Understanding protein-ligand interactions: the price of protein flexibility

In order to design selective, high-affinity ligands to a target protein, it is advantageous to understand the structural determinants for protein-ligand complex formation at the atomic level. In a model system, we have successively mapped the factor Xa binding site onto trypsin, showing that certain mutations influence both protein structure and inhibitor specificity. Our previous studies have shown that introduction of the 172SSFI175 sequence of factor Xa into rat or bovine trypsin results in the destabilisation of the intermediate helix with burial of Phe174 (the down conformation). Surface exposure of the latter residue (the up conformation) is critical for the correct formation of the aromatic box found in factor Xa-ligand complexes. In the present study, we investigate the influence of aromatic residues in position 174. Replacement with the bulky tryptophan (SSWI) shows reduced affinity for benzamidine-based inhibitors (1) and (4), whereas removal of the side-chain (alanine, SSAI) or exchange with a hydrophilic residue (arginine, SSRI) leads to a significant loss in affinity for all inhibitors studied. The variants could be crystallised in the presence of different inhibitors in multiple crystal forms. Structural characterisation of the variants revealed three different conformations of the intermediate helix and 175 loop in SSAI (down, up and super-up), as well as a complete disorder of this region in one crystal form of SSRI, suggesting that the compromised affinity of these variants is related to conformational flexibility. The influence of Glu217, peripheral to the ligand-binding site in factor Xa, was investigated. Introduction of Glu217 into trypsin variants containing the SSFI sequence exhibited enhanced affinity for the factor Xa ligands (2) and (3). The crystal structures of these variants also exhibited the down and super-up conformations, the latter of which could be converted to up upon soaking and binding of inhibitor (2). The improved affinity of the Glu217-containing variants appears to be due to a shift towards the up conformation. Thus, the reduction in affinity caused by conformational variability of the protein target can be partially or wholly offset by compensatory binding to the up conformation. The insights provided by these studies will be helpful in improving our understanding of ligand binding for the drug design process.     

ZZ made EZ: influence of inhibitor configuration on enzyme selectivity

Selectivity of drug targeting is necessary in order to forestall undesired side-effects. Here, we examine the structural grounds for the configuration-dependent selectivity of 2,7-bis(4-amidinobenzylidene)-cycloheptan-1-one (1) for factor Xa and trypsin: Previous studies showed that factor Xa is preferentially inhibited by the (Z,Z) configuration isomer of (1), whilst trypsin binds equally well to both (E,Z) and (Z,Z) forms. Using engineered trypsin variants, we find similar overall binding modes for the (E,Z) and (Z,Z) isomers. Minor changes in van der Waals' contacts to Tyr99 (Leu in trypsin) explain the differential inhibition of factor Xa. We note differences in the experimental electron densities observed from co-crystallisation and soaking experiments: while the co-crystallisation of (1) with variants containing Tyr99 (Leu99) reveal the exclusive presence of the (Z,Z) ((E,Z)) configurations respectively, soaking experiments with either variant result in mixtures of (E,Z), (Z,Z) and (E,E). This discrepancy arises presumably from differences in the spatial (packing considerations) or chemical (crystallisation conditions) microenvironments. The results presented here represent an extreme example of the problems that face structure-based drug design, in particular the dangers inherent in relying on a single crystal structure for interpreting protein-ligand interactions.     

Structural basis for inhibition promiscuity of dual specific thrombin and factor Xa blood coagulation inhibitors

BACKGROUND: A major current focus of pharmaceutical research is the development of selective inhibitors of the blood coagulation enzymes thrombin or factor Xa to be used as orally bioavailable anticoagulant drugs in thromboembolic disorders and in the prevention of venous and arterial thrombosis. Simultaneous direct inhibition of thrombin and factor Xa by synthetic proteinase inhibitors as a novel approach to antithrombotic therapy could result in potent anticoagulants with improved pharmacological properties. RESULTS: The binding mode of such dual specific inhibitors of thrombin and factor Xa was determined for the first time by comparative crystallography using human alpha-thrombin, human des-Gla (1--44) factor Xa and bovine trypsin as the ligand receptors. The benzamidine-based inhibitors utilize two different conformations for the interaction with thrombin and factor Xa/trypsin, which are evoked by the steric requirements of the topologically different S2 subsites of the enzymes. Compared to the unliganded forms of the proteinases, ligand binding induces conformational adjustments of thrombin and factor Xa active site residues indicative of a pronounced induced fit mechanism. CONCLUSION: The structural data reveal the molecular basis for a desired unselective inhibition of the two key components of the blood coagulation cascade. The 4-(1-methyl-benzimidazole-2-yl)-methylamino-benzamidine moieties of the inhibitors are able to fill both the small solvent accessible as well as the larger hydrophobic S2 pockets of factor Xa and thrombin, respectively. Distal fragments of the inhibitors are identified which fit into both the cation hole/aromatic box of factor Xa and the hydrophobic aryl binding site of thrombin. Thus, binding constants in the medium-to-low nanomolar range are obtained against both enzymes.     

