Molecular recognition sites on factor Xa which participate in the prothrombinase complex.

Coagulation factor X, when activated to factor Xa by proteolytic cleavage, itself becomes an active serine protease which participates as a component of the macromolecular prothrombinase complex along with factor Va, phospholipid, and calcium ions. To identify specific structural regions on factor Xa responsible for mediating its function in activating prothrombin, we used 21 synthetic peptides corresponding to 65% of the primary structure of factor X as potential inhibitors of prothrombin activation. Using purified components, thrombin formation was inhibited by seven peptides in a dose-dependent noncompetitive manner. Antibodies to selected inhibitory peptides affinity purified on a factor Xa-agarose column inhibited thrombin formation in a dose-dependent manner, indicating that the corresponding regions on factor Xa are surface-exposed. Kinetic analyses varying the order of reagent addition suggested that peptides 211-222, 254-269, and 263-274 were highly effective in preventing the factor Xa-factor Va interaction. Peptides 275-287 and 415-425 were considered to derive from a distal region involved in substrate binding, based upon mixed inhibition kinetic analyses and assuming that inhibitory peptides not inhibitory in factor Va binding are related to a specific region of substrate interaction. Cross-linking studies confirmed that peptides 263-274 and 263-276 could bind specifically to the light chain of factor V/Va. These findings provide the basis for further pursuing the precise definition of interactive sites on factor Xa using site-directed mutagenesis and molecular modeling.     

Structural transitions in bovine factor X associated with metal binding and zymogen activation. Studies using conformation-specific antibodies

Conformation-specific antibodies against distinct regions of Factor X were employed to locate antigenic determinants which are altered during zymogen activation or by metal binding. Anti-Factor X antibodies, raised in rabbits against Factor X, were purified by affinity chromatography using Factor X covalently bound to Sepharose. Quantitative equilibrium and kinetic measurements of precipitation of Factor X and Factor Xa by antibodies indicated differences in the antigenic structure of the zymogen and the enzyme form of factor X. The factor X antibodies were further fractionated by sequential immunoabsorption using fragments of Factor X and Factor Xa. With conformation-specific antibodies directed against the heavy chain and the light chain of Factor X, zymogen activation was shown to involve a structural transition in the heavy chain but not the light chain. Antibodies directed against the activation peptide domain 1-51 of the heavy chain, the trypsin-like region of the heavy chain 52-290, and the substrate-binding site suggest a generalized conformational transition in the heavy chain. Antibodies were isolated which are specific for the Factor X:Ca(II) complex and bind to Factor X only in the presence of metal ions. Subfractions were directed against either the heavy chain or the light chain, indicating that both the heavy chain and the light chain of Factor X undergo a metal-induced conformational transition. Half-maximal antibody-factor X interaction was observed at 0.13 mM CaCl2 for the light chain and 0.7 mM CaCl2 for the heavy chain. These results indicate that zymogen activation is limited to structural changes in the heavy chain, but metal binding is associated with changes in the structure of both the heavy and light chains. Metal-dependent binding of Factor X to the platelet Factor Xa receptor after activation may involve surfaces of the heavy as well as the light chains.     

The activation of coagulation factor X. Identity of cleavage sites in the alternative activation pathways and characterization of the COOH-terminal peptide.

