Residues 88-109 of factor IXa are important for assembly of the factor X activating complex.

Activated platelets and phospholipid vesicles promote assembly of the intrinsic factor X (FX) activating complex by presenting high-affinity binding sites for blood coagulation FIXa, FVIIIa, and FX. Previous reports suggest that the second epidermal growth factor (EGF)-like domain of FIXa mediates assembly of the FX activating complex (Ahmad, S. S., Rawala, R., Cheung, W. F., Stafford, D. W., and Walsh, P. N. (1995) Biochem. J. 310, 427-431; Wong, M. Y., Gurr, J. A., and Walsh, P. N. (1999) Biochemistry 38, 8948-8960). To identify important residues, we prepared several chimeric FIXa proteins using homologous sequences from FVII: FIXa(FVIIEGF2) (FIX Delta 88-124,inverted Delta FVII91-127), FIXa(loop1) (FIX Delta 88-99,inverted Delta FVII91-102), FIXa(loop2) (FIX Delta 95-109,inverted Delta FVII98-112), FIXa(loop3) (FIX Delta 111-124,inverted Delta FVII114-127), and point mutants (FIXaR94D and FIXa(loop1)G94R). In the presence and absence of FVIIIa, a 2- to 10-fold reduced V(max) of FX activation (nm FXa min(-1)) was observed for FIXa(FVIIEGF2), FIXa(loop1), FIXa(loop2), and FIXa(loop1)G94R, whereas FIXa(loop3) and FIXaR94D were normal. For all of the FIXa proteins, K(m)((app)) values were normal as were EC(50) values for interactions with FVIIIa. However, K(d)((app)) (in nm) for the FX activating complex assembled on phospholipid vesicles was increased for FIXa(FVIIEGF2) (43.3 +/- 2.70), FIXa(loop1)(10.9 +/- 2.8), FIXa(loop2) (70.5 +/- 1.60), and FIXa(loop1)G94R (17.1 +/- 2.90) relative to FIXa(N) (3.9 +/- 0.11), FIXa(WT) (4.6 +/- 0.17), FIXa(loop3) (4.5 +/- 0.20), and FIXaR94D (2.2 +/- 0.09) suggesting that reduced V(max) is a result of impaired complex assembly. These data indicate that residues 88-109 (but not Arg(94)) are important for normal assembly of the FX activating complex on phospholipid vesicles.     

The factor IXa second epidermal growth factor (EGF2) domain mediates platelet binding and assembly of the factor X activating complex.

Previously we have determined that residues 88-109 (but not Arg(94)) in the second epidermal growth factor (EGF2)-like domain of factor IXa (FIXa) are important for assembly of the factor X (FX) activating complex on phospholipid vesicles (Wilkinson, F. H., London, F. S., and Walsh, P. N. (2002) J. Biol. Chem. 277, 5725-5733). Here we report that these residues are important for platelet binding affinity, stoichiometry, and assembly of the FX activating complex. We prepared several chimeric FIXa proteins using homologous sequences from factor VII (FVII): FIXa(FVIIEGF2) (FIX Delta 88-124,inverted Delta FVII91-127), FIXa(loop1) (FIX Delta 88-99,inverted Delta FVII91-102), FIXa(loop2) (FIX Delta 95-109,inverted Delta FVII98-112), and FIXa(loop3) (FIX Delta 111-124,inverted Delta FVII114-127) and tested their ability to bind to thrombin-activated platelets. Binding affinities (K(d) values in 10(-9) m) for the proteins were as follows in the presence and absence of FVIIIa, respectively: FIXa(N) (0.55 +/- 0.06, 2.9 +/- 0.45), FIXa(WT) (0.80 +/- 0.08, 3.5 +/- 0.5), FIXa(loop1) (19 +/- 4.0, 27 +/- 5.0), FIXa(loop2) (35 +/- 9.0, 65 +/- 12.0), and FIXa(loop3) (1.1 +/- 0.09, 5.0 +/- 0.90). These K(d) values are in good agreement with K((d)(app)) values (in 10(-9) m) determined from the activation of FX (in the presence and absence of FVIIIa, respectively): FIXa(N) (0.46 +/- 0.05, 1.40 +/- 0.14), FIXa(WT) (0.72 +/- 0.08, 3.8 +/- 0.08), FIXa(loop1) (3.2 +/- 0.72, 14.0 +/- 1.60), FIXa(loop2) (18.4 +/- 1.60, 26.3 +/- 3.40), and FIXa(loop3) (0.7 +/- 0.05, 3.0 +/- 0.15). Moreover, the stoichiometry of binding (sites/platelet) showed an agreement with V(max) of FX activation and was reduced in those proteins that also showed a decreased platelet binding affinity. A peptide corresponding to the FIX EGF2 domain (Leu(84)-Val(128)) was an effective inhibitor of FIXa binding to platelets in both the presence (K(i) = 0.7 x 10(-6) m) and the absence (K(i) = 1.5 x 10(-6) m) of FVIIIa and FX. We conclude that residues 88-109 of the FIXa EGF2 domain mediate binding to platelets and assembly of the FX activating complex.ut not Ar     

