Inactivation of factor X by plasmin]

Plasmin does not activate factor X into the enzyme--factor Xa. On the contrary, the enzyme inactivates factor X, rendering it incapable of conversion into factor Xa during incubation in 25% sodium citrate. After proteolysis by plasmin the prothrombin preparations contaminated with factor X lose their ability to generate thrombin. This ability is partially restored by an addition of factor X.     

Proteolysis of factor Va by factor Xa and activated protein C

Bovine Factor Va, produced by selective proteolytic cleavage of Factor V by thrombin, consists of a heavy chain (D chain) of Mr = 94,000 and a light chain (E chain) of Mr = 74,000. These peptides are noncovalently associated in the presence of divalent metal ion(s). Each chain is susceptible to proteolysis by activated protein C and by Factor Xa. Sodium dodecyl sulfate electrophoretic analysis indicates that cleavage of the E chain by either activated protein C or Factor Xa yields two major fragments: Mr = 30,000 and Mr = 48,000. Amino acid sequence analysis indicates that the Mr = 30,000 fragments have identical NH2-terminal sequences and that this sequence corresponds to that of intact E chain. The Mr = 48,000 fragments also have identical NH2-terminal sequences, indicating that activated protein C and Factor Xa cleave the E chain at the same position. Sodium dodecyl sulfate electrophoretic analysis indicates that activated protein C cleavage of the D chain yields two products: Mr = 70,000 and Mr = 24,000. Amino acid sequence analysis indicates that the Mr = 70,000 fragment has the same NH2-terminal sequence as intact D chain, whereas the Mr = 24,000 fragment does not. Factor Xa cleavage of the D chain also yields two products: Mr = 56,000 and Mr = 45,000. The Mr = 56,000 fragment corresponds to the NH2-terminal end of the D chain and Factor V. Functional studies have shown that both chains of Factor Va may be entirely cleaved to products by Factor Xa without loss of activity, whereas activated protein C cleavage results in loss of activity. Since activated protein C and Factor Xa cleave the E chain at the same position, the cleavage of the D chain by activated protein C is responsible for the inactivation of Factor Va.     

Defining the factor Xa-binding site on factor Va by site-directed glycosylation

Activated Factor V (FVa) functions as a membrane-bound cofactor to the enzyme Factor Xa (FXa) in the conversion of prothrombin to thrombin, increasing the catalytic efficiency of FXa by several orders of magnitude. To map regions on FVa that are important for binding of FXa, site-directed mutagenesis resulting in novel potential glycosylation sites on FV was used as strategy. The consensus sequence for N-linked glycosylation was introduced at sites, which according to a computer model of the A domains of FVa, were located at the surface of FV. In total, thirteen different regions on the FVa surface were probed, including sites that are homologous to FIXa-binding sites on FVIIIa. The interaction between the FVa variants and FXa and prothrombin were studied in a functional prothrombin activation assay, as well as in a direct binding assay between FVa and FXa. In both assays, the four mutants carrying a carbohydrate side chain at positions 467, 511, 652, or 1683 displayed attenuated FXa binding, whereas the prothrombin affinity was unaffected. The affinity toward FXa could be restored when the mutants were expressed in the presence of tunicamycin to inhibit glycosylation, indicating the lost FXa affinity to be caused by the added carbohydrates. The results suggested regions surrounding residues 467, 511, 652, and 1683 in FVa to be important for FXa binding. This indicates that the enzyme:cofactor assembly of the prothrombinase and the tenase complexes are homologous and provide a useful platform for further investigation of specific structural elements involved in the FVa.FXa complex assembly.     

Inactivation of factor VIII by factor IXa.

Factor VIII (FVIII) is the nonproteolytic cofactor for FIXa in the tenase complex of blood coagulation. FVIII is proteolytically activated by thrombin and FXa in vitro to form a heterotrimer with full procoagulant activity. Activated protein C inactivates thrombin-activated FVIII through cleavage adjacent to position Arg 336 in the cofactor. We have investigated the interaction of FIXa and FVIII and subjected FVIII polypeptides to N-terminal amino acid sequence analysis. Contrary to previous reports, we were unable to demonstrate the activation of FVIII by FIXa. Incubation of these two proteins at equimolar or close to equimolar concentrations resulted in the inactivation of FVIII, coincident with cleavage of the FVIII heavy chain adjacent to Arg 336 and the light chain adjacent to Arg 1719. These cleavages were detected in the presence or absence of thrombin, indicating that FIXa does not stabilize thrombin-activated FVIIIa. APC cleaved FVIII at the same position in the heavy chain, and simultaneous incubation of FVIII, APC, and FIXa did not result in stabilization of the cofactor. We conclude that FIXa does not play a role in the stabilization or activation of FVIII.     