Bovine Factor X can be activated by two alternative pathways. The first, favored at high concentrations of the complex of tissue factor and Factor VII, is initiated by the action of Factor VII on Factor X to cleave an activation peptide from the NH2 terminus of the heavy chain, to produce alpha-Xa. This is then converted autocatalytically to another form of Factor Xa, beta-Xa, by the loss of a 17-residue glycopeptide from the COOH terminus of the heavy chain, in a lipid-dependent reaction. The alternative pathway, favored at lower activator concentrations, is initiated by the action of Factor Xa on Factor X, in the presence of lipid, to release the same COOH-terminal peptide as is produced in the conversion of alpha-Xa to beta-Xa. The intermediate produced by the loss of this peptide from Factor X,I1, can be activated directly to beta-Xa by the tissue factor-Factor VII complex, with the loss of the same NH2-terminal peptide as is produced in the conversion of Factor X to alpha-Xa. The autocatalytic activation of Factor X by Factor Xa described previously occurs to a marked extent only at very low activator concentrations, and has been shown to proceed largely by the loss of the normal NH2-terminal peptide from the heavy chain of I1-Initial experiments show that neither peptide affects the rate of coagulation by either the extrinsic or intrinsic pathways. The amino acid sequences have been determined on both sides of the peptide cleavages, and it has been shown that the cleavage sites are the same, regardless of the pathway of activation. The amino acid sequence and carbohydrate composition of the COOH-terminal peptide have been determined. The carbohydrate moiety is attached via an O-glycosidic linkage at a threonine residue, and contains galactosamine but no glucosamine.     

Pathways in the activation of human coagulation factor X.

Purified human Factor X (apparent mol.wt. 72000), which consists of two polypeptide chains (mol.wt. 55000 and 19000), was activated by both Russell's-viper venom and the purified physiological activators (Factor VII/tissue factor and Factor IXa/Factor VIII). They all convert Factor X to catalytically active Factor Xa (mol.wt. 54000) by cleaving the heavy chain at a site on the N-terminal region. In the presence of Ca2+ and phospholipid, the Factor Xa formed catalyses (a) the cleavage of a small peptide (mol.wt. 4000) from the C-terminal region of the heavy chain of Factor Xa, resulting in a second active form (mol.wt. 50000), and (b) the cleavage of a peptide containing the active-site serine residue (mol.wt. 13000) from the C-terminal region of the heavy chain of Factor X, resulting in an inactivatable component (mol.wt. 59000). A nomenclature for the various products is proposed.     

Exosite-mediated substrate recognition of factor IX by factor XIa. The factor XIa heavy chain is required for initial recognition of factor IX

Studies of the mechanisms of blood coagulation zymogen activation demonstrate that exosites (sites on the activating complex distinct from the protease active site) play key roles in macromolecular substrate recognition. We investigated the importance of exosite interactions in recognition of factor IX by the protease factor XIa. Factor XIa cleavage of the tripeptide substrate S2366 was inhibited by the active site inhibitors p-aminobenzamidine (Ki 28 +/- 2 microM) and aprotinin (Ki 1.13 +/- 0.07 microM) in a classical competitive manner, indicating that substrate and inhibitor binding to the active site was mutually exclusive. In contrast, inhibition of factor XIa cleavage of S2366 by factor IX (Ki 224 +/- 32 nM) was characterized by hyperbolic mixed-type inhibition, indicating that factor IX binds to free and S2366-bound factor XIa at exosites. Consistent with this premise, inhibition of factor XIa activation of factor IX by aprotinin (Ki 0.89 +/- 0.52 microM) was non-competitive, whereas inhibition by active site-inhibited factor IXa beta was competitive (Ki 0.33 +/- 0.05 microM). S2366 cleavage by isolated factor XIa catalytic domain was competitively inhibited by p-aminobenzamidine (Ki 38 +/- 14 microM) but was not inhibited by factor IX, consistent with loss of factor IX-binding exosites on the non-catalytic factor XI heavy chain. The results support a model in which factor IX binds initially to exosites on the factor XIa heavy chain, followed by interaction at the active site with subsequent bond cleavage, and support a growing body of evidence that exosite interactions are critical determinants of substrate affinity and specificity in blood coagulation reactions.     