X-ray analysis of a thrombin inhibitor-trypsin complex

The three-dimensional structure of a thrombin inhibitor-trypsin complex has been determined by an X-ray analysis at 2.5 A resolution. The result has given experimental support to the mechanisms previously proposed by the authors for the selective inhibition of trypsin, thrombin, factor Xa, and plasmin by inhibitors with an arginine or lysine backbone. The differences in the amino acid sequences at the positions corresponding to Ilc63, Leu99, and Ser190 of trypsin give each enzyme different binding affinities toward inhibitors and result in the selective inhibition. Furthermore, the X-ray analysis has revealed a novel type of interaction between the inhibitor and trypsin. The hydrogen bonds between the inhibitor main chain and trypsin Gly216 play an essential role in the complex formation.     

Intermolecular interactions and characterization of the novel factor Xa exosite involved in macromolecular recognition and inhibition: crystal structure of human Gla-domainless factor Xa complexed with the anticoagulant protein NAPc2 from the hematophagous nematode Ancylostoma caninum

NAPc2, an anticoagulant protein from the hematophagous nematode Ancylostoma caninum evaluated in phase-II/IIa clinical trials, inhibits the extrinsic blood coagulation pathway by a two step mechanism, initially interacting with the hitherto uncharacterized factor Xa exosite involved in macromolecular recognition and subsequently inhibiting factor VIIa (K(i)=8.4 pM) of the factor VIIa/tissue factor complex. NAPc2 is highly flexible, becoming partially ordered and undergoing significant structural changes in the C terminus upon binding to the factor Xa exosite. In the crystal structure of the ternary factor Xa/NAPc2/selectide complex, the binding interface consists of an intermolecular antiparallel beta-sheet formed by the segment of the polypeptide chain consisting of residues 74-80 of NAPc2 with the residues 86-93 of factor Xa that is additional maintained by contacts between the short helical segment (residues 67-73) and a turn (residues 26-29) of NAPc2 with the short C-terminal helix of factor Xa (residues 233-243). This exosite is physiologically highly relevant for the recognition and inhibition of factor X/Xa by macromolecular substrates and provides a structural motif for the development of a new class of inhibitors for the treatment of deep vein thrombosis and angioplasty.     

A predicted tertiary structure of a thrombin inhibitor-trypsin complex explains the mechanisms of the selective inhibition of thrombin, factor Xa, plasmin, and trypsin

The tertiary structure of a thrombin inhibitor-trypsin complex has been predicted by a molecular modelling considering the van der Waals interactions between the inhibitor and the enzyme. The selective inhibition of trypsin, thrombin, factor Xa, and plasmin exhibited by arginine and lysine derivatives has been clearly explained based on the predicted structure and the homology in the amino acid sequences of these enzymes. The differences in the amino acid sequences at the positions corresponding to Ile63, Leu99, and Ser190 of trypsin give each enzyme different binding affinities toward inhibitors and result in the selective inhibition. The X-ray analysis of the inhibitor-trypsin complex is in progress to prove the predicted structure.     

The conformational switch from the factor X zymogen to protease state mediates exosite expression and prothrombinase assembly

Zymogens of the chymotrypsin-like serine protease family are converted to the protease state following insertion of a newly formed, highly conserved N terminus. This transition is accompanied by active site formation and ordering of several surface loops in the catalytic domain. Here we show that disruption of this transition in factor X through mutagenesis (FXa(I16L) and FXa(V17A)) not only alters active site function, but also significantly impairs Na(+) and factor Va binding. Active site binding was improved in the presence of high NaCl or with saturating amounts of factor Va membranes, suggesting that allosteric linkage exists between these sites. In line with this, irreversible stabilization of FXa(I16L) with Glu-Gly-Arg-chloromethyl ketone fully rescued FVa binding. Furthermore, the K(m) for prothrombin conversion with the factor Xa variants assembled into prothrombinase was unaltered, whereas the k(cat) was modestly reduced (3- to 4-fold). These findings show that intramolecular activation of factor X following the zymogen to protease transition not only drives catalytic site activation but also contributes to the formation of the Na(+) and factor Va binding sites. This structural plasticity of the catalytic domain plays a key role in the regulation of exosite expression and prothrombinase assembly.     