Factor VIII Lacking the C2 Domain Retains Cofactor Activity in Vitro

Factor (F) VIII consists of a heavy chain (A1A2B domains) and light chain (A3C1C2 domains). The activated form of FVIII, FVIIIa, functions as a cofactor for FIXa in catalyzing the membrane-dependent activation of FX. Whereas the FVIII C2 domain is believed to anchor FVIIIa to the phospholipid surface, recent x-ray crystal structures of FVIII suggest that the C1 domain may also contribute to this function. We constructed a FVIII variant lacking the C2 domain (designated ΔC2) to characterize the contributions of the C1 domain to function. Binding affinity of the ΔC2 variant to phospholipid vesicles as measured by energy transfer was reduced ∼14-fold. However, the activity of ΔC2 as measured by FXa generation and one-stage clotting assays retained 76 and 36%, respectively, of the WT FVIII value. Modest reductions (∼4-fold) were observed in the functional affinity of ΔC2 FVIII for FIXa and rates of thrombin activation. On the other hand, deletion of C2 resulted in significant reductions in FVIIIa stability (∼3.6-fold). Thrombin generation assays showed peak thrombin and endogenous thrombin potential were reduced as much as ∼60-fold. These effects likely result from a combination of the intermolecular functional defects plus reduced protein stability. Together, these results indicate that FVIII domains other than C2, likely C1, make significant contributions to membrane-binding and membrane-dependent function.     

Structural and functional characterization of platelet receptor-mediated factor VIII binding

Optimal rates of factor X (FX) activation require occupancy of receptors for factor IXa (FIXa), factor VIII (FVIII), and FX on the activated platelet surface. The presence of FVIII and FX increases 5-fold the affinity of FIXa for the surface of activated platelets, and the presence of FVIII or FVIIIa generates a high affinity, low capacity specific FX-binding site on activated platelets. We have now examined the effects of FX and active site-inhibited FIXa (EGR-FIXa) on the binding of both FVIII and FVIIIa to activated platelets and show the following: (a) von Willebrand factor inhibits FVIII binding (K(i) = 0.54 nM) but not FVIIIa binding; (b) thrombin and the thrombin receptor activation peptide (SFLLRN amide) are the most potent agonists required for FVIII-binding site expression, whereas ADP is inert; (c) FVa does not compete with FVIIIa or FVIII for functional platelet-binding sites; and (d) Annexin V is a potent inhibitor of FVIIIa binding (IC(50) = 10 nM) to activated platelets. The A2 domain of FVIII significantly increases the affinity and stoichiometry of FVIIIa binding to platelets and contributes to the stability of the FX-activating complex. Both FVIII and FVIIIa binding were specific, saturable, and reversible. FVIII binds to specific, high affinity receptors on activated platelets (n = 484 +/- 59; K(d) = 3.7 +/- 0.31 nM) and FVIIIa interacts with an additional 300-500 sites per platelet with enhanced affinity (K(d) = 1.5 +/- 0.11 nM). FVIIIa binding to activated platelets in the presence of FIXa and FX is closely coupled with rates of F-X activation. The presence of EGR-FIXa and FX increases both the number and the affinity of binding sites on activated platelets for both FVIII and FVIIIa, emphasizing the validity of a three-receptor model in the assembly of the F-X-activating complex on the platelet surface.     