Molecular recognition in the activation of human blood coagulation factor X

Factor X can be activated by the extrinsic activation complex (factor VIIa:tissue factor), the intrinsic activation complex (factor IXa:factor VIIIa) and by an enzyme from Russell's viper venom (RVV-X). To identify the regions on the surface of factor X that mediate its association with these three activators, we have prepared 21 synthetic peptides representing 65% of the primary structure of factor X. Only 3 of the 21 peptides inhibited the rate of factor X activation, indicating the regions represented by these three peptides are involved in factor X association. Using purified components, the rate of factor Xa formation was inhibited in a dose-dependent manner by these three peptides with the same relative potency of inhibition in each of the activation systems. The observed relative potencies were: peptide 267-283 greater than or equal to peptide 284-303 greater than peptide 417-431. Kinetic analyses indicated that the three peptides inhibited factor X activation in a non-competitive manner, and in mixed inhibitor assays the peptides were shown to be mutually exclusive of one another. In coagulation-based assays, the potency of inhibition by each peptide was decreased. However, in Russell's viper venom-X-initiated assays peptide 417-431 was the best inhibitor. Fab fragments of antibodies raised to these peptides and affinity purified on factor X-agarose columns inhibited both the purified and coagulation-based assays in a dose-dependent manner. Using the x-ray crystal structure of chymotrypsinogen as a model, these three peptides were found to be located spatially close to one another on the surface of factor X and opposite to the region where factor X is cleaved for activation. These data are consistent with a model in which the three activators combine with factor X through a recognition site composed of multiple loci that is distal to the potential cleavage site. This interaction aligns the active sites of these three enzymes in the correct orientation to cleave factor X at the same arginyl-isoleucyl bond.     

Analysis of the generation and inhibition of activated coagulation factor X in pure systems and in human plasma

The overall generation and inhibition of human factor Xa have been studied in pure systems and plasma to determine the kinetic characteristics of inhibition during factor Xa generation. Generation curves were measured amidolytically in a pure system containing factor X and antithrombin, which was activated with the factor X-activating enzyme of Russell's viper venom (RVV-X). The measured change in factor Xa level with time was fitted to a 3-parameter 2-exponential model to determine apparent first-order rates of inhibition. With antithrombin at 4.5 microM, the inhibition rate constant thus obtained was very close to the known rate of inhibition of exogenous enzyme. Factor Xa generation curves were also analyzed in plasma; however, to reduce interference in the assay of thrombin, congenitally prothrombin-deficient plasma was used containing 0.5 microM D-Phe-Pro-Arg-chloromethylketone. In plasma, factor Xa generated in the presence of phospholipid and Ca2+ ions by RVV-X, factor IXa, or tissue factor was inhibited more slowly than exogenous enzyme. The reduction was particularly severe with tissue factor activation, where the rate was 0.04-0.06 min-1. This protection by tissue factor was also observed in pure systems and apparently required factor VII.     

Characterization of rat factors X and Xa: demonstration of factor Xa in rat plasma.

We have found that rat plasma corrected the non-activated PT of human normal or factor-X deficient plasma, and the factor Xa-like activity being constantly detected in every 1 ml of blood collected via the cannulated carotid artery of rats. The present study was undertaken to characterize the factor Xa-like activity in rat plasma by preparing rat factor X and a monoclonal antibody against it. Factor X was purified from a BaCl2 eluate of rat plasma by chromatographies on columns of DEAE-Sepharose CL-6B and Sulfate Cellulofine or on a column of Affi-Gel 10 conjugated with a monoclonal antibody against rat factor X. Factor Xa-like activity in rat plasma was eliminated by the treatment of rat plasma with a monoclonal antibody which recognized the heavy chain portions of rat factors X and Xa. A kinetical study demonstrated that rat factor Xa was strongly inhibited by rat antithrombin III, with a Ki of 2.2 x 10(-11) M, in the presence of heparin. However, in the absence of heparin, the second order rate constant for the inhibition of rat factor Xa by rat antithrombin III was 2.6 x 10(4) M-1.min-1, which was one forty-third that for the inhibition of human factor Xa by human antithrombin III. Furthermore, rat factor Xa was resistant to the inhibition by rat alpha-1-antitrypsin and alpha-2-macroglobulin.(ABSTRACT TRUNCATED AT 250 WORDS)     

