilibrium complexes of the factor with trypsin, urokinase, and thrombin were 17, 280, and 18 pM, respectively, and the apparent second-order rate constants for the interaction of the factor with these enzymes were, respectively, 4.7 X 10(6), 1.2 X 10(5), and 2.1 X 10(6) M-1S-1. Heparin increased the rate at which the factor reacted with thrombin by over 40-fold to 8.9 X 10(7) M-1S-1 and decreased the dissociation constant of the complex by over 80-fold to 0.3 pM. The values obtained for the apparent second-order rate constants when compared with the kinetics of neurite induction by the factor indicate that the neurite-promoting activity of the factor is not due to the inhibition of urokinase but could be due to the inhibition of an enzyme with a specificity similar to that of thrombin or trypsin. Comparison of the values of the apparent second-order rate constants obtained for the factor with those obtained for protease nexin suggests that these two molecules are very similar in their inhibitory properties.     

Human prothrombinase complex assembly and function on isolated peripheral blood cell populations

A membrane-bound Ca2+-dependent complex of the cofactor Factor Va and the enzyme Factor Xa comprises the prothrombinase coagulation complex which catalyzes the proteolytic conversion of prothrombin to thrombin. Analyses of the kinetics of prothrombin activation permit calculation of the stoichiometry and binding parameters governing the functional interactions of Factor Va and Factor Xa with isolated thrombin-activated human platelets and isolated leukocyte subpopulations. Our kinetic approach indicates that Factor Xa binds to approximately 2700 +/- 1000 (n = 8) functional sites on the surface of thrombin-activated platelets with an apparent dissociation constant (Kd) equal to 1.18 +/- 0.53 X 10(-10) M and kcat equal to 19 +/- 7 mol of thrombin/s/mol of Factor Xa bound. The store of Factor V in normal platelets prevents an analogous determination of the functional Factor Va platelet binding sites. Factor Va and Factor Xa titrations performed using platelets from a Factor V antigen-deficient individual indicate that Factor Va and Factor Xa form a 1:1 stoichiometric complex on the surface of thrombin-activated platelets. Both binding isotherms are governed by the same apparent Kd (approximately equal to 10(-10) M) and expressed the same kcat/site (14-17 s-1. Factor Xa-platelet binding parameters are not altered by the use of different platelet agonists, the choice of anticoagulant, or platelet washing procedure. Kinetics of prothrombin activation indicate also that monocytes, lymphocytes, and neutrophils possess, respectively, 16,000, 45,000, and 8,000 Factor Va-Factor Xa receptor sites/cell, which are all governed by apparent KdS approximately equal to 10(-10) M. Enzymatic complexes bound to monocytes or neutrophils exhibit kcat values similar to the platelet-bound complex. Complexes bound to lymphocytes are only 25% as active.     

Aprotinin can inhibit the proteolytic activity of thrombin. A fluorescence and an enzymatic study.

Aprotinin has been shown to reduce blood loss and blood requirement when administered prior to surgery and this therapeutic benefit appears to be related to its specificity as a protease inhibitor. The inhibition of plasmin by aprotinin is well characterized, but little is known of its effect on thrombin. In preliminary experiments, we showed that aprotinin can prevent platelet aggregation induced by thrombin. Follow-up studies have now been performed in order to clarify the effect of aprotinin on thrombin. A fluorescence study of the direct binding of aprotinin to human alpha-thrombin was analysed according to the Michaelis-Menten model and a dissociation constant of 30 x 10(-6) mol.l-1 was determined. Aprotinin can displace p-aminobenzamidine, a fluorescent-probe molecule which binds to the active site of serine proteases, showing that the active site of thrombin was involved. Aprotinin also inhibited the ability of thrombin to induce a fibrin clot from purified fibrinogen and to induce the hydrolysis of the chromogenic substrate H-D-phenylalanylpipecolylarginine-p-nitroanalidehydrochloride++ + (S-2238). With S-2238, double-reciprocal plots show that the inhibition is competitive with a Ki of 61 microM and a Km of 1.72 microM. Aprotinin was a potent inhibitor of thrombin-induced aggregation. A Schild plot of the aggregation data yielded a slope of 0.97 +/- 0.12 and an apparent dissociation constant of 57.0 +/- 13.1 microM (mean +/- SEM). Thus, the inhibition of thrombin-induced platelet aggregation by aprotinin fits a model of competitive inhibition. Conclusions are that, in addition to a possible direct effect of aprotinin on platelets, the inhibition of thrombin-induced platelet activation by aprotinin can be also explained, in part, by a direct effect of the inhibitor on the thrombin molecule itself. This supports the concept that a proteolytic step is involved in the platelet response to thrombin. Finally, evidence is in favour of the participation of Trp245 in the fluorescence response of thrombin on binding to aprotinin.     