Factor Xa-evoked relaxation in rat aorta: involvement of PAR-2

Protease-activated receptor-2 (PAR-2) and/or effector cell protease receptor-1 (EPR-1) may mediate the direct cellular actions of coagulation factor Xa in some cultured cell lines. The present study examined if factor Xa could actually evoke relaxation through either of these receptor systems in isolated rat aorta. Factor Xa at 8.5-85 nM, like the PAR-2-activators trypsin and SLIGRL-NH(2), produced nitric oxide-dependent relaxation in the precontracted aortic rings. PAR-2 desensitization abolished relaxation responses to factor Xa as well as trypsin in the rings. The factor Xa interepidermal growth factor synthetic peptide L(83)FTRKL(88)(G)-NH(2), known to block factor Xa binding to EPR-1, failed to inhibit factor Xa-evoked relaxation in the preparations. Our findings provide evidence that factor Xa evokes relaxation by activating PAR-2, but independently of EPR-1, in the rat aorta. The factor Xa-PAR-2 pathway might thus contribute to the severe hypotension during sepsis, in which multiple coagulation factors including factor X would become activated and PAR-2 would be induced.     

(R)-3-Amidinophenylalanine-derived inhibitors of factor Xa with a novel active-site binding mode

A putative non-substrate like binding mode of (R)-3-amidinophenylalanine derivatives to factor Xa, as derived from modeling experiments based on X-ray analysis of their complexes with trypsin, was used to design a new generation of inhibitors. However, the resulting inhibitory potencies were not at all consistent with the working assumption, although with an adamantyl-ureido derivative of (R)-3-amidinophenylalanine phenetyl amide a highly selective nanomolar inhibition of factor Xa was achieved. The X-ray analysis of the complex of this ligand with factor Xa revealed an unexpected new binding mode, of which the most important feature is the interaction of the C-terminal aryl moiety with a hydrophobic subregion of the S1 subsite, while the adamantyl group occupies the hydrophobic S3/S4 subsites of the enzyme.     

Prothrombinase assembly and S1 site occupation restore the catalytic activity of FXa impaired by mutation at the sodium-binding site

Two loop segments (183-189 and 221-225) in the protease domain of factor Xa contribute to the formation of a Na(+)-binding site. Studies with factor Xa indicate that binding of a single Na(+) ion to this site influences its activity by altering the S1 specificity site, and substitution of Tyr(225) with Pro diminishes sensitivity to Na(+). Using full-length factor Xa(Y225P), the allosteric relationship between the Na(+) site and other structural determinants in factor Xa and prothrombinase was investigated. Direct binding and kinetic measurements with probes that target the S1 specificity pocket indicate that assembly of the mutant in prothrombinase corrected the impaired binding of these probes observed with free factor Xa(Y225P). This appears to result from the apparent allosteric linkage between the factor Va, S1, and Na(+)-binding sites, since binding of the cofactor to membrane-bound factor Xa(Y225P) enhances binding at the S1 site and vice versa. Additional studies revealed that the internal salt bridge (Ile(16)-Asp(194)) of factor Xa(Y225P) is partially destabilized, a process that is reversible upon occupation of the S1 site. The data establish that alterations at the factor Xa Na(+)-binding site shift the zymogen-protease equilibrium to a more zymogen-like state, and as a consequence binding of S1-directed probes and factor Va are adversely affected. Therefore, the zymogen-like characteristics of factor Xa(Y225P) have allowed for the apparent allosteric linkage between the S1, factor Va, and Na(+) sites to become evident and has provided insight into the structural transitions which accompany the conversion of factor X to factor Xa.     