Na+ site in blood coagulation factor IXa: effect on catalysis and factor VIIIa binding

During blood coagulation, factor IXa (FIXa) activates factor X (FX) requiring Ca2+, phospholipid, and factor VIIIa (FVIIIa). The serine protease domain of FIXa contains a Ca2+ site and is predicted to contain a Na+ site. Comparative homology analysis revealed that Na+ in FIXa coordinates to the carbonyl groups of residues 184A, 185, 221A, and 224 (chymotrypsin numbering). Kinetic data obtained at several concentrations of Na+ and Ca2+ with increasing concentrations of a synthetic substrate (CH3-SO2-d-Leu-Gly-Arg-p-nitroanilide) were fit globally, assuming rapid equilibrium conditions. Occupancy by Na+ increased the affinity of FIXa for the synthetic substrate, whereas occupancy by Ca2+ decreased this affinity but increased k(cat) dramatically. Thus, Na+-FIXa-Ca2+ is catalytically more active than free FIXa. FIXa(Y225P), a Na+ site mutant, was severely impaired in Na+ potentiation of its catalytic activity and in binding to p-aminobenzamidine (S1 site probe) validating that substrate binding in FIXa is linked positively to Na+ binding. Moreover, the rate of carbamylation of NH2 of Val16, which forms a salt-bridge with Asp194 in serine proteases, was faster for FIXa(Y225P) and addition of Ca2+ overcame this impairment only partially. Further studies were aimed at delineating the role of the FIXa Na+ site in macromolecular catalysis. In the presence of Ca2+ and phospholipid, with or without saturating FVIIIa, FIXa(Y225P) activated FX with similar K(m) but threefold reduced k(cat). Further, interaction of FVIIIa:FIXa(Y225P) was impaired fourfold. Our previous data revealed that Ca2+ binding to the protease domain increases the affinity of FIXa for FVIIIa approximately 15-fold. The present data indicate that occupancy of the Na+ site further increases the affinity of FIXa for FVIIIa fourfold and k(cat) threefold. Thus, in the presence of Ca2+, phospholipid, and FVIIIa, binding of Na+ to FIXa increases its biologic activity by approximately 12-fold, implicating its role in physiologic coagulation.     

Characterization of a factor Xa binding site on factor Va near the Arg-506 activated protein C cleavage site

Prothrombin is proteolytically activated by the prothrombinase complex comprising the serine protease Factor (F) Xa complexed with its cofactor, FVa. Based on inhibition of the prothrombinase complex by synthetic peptides, FVa residues 493-506 were proposed as a FXa binding site. FVa is homologous to FVIIIa, the cofactor for the FIXa protease, in the FX-activating complex, and FVIIIa residues 555-561 (homologous to FVa residues 499-506) are recognized as a FIXa binding sequence. To test the hypothesis that FVa residues 499-505 contribute to FXa binding, we created the FVa loop swap mutant (designated 499-505(VIII) FV) with residues 499-505 replaced by residues 555-561 of FVIIIa, which differ at five of seven positions. Based on kinetic measurements and spectroscopic titrations, this FVa loop swap mutant had significantly reduced affinity for FXa. The fully formed prothrombinase complex containing this FVa mutant had fairly normal kinetic parameters (k(cat) and K(m)) for cleavage of prothrombin at Arg-320. However, small changes in both Arg-320 and Arg-271 cleavage rates result together in a moderate change in the pathway of prothrombin activation. Although residues 499-505 directly precede the Arg-506 cleavage site for activated protein C (APC), the 499-505(VIII) FVa mutant was inactivated entirely normally by APC. These results suggest that this A2 domain sequence of the FVa and FVIIIa cofactors evolved to have different specificity for binding FXa and FIXa while retaining compatibility as substrate for APC. In an updated three-dimensional model for the FVa structure, residues 499-505, along with Arg-506, Arg-306, and other previously suggested FXa binding sequences, delineate a continuous surface on the A2 domain that is strongly implicated as an extended FXa binding surface in the prothrombinase complex.     

Factor VIIIa A2 Subunit Shows a High Affinity Interaction with Factor IXa: CONTRIBUTION OF A2 SUBUNIT RESIDUES 707-714 TO THE INTERACTION WITH FACTOR IXa*

