The interaction of bovine factor V and factor V-derived peptides with phospholipid vesicles

The binding of bovine Factor V, isolated Factor Va, and isolated activation intermediates to single bilayer phospholipid vesicles was studied by light scattering. The vesicles composed of 25% phosphatidylserine and 75% phosphatidylcholine had a mean radius of approximately 163 A as determined by quasi-elastic light scattering. When these vesicles were saturated with Factor V, the radii increased by approximately 120 A in both 0.15 and 1 M NaCl. At saturation, about 35 molecules of Factor V and 141 molecules of Factor Va were bound to each vesicle. Studies of the binding of Factor V and Factor Va at various ionic strengths showed little change in either Kd or n, suggesting that the binding is not electrostatic. The dissociation constants (Kd) and the lipid to protein ratios at saturation, moles/mol (n), obtained by relative light scattering intensities were: Factor V (Kd = 4.3 X 10(-8) M, n = 214); isolated Factor Va (Kd = 1.7 X 10(-7) M, n = 57); component B, Mr = 205,000 (Kd = 1.8 X 10(-7) M, n = 140); component C, Mr = 150,000 (Kd = 7.0 X 10(-7) M, n = 136); component D, Mr = 94,000 (no binding could be demonstrated); component E, Mr = 74,000 (Kd = 3.8 X 10(-7) M, n = 42). The results presented here indicate that the lower Kd exhibited by Factor V compared to Factor Va (components D and E) is primarily due to the interaction present within the component C portion of the molecule which is destroyed when component C is further cleaved to give component D. The interactions responsible for the binding of Factor Va are expressed in component E as well as in its precursor peptide component B. Dissociation of components D and E by the addition of EDTA indicate that component E alone is responsible for the interaction of bovine Factor Va with phospholipid.     

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.     

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.     

Comparison of coagulation factor Xa and des-(1-44)factor Xa in the assembly of prothrombinase

The gamma-carboxyglutamic acid (Gla)-domain region of factor X (residues 1-44 of the light chain) was selectively removed by limited proteolysis with alpha-chymotrypsin. The Gla-domainless factor X was then activated by the factor X coagulant protein of Russell's viper venom. Apparent dissociation constants Kd' values for the interaction of factor Va with either factor Xa or Gla-domainless factor Xa were determined kinetically using prothrombin as the substrate. In the absence of phospholipid, factor Va interacted with Gla-domainless factor Xa with lower affinity (Kd' 4 X 10(-6) M) than with factor Xa (Kd' = 5 X 10(-8) M). At saturating concentrations of factor Va, maximal rates of thrombin formation were similar for either enzyme. The addition of phospholipid increased the affinity of factor Va for factor Xa approximately 75-fold (Kd' = 3.3 X 10(-10) M). In contrast, phospholipid had no effect on the affinity of Gla-domainless factor Xa for factor Va (Kd' = 4 X 10(-6) M). The maximal rate of thrombin formation increased approximately 300-fold with the addition of phospholipid to the factor Xa-factor Va system. Under the same conditions, phospholipid had no effect on the rate of thrombin formation when Gla-domainless factor Xa was the enzymatic moiety. These results demonstrate phospholipid has little or no effect on factor Va function when factor Xa has lost its Gla-mediated Ca2+-binding sites.     

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.     

The effect of phospholipids, calcium ions and protein S on rate constants of human factor Va inactivation by activated human protein C.

