Crystal structure of human factor VIII: implications for the formation of the factor IXa-factor VIIIa complex

Factor VIII is a procofactor that plays a critical role in blood coagulation, and is missing or defective in hemophilia A. We determined the X-ray crystal structure of B domain-deleted human factor VIII. This protein is composed of five globular domains and contains one Ca(2+) and two Cu(2+) ions. The three homologous A domains form a triangular heterotrimer where the A1 and A3 domains serve as the base and interact with the C2 and C1 domains, respectively. The structurally homologous C1 and C2 domains reveal membrane binding features. Based on biochemical studies, a model of the factor IXa-factor VIIIa complex was constructed by in silico docking. Factor IXa wraps across the side of factor VIII, and an extended interface spans the factor VIII heavy and light chains. This model provides insight into the activation of factor VIII and the interaction of factor VIIIa with factor IXa on the membrane surface.     

Activated protein C-catalyzed inactivation of human factor VIII and factor VIIIa. Identification of cleavage sites and correlation of proteolysis with cofactor activity

Human factor VIII and factor VIIIa were proteolytically inactivated by activated protein C. Cleavages occurred within the heavy chain (contiguous A1-A2-B domains) of factor VIII and in the heavy chain-derived A1 and A2 subunits of factor VIIIa, whereas no proteolysis was observed in the light chain or light chain-derived A3-C1-C2 subunit. Reactivity to an anti-A2 domain monoclonal antibody and NH2-terminal sequence analysis of three terminal digest fragments from factor VIII allowed ordering of fragments and identification of cleavage sites. Fragment A1 was derived from the NH2 terminus and resulted from cleavage at Arg336-Met337. The A2 domain was bisected following cleavage at Arg562-Gly563 and yielded fragments designated A2N and A2C. A third cleavage site is proposed at the A2-B junction (Arg740-Ser741) since fragment A2C was of equivalent size when derived either from factor VIII or factor VIIIa. The site at Arg562 was preferentially cleaved first in factor VIII(alpha) compared with the site at Arg336, and it was this initial cleavage that most closely correlated with the loss of cofactor activity. Factor VIIIa was inactivated 5-fold faster than factor VIII, possibly as a result of increased protease utilization of the site at Arg562 when the A2 subunit is not contiguous with the A1 domain. When initial cleavage occurred at Arg336, it appeared to preclude subsequent cleavage at Arg562, possibly by promoting dissociation of the A2 domain (subunit) from the A1/light chain dimer. This conclusion was supported by the failure of protease treated A1/A3-C1-C2 dimer to bind A2 subunit and gel filtration analysis that showed dissociation of the A2 domain-derived fragments, A2N and A2C, from the A1 fragment/light chain dimer. These results suggest a mechanism for activated protein C-catalyzed inactivation of factor VIII(alpha) involving both covalent alteration and fragment dissociation.     

Human inhibitor antibodies specific for the factor VIII A2 domain disrupt the interaction between the subunit and factor IXa.

Factor VIIIa, a heterotrimer of the A1, A2, and A3-C1-C2 subunits, increases the catalytic efficiency for factor IXa-catalyzed activation of factor X. A significant fraction of naturally occurring, anti-factor VIII inhibitor antibodies reacts with the A2 domain. Utilizing the capacity for isolated A2 subunit to stimulate factor IXa activity, we show that a panel of these inhibitors block this activity. Inhibition of activity parallels the antibody potency as measured in the Bethesda assay. These antibodies also block the A2-dependent increases in fluorescence anisotropy of fluorescein-Phe-Phe-Arg factor IXa. Similar to the IgG fractions, a peptide representing the sequence of the inhibitor epitope (A2 residues 484-509) blocked the A2-dependent stimulation of factor IXa. These results indicate that antibodies possessing this specificity directly inhibit the interaction of A2 subunit with factor IXa, thus abrogating the contribution of this subunit to cofactor activity. Furthermore, these results also suggest that factor VIII residues 484-509 contribute to a factor IXa-interactive site.     

Thrombin-activated and factor Xa-activated human factor VIII: differences in cofactor activity and decay rate.

The decay of human coagulation factor VIIIa has been studied by kinetic methods that ensure no interference through proteolytic feedback. The rate of decay of factor VIIIa activity was found to vary with the activator used to activate factor VIII. Thrombin-activated factor VIII-