Factor (F) VIIIa forms a number of contacts with FIXa in assembling the FXase enzyme complex. Surface plasmon resonance was used to examine the interaction between immobilized biotinylated active site-modified FIXa, and FVIII and FVIIIa subunits. The FVIIIa A2 subunit bound FIXa with high affinity (K_d = 3.9 ± 1.6 nm) that was similar to the A3C1C2 subunit (K_d = 3.6 ± 0.6 nm). This approach was used to evaluate a series of baculovirus-expressed, isolated A2 domain (bA2) variants where alanine substitutions were made for individual residues within the sequence 707-714, the C-terminal region of A2 thought to be FIXa interactive. Three of six bA2 variants examined displayed 2- to 4-fold decreased affinity for FIXa as compared with WT bA2. The variant bA2 proteins were also tested in two reconstitution systems to determine activity and affinity parameters in forming FXase and FVIIIa. V_max values for all variants were similar to the WT values, indicating that these residues do not affect cofactor function. All variants showed substantially greater increases in apparent K_d relative to WT in reconstituting the FXase complex (8- to 26-fold) compared with reconstituting FVIIIa (1.3- to 6-fold) suggesting that the mutations altered interaction with FIXa. bA2 domain variants with Ala replacing Lys⁷⁰⁷, Asp⁷¹², and Lys⁷¹³ demonstrated the greatest increases in apparent K_d (17- to 26-fold). These results indicate a high affinity interaction between the FVIIIa A2 subunit and FIXa and show a contribution of several residues within the 707-714 sequence to this binding.     

Role of the C2 domain of factor VIIIa in the assembly of factor-X activating complex on the platelet membrane

Optimal rates of factor X (FX) activation require binding of factor IXa (FIXa), factor VIII(a) [FVIII(a)], and FX to activated platelet receptors. To define the FVIIIa domains that mediate platelet interactions, albumin density gradient washed, gel-filtered platelets (3.5 x 10(8)/mL) activated by the thrombin receptor peptide, SFLLRN (25 microM), were incubated with 125I-labeled FVIII C2 domain, or 125I-FVIIIa, or 125I-FVIII((LC)), or peptides from the C2 domain region, with or without anti-C2 domain monoclonal antibodies (MoAb), ESH4 or ESH8. FVIIIa (Kd approximately 1.7 nM), FVIII((LC)) (Kd approximately 3 nM), and the C2 domain (Kd approximately 16 nM) all interacted with approximately 700-800 binding sites/platelet. Unlike FVIIIa, the C2 domain did not respond to the presence of excess EGR-FIXa (45 nM) and FX (1.5 microM) with enhanced binding stoichiometry and affinity. Both the MoAb ESH4 and a synthetic peptide corresponding to FVIII residues 2303-2332 (epitope for FVIII MoAb, ESH4) inhibited FVIIIa binding to platelets, whereas MoAb ESH8 and a C2 domain peptide corresponding to residues 2248-2285 (epitope for the FVIII MoAb, ESH8) failed to inhibit FVIIIa binding. Thus, a major platelet-binding site resides within residues 2303-2332 in the C2 domain of FVIIIa, and an additional site within residues 2248-2285 increases the stoichiometry and affinity of FVIIIa binding to activated platelets only in the presence of FIXa and FX but does not directly mediate FVIIIa binding to the platelet surface.     

Down-regulation of factor IXa in the factor Xase complex by protein Z-dependent protease inhibitor

Protein Z-dependent protease inhibitor (ZPI) is a serpin inhibitor of coagulation factor (F) Xa dependent on protein Z, Ca2+, and phospholipids. In new studies, ZPI inhibited FIXa in the FXase complex. Since this observation could merely represent inhibition of the FXa product whose activity was measured, inhibition of FIXa was investigated five ways. 1) FXase incubation mixtures with/without ZPI/protein Z were diluted in EDTA; FXa activity was measured after reversal of its inhibition. 2) FXase incubation mixtures were immunoblotted for FXa product. 3) FX activation peptide region was 3H-labeled; release of 3H was used to measure FXase activity. 4) Activity was monitored in a FIXa-based clotting assay. 5) FIXa amidolytic activity was measured. In all cases, FIXa was inhibited by subphysiologic levels of ZPI. Unlike inhibition of FXa, inhibition of FIXa did not strictly require protein Z. Low concentrations of FVIIIa increased the efficiency of ZPI inhibition of FIXa; FVIIIa in molar excess was not protective of FIXa unless FIXa/FVIIIa interacted prior to ZPI exposure. Unusual time courses were observed for inhibition of both FIXa in the FXase complex and FXa in the prothrombinase complex. Activity loss stabilized in <100 s at a level dependent on ZPI concentration, suggesting equilibrium interactions rather than typical covalent serpin-protease interactions. Surface plasmon resonance binding experiments revealed binding and dissociation of ZPI/FIXa with Kd (app) of 9-12 nm, similar to the concentration of ZPI needed for 50% inhibition. ZPI may be an unusual physiologic regulator of both the intrinsic FXase and the prothrombinase complexes.     