Rate constants for human factor Va inactivation by activated human protein C (APC) were determined in the absence and presence of Ca2+ ions, protein S and varying concentrations of phospholipid vesicles of different lipid composition. APC-catalyzed factor Va inactivation in free solution (in the presence of 2 mM Ca2+) was studied under first-order reaction conditions with respect to both APC and factor Va and was characterized by an apparent second-order rate constant of 6.1 x 10(5) M-1 s-1. Stimulation of APC-catalyzed factor Va inactivation by phospholipids was dependent on the concentration and composition of the phospholipid vesicles. Optimal acceleration (230-fold) of factor Va inactivation was observed with 10 microM phospholipid vesicles composed of 20 mol% dioleoylglycerophosphoserine (Ole2GroPSer) and 80 mol% dioleoylglycerophosphocholine (Ole2GroPCho). At higher vesicle concentrations and at higher molar fractions of Ole2GroPSer some inhibition of APC-catalyzed factor Va inactivation was observed. Membranes that contained anionic phospholipids other than phosphatidylserine also promoted factor Va inactivation. The ability of different anionic lipids to enhance factor Va inactivation increased in the order phosphatidylethanolamine less than oleic acid less than phosphatidic acid less than phosphatidylglycerol less than phosphatidylmethanol less than phosphatidylserine. APC-catalyzed factor Va inactivation in the presence of phospholipid vesicles could be saturated with respect to factor Va and the reaction obeyed Michaelis-Menten kinetics. Both the Km for factor Va and the Vmax of factor Va inactivation were a function of the phospholipid concentration. The Km increased from 1 nM at 2.5 microM phospholipid (Ole2GroPSer/Ole2GroPCho 20:80, mol/mol) to 65 nM at 250 microM phospholipid. The Vmax increased from 20 mol factor Va inactivated.min-1.mol APC-1 at 2.5 microM phospholipid to 62 mol factor Va inactivated.min-1.mol APC-1 at 10 microM phospholipid and remained constant at higher phospholipid concentrations. Protein S appeared to be a rather poor stimulator of APC-catalyzed factor Va inactivation. Protein-S-dependent rate enhancements were only observed in reaction mixtures that contained negatively charged phospholipid vesicles. Independent of the concentration and the lipid composition of the vesicles, protein S caused a twofold stimulation of APC-catalyzed factor Va inactivation. This suggests that, in the human system, enhancement of APC binding to phospholipid vesicles by protein S is of minor importance. Considering that protein S is a physiologically essential antithrombotic agent, it is likely that other factors or phenomena contribute to the in vivo antithrombotic action of protein S.     

Membrane-mediated assembly of the prothrombinase complex

Prothrombinase assembly was studied on macroscopic planar bilayers consisting of 20% dioleoyl-phosphatidylserine (DOPS) and 80% dioleoyl-phosphatidylcholine (DOPC). The dissociation constant for the binding of factor Xa to the bilayer, measured by ellipsometry, was Kd = 47 +/- 8 nM (mean +/- S.D.) and this value was lowered to Kd = 2.2 +/- 0.3 pM by preadsorption of factor Va. This latter value was determined from direct measurement of steady-state thrombin production. A comparable value of Kd = 1.0 +/- 0.1 pM was found by repeating these experiments in suspensions of phospholipid vesicles, and it was verified that prothrombinase assembly was not influenced by the addition of prothrombin. Using a minute amount (0.094 fmol cm-2) of preadsorbed factor Va, it was found that the rate of prothrombinase assembly exceeds the rate of collisions between Xa molecules from the buffer and the sparse Va molecules on the bilayer. Apparently, factor Xa adsorbs first to the membrane and then associates rapidly with factor Va by lateral diffusion. The data indicate almost instantaneous equilibrium of this complex formation on the surface with a lower limit for the bimolecular rate constant of kon = 2.8 x 10(13) (mol/cm2)-1 s-1. In suspensions of small phospholipid vesicles, prothrombinase assembly is collisionally limited and the value of kon should be proportional to vesicle diameter. This was verified with a method for estimation of kon values from thrombin generation curves. Values of 0.36 x 10(9) and 1.6 x 10(9) M-1 s-1 were found for vesicles of 20-30- and 60-80-nm diameter, respectively.     

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.     

Interaction of bovine blood clotting factor Va and its subunits with phospholipid vesicles

Thrombin-activated factor Va and factor Va subunit binding to large-volume vesicles was investigated by a technique based on the separation by centrifugation of phospholipid-bound protein from the bulk solution. This technique allows the direct measurement of free-protein concentration. It is concluded that the phospholipid binding site on factor Va is located on a basic factor Va subunit with Mr 80 000 (factor Va-LC). The effects of phospholipid vesicle composition, calcium concentration, pH, and ionic strength on the equilibrium constants of factor Va- and factor Va-LC-phospholipid interaction were studied. Factor Va and factor Va-LC binding to phospholipid requires the presence of negatively charged phospholipids. It is further demonstrated that the following occur: (a) Calcium ions compete with factor Va and factor Va-LC for phospholipid-binding sites. (b) The dissociation constant of protein-phospholipid interaction increases with the ionic strength, whereas the maximum protein-binding capacity of the phospholipid vesicle was not affected by ionic strength. (c) The dissociation constant for factor Va-phospholipid interaction depends on pH when the vesicle consists of phosphatidic acid. It is concluded that factor Va-phospholipid interaction is primarily electrostatic in nature, where positively charged groups on the protein directly interact with the phosphate group of net negatively charged phospholipids. The results suggest that factor Va, like factor Xa and prothrombin, has the characteristics of an extrinsic membrane protein.     