The in situ inhibition of prothrombinase-formed human alpha-thrombin and meizothrombin(des F1) by antithrombin III and heparin

The inhibition of thrombin by antithrombin III (AT III) and heparin has been studied in pure systems to determine the kinetics of inhibition during human prothrombin activation. The present study shows that prothrombinase-catalyzed prothrombin activation resulted in the generation of thrombin and meizothrombin(des F1). In the absence of heparin the second-order rate constants of the inactivation of both thrombin and meizothrombin(des F1) formed in the reaction mixture appeared to be identical, k = 3.7 X 10(5) M-1 min-1. The rate constant of inhibition of purified thrombin was 6.5 X 10(5) M-1 min-1. In the presence of heparin the decay of the amidolytic activity was biexponential and could be modeled by a four-parameter equation to determine the pseudo first-order rate constants of inhibition as well as the composition of the reaction with respect to the levels of thrombin and meizothrombin(des F1). The ratio of thrombin over meizothrombin(des F1) varied with the initial prothrombin concentration. Heparin catalyzed the AT III inhibition of thrombin but not meizothrombin(des F1) formed during the prothrombin activation. Thrombin, generated by (Xa-Va-phospholipid-Ca2+) was inhibited by AT III/heparin more slowly than purified thrombin, and the saturation kinetics of the inhibition with respect to AT III differed from those found with purified thrombin.     

Proteolytic formation of either of the two prothrombin activation intermediates results in formation of a hirugen-binding site.

Hirugen, a synthetic dodecapeptide corresponding to the carboxyl-terminal amino acids 53-64 of hirudin, binds within a deep groove in thrombin that contains a cationic region referred to as the anion-binding exosite. This region is important in many of the binary interactions of thrombin with macromolecular substrates and cofactors. Fluorescein-labeled hirugen was used to probe which steps in the prothrombin activation process generate this anion-binding exosite. Two activation cleavage sites exist in bovine prothrombin. Cleavage at Arg274-Thr275 releases the activation fragments to generate the thrombin precursor, prethrombin 2. Cleavage of prothrombin within a disulfide loop at Arg323-Ile324 leads to formation of meizothrombin with no loss of peptide material but with formation of amidolytic activity. Cleavage of the same bond in prethrombin 2 generates thrombin. Hirugen, labeled at the amino terminus with fluorescein isothiocyanate, does not bind to prothrombin but does bind to thrombin (Kd = 9.6 +/- 1.2 x 10(-8) M), prethrombin 2 (Kd = 1.3 +/- 0.1 x 10(-7) M), thrombin-fragment-2 complex (Kd = 1.1 +/- 0.2 x 10(-6) M), and meizothrombin (Kd = 1.6 +/- 0.5 x 10(-8) M). Prothrombin fragment-2 and hirugen both bind independently to thrombin. A ternary complex can form with hirugen and fragment-2 and either thrombin or prethrombin 2, suggesting that fragment-2 and hirugen bind to discrete sites. Hirugen also alters the active site conformation of thrombin as detected by modulation of synthetic substrate hydrolytic activity. These studies suggest that conformational changes, rather than alleviating steric hindrance, are responsible for the formation of the hirugen-binding site during prothrombin activation. Furthermore, this conformational change can be effected by the cleavage of either of the two bonds required for activation of prothrombin.     

Involvement of heparin chain length in the heparin-catalyzed inhibition of thrombin by antithrombin III

The mechanism of the heparin-promoted reaction of thrombin with antithrombin III was investigated by using covalent complexes of antithrombin III with either high-affinity heparin (Mr = 15,000) or heparin fragments having an average of 16 and 12 monosaccharide units (Mr = 4,300 and 3,200). The complexes inhibit thrombin in the manner of active site-directed, irreversible inhibitors: (Formula: see text) That is, the inhibition rate of the enzyme is saturable with respect to concentration of complexes. The values determined for Ki = (k-1 + k2)/k1 are 7 nM, 100 nM, and 6 microM when the Mr of the heparin moieties are 15,000, 4,300, 3,200, respectively, whereas k2 (2 S-1) is independent of the heparin chain length. The bimolecular rate constant k2/Ki for intact heparin is 3 X 10(8) M-1 S-1 and the corresponding second order rate constant k1 is 6.7 X 10(8) M-1 S-1, a value greater than that expected for a diffusion-controlled bimolecular reaction. The bimolecular rate constants for the complexes with heparin of Mr = 4,300 and 3,200 are, respectively, 2 X 10(7) M-1 S-1 and 3 X 10(5) M-1 S-1. Active site-blocked thrombin is an antagonist of covalent antithrombin III-heparin complexes: the effect is monophasic and half-maximum at 4 nM of antagonist against the complex with intact heparin, whereas the effect is weaker against complexes with heparin fragments and not monophasic. We conclude that virtually all of the activity of high affinity, high molecular weight heparin depends on binding both thrombin and antithrombin III to heparin, and that the exceptionally high activity of heparin results in part from the capacity of thrombin bound nonspecifically to heparin to diffuse in the dimension of the heparin chain towards bound antithrombin III. Increasing the chain length of heparin results in an increased reaction rate because of a higher probability of interaction between thrombin and heparin in solution.     