The tissue factor region that interacts with factor Xa in the activation of factor VII

Tissue factor is the cell membrane-anchored cofactor for factor VIIa and triggers the coagulation reactions. The initial step is the conversion of factor VII to factor VIIa which, in vitro, is efficiently catalyzed by low concentrations of factor Xa. To identify the tissue factor region that interacts with the activator factor Xa during this process, we evaluated a panel of soluble tissue factor (1-219) mutants for their ability to support factor Xa-mediated activation of factor VII. The tissue factor residues identified as most important for this interaction (Tyr157, Lys159, Ser163, Gly164, Lys165, Lys166, and Tyr185) were identical to those found to be important for the interaction of substrate factor X with the tissue factor.factor VIIa complex. The residues form a continuous surface-exposed patch with an area of about 500 A(2), which appears to be located outside the tissue factor-factor VII contact zone. In agreement, the two monoclonal antibodies 5G6 and D3H44-F(ab')(2), whose epitopes overlap with this identified region, inhibited the rates of factor VII activation by 86% and 95%, respectively. These antibodies also strongly inhibited the conversion of (125)I-labeled factor VII when cell membrane-expressed, full-length tissue factor (1-263) was employed. Together the results suggest the usage of a common surface region of tissue factor in its dual role-as a cofactor for factor Xa-mediated factor VII activation and as a cofactor for factor VIIa-mediated factor X activation. The finding that factor Xa and factor X may engage in similar, if not identical, molecular interactions with tissue factor further indicates that factor Xa and factor X are similarly oriented toward their respective interaction partners in the ternary catalytic complexes.     

Activation and control of factor VII by activated factor X and thrombin. Isolation and characterization of a single chain form of factor VII.

Factor VII purified as previously described, was found to consist of two polypeptide chains joined by disulfide bridges. We now report the isolation and 200,000-fold purification of a single chain form of Factor VII. This was accomplished by protecting the molecule against proteolysis by including benzamidine during the entire purification. The purification was essentially as previously reported except that barium cirtate was substituted for barium sulfate as an absorbant for Factor VII as it resulted in a 4-fold increase in yield. Single chain Factor VII is rapidly hydrolyzed by Factor Xa in the presence of calcium ions and phospholipids, and by thrombin, to a two-chain form which possesses at least 85 times the Factor VII clotting activity of the single chain species. The two-chain form of the enzyme requires tissue factor in order to activate Factor X. From the observed rates of activation of Factor VII by Xa in the presence of clacium ions and phospholipids, it was claculated that at approximately physiological concentration, Factor VII activity would increase at an initial rate of 20-fold per min; this reaction is sufficiently rapid to constitute a feedback control mechanism. The action of thrombin is approximately 40-fold slower under these conditions. Diisopropylphosphorofluoridate inactivates the single chain and two-chain forms of Factor VII at approximately equal rates. After inhibition, the single chain species could be cleaved but not activated by proteolysis.     

The synthesis of arginylfluoroalkanes, their inhibition of trypsin and blood-coagulation serine proteinases and their anticoagulant activity.

Seven arginylfluoroalkanes ('arginine fluoroalkyl ketones') were synthesized by using a modified Dakin-West procedure. The structure of benzoyl-Arg-CF2CF3 was analysed by 19F-n.m.r. spectroscopy and m.s. and the compound was shown to exist primarily as a hydrate or cyclic carbinolamine. Arginylfluoroalkanes are good inhibitors of blood-coagulation serine proteinases and were found to be slow-binding inhibitors for bovine trypsin with Ki values of 0.2-56 microM. Benzoyl-Arg-CF2CF3 was the best inhibitor for bovine thrombin and human Factor XIa, and inhibited thrombin and Factor XIa competitively with Ki values of 13 microM and 62 microM respectively. The best inhibitor for pig pancreatic kallikrein was p-toluoyl-Arg-CF3, with a Ki value of 35 microM. Benzoyl-Arg-CF3 and benzoyl-Arg-CF2CF3 inhibited human plasma kallikrein competitively, with Ki values of 50 microM. None of the seven arginylfluoroalkanes was a good inhibitor of human factor Xa or of Factor XIIa. The arginylfluoroalkanes were tested in the prothrombin time (PT) and activated partial thromboplastin time (APTT) coagulant assays. Two fluoroketones, benzoyl-Arg-CF2CF3 and 1-naphthoyl-Arg-CF3, had significant anticoagulant activity. Benzoyl-Arg-CF2CF3 was found to prolong the PT 1.8-fold at 120 microM and to prolong the APTT 2.4-fold at 90 microM, whereas 1-naphthoyl-Arg-CF3 only prolonged the APTT 1.7-fold at 100 microM.     