Crystal structures of uninhibited factor VIIa link its cofactor and substrate-assisted activation to specific interactions

Factor VIIa initiates the extrinsic coagulation cascade; this event requires a delicately balanced regulation that is implemented on different levels, including a sophisticated multi-step activation mechanism of factor VII. Its central role in hemostasis and thrombosis makes factor VIIa a key target of pharmaceutical research. We succeeded, for the first time, in recombinantly producing N-terminally truncated factor VII (rf7) in an Escherichia coli expression system by employing an oxidative, in vitro, folding protocol, which depends critically on the presence of ethylene glycol. Activated recombinant factor VIIa (rf7a) was crystallised in the presence of the reversible S1-site inhibitor benzamidine. Comparison of this 1.69A crystal structure with that of an inhibitor-free and sulphate-free, but isomorphous crystal form identified structural details of factor VIIa stimulation. The stabilisation of Asp189-Ser190 by benzamidine and the capping of the intermediate helix by a sulphate ion appear to be sufficient to mimic the disorder-order transition conferred by the cofactor tissue factor (TF) and the substrate factor X. Factor VIIa shares with the homologous factor IXa, but not factor Xa, a bell-shaped activity modulation dependent on ethylene glycol. The ethylene glycol-binding site of rf7a was identified in the vicinity of the 60 loop. Ethylene glycol binding induces a significant conformational rearrangement of the 60 loop. This region serves as a recognition site of the physiologic substrate, factor X, which is common to both factor VIIa and factor IXa. These results provide a mechanistic framework of substrate-assisted catalysis of both factor VIIa and factor IXa.     

Trypsin mutants for structure-based drug design: expression,refolding and crystallisation

New techniques in drug discovery are essential for the fast and efficient development of novel innovative drugs to deal with the challenges of the future. Structure determinations of various members of serine proteinases have provided a basis for computer-based drug design within this class of enzymes. In many proteins of interest, however, this course is blocked through a lack of suitable crystals. As a strategy for circumventing such problems, we have investigated the use of surrogate proteins for studying protein-ligand interactions. To test the feasibility of this approach, we have chosen bovine trypsin as a scaffold to reconstruct the ligand binding site of factor Xa. The simple modular design of trypsin, its readiness to crystallise and straightforward handling lends itself to such drug design by proxy. The expression, folding, purification, crystallographic and kinetic characterisation of bovine trypsin forms with factor Xa phenotype are presented.     

Comparative molecular modeling analysis of­5‐amidinoindole and benzamidine binding to thrombin and trypsin: specific H‐bond formation contributes to high 5‐amidinoindole potency and selectivity for thrombin and factor Xa

The coagulation cascade enzymes thrombin and factor Xa are known to have specificity pockets very similar to those of trypsin and plasmin. However, comparative molecular modeling analysis of the crystal structures of benzamidine–thrombin and benzamidine–trypsin, in conjunction with a docking analysis of 5‐amidinoindole and related inhibitors in both enzymes reveals subtle differences between the specificity sites of the two types of enzymes. Specifically, thrombin and factor Xa, which have an alanine residue at position 190, exhibit increased activities for the rigid and more bulky bicyclic derivatives of benzamidine (e.g. amidinobenzofuran, amidinothiophene and amidinoindole), because of additional hydrophobic and H‐bond interactions between the inhibitors and the specificity sites, whereas enzymes with a serine residue at position 190, like trypsin and plasmin, exhibit little difference in activity among the same set of compounds because of the orientational restriction imposed on the inhibitors by Ser190, which forms an additional H‐bond with the amidino group of the inhibitors. Enzymes of both groups show similar responses to the flexible aminobenzamidine since the smaller size and the rotatable anilino group of the inhibitor would allow the inhibitor to achieve favorable electrostatic interactions with both groups of enzymes. 5‐Amidinoindole is the most dramatic example of the rigid bicyclic type inhibitor. Based on our docking analysis, we propose that a selective H‐bond with the hydroxyl group of the catalytic Ser195 and the subtle differences in steric fit imposed by Ala/Ser at position 190 explain the high potency and selectivity of 5‐amidinoindole for thrombin and factor Xa. Copyright © 1999 John Wiley & Sons, Ltd.     

Inherent flexibility in a potent inhibitor of blood coagulation, recombinant nematode anticoagulant protein c2.