The use of prothrombin(S525C) labeled with fluorescein to directly study the inhibition of prothrombinase by antithrombin during prothrombin activation

Serine 525 of human prothrombin was mutated to cysteine and covalently labeled with fluorescein to make II(S525C)-fluorescein. Kinetics of cleavage of this derivative by prothrombinase are identical to those of wild-type prothrombin. Cleavage is coincident with a 50% increase in fluorescence intensity and the product is catalytically inactive. Thus, it allows convenient monitoring of prothrombin activation without generating active thrombin. The kinetics of inhibition of factor Xa (FXa) by antithrombin (AT) and AT-heparin were measured by monitoring activation of II(S525C)-fluorescein and the hydrolysis of the chromogenic substrate S2222 in the presence of AT. With S2222 as the substrate the rate constant for inhibition of FXa, Ca(2+), and unilamellar vesicles of phosphatidylcholine and phosphatidylserine (75:25) (PCPS) vesicles by AT was 3.51 x 10(3) m(-1) s(-1); when factor Va (FVa) was included the rate constant was 1.55 x 10(3) m(-1) s(-1). In the absence of FVa, II(S525C)-fluorescein had no effect on inhibition. When II(S525C)-fluorescein was the substrate, however, FVa at saturating concentrations profoundly protected FXa from inhibition by AT, increasing the half-life from 3 min with FXa, Ca(2+), PCPS, and II(S525C)-fluorescein, to greater than 69 min when FVa was included. Thus, both FVa and prothrombin are necessary for this level of protection. In the absence of prothrombin, FVa decreased the second order rate constant for inhibition by the AT-heparin complex from 1.58 x 10(7) m(-1) s(-1), for FXa, Ca(2+), and PCPS, to 7.72 x 10(6) m(-1) s(-1). II(S525C)-fluorescein and factor Va together reduced the rate constant to less than 1% of that for FXa, Ca(2+), and PCPS. At a heparin concentration of 0.2 unit/ml, this corresponds to a half-life increase from 1 s to 136 s.     

Binding of histidinal to histidinol dehydrogenase

One molecule of the enzymatic intermediate histidinal is firmly bound per subunit of histidinol dehydrogenase (EC 1.1.1.23) and protected against decomposition. The dissociation rate constant of the histidinal--histidinol dehydrogenase complex is estimated as 2.5 X 10(-5) S-1. Steady-state kinetic measurements studying the oxidation of histidinal to histidine and the reduction of histidinal to histidinol allow to calculate the association rate constants for histidinal. For both reactions the association rate constant is found as 1.9 X 10(6) M-1 S-1. Thus the dissociation constant of the histidinal--histidinol dehydrogenase complex is estimated to be of the order of 1.4 X 10(-11) M.     

The contribution of bovine Factor V and Factor Va to the activity of prothrombinase.

The rates of prothrombin activation under initial conditions of invariant concentrations of prothrombin and Factor Xa were studied in the presence of various combinations of Ca2+, homogeneous bovine Factor V, Factor Va, phosphatidylcholine-phosphatidylserine vesicles, and activated bovine platelets. Reactions were monitored continuously through the enhanced fluorescence accompanying the interaction of newly formed thrombin with dansylarginine-N-(3-ethyl-1,5-pentanediyl) amide. The complete prothrombinase (Factor Xa, Ca2+, phospholipid, and Factor Va) behaved as a "typical" enzyme and catalyzed the activation of prothrombin with an apparent Vmax of 2100 mol of thrombin/min/mol of Factor Va or Factor Xa, whichever was the rate-limiting component. Regardless of whether the enzymatic complex was composed of Factor Xa, Ca2+, and plasma Factor Va plus phospholipid vesicles, or activated platelets in the place of the latter components, similar specific activity values were observed. The combination of Factor Va, Ca2+, and phospholipid enhanced the rate of the Factor Xa-catalyzed activation of prothrombin by a factor of 278,000. Factor Va itself when added to Factor Xa, Ca2+, and phospholipid, enhanced the rate of prothrombin activation by a factor of 13,000. Unactivated Factor V appears to possess 0.27% of the procoagulant activity of thrombin-activated Factor Va. From the kinetics of prothrombinase activity, an interaction between Factor Xa and both Factor V and Factor Va was observed, with apparent 1:1 stoichiometries and dissociation constants of 7.3 x 10(-10) M for Factor Va and 2.7 x 10(-9) M for Factor V. The present data, combined with data on the equilibrium binding of prothrombinase components to phospholipid, indicate that the model prothrombinase described in this paper consists of a phospholipid-bound, stoichiometric complex of Factor Va and Factor Xa, with bound Factor Va serving as the "binding site" for Factor Xa, in concert with its proposed role in platelets.     