Preparation and properties of derivatives of bovine factor X and factor Xa from which the gamma-carboxyglutamic acid containing domain has been removed

Limited proteolysis of bovine blood coagulation Factor X by chymotrypsin produces a derivative in which the light chain is cleaved between Tyr 44 and Lys 45. Two peptide products, residues 1-44 of the Factor X light chain and a modified zymogen, Factor X(-GD) have been isolated and characterized by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, elution behavior on anion-exchange chromatography, amino acid composition, and by partial amino acid sequence determination. Factor X(-GD) no longer contains the 12 gamma-carboxyglutamic acid residues of the native zymogen and thus serves as a model for investigation of the properties conferred on Factor X by the presence of gamma-carboxyglutamic acid. Cleavage of Factor X at Tyr 44 by chymotrypsin is inhibited by Ca2+ and Mg2+ ions. Factor X(-GD) is activated by the coagulation factor activator of Vipera russellii venom, but at less than 1% of the rate of activation of native Factor X. The susceptibility of Tyr 44 to chymotryptic cleavage implies that this residue is on the surface of the light chain of Factor X. Factor Xa(-GD) is indistinguishable from native Factor Xa in its activity on Benzoyl-Ile-Glu-Gly-Arg-p-nitroanilide, on prothrombin alone, and on prothrombin plus Factor Va. In the presence of phospholipid the rate of prothrombin activation catalyzed by Factor Xa(-GD) is the same as in the absence of phospholipid.     

Sphingosine inhibits monocyte tissue factor-initiated coagulation by altering factor VII binding

Tissue factor is a lipoprotein, expressed on the surface of cells, which binds coagulation Factor VII or VIIa, leading to activation of Factors X and IX with subsequent fibrin generation. Cellular tissue factor activity is important in pathophysiologic processes such as inflammation and disseminated intravascular coagulation. In this study, the long-chain base sphingosine inhibited coagulation initiated by lipopolysaccharide-stimulated intact human monocytes. Sphingosine (5-100 microM) also profoundly inhibited thromboplastin-initiated coagulation (greater than 90% decrease in thromboplastin activity). This inhibition was dose- and time-dependent. Sphingosine inhibited neither the intrinsic pathway of coagulation nor thrombin generation of fibrin. The sphingosine analogues sphingomyelin, ceramide, or N-acetylsphingosine did not affect thromboplastin activity, suggesting that the polar head of sphingosine was necessary for interaction of the molecule with the coagulation system. Investigation of the biochemical mechanism revealed that sphingosine (5-50 microM), but neither sphingomyelin nor ceramide, inhibited specific binding of radiolabeled Factor VII to lipopolysaccharide-stimulated intact monocytes. The results suggest that sphingosine may regulate monocyte tissue factor-initiated coagulation by modulating Factor VII binding to tissue factor. Sphingosine may represent a new class of inhibitors of hemostasis.     