Nematode anticoagulant proteins (NAPs) from the hematophagous nematode Ancylostoma caninum inhibit blood coagulation with picomolar inhibition constants, and have been targeted as novel pharmaceutical agents. NAP5 and NAP6 inhibit factor Xa by binding to its active site, whereas NAPc2 binds to factor Xa at a different, as yet unidentified, site and the resultant binary complex inhibits the tissue factor-factor VIIa complex. We have undertaken NMR studies of NAPc2, including the calculation of a solution structure, and found that the protein is folded, with five disulfide bonds, but is extremely flexible, especially in the acidic loop. The Halpha secondary shifts and 3JHNHalpha coupling constants indicate the presence of some beta structure and a short helix, but the intervening loops are highly conformationally heterogeneous. Heteronuclear NOE measurements showed the presence of large amplitude motions on a subnanosecond timescale at the N-terminus and C-terminus and in the substrate-binding loop, indicating that the conformational heterogeneity observed in the NMR structures is due to flexibility of the polypeptide chain in these regions. Flexibility may well be an important factor in the physiological function of NAPc2, because it must interact with other proteins in the inhibition of blood coagulation. We suggest that this inhibitor is likely to become structured on binding to factor Xa, because the inhibition of the tissue factor-factor VIIa complex requires both NAPc2 and factor Xa.     

Identification of a binding site for quaternary amines in factor Xa

In the process of characterizing the Na(+)-binding properties of factor Xa, a specific inhibition of this enzyme by quaternary amines was identified, consistent with previous observations. The binding occurs with K(i) in the low millimolar range, with trimethylphenylammonium (TMPA) showing the highest specificity. Binding of TMPA inhibits substrate hydrolysis in a competitive manner, does not inhibit the binding of p-aminobenzamidine to the S1 pocket, and is positively linked to Na(+) binding. Inhibition by TMPA is also seen in thrombin and tissue plasminogen activator (tPA), though to a lesser extent compared to factor Xa. Computer modeling using the crystal structure of factor Xa suggests that TMPA binds to the S2/S3 specificity sites, with its hydrophobic moiety making van der Waals interactions with the side chains of Y99, F174, and W215, and the charged amine coupling electrostatically with the carboxylates of E97. Site-directed mutagenesis of factor Xa, thrombin, and tPA confirms the predictions drawn by docking calculations and reveal a dominant role for residue Y99. Binding of TMPA to factor Xa is drastically (25-fold) reduced by the Y99T replacement. Likewise, the Y99L substitution compromises binding of TMPA to tPA. On the other hand, the affinity of TMPA is enhanced 4-fold in thrombin with the substitution L99Y. The identification of a binding site for quaternary amines in factor Xa has a bearing on the rational design of selective inhibitors of this clotting enzyme.     

Isolation of human blood coagulation alpha-factor Xa by soybean trypsin inhibitor-sepharose chromatography and its active-site titration with fluorescein mono-p-guanidinobenzoate

A method based on active-site affinity chromatography on soybean trypsin inhibitor (SBTI)-Sepharose was developed for isolation of human factor Xa in primarily the undergraded alpha-form. The chromatography procedure separated factor Xa from factor X, the Russel's viper venom proteinase used to activate factor X, and traces of contaminating thrombin. alpha-Factor Xa was unstable at pH 7.6 and 25 degrees C, undergoing slow proteolytic degradation to functionally heterogeneous products as evidenced by the greater loss of coagulation assay activity compared to activity measured with a chromogenic substrate. The results of monitoring factor Xa degradation by sodium dodecyl sulfate-polyacrylamide gel electrophoresis were consistent with proteolysis of the light chain as a major component reaction occurring in parallel with slower proteolysis of the heavy chain. The decreased rates of these reactions at pH 6.0 enabled isolation and storage of factor Xa in greater than or equal to 88% alpha-form and minimized the heterogeneity due to proteolytic degradation. Characterization of the reaction of fluorescein mono-p-guanidinobenzoate (FMGB) with human and bovine factor Xa isolated by SBTI-Sepharose chromatography demonstrated its utility as a sensitive reagent for continuous fluorometric active-site titration. Analysis of the reaction kinetics as a function of FMGB and human factor Xa concentrations in G/2 0.3, pH 7.4, buffer at 25 degrees C indicated that the ratio of acylation to deacylation rate constants was greater than 200 and that the Km for FMGB was 0.06-0.11 microM, predicting pre-steady-state burst amplitudes of greater than or equal to 96-98% of the active-site concentration at FMGB concentrations greater than or equal to 5 microM. Human factor Xa active-site concentrations were consistent with 82-99% active preparations when compared with the protein concentrations determined from the 280-nm absorbance. Concentrations of human alpha-factor Xa as low as 20 nM could be measured with FMGB, indicating a sensitivity approximately 50 times greater than that measured by spectrophotometric active-site titration with p-nitophenyl p'-guanidinobenzoate.     