Interaction of clotting factor V heavy chain with prothrombin and prethrombin 1 and role of activated protein C in regulating this interaction: analysis by analytical ultracentrifugation

Changes in the affinity of the heavy subunit of blood coagulation factor Va (Vh) for prothrombin are thought to be important in regulating the rate of thrombin production. Using analytical ultracentrifugation, we have measured the affinity of bovine Vh for prothrombin and for the prethrombin 1 fragment of prothrombin at 23.3 degrees C, pH 7.65, in 50 mM tris(hydroxymethyl)aminomethane, 0.1 M NaCl, 0.1 mM benzamidine, and either 2 mM Ca2+ or 2 mM ethylenediaminetetraacetate (EDTA). Under these conditions a 1:1 complex of Vh with prothrombin is formed that is governed by a dissociation constant (Kd) of 10 microM, regardless of whether the buffer contains Ca2+ or EDTA. An identical Kd is observed when prethrombin 1 is substituted for prothrombin. This indicates that the fragment 1 portion of prothrombin, containing the gamma-carboxyglutamic acid residues, does not influence the association. Substitution of human prethrombin 1 for the bovine molecule also results in a 1:1 Vh-prethrombin 1 complex governed by a slightly weaker Kd (27 microM). Discrete proteolysis of bovine Vh by the anticoagulant activated protein C converts the Vh to a form with little or no affinity for prethrombin 1 (Kd greater than 1 mM), without detectable change in the mass of the Vh.     

Meizothrombin formation during factor Xa-catalyzed prothrombin activation. Formation in a purified system and in plasma

Meizothrombin and thrombin formation were quantitated during factor Xa-catalyzed activation of human prothrombin in reaction systems containing purified proteins and in plasma. In the purified system considerable amounts of meizothrombin accumulated when prothrombin was activated by factor Xa (with or without accessory components) under initial steady state conditions. The ratio of the rates of meizothrombin and thrombin formation was not influenced by variation of the pH, temperature, or ionic strength of the reaction medium. When 2 microM prothrombin was activated by the complete prothrombinase complex (factor Xa, factor Va, Ca2+, and phospholipid) 80-90% of the initially formed reaction product was meizothrombin. Lowering the prothrombin concentration from 2 to 0.03 microM caused a gradual decrease in the ratio of meizothrombin/thrombin formation from 5 to 0.6. When the phosphatidylserine content of the phospholipid vesicles was varied between 20 and 1 mol % and prothrombin activation was analyzed at 2 microM prothrombin the relative amount of meizothrombin formed decreased from 85 to 55%. With platelets, cephalin, or thromboplastin as procoagulant lipid, thrombin was the major reaction product and only 30-40% of the activation product was meizothrombin. We also analyzed complete time courses of prothrombin activation both with purified proteins and in plasma. In reaction systems with purified proteins substantial amounts of meizothrombin accumulated under a wide variety of experimental conditions. However, little or no meizothrombin was detected in plasma in which coagulation was initiated via the extrinsic pathway with thromboplastin or via the intrinsic pathway with kaolin plus phospholipid (cephalin, platelets, or phosphatidylserine-containing vesicles). Thus, thrombin was the only active prothrombin activation product that accumulated during ex vivo coagulation experiments in plasma.     

Electrostatic dependence of the thrombin-thrombomodulin interaction

The rate constants for the binding interaction between thrombin and a fully active fragment of its anticoagulant cofactor, thrombomodulin, have been determined by surface plasmon resonance. At physiological ionic strength, the k(a) was 6.7x10(6) M(-1) s(-1 )and the dissociation rate constant was 0.033 s(-1). These extremely fast association and dissociation rates resulted in an overall binding equilibrium constant of 4.9 nM, which is similar to previously reported values. Changing the ionic strength from 100 mM to 250 mM NaCl caused a tenfold decrease in the association rate while the dissociation rate did not change significantly. A similar effect was observed with tetramethylammonium chloride. A Debye-Hückel plot of the data had a slope of -6 and an intercept at 0 ionic strength of 10(9) M(-1) s(-1). The same slope and intercept were obtained for data that was collected in the presence of glycerol to slow the association rates. These results show that the thrombin-TM456 interaction is extremely rapid and nearly completely electrostatically steered. An association model is presented in which TM456 approaches thrombin along the direction of the thrombin molecular dipole.