Residues Y179 and H101 of a hydrophobic patch of factor VII are involved in activation by factor Xa

We studied factor Xa activation of human factor VII in hopes of identifying factor VII residues, not adjacent to the cleavage site, involved in this interaction. We made eight factor VIIs with single mutations (N100A, H101A, D102Q, L144A, R147A, Y179A, D186A, and F256A) and two factor VIIs with multiple mutations [MM3 (L144A/R147A/D186A) and MM4 (N100A/H101A/Y179A/F256A)]. Residues in MM3 have previously been identified as affecting factor X activation, and the residues of MM4 are located at a hydrophobic patch of factor VII on the opposite side of the catalytic domain from those in MM3. Only H101A, Y179A, and MM4 were activated significantly more slowly than the wild type. Results of our kinetic analyses showed that the catalytic efficiency of factor Xa for activation of factor VII was 176- and 234-fold higher than that for H101A andY179A, respectively. All the mutants with measurable activity had affinities for tissue factor similar to those of the wild type. The activated hydrophobic patch residues, except N100A, which is adjacent to one of the catalytic residues, had normal activities toward both a small peptide substrate and factor X. The rest of the activated mutants (except D102Q with no activity) had reduced activities toward the small substrate (except R147A) and factor X. We conclude that factor VII activation by factor Xa and factor VIIa's catalytic interaction with factor X involve different regions in the catalytic domain, and residues H101 and Y179, part of an aromatic hydrophobic patch, are specifically involved in factor Xa activation of factor VII.     

Binding sites for blood coagulation factor Xa and protein S involving residues 493-506 in factor Va.

Inactivation due to cleavage of Factor Va (FVa) at Arg 506 by activated protein C (APC) helps to downregulate blood coagulation. To identify potential functional roles of amino acids near Arg 506, synthetic overlapping pentadecapeptides comprising FVa heavy chain residues 481-525 were tested for their ability to inhibit prothrombin activation by prothrombinase complexes [Factor Xa (FXa):FVa:phospholipids:Ca2+]. The most potent inhibition was observed for peptide VP493 (residues 493-506), with 50% inhibition at 2.5 microM. VP493 also inhibited FXa in plasma in FXa-1-stage clotting assays by 50% at 3 microM. When the C-terminal carboxamide group of VP493 was replaced by a carboxyl group, most prothrombinase inhibitory activity was lost. VP493 preincubated with FXa inhibited prothrombinase with a pattern of mixed inhibition. Homologous peptides from Factor VIII sequences did not inhibit prothrombinase. Affinity-purified antibodies to VP493 inhibited prothrombinase activity and prolonged FXa-1-stage clotting times. VP493 also blocked the ability of protein S to inhibit prothrombinase independently of APC. Immobilized VP493 bound specifically with similar affinity to both FXa and protein S (Kd approximately 40 nM), but did not measurably bind prothrombin or APC. These studies suggest that FVa residues 493-506 contribute to binding sites for both FXa and protein S, providing a rationale for the ability of protein S to negate the protective effect of FXa toward APC cleavage of FVa. Possible loss of this FVa binding site for FXa due to cleavage at Arg 506 by APC may help explain why this cleavage causes 40% decrease in FVa activity and facilitates inactivation of FVa.     

Blood coagulation induced by the venom of Bothrops atrox. 2. Identification, purification, and properties of two factor X activators

We have characterized and purified the two components of the venom of Bothrops atrox that activate the coagulation factor X. Activator 1 and activator 2 were separated by ion-exchange chromatography but otherwise presented similar characteristics. They consist of a heavy polypeptide of Mr 59,000 and either one or two light chains forming a doublet of Mr 14,000-15,000. They are inactive on synthetic substrates and on prothrombin or fibrinogen and thus appear to act specifically on factor X. They are not sensitive to inhibitors of serine proteases or thiol esterases. The activation of factor X is activated by Ca2+ ions with a Hill coefficient of 2.4 and is inhibited by Hg2+, Ba2+, and Cd2+. Its pH dependency suggests that the activity depends on the ionization of a group with an apparent pK of 6.9. We studied the cleavage of purified bovine factor X by B. atrox activators and compared it to that obtained with the factor X activator from Vipera russelli venom. Like the physiological activators, the venom's activators cleave the heavy chain of factor X, producing the activated factor Xa alpha. They produce however two other cleavages: one near the N-terminal end of the heavy chain of factor X, generating factor Xmu, and a second one located at one extremity of the heavy chain of factor Xa alpha, generating factor Xav.     