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.     

The role of the membrane in the inactivation of factor va by plasmin. Amino acid region 307-348 of factor V plays a critical role in factor Va cofactor function

The mechanism of inactivation of bovine factor Va by plasmin was studied in the presence and absence of phospholipid vesicles (PCPS vesicles). Following 60-min incubation with plasmin (4 nm) membrane-bound factor Va (400 nm) is completely inactive, whereas in the absence of phospholipid vesicles following a 1-h incubation period, the cofactor retains 90% of its initial cofactor activity. Amino acid sequencing of the fragments deriving from cleavage of factor Va by plasmin demonstrated that while both chains of factor Va are cleaved by plasmin, only cleavage of the heavy chain correlates with inactivation of the cofactor. In the presence of a membrane surface the heavy chain of the bovine cofactor is first cleaved at Arg(348) to generate a fragment of M(r) 47,000 containing the NH(2)-terminal part of the cofactor (amino acid residues 1-348) and a M(r) 42,000 fragment (amino acid residues 349-713). This cleavage is associated with minimal loss in cofactor activity. Complete loss of activity of the membrane-bound cofactor coincides with three cleavages at the COOH-terminal portion of the M(r) 47,000 fragment: Lys(309), Lys(310), and Arg(313). These cleavages result in the release of the COOH terminus of the molecule and the production of a M(r) 40,000 fragment containing the NH(2)-terminal portion of the factor Va molecule. Factor Va was treated with plasmin in the absence of phospholipid vesicles followed by the addition of PCPS vesicles and activated protein C (APC). A rapid inactivation of the cofactor was observed as a result of cleavage of the M(r) 47,000 fragment at Arg(306) by APC and appearance of a M(r) 39,000 fragment. These data suggest a critical role of the amino acid sequence 307-348 of factor Va. A 42-amino acid peptide encompassing the region 307-348 of human factor Va (N42R) was found to be a good inhibitor of factor Va clotting activity with an IC(50) of approximately 1.3 microm. These data suggest that plasmin is a potent inactivator of factor Va and that region 307-348 of the cofactor plays a critical role in cofactor function and may be responsible for the interaction of the cofactor with factor Xa and/or prothrombin.     

Homocysteine inhibits inactivation of factor Va by activated protein C

We report the effect of homocysteine on the inactivation of factor Va by activated protein C (APC) using clotting assays, immunoblotting, and radiolabeling experiments. Homocysteine, cysteine, or homocysteine thiolactone have no effect on factor V activation by alpha-thrombin. Factor Va derived from homocysteine-treated factor V was inactivated by APC at a reduced rate. The inactivation impairment increased with increasing homocysteine concentration (pseudo first order rate k = 1.2, 0.9, 0.7, 0.4 min(-1) at 0, 0.03, 0.1, 1 mm homocysteine, respectively). Neither cysteine nor homocysteine thiolactone treatment of factor V affected APC inactivation of derived factor Va. Western blot analyses of APC inactivation of homocysteine-modified factor Va are consistent with the results of clotting assays. Factor Va, derived from factor V treated with 1 mm beta-mercaptoethanol was inactivated more rapidly than the untreated protein sample. Factor V incubated with [(35)S]homocysteine (10-450 micrometer) incorporated label within 5 min, which was found only in those fragments that contained free sulfhydryl groups: the light chain (Cys-1960, Cys-2113), the B region (Cys-1085), and the 26/28-kDa (residues 507-709) APC cleavage products of the heavy chain (Cys-539, Cys-585). Treatment with beta-mercaptoethanol removed all radiolabel. Plasma of patients assessed to be hyperhomocysteinemic showed APC resistance in a clot-based assay. Our results indicate that homocysteine rapidly incorporates into factor V and that the prothrombotic tendency in hyperhomocysteinemia may be related to impaired inactivation of factor Va by APC due to homocysteinylation of the cofactor by modification of free cysteine(s).     