Replacing the Factor VIII C1 Domain with a Second C2 Domain Reduces Factor VIII Stability and Affinity for Factor IXa

Factor VIII (FVIII) consists of a heavy chain (A1(a1)A2(a2)B domains) and light chain ((a3)A3C1C2 domains). To gain insights into a role of the FVIII C domains, we eliminated the C1 domain by replacing it with the homologous C2 domain. FVIII stability of the mutant (FVIII_C2C2) as measured by thermal decay at 55 °C of FVIII activity was markedly reduced (∼11-fold), whereas the decay rate of FVIIIa due to A2 subunit dissociation was similar to WT FVIIIa. The binding affinity of FVIII_C2C2 for phospholipid membranes as measured by fluorescence resonance energy transfer was modestly lower (∼2.8-fold) than that for WT FVIII. Among several anti-FVIII antibodies tested (anti-C1 (GMA8011), anti-C2 (ESH4 and ESH8), and anti-A3 (2D2) antibody), only ESH4 inhibited membrane binding of both WT FVIII and FVIII_C2C2. FVIIIa cofactor activity measured in the presence of each of the above antibodies was examined by FXa generation assays. The activity of WT FVIIIa was inhibited by both GMA8011 and ESH4, whereas the activity of FVIII_C2C2 was inhibited by both the anti-C2 antibodies, ESH4 and ESH8. Interestingly, factor IXa (FIXa) binding affinity for WT FVIIIa was significantly reduced in the presence of GMA8011 (∼10-fold), whereas the anti-C2 antibodies reduced FIXa binding affinity of FVIII_C2C2 variant (∼4-fold). Together, the reduced stability plus impaired FIXa interaction of FVIII_C2C2 suggest that the C1 domain resides in close proximity to FIXa in the FXase complex and contributes a critical role to FVIII structure and function.     

Altered interactions between the A1 and A2 subunits of factor VIIIa following cleavage of A1 subunit by factor Xa

Factor VIIIa consists of subunits designated A1, A2, and A3-C1-C2. The limited cofactor activity observed with the isolated A2 subunit is markedly enhanced by the A1 subunit. A truncated A1 (A1(336)) was previously shown to possess similar affinity for A2 and retain approximately 60% of its A2 stimulatory activity. We now identify a second site in A1 at Lys(36) that is cleaved by factor Xa. A1 truncated at both cleavage sites (A1(37-336)) showed little if any affinity for A2 (K(d)>2 microm), whereas factor VIIIa reconstituted with A2 plus A1(37-336)/A3-C1-C2 dimer demonstrated significant cofactor activity ( approximately 30% that of factor VIIIa reconstituted with native A1) in a factor Xa generation assay. These affinity values were consistent with values obtained by fluorescence energy transfer using acrylodan-labeled A2 and fluorescein-labeled A1. In contrast, factor VIIIa reconstituted with A1(37-336) showed little activity in a one-stage clotting assay. This resulted in part from a 5-fold increase in K(m) for factor X when A1 was cleaved at Arg(336). These findings suggest that both A1 termini are necessary for functional interaction of A1 with A2. Furthermore, the C terminus of A1 contributes to the K(m) for factor X binding to factor Xase, and this parameter is critical for activity assessed in plasma-based assays.     

Identification of residues Asn89, Ile90, and Val107 of the factor IXa second epidermal growth factor domain that are essential for the assembly of the factor X-activating complex on activated platelets

Activated platelets promote intrinsic factor X-activating complex assembly by presenting high affinity, saturable binding sites for factor IXa mediated by two disulfide-constrained loop structures (loop 1, Cys88-Cys99; loop 2, Cys95-Cys109) within the second epidermal growth factor (EGF2) domain. To identify amino acids essential for factor X activation complex assembly, recombinant factor IXa point mutants in loop 1 (N89A, I90A, K91A, and R94A) and loop 2 (D104A, N105A, and V107A) were prepared. All seven mutants were similar to the native factor IXa by SDS-PAGE, active site titration, and content of gamma-carboxyglutamic acid residues. Kinetic constants obtained by either titrating factor X or factor VIIIa on SFLLRN-activated platelets or phospholipid vesicles revealed near normal values of Km(app) and Kd(app)FVIIIa for all mutants, indicating normal substrate and cofactor binding. In a factor Xa generation assay in the presence of activated platelets and cofactor factor VIIIa, compared with native factor IXa (Kd(app)FIXa approximately 1.1 nm, Vmax approximately 12 nm min(-1)), N89A displayed an increase of approximately 20-fold in Kd(app)FIXa and a decrease of approximately 20-fold in Vmax; I90A had an increase of approximately 5-fold in Kd(app)FIXa and approximately 10-fold decrease in Vmax; and V107A had an increase of approximately 3-fold in Kd(app)FIXa and approximately 4-fold decrease in Vmax. We conclude that residues Asn89, Ile90, and Val107 within loops 1 and 2 (Cys88-Cys109) of the EGF2 domain of factor IXa are essential for normal interactions with the platelet surface and for the assembly of the factor X-activating complex on activated platelets.     