Identification of a binding site for blood coagulation factor Xa on the heavy chain of factor Va. Amino acid residues 323-331 of factor V represent an interactive site for activated factor X

We have recently shown that amino acid region 307-348 of factor Va heavy chain (42 amino acids, N42R) is critical for cofactor activity and may contain a binding site for factor Xa and/or prothrombin [(2001) J. Biol. Chem. 276, 18614-18623]. To ascertain the importance of this region for factor Va cofactor activity, we have synthesized eight overlapping peptides (10 amino acid each) spanning amino acid region 307-351 of the heavy chain of factor Va and tested them for inhibition of prothrombinase activity. The peptides were also tested for the inhibition of the binding of factor Va to membrane-bound active site fluorescent labeled Glu-Gly-Arg human factor Xa ([OG488]-EGR-hXa). Factor Va binds specifically to membrane-bound [OG488]-EGR-hXa (10nM) with half-maximum saturation reached at approximately 6 nM. N42R was also found to interact with [OG488]-EGR-hXa with half-maximal saturation observed at approximately 230 nM peptide. N42R was found to inhibit prothrombinase activity with an IC50 of approximately 250 nM. A nonapeptide containing amino acid region 323-331 of factor Va (AP4') was found to be a potent inhibitor of prothrombinase. Kinetic analyses revealed that AP4' is a noncompetitive inhibitor of prothrombinase with respect to prothrombin, with a K(i) of 5.7 microM. Thus, the peptide interferes with the factor Va-factor Xa interaction. Displacement experiments revealed that the nonapeptide inhibits the direct interaction of factor Va with [OG488]-EGR-hXa (IC50 approximately 7.5 microM). The nonapeptide was also found to bind directly to [OG488]-EGR-hXa and to increase the catalytic efficiency of factor Xa toward prothrombin in the absence of factor Va. In contrast, a peptadecapeptide from N42R encompassing amino acid region 337-351 of factor Va (P15H) had no effect on either prothrombinase activity or the ability of the cofactor to interact with [OG488]-EGR-hXa. Our data demonstrate that amino acid sequence 323-331 of factor Va heavy chain contains a binding site for factor Xa.     

The activation of factor X by hepatocyte plasma membranes

Synthesis and secretion of blood coagulation factor X was studied during incubations of hepatocytes prepared by perfusion of rat livers with collagenase. The apparent molecular weight of factor X isolated from the incubation medium was about 14,000 less than factor X isolated from rat plasma. The extracellular form of factor X was a two-chain polypeptide and the observed difference in molecular weight was reflected in the heavy chain. Since these properties were more characteristic of factor Xa than factor X, experiments were designed to determine if factor X activation occurred during the incubations. Clotting factor assays indicated that factor X secreted by hepatocytes was present as factor Xa. Also, when purified plasma factor X was added to incubations of hepatocytes the added factor X was converted to factor Xa. Plasma membranes prepared from isolated hepatocytes or from liver homogenates contained an enzyme that converted factor X to factor Xa in a calcium-dependent reaction. The results suggest that the activity is due to the presence of thromboplastin (tissue factor) and factor VII in the membrane preparations.     