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.     

Definition of a factor Va binding site in factor Xa

We reported previously that residue 347 in activated fX (fXa) contributes to binding of the cofactor, factor Va (fVa) (Rudolph, A. E., Porche-Sorbet, R. and Miletich, J. P. (2000) Biochemistry 39, 2861-2867). Four additional residues that participate in fVa binding have now been identified by mutagenesis. All five resulting fX species, fX(R306A), fX(E310N), fX(R347N), fX(K351A), and fX(K414A), are activated and inhibited normally. However, the rate of inhibition by antithrombin III in the presence of submaximal concentrations of heparin is reduced for all the enzymes. In the absence of fVa, all of the enzymes bind and activate prothrombin similarly except fXa(E310N), which has a reduced apparent affinity ( approximately 3-fold) for prothrombin compared with wild type fXa (fXa(WT)). In the absence of phospholipid, fVa enhances the catalytic activity of fXa(WT) significantly, but the response of the variant enzymes was greatly diminished. On addition of 100 nm PC:PS (3:1) vesicles, fVa enhanced fXa(WT), fXa(R306A), and fXa(E310N) similarly, whereas fXa(R347N), fXa(K351A), and fXa(K414A) demonstrated near-normal catalytic activity but reduced apparent affinity for fVa under these conditions. All enzymes function similarly to fXa(WT) on activated platelets, which provide saturating fVa on an ideal surface. Loss of binding affinity for fVa as a result of the substitutions in residues Arg-347, Lys-351, and Lys-414 was verified by a competition binding assay. Thus, Arg-347, Lys-351, and Lys-414 are likely part of a core fVa binding site, whereas Arg-306 and Glu-310 serve a less critical role.     

Phospholipid-binding properties of bovine factor V and factor Va.

Factor V and factor Va binding to single bilayer phospholipid vesicles was investigated by light-scattering intensity measurements. This technique allows the measurement of free and phospholipid-bound protein concentrations from which equilibrium constants can be obtained. As controls, the Ca2+-dependent phospholipid binding of prothrombin and factor X were also studied. The average values obtained for the dissociation constants (Kd) and lipid to protein ratio at saturation, moles/mole (n), for prothrombin (Kd = 2.3 X 10(-6) M, n = 104) and factor X (Kd = 2.5 X 10(-6) M, n = 46) binding to vesicles containing 25% Folch fraction III and 75% phosphatidylcholine in the presence of 2 mM Ca2+ were in agreement with those reported in the literature. The average factor V and factor Va values for the dissociation constants and lipid to protein ratio at saturation (moles/mole) were Kd = 7.2 X 10(-8) M and n = 270 for factor V and Kd = 4.4 X 10(-7) M and n = 76 for factor Va. In contrast to prothrombin and factor X, factor V and factor Va demonstrated Ca2+-independent lipid binding. In addition, the number of factor V and factor Va molecules bound per vesicle was found to be dependent both on the phosphatidylserine content of the vesicle and the ionic strength of the buffer.     

Resistance of factor XIII to degradation or activation by plasmin

The effect of plasmin on the subunit polypeptides of factor XIII has been investigated. purified human plasma (a2b2) and platelet (a2) zymogens and the enzyme (a2) were incubated with plasmin at plasmin: factor XIII ratios of 0.03-0.5 casein units per mg protein. Under conditions in which plasmin readily digested fibrinogen and casein, it had no effect on either a2b2 or a2. There was no evidence for cleavage of peptide bonds in the zymogens, and all the potential catalytic activity was retained after prolonged incubation. Similarly a2*, either in the presence or absence of b subunit, was also unaffected by plasmin incubation. 90% of the activity was recovered after incubation of factor XIII with plasmin. b subunit was also not degraded. Additionally, no evidence was obtained that plasmin could activate factor Xiii. These results indicate that in purified systems there is no significant interaction between plasmin and factor XIII.     