Roles of factor Va heavy and light chains in protein and lipid rearrangements associated with the formation of a bovine factor Va-membrane complex.

Factor Va is an essential protein cofactor of the enzyme factor Xa, which activates prothrombin to thrombin during blood coagulation. Peptides with an apparent Mr of approximately 94,000 (heavy chain; HC) and approximately 74,000 or 72,000 (light chain; LC) interact in the presence of Ca2+ to form active Va. The two forms of Va-LC differ in their carboxyl-terminal C2 domain. Using Va reconstituted with either LC form, we examined the effects of the two LC species on membrane binding and on the activity of membrane-bound Va. We found that 1) Va composed of the 72,000 LC bound only slightly more tightly to membranes composed of a mixture of neutral and acidic lipids, the Kd being reduced by a factor of approximately 3 at 5 mM and by a factor of 6 at 2 mM Ca2+. 2) The two forms of Va seemed to undergo different conformational changes when bound to a membrane. 3) The activity of bovine Va varied somewhat with LC species, the difference being greatest at limiting Xa concentration. We have also addressed the role of the two Va peptides in membrane lipid rearrangements and binding: 1) Va binding increased lateral packing density in mixed neutral/acidic lipid membranes. In the solid phase, Va-HC had no effect, whereas Va-LC and whole Va had similar but small effects. In the fluid phase, Va-HC and whole Va both altered membrane packing, with Va-HC having the largest effect. 2) Va-HC bound reversibly and in a Ca2+-independent fashion to membranes composed of neutral phospholipid (Kd, approximately 0.3 microM; stoichiometry approximately 91). High ionic strength had little effect on binding. 3) The substantial effect of Va on packing within neutral phospholipid membranes was mimicked by Va-HC. 4) Based on measurements of membrane phase behavior, binding of Va or its peptide components did not induce thermodynamically discernible lateral membrane domains. These results suggest that the membrane association of factor Va is a complex process involving both chains of Va, changes in lipid packing, and changes in protein structure.     

The binding of activated protein C to factors V and Va

Activated protein C has been derivatized with the active site-directed fluorophore 2-(dimethylamino)-6-naphthalenesulfonylglutamylglycylarginyl chloromethyl ketone (2,6-DEGR-APC). Covalently modified activated protein C has been used to investigate the binding interactions of the protein to factors V and Va in the presence of phospholipid vesicles. The fluorescence polarization of the 6-dimethylaminonaphthalene-2-sulfonyl moiety increased saturably with increasing phospholipid concentrations in the presence or absence of factor V or Va. Differences in the limiting polarization values indicated distinguishable differences in the interactions between 2,6-DEGR-APC and phospholipid in the presence of factor V or Va. The dissociation constant calculated for the 2,6-DEGR-APC/phospholipid interaction (7.3 X 10(-8) M) was not significantly altered by factor V but was decreased to 7 X 10(-9) M in the presence of factor Va. The interaction between 2,6-DEGR-APC and factor V or Va was characterized by a 1:1 stoichiometry. The binding of 2,6-DEGR-APC to factor V or Va in the presence of phospholipid could be reduced in a competitive manner by diisopropylphosphofluoridate-treated activated protein C. An analysis of the displacement curves indicated that the binding of 2,6-DEGR-APC was indistinguishable from the binding of diisopropylphosphofluoridate-treated activated protein C. The interaction between 2,6-DEGR-APC and phospholipid-bound factor Va was further examined using the isolated subunits of factor Va. Fluorescence polarization changes observed with component E of Va (light chain) closely corresponded with the changes observed with factor Va, whereas isolated component D (heavy chain) had little influence on the binding of 2,6-DEGR-APC to phospholipid vesicles. The data presented are consistent with the interpretation that component E of factor Va contains a binding site for activated protein C.     