The A1 and A2 subunits of factor VIIIa synergistically stimulate factor IXa catalytic activity.

Factor VIIIa, the protein cofactor for factor IXa, is comprised of A1, A2, and A3-C1-C2 subunits. Recently, we showed that isolated A2 subunit enhanced the kcat for factor IXa-catalyzed activation of factor X by approximately 100-fold ( approximately 1 min-1), whereas isolated A1 or A3-C1-C2 subunits showed no effect on this rate (Fay, P. J., and Koshibu, K. J. (1998) J. Biol. Chem. 273, 19049-19054). However, A1 subunit increased the A2-dependent stimulation by approximately 10-fold. The Km for factor X in the presence of A2 subunit was unaffected by A1 subunit, whereas the kcat observed in the presence of saturating A1 and A2 subunits ( approximately 15 min-1) represented 5-10% of the value observed for native factor VIIIa (approximately 200 min-1). An anti-A1 subunit antibody that blocks the association of A2 eliminated the A1-dependent contribution to factor IXa activity. Inclusion of both A1 and A2 subunits resulted in greater increases in the fluorescence anisotropy of fluorescein-Phe-Phe-Arg factor IXa than that observed for A2 subunit alone and approached values obtained with factor VIIIa. These results indicate that A1 subunit alters the A2 subunit-dependent modulation of the active site of factor IXa to synergistically increase cofactor activity, yielding an overall increase in kcat of over 1000-fold compared with factor IXa alone.     

Factor VIII A3 domain residues 1954-1961 represent an A1 domain-interactive site

Factor VIIIa consists of subunits designated A1, A2, and A3C1C2. Reassociation of the A1 and A3C1C2 subunits monitored by the factor Xa generation assay and fluorescence resonance energy transfer yielded intersubunit affinity values (K(d)) of 58.0 +/- 12.5 and 58.8 +/- 16.8 nM, respectively. These affinity values were equivalent to that previously determined for factor VIII heavy and light chains [Wakabayashi, H., et al. (2001) Biochemistry 40, 10293-10300], suggesting that the A2 domain makes a minimal contribution to the interchain affinity in factor VIII. Ca(2+) showed no effect on A1/A3C1C2 intersubunit affinity (K(d) = 51.6 +/- 16.6 nM), while Cu(2+) enhanced the A1/A3C1C2 intersubunit affinity approximately 5-fold (K(d) = 12.5 +/- 2.3 nM). A synthetic peptide to A3 domain residues 1954-1961 inhibited association of the A1 and A3C1C2 subunits (K(i) = 65.8 +/- 11.9 microM). Three factor VIII point mutants, His1957Ala, Gly1960Val, and His1961Asp, were stably expressed in BHK cells and purified. All mutants exhibited reduced specific activity (39, 42, and 4%, respectively) compared with that of wild-type factor VIII, and their activity was less stable following heat denaturation analysis (t(1/2) values of 13.3 +/- 0.7, 8.7 +/- 0.3, and 8.1 +/- 0.1 min, respectively) compared with that of the wild type (18.8 +/- 0.8 min). This reduced stability appeared to result from an approximately 2-fold increased dissociation rate for the Gly1960Val and His1961Asp dimers as judged by solid-phase binding assays. We propose that residues 1954-1961 of the A3 domain contribute to interactions with the A1 domain, facilitating their association in factor VIII.     

Characterization of the interaction between the A2 subunit and A1/A3-C1-C2 dimer in human factor VIIIa.