The contribution of amino acid region ASP695-TYR698 of factor V to procofactor activation and factor Va function

There is strong evidence that a functionally important cluster of amino acids is located on the COOH-terminal portion of the heavy chain of factor Va, between amino acid residues 680 and 709. To ascertain the importance of this region for cofactor activity, we have synthesized five overlapping peptides representing this amino acid stretch (10 amino acids each, HC1-HC5) and tested them for inhibition of prothrombinase assembly and function. Two peptides, HC3 (spanning amino acid region 690-699) and HC4 (containing amino acid residues 695-704), were found to be potent inhibitors of prothrombinase activity with IC(50) values of approximately 12 and approximately 10 microm, respectively. The two peptides were unable to interfere with the binding of factor Va to active site fluorescently labeled Glu-Gly-Arg human factor Xa, and kinetic analyses showed that HC3 and HC4 are competitive inhibitors of prothrombinase with respect to prothrombin with K(i) values of approximately 6.3 and approximately 5.3 microm, respectively. These data suggest that the peptides inhibit prothrombinase because they interfere with the incorporation of prothrombin into prothrombinase. The shared amino acid motif between HC3 and HC4 is composed of Asp(695)-Tyr-Asp-Tyr-Gln(699) (DYDYQ). A pentapeptide with this sequence inhibited both prothrombinase function with an IC(50) of 1.6 microm (with a K(D) for prothrombin of 850 nm), and activation of factor V by thrombin. Peptides HC3, HC4, and DYDYQ were also found to interact with immobilized thrombin. A recombinant factor V molecule with the mutations Asp(695) --> Lys, Tyr(696) --> Phe, Asp(697) --> Lys, and Tyr(698) --> Phe (factor V(2K2F)) was partially resistant to activation by thrombin but could be readily activated by RVV-V activator (factor Va(RVV)(2K2F)) and factor Xa (factor Va(Xa)(2K2F)). Factor Va(RVV)(2K2F) and factor Va(Xa)(2K2F) had impaired cofactor activity within prothrombinase in a system using purified reagents. Our data demonstrate for the first time that amino acid sequence 695-698 of factor Va heavy chain is important for procofactor activation and is required for optimum prothrombinase function. These data provide functional evidence for an essential and productive contribution of factor Va to the activity of prothrombinase.     

Reactivity of bovine blood coagulation factor IXa beta, factor Xa beta, and factor XIa toward fluorogenic peptides containing the activation site sequences of bovine factor IX and factor X

The published activation site sequences of bovine factors IX and X have been utilized to synthesize a number of peptides specifically designed respectively as substrates for bovine factors XIa and IXa beta. The substrates contain a fluorophore (2-aminobenzoyl group, Abz) and a quenching group (4-nitrobenzylamide, Nba) that are separated upon enzymatic hydrolysis with a resultant increase in fluorescence that was utilized to measure hydrolysis rates. Factor XIa cleaved all of the peptides bearing factor IX activation site sequences with Abz-Glu-Phe-Ser-Arg-Val-Val-Gly-Nba having the highest kcat/KM value. The kinetic behavior of factor XIa toward the synthetic peptide substrate indicates that it has a minimal extended substrate recognition site at least five residues long spanning S4 to S1' and has favorable interactions over seven subsites. The hexapeptide Abz-Glu-Phe-Ser-Arg-Val-Val-Nba was the most specific factor XIa substrate and was not hydrolyzed by factors IXa beta or Xa beta or thrombin. Factor IXa beta failed to hydrolyze any of the synthetic peptides bearing the activation site sequence of factor X. This enzyme slowly cleaved four hexa- and heptapeptide substrates with factor IX activation site sequences extending from P4 or P3 to P3'. Factor Xa beta poorly hydrolyzed all but one of the factor XIa substrates and failed to cleave any of the factor IXa beta substrates. Thrombin failed to hydrolyze any of the peptides examined while trypsin, as expected, was highly reactive and not very specific. Phospholipids had no effect on the reactivity of either factors IXa beta or Xa beta toward synthetic substrates. Both factor IXa beta and Xa beta cleaved the peptide substrates at similar rates to their natural substrates under comparable conditions. However the rates were substantially lower than optimum activation rates observed in the presence of Ca2+, phospholipids, and protein cofactors. In the future, it may be useful to investigate synthetic substrates that can bind to phospholipid vesicles in the same manner as the natural substrates for factors IXa beta and Xa beta.