Prothrombinase complex assembly. Contributions of protein-protein and protein-membrane interactions toward complex formation

Equilibrium binding studies of prothrombinase complex formation were undertaken using phospholipid vesicles composed of phosphatidylcholine and phosphatidylserine (PCPS), factor Va, and factor Xa modified with dansyl glutamylglycinylarginyl chloromethyl ketone (DEGR.Xa). The interaction between the Va.PCPS and DEGR.Xa.PCPS binary complexes was experimentally isolated using saturating concentrations of PCPS. Fluorescence titrations indicated that the membrane-bound proteins interact tightly (Kd approximately 10(-9) M) with a stoichiometry of 1 mol of Va bound/mol of DEGR.Xa at saturation. Complex formation was also investigated by kinetic studies of prothrombin activation using unmodified factor Xa. The kinetic studies yielded a Kd approximately 10(-9) M, which was independent of the concentration of prothrombin in the range of 0.5-5.0 microM. Fluorescence studies of complex assembly at limiting PCPS concentrations provided evidence for an altered DEGR.Xa-PCPS interaction when the enzyme was assembled into the complex. The data suggest that although both proteins are associated with PCPS when complexed with each other, the presence of factor Va on the membrane surface increases the affinity for the Xa-PCPS interaction by an estimated 100-fold. Prothrombinase complex assembly therefore proceeds independently of the availability of substrate and is stabilized by protein-protein and protein-phospholipid interactions. Linkage between the two protein-membrane combination events leads to the further stabilization of the complex on the vesicle surface.     

Interaction of an amphitropic protein (factor Xa) with membrane models in a complex system

Phosphatidylserine (PS) plays a crucial role, in the conversion of prothrombin into thrombin by the protease, factor Xa. Physiologically, the conversion occurs in the prothrombinase complex. The question of how water-soluble proteins that normally circulate in plasma bind remains to be unambiguously determined. We previously found that the amphitropic proteins (prothrombin, factors V and Va) penetrate into phospholipid layers. AC polarography has allowed the detection for the first time of insertion of factor Xa into condensed monolayers containing phosphatidylserine (PS) and phosphatidylcholine (PC) either 100% PS or 25% PS in the presence of Ca2+. This observation demonstrates that part of factor Xa can cross the phospholipid polar headgroup/hydrocarbon chain interface. In parallel experiments, radioactive surface measurements permitted measuring binding of tritium-labeled factor Xa onto a PS monolayer and calculate an association constant, 6x10(6) M(-1). Penetration of factor Xa into PS-containing vesicles was investigated also using photoactivable 5-[125I]iodonaphthalene-1-azide, which binds selectively to the lipid embedded domains of the protein. These experiments suggest that Factor Xa penetrates preferentially by its heavy chain, an alternative mode of binding to the commonly accepted binding via its Gla domain. Interaction of factor Xa with PS vesicles also changes its apparent K(m) for S 2222.     

A domain of membrane-bound blood coagulation factor Va is located far from the phospholipid surface. A fluorescence energy transfer measurement

The larger subunit of blood coagulation factor Va was covalently labeled with iodoacetamido derivatives of fluorescein and rhodamine without loss of functional activity, as measured by either the one-stage clotting assay or the ability to accelerate prothrombin activation in a purified system. The spectral properties of the dyes were not altered by the presence or absence of the smaller subunit of factor Va, Ca2+, prothrombin, factor Xa, or phosphatidylcholine/phosphatidylserine (PC/PS, 4:1) vesicles. When fluorescein-labeled protein (factor VaF) was titrated with PC/PS vesicles containing either octadecylrhodamine or 5-(N-hexadecanoylamino)eosin, fluorescence energy transfer was observed between the protein-bound donor dyes and the acceptor dyes at the outer surface of the phospholipid bilayer. The extent of energy transfer correlated directly with the extent of protein binding to the vesicles monitored by light scattering. The distance of closest approach between the fluorescein on factor Va and the bilayer surface averaged 90 A for the two different acceptors. Association of factor VaF with factor Xa on the phospholipid surface reduced this separation by 7 A, but association with prothrombin did not alter the distance between the labeled domain on factor VaF and the surface. The efficiency of diffusion-enhanced energy transfer between rhodamine-labeled factor Va and terbium dipicolinate entrapped inside PC/PS vesicles was less than 0.01, consistent with the location of the dye far above the inner surface of the vesicle. Thus, a domain of membrane-bound factor Va is located a minimum of 90 A above the phospholipid surface.(ABSTRACT TRUNCATED AT 250 WORDS)     

Clustering of lipid-bound annexin V may explain its anticoagulant effect.