Factor VIIIa is a heterotrimer of the factor VIII heavy chain-derived A1 and A2 subunits plus the factor VIII light chain-derived A3-C1-C2 subunit. While the A1 and A3-C1-C2 subunits can be isolated as a stable dimer, the A2 subunit is weakly associated with the dimer. In the human protein, the association of A2 with dimer is reversible and governed by a pH-dependent dissociation constant. Using the specific activity of factor VIIIa as an indicator of trimer concentration, the Kd (pH 6.0) was determined to be 28 nM whereas at the more physiologic pH (pH 7.4) this value was approximately 260 nM. Results from pH shift experiments confirmed the reversible binding of A2 to dimer as did the capacity for high levels of exogenous A2 subunit to inhibit the spontaneous decay of factor VIIIa activity. A2 subunit associated with the A1 subunit in the A1/A3-C1-C2 dimer based upon the capacity for free A1 subunit to inhibit the reconstitution of factor VIIIa from A2 subunit and dimer. These results indicate that the primary mechanism for the spontaneous decay of human factor VIIIa is the reversible dissociation of A2 subunit from the A1 subunit of the A1/A3-C1-C2 dimer.     

Cofactor activities of factor VIIIa and A2 subunit following cleavage of A1 subunit at Arg336.

Factor VIIIa consists of three subunits designated A1, A2, and A3-C1-C2. The isolated A2 subunit possesses limited cofactor activity in stimulating factor IXa-catalyzed activation of factor X. This activity is markedly enhanced by the A1 subunit (inter-subunit K(d) = 1.8 microm). The C-terminal region of A1 subunit (residues 337-372) is thought to represent an A2-interactive site. This region appears critical to factor VIIIa, because proteolysis at Arg(336) by activated protein C or factor IXa is inactivating. A truncated A1 (A1(336)) showed similar affinity for A2 subunit (K(d) = 0.9 microm) and stimulated its cofactor activity to approximately 50% that observed for native A1. However, A1(336) was unable to reconstitute factor VIIIa activity in the presence of A2 and A3-C1-C2 subunits. Fluorescence anisotropy of fluorescein (Fl)-FFR-factor IXa was differentially altered by factor VIIIa trimers containing either A1 or A1(336). Fluorescence energy transfer demonstrated that, although Fl-A1(336)/A3-C1-C2 bound acrylodan-A2 with similar affinity as the native dimer, an increased inter-fluorophore separation was observed. These results indicate that the C-terminal region of A1 appears necessary to properly orient A2 subunit relative to factor IXa in the cofactor rather than directly stimulate A2 and elucidate the mechanism for cofactor inactivation following cleavage at this site.     

Role of factor VIII C2 domain in factor VIII binding to factor Xa.

Factor VIII (FVIII) is activated by proteolytic cleavages with thrombin and factor Xa (FXa) in the intrinsic blood coagulation pathway. The anti-C2 monoclonal antibody ESH8, which recognizes residues 2248-2285 and does not inhibit FVIII binding to von Willebrand factor or phospholipid, inhibited FVIII activation by FXa in a clotting assay. Furthermore, analysis by SDS-polyacrylamide gel electrophoresis showed that ESH8 inhibited FXa cleavage in the presence or absence of phospholipid. The light chain (LCh) fragments (both 80 and 72 kDa) and the recombinant C2 domain dose-dependently bound to immobilized anhydro-FXa, a catalytically inactive derivative of FXa in which dehydroalanine replaces the active-site serine. The affinity (K(d)) values for the 80- and 72-kDa LCh fragments and the C2 domain were 55, 51, and 560 nM, respectively. The heavy chain of FVIII did not bind to anhydro-FXa. Similarly, competitive assays using overlapping synthetic peptides corresponding to ESH8 epitopes (residues 2248-2285) demonstrated that a peptide designated EP-2 (residues 2253-2270; TSMYVKEFLISSSQDGHQ) inhibited the binding of the C2 domain or the 72-kDa LCh to anhydro-FXa by more than 95 and 84%, respectively. Our results provide the first evidence for a direct role of the C2 domain in the association between FVIII and FXa.     