Mapping of the factor Xa binding site on factor Va by site-directed mutagenesis

Activated coagulation factor V functions as a cofactor to factor Xa in the conversion of prothrombin to thrombin. Based on the introduction of extra carbohydrate side chains in recombinant factor V, we recently proposed several regions in factor Va to be important for factor Xa binding. To further define which residues are important for factor Xa binding, we prepared fifteen recombinant factor V variants in which clusters of charged amino acid residues were mutated, mainly to alanines. The factor V variants were expressed in COS-1 cells, and their functional properties evaluated in a prothrombinase-based assay, as well as in a direct binding test. Four of the factor V variants, 501A/510A/511D, 501A/510A/511D/513A, 513A/577A/578A, and 501A/510A/511D/513A/577A/578A exhibited markedly reduced factor Xa-cofactor activity tested in the prothrombinase assay, and reduced binding affinity as judged by the direct binding assay. These factor Va variants were normally cleaved at Arg-506 by activated protein C, and the interaction between the factor Xa-factor Va complex and prothrombin was unaffected by the introduced mutations. Based on the integration of all available data, we propose a key factor Xa binding surface to be centered on Arg-501, Arg-510, Ala-511, Asp-513, Asp-577, and Asp-578 in the factor Va A2 domain. These residues form an elongated charged factor Xa binding cluster on the factor Va surface.     

Differentiation of enzyme and substrate binding in the prothrombinase complex

The Ca2+ dependence of factor Xa binding to phospholipid vesicles was measured in the presence and absence of factor Va. The increase in polarization of a fluorescently labeled derivative of factor Xa, [5-(dimethylamino)-1-naphthalenesulfonyl] glutamylglycylarginyl factor Xa (Dns-EGR-Xa), was used as a probe to measure the interaction of factor Xa with phospholipid. The Ca2+ concentration required for half-maximal binding of Dns-EGR-Xa to phospholipid vesicles was 3.5 X 10(-4) M in the presence of factor Va and 9.5 X 10(-4) M in the absence of factor Va. At a Ca2+ concentration of 5 X 10(-4) M, the binding of Dns-EGR-Xa to phospholipid-bound factor Va was near maximal, whereas there was no detectable interaction of Dns-EGR-Xa with phospholipid alone at this Ca2+ concentration as detected by fluorescence polarization. These results were qualitatively confirmed by high-performance liquid chromatography. The rate of hydrolysis of the factor Xa synthetic substrate, benzoylisoleucylglutamylglycylarginine p-nitroanilide, by factor Xa in the presence of factor Va and phospholipid decreased in a Ca2+-dependent manner. These data were analyzed as fraction of factor Xa bound to the phospholipid. A Ca2+ concentration of 2.7 X 10(-4) M resulted in half-maximal binding by this technique. The relationship observed between rates of prothrombin activation and Ca2+ concentration could be predicted quantitatively from calculations of local enzyme and substrate concentrations.     

Interaction of prothrombin with factor Va-phospholipid complexes

The effects of factor Va and the phospholipid-binding fragment of factor Va [factor Va light chain (LC), Mr 80000] on the binding of prothrombin, factor X, and factor Xa to phospholipid vesicles are reported. Equilibrium binding experiments were performed that utilized large-volume vesicles, which can be removed from the bulk solution by centrifugation. Factor Va decreased the dissociation constant of the prothrombin-phospholipid complex 50-fold, from 2.0 X 10(-7) M to 4.0 X 10(-9) M. For the factor X-phospholipid complex the decrease was 60-fold (1.8 X 10(-7) M to 3.0 X 10(-9) M) and for factor Xa, 160-fold (1.6 X 10(-7) M to 1.0 X 10(-9) M). The ratios of moles of protein bound to moles of total added factor Va at saturation of phospholipid-bound factor Va indicate an 1:1 stoichiometric complex of either factor Xa, factor X, or prothrombin and phospholipid-bound factor Va. In the presence of factor Va LC, the dissociation constants of factor Xa- and prothrombin-phospholipid complexes were increased, while the maximal protein-binding capacities of the vesicles were not affected by factor Va LC. The data suggest a competitive interaction between factor Xa and factor Va LC binding as well as between prothrombin and factor Va LC binding at the phospholipid surface. From this, it is concluded that the phospholipid-binding fragment of factor Va alone does not serve as the binding site for interactions of factor Xa and prothrombin with factor Va.