In 1985 we isolated a new vascular anticoagulant protein VAC alpha, now called annexin V, with a high binding affinity (Kd less than 10(-10) M) for phospholipids. Its anticoagulant effect was attributed to displacement of coagulation factors from the phospholipid membrane. The present study demonstrates that the inhibition of prothrombinase activity by annexin V strongly depends on the curvature of the membrane surface and on the calcium concentration. Half-maximal inhibition of prothrombinase on and binding of annexin V to small vesicles, composed of 20% phosphatidylserine and 80% phosphatidylcholine, requires 2-3 mM calcium. With large vesicles and planar bilayers considerably less calcium is required for inhibition of prothrombinase and for lipid binding. Half-maximal binding of annexin V to large vesicles and to planar bilayers occurs at 0.7 and 0.2 mM calcium, respectively. This seemingly confirms the displacement model. The displacement of coagulation factors, however, proved to be incomplete, with residual surface concentrations of factors Xa, Va, and prothrombin sufficient for effective production of thrombin. Cryoelectron microscopy revealed that annexin V binding to large vesicles caused planar facets, indicating the formation of large sheets of clustered annexin V. Apparently, the formation of these two-dimensional arrays is promoted by calcium and hampered by high surface curvature. It is speculated that the complete inhibition (greater than 99%) of prothrombinase activity by annexin V is caused by the reduced lateral mobility of prothrombin and factor Xa in rigid sheets of annexin V covering the membrane.     

The effect of membrane composition on the hemostatic balance

The phospholipid composition requirements for optimal prothrombin activation and factor Va inactivation by activated protein C (APC) anticoagulant were examined. Vesicles composed of phosphatidylethanolamine (PE) and phosphatidylcholine (PC) supported factor Va inactivation relatively well. However, optimal factor Va inactivation still required relatively high concentrations of phosphatidylserine (PS). In addition, at a fixed concentration of phospholipid, PS, and APC, vesicles devoid of PE never attained a rate of factor Va inactivation achievable with vesicles containing PE. Polyunsaturation of any vesicle component also contributed significantly to APC inactivation of factor Va. Thus, PE makes an important contribution to factor Va inactivation that cannot be mimicked by PS. In the absence of polyunsaturation in the other membrane constituents, this contribution was dependent upon the presence of both the PE headgroup per se and unsaturation of the 1,2 fatty acids. Although PE did not affect prothrombin activation rates at optimal PS concentrations, PE reduced the requirement for PS approximately 10-fold. The Km(app) for prothrombin and the Kd(app) for factor Xa-factor Va decreased as a function of increasing PS concentration, reaching optimal values at 10-15% PS in the absence of PE but only 1% PS in the presence of PE. Fatty acid polyunsaturation had minimal effects. A lupus anticoagulant immunoglobulin was more inhibitory to both prothrombinase and factor Va inactivation in the presence of PE. The degree of inhibition of APC was significantly greater and much more dependent on the phospholipid composition than that of prothrombinase. Thus, subtle changes in the phospholipid composition of cells may control procoagulant and anticoagulant reactions differentially under both normal and pathological conditions.     

The association of coagulation factor Xa and factor Va

The binding of factor Xa to factor Va in the presence of Ca2+ ions and phospholipid is fundamental for the activation of prothrombin to thrombin. Nevertheless, the biochemistry of the intrinsic association between factors Xa and Va is poorly understood. In the present study we have measured the formation of the protein-protein complex in the absence of phospholipid by using analytical ultracentrifugation. Factor Xa or factor Va were respectively modified with a chromophore-peptidyl-chloromethyl ketone or a thiol-specific chromophore, which permitted selective evaluation of the sedimentation of either component by virtue of its unique absorbance properties. Regardless of which protein was labeled, a factor Xa-Va complex (s20,w = 9.8) was formed. The interaction is specific and reversible. In 2 mM Ca2+ and at 20 degrees C, the dissociation constant for the binding of factor Xa to factor Va is 0.8 microM with a 1:1 stoichiometry. The association has multiphasic Ca2+ dependence. At concentrations of Ca2+ below 1 mM or above 2 mM, a weaker protein-protein equilibrium is maintained.     

The adsorption of prothrombin to phospholipid monolayers quantitated by ellipsometry