Mn2+ binding to factor VIII subunits and its effect on cofactor activity

Metal ions, such as Ca2+ and Mn2+, are necessary for the generation of cofactor activity following reconstitution of factor VIII from its isolated light chain (LC) and heavy chain (HC). Titration of EDTA-treated factor VIII with Mn2+ showed saturable binding with high affinity (K(d) = 5.7 +/- 2.1 microM) as detected using a factor Xa generation assay. No significant competition between Ca2+ and Mn2+ for factor VIII binding (K(i) = 4.6 mM) was observed as measured by equilibrium dialysis using 20 microM Ca2+ and 8 microM factor VIII in the presence of 0-1 mM Mn2+. The intersubunit affinity measured by fluorescence energy transfer of an acrylodan-labeled LC (fluorescence donor) and fluorescein-labeled HC (fluorescence acceptor) in the presence of 20 mM Mn2+ (K(d) = 53.0 +/- 17.1 nM) was not significantly different from the affinity value previously obtained in the absence of metal ion (K(d) = 53.8 +/- 14.2 nM). The sensitization of phosphorescence of Tb3+ bound to factor VIII subunits was utilized to detect Mn2+ binding to the subunits. Mn2+ inhibited the phosphorescence of Tb3+ bound to HC and LC, as well as the HC-derived A1 and A2 subunits with a relatively wide range of estimated inhibition constant values (K(i) values = 169-1147 microM), whereas Ca2+ showed no effect on Tb3+ phosphorescence. These results suggest that factor VIII cofactor activity can be generated by Mn2+ binding to site(s) on factor VIII that are different from the high-affinity Ca2+ binding site. However, like Ca2+, Mn2+ did not alter the affinity for HC and LC association. Thus, Mn2+appears to generate factor VIII cofactor activity by a similar mechanism as observed for Ca2+following its association at nonidentical sites on the protein.     

Localization of a pH-dependent, A2 subunit-interactive surface within the factor VIIIa A1 subunit

Factor VIIIa can be reconstituted from A2 subunit and A1/A3-C1-C2 dimer in a reaction that is facilitated by slightly acidic pH. We recently demonstrated that a truncated A1 (A1(37-336)) possessed markedly reduced affinity for A2 compared with intact A1, but retained 30% of native factor VIIIa activity in the presence of A3-C1-C2. We now identify A1-interactive regions for A2 using A1 fragments derived from a limited tryptic digest. Unfractionated trypsin-cleaved A1 inhibited reconstituted factor VIIIa activity. Two fragments, designated A1(37-121) and A1(221-336), markedly inhibited factor VIIIa reconstitution with either native A1 (K(i)=340 and 194 nM, respectively) or with A1(37-336) (K(i)=69 and 116 nM, respectively) at pH 6.0. A third fragment designated A1(122-206) did not possess inhibitory activity. At pH 7.2, the A1(221-336) partially inhibited reconstitution, whereas the A1(37-121) possessed little if any inhibitory activity. Both fragments inhibited factor VIIIa reconstitution as judged by fluorescence energy transfer using acrylodan-labeled A2 and fluorescein-labeled A1 forms at pH 6.0. Furthermore, covalent cross-linking between A2 and A1(37-121) but not A1(221-336) was observed following reaction with a zero-length cross-linker. These findings demonstrate the presence of an extended, pH-dependent A2-interactive surface within regions 37-121 and 221-336 of A1. This interactive surface appears conformationally labile in the truncated A1 as judged by its apparent stabilization following association with A3-C1-C2.     

Mechanisms by which soluble endothelial cell protein C receptor modulates protein C and activated protein C function

The endothelial cell protein C receptor (EPCR) functions as an important regulator of the protein C anticoagulant pathway by binding protein C and enhancing activation by the thrombin-thrombomodulin complex. EPCR binds to both protein C and activated protein C (APC) with high affinity. A soluble form of EPCR (sEPCR) circulates in plasma and inhibits APC anticoagulant activity. In this study, we investigate the mechanisms by which sEPCR modulates APC function. Soluble EPCR inhibited the inactivation of factor Va by APC only in the presence of phospholipid vesicles. By using flow cytometric analysis in the presence of 3 mM CaCl(2) and 0. 6 mM MgCl(2), sEPCR inhibited the binding of protein C and APC to phospholipid vesicles (K(i) = 40 +/- 7 and 33 +/- 4 nM, respectively). Without MgCl(2), the K(i) values increased approximately 4-fold. Double label flow cytometric analysis using fluorescein-APC and Texas Red-sEPCR indicated that the APC.sEPCR complex does not interact with phospholipid vesicles. By using surface plasmon resonance, we found that sEPCR also inhibited binding of protein C to phospholipid in a dose-dependent fashion (K(i) = 32 nM). To explore the possibility that sEPCR evokes structural changes in APC, fluorescence spectroscopy studies were performed to monitor sEPCR/Fl-APC interactions. sEPCR binds saturably to Fl-APC (K(d) = 27 +/- 13 nM) with a maximum decrease in Fl-APC fluorescence of 10.8 +/- 0.6%. sEPCR also stimulated the amidolytic activity of APC toward synthetic substrates. We conclude that sEPCR binding to APC blocks phospholipid interaction and alters the active site of APC.