Mechanism of factor Va inactivation by plasmin. Loss of A2 and A3 domains from a Ca2+-dependent complex of fragments bound to phospholipid

The coagulation cofactor Va (FVa) is a noncovalent heterodimer consisting of a heavy chain (FVaH) and a light chain (FVaL). Previously, the fibrinolytic effector plasmin (Pn) has been shown to inhibit FVa function. To understand this mechanism, the fragmentation profile of human FVa by Pn and the noncovalent association of the derived fragments were determined in the presence of Ca(2+) using anionic phospholipid (aPL)-coated microtiter wells and large (1 microm) aPL micelles as affinity matrices. Following Pn inactivation of aPL-bound FVa, a total of 16 fragments were observed and their NH(2) termini sequenced. These had apparent molecular weights and starting residues as follows (single letter abbreviation is used): 50(L1766), 48(L1766), 43(Q1828), 40(Q1828), 30(S1546), 12(T1657), and 7(S1546) kDa from FVaL; and 65(A1), 50(A1), 45(A1), 34(S349), 30(L94), 30(M110), and 3 small <5(W457, W457, and K365) kDa from FVaH. Of these, 50(L1766), 48(1766), 43(Q1828), and 40(Q1828) spanning the C1/C2 domains, and 30(L94), but not the similar 30(M110), positioned within the A1 domain remained associated with aPL. These were detected antigenically during Pn- or tissue plasminogen activator-mediated lysis of fibrin clot formed in plasma. Chelation by EDTA dissociated the 30(L94)-kDa fragment, which was observed to associate with intact FVaL upon recalcification, indicating that the Leu-94 to Lys-109 region of the A1 domain plays a critical role in the FVaL and FVaH Ca(2+)-dependent association. By using domain-specific monoclonal antibodies and an assay for thrombin generation, loss of FVa prothrombinase function was coincident with proteolysis at sites in the A2 and A3 domains resulting in their dissociation. Inactivation of FV or FVa by Pn was independent of the thrombophilic R506Q mutation. These results identify the molecular composition of Pn-cleaved FVa that remains bound to membrane as largely A1-C1/C2 in the presence of Ca(2+) and suggest that Pn inhibits FVa by a process involving A2 and A3 domain dissociation.     

Structural requirements for expression of factor Va activity

Thrombin activated factor Va (factor VIIa, residues 1-709 and 1546-2196) has an apparent dissociation constant (Kd,app) for factor Xa within prothrombinase of approximately 0.5 nM. A protease (NN) purified from the venom of the snake Naja nigricollis nigricollis, cleaves human factor V at Asp697, Asp1509, and Asp1514 to produce a molecule (factor VNN) that is composed of a Mr 100,000 heavy chain (amino acid residues 1-696) and a Mr 80,000 light chain (amino acid residues 1509/1514-2196). Factor VNN, has a Kd,app for factor Xa of 4 nm and reduced clotting activity. Cleavage of factor VIIa by NN at Asp697 results in a cofactor that loses approximately 60-80% of its clotting activity. An enzyme from Russell's viper venom (RVV) cleaves human factor V at Arg1018 and Arg1545 to produce a Mr 150,000 heavy chain and Mr 74,000 light chain (factor VRVV, residues 1-1018 and 1546-2196). The RVV species has affinity for factor Xa and clotting activity similar to the thrombin-activated factor Va. Cleavage of factor VNN at Arg1545 by alpha-thrombin (factor VNN/IIa) or RVV (factor VNN/RVV) leads to enhanced affinity of the cofactor for factor Xa (Kd,app approximately 0.5 nM). A synthetic peptide containing the last 13 residues from the heavy chain of factor Va (amino acid sequence 697-709, D13R) was found to be a competitive inhibitor of prothrombinase with respect to prothrombin. The peptide was also found to specifically interact with thrombin-agarose. These data demonstrate that 1) cleavage at Arg1545 and formation of the light chain of factor VIIa is essential for high affinity binding and function of factor Xa within prothrombinase and 2) a binding site for prothrombin is contributed by amino acid residues 697-709 of the heavy chain of the cofactor.     