We investigated by means of an automated ellipsometer the calcium-dependent binding of prothrombin from a buffer solution to monolayers of dioleoylphosphatidylserine (DOPS) and dioleoylphosphatidylcholine (DOPC) deposited on chromium slides. This technique allows direct measurements of bound and free protein concentrations and is not hampered by calcium-induced aggregation of vesicles. For pure DOPS a dominant class of binding sites exists with a dissociation constant, Kd = (6 +/- 2) X 10(-10) M (mean +/- S.D.) and maximal binding of prothrombin, gamma max = 0.26 +/- 0.03 micrograms/cm2. Incorporation of a small fraction of DOPC in the monolayer causes a large decrease in the binding affinity with a pronounced biphasic behavior of the binding curve. For monolayers consisting of 20% DOPS and 80% DOPC the binding curve becomes monophasic with Kd = (1.6 +/- 0.6) X 10(-7) M and gamma max = 0.22 +/- 0.03 micrograms/cm2. The procoagulant activity of the monolayers was tested by measuring the generation of thrombin after addition of prothrombin and activated coagulation factors X and V. The thrombin-generating capacity of monolayers and single-bilayer vesicles is comparable but is apparently diffusion limited in the monolayer system. The calcium-dependent formation of stacked multilayers according to the Blodgett technique appeared to be strongly influenced by the DOPS/DOPC ratio in the phospholipid monolayer. From these results it is concluded that for pure DOPS monolayers high-affinity prothrombin-phospholipid and phospholipid-phospholipid interactions exist which are radically disturbed when the monolayer contains more than 20-30% of DOPC.     

Kinetic studies of prothrombin activation: effect of factor Va and phospholipids on the formation of the enzyme-substrate complex

The kinetic parameters of bovine prothrombin activation by factor Xa were determined in the absence and presence of factor Va as a function of the phospholipid concentration and composition. In the absence of factor Va, the Km for prothrombin increases proportionally with the phospholipid concentration and correlates well with the affinity of prothrombin for the different membranes. Phospholipid vesicles with a high affinity for prothrombin yield low Km values compared to membranes with less favorable binding parameters. At limited phospholipid concentrations, the Vmax of prothrombin activation correlates with the binding affinity of factor Xa for the various phospholipid vesicles. Membranes with a high affinity for factor Xa have high Vmax values, while for membranes with a low affinity a low Vmax is observed. Extrapolation of double-reciprocal plots of 1/Vmax vs. 1/[phospholipid] to infinite phospholipid concentrations, a condition at which all factor Xa would participate in prothrombin activation, yields a kcat of 2-4 min-1 independent of the type and amount of acidic phospholipid present in the vesicles. Also, in the presence of factor Va the Km for prothrombin varies proportionally with the phospholipid concentration. There is, however, no correlation between the binding parameters and the Km. Factor Va drastically lowers the Km for prothrombin for vesicles that have a low affinity for prothrombin. Vesicles composed of 20 mol % phosphatidylglycerol and 80 mol % phosphatidylcholine have a Km of 0.04 microM when factor Va is present, compared to 2.2 microM determined in the absence of factor Va.(ABSTRACT TRUNCATED AT 250 WORDS)     

Incorporation of factor Va into prothrombinase is required for coordinated cleavage of prothrombin by factor Xa

Prothrombin is activated to thrombin by two sequential factor Xa-catalyzed cleavages, at Arg271 followed by cleavage at Arg320. Factor Va, along with phospholipid and Ca2+, enhances the rate of the process by 300,000-fold, reverses the order of cleavages, and directs the process through the meizothrombin pathway, characterized by initial cleavage at Arg320. Previous work indicated reduced rates of prothrombin activation with recombinant mutant factor Va defective in factor Xa binding (E323F/Y324F and E330M/V331I, designated factor VaFF/MI). The present studies were undertaken to determine whether loss of activity can be attributed to selective loss of efficiency at one or both of the two prothrombin-activating cleavage sites. Kinetic constants for the overall activation of prothrombin by prothrombinase assembled with saturating concentrations of recombinant mutant factor Va were calculated, prothrombin activation was assessed by SDS-PAGE, and rate constants for both cleavages were analyzed from the time course of the concentration of meizothrombin. Prothrombinase assembled with factor VaFF/MI had decreased k(cat) for prothrombin activation with Km remaining unaffected. Prothrombinase assembled with saturating concentrations of factor VaFF/MI showed significantly lower rate for cleavage of plasma-derived prothrombin at Arg320 than prothrombinase assembled with saturating concentrations of wild type factor Va. These results were corroborated by analysis of cleavage of recombinant prothrombin mutants rMz-II (R155A/R284A/R271A) and rP2-II (R155A/R284A/R320A), which can be cleaved only at Arg320 or Arg271, respectively. Time courses of these mutants indicated that mutations in the factor Xa binding site of factor Va reduce rates for both bonds. These data indicate that the interaction of factor Xa with the heavy chain of factor Va strongly influences the catalytic activity of the enzyme resulting in increased rates for both prothrombin-activating cleavages.