Proteolytic alterations of factor Va bound to platelets

The coagulation protein Factor Va forms the receptor for the serine protease Factor Xa at the platelet surface. This membrane-bound complex of Factor Va and Factor Xa plus calcium constitutes the enzymatic complex prothrombinase, which effects the conversion of prothrombin to the clotting enzyme, thrombin. Studies were undertaken to investigate the proteolytic events accompanying the inactivation of platelet-bound Factor Va by activated protein C as well as the ability of Factor Xa to protect Factor Va from activated protein C inactivation. During the course of these studies, observations were made which indicated that Factor Va was also cleaved by both a platelet-associated protease, as well as Factor Xa. When Factor Va was incubated with washed platelets, electrophoresis and autoradiography of solubilized platelet pellets indicated that three Factor Va peptides were associated with the platelet: component D (Mr = 94,000), component E (Mr = 74,000), and a 90,000-dalton peptide (component D') which appeared with time as the result of a platelet-associated protease cleavage of component D. The Factor Va peptides bound to platelets were proteolytically inactivated by activated protein C, resulting in five peptide products, all of which remained associated with the platelet-membrane surface. Factor Va was protected from activated protein C proteolysis by complex formation with Factor Xa or active site-blocked Factor Xa. However, active Factor Xa cleaved platelet-bound Factor Va to peptide products which also remained associated with the platelet. Whereas activated protein C rapidly cleaved components D and D' with secondary cleavages occurring in component E, Factor Xa rapidly cleaved component E with secondary cleavages occurring in components D and D'. The Factor Xa-cleaved Factor Va is catalytically functional. To determine whether cleavage was necessary for function, prothrombin conversion reaction mixtures were monitored for thrombin formation and Factor Va cleavage with time in a defined phospholipid vesicle model system. The results indicated that Factor Xa cleavage of Factor Va is not essential for Factor Va activity but may promote its ability to function in the prothrombinase complex.     

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.     

The effects of phospholipid and factor Va on the inhibition of factor Xa by antithrombin III

The rate of inhibition of Factor Xa by antithrombin III was found to be influenced by either phospholipid or Factor Va combined with phospholipid. Our results confirmed that Factor Va and phospholipid could protect Factor Xa from inhibition. However, when antithrombin III levels were extrapolated to infinity, the protective effect of lipid and Factor Va were eliminated and the rate of inhibition was accelerated. This indicated that the protective effect that was observed at low antithrombin III concentrations in the presence of phospholipid and Factor Va was due to inhibition of binding of the inhibitor to Factor Xa.     

The binding of factor Va to phospholipid vesicles

The analysis of free sulfhydryl groups in factor Va using dithiobis-(nitrobenzoic acid) (DTNB) indicated the presence of one accessible thiol in each of the two subunits of the cofactor. Intact factor Va contained one readily accessible sulfhydryl group under native conditions and approximately two such groups after denaturation. A comparison of the rate of modification of the accessible thiol in factor Va under native conditions to those observed with the isolated subunits indicated that the thiol present in component D of the cofactor was readily accessible to reaction with DTNB. Factor Va was reacted with the sulfhydryl-directed fluorophore N-(1-pyrene)maleimide, resulting in the concomitant loss of the accessible thiol with no detectable alteration in the activity of the cofactor. This fluorescent derivative of factor Va (Pyr-Va) was used to examine the binding of factor Va to phospholipid vesicles by fluorescence polarization. Fluorescence polarization of the pyrene moiety increased saturably when Pyr-Va was titrated with increasing concentrations of vesicles composed of phosphatidylcholine and phosphatidylserine (PS). Systematic analysis of the binding of Pyr-Va to PCPS (75% phosphatidylcholine, 25% PS) indicated that the binding interaction was characterized by a dissociation constant of 2.7 x 10(-9) M with 42 mol of PCPS bound per mol of Va at saturation. The data obtained by varying the PS content of the vesicles are consistent with the interpretation that the Va-combining site on the vesicle surface is composed of a discrete number of PS molecules. The binding of Pyr-Va to PCPS was independent of added calcium ion and could be reversed by the addition of unlabeled Va or isolated component E but not by component D. Analysis of the displacement curves indicated that native factor Va or isolated component E and Pyr-Va mutually excluded each other on the vesicle surface with identical affinities. Competition experiments conducted using component E digested by factor Xa or the isolated derivative peptides indicated that the cleavage of component E by factor Xa had no effect on the PCPS binding properties of this subunit. Further, the data obtained with the isolated peptides suggest that the lipid-binding domain of component E is present in the amino-terminal region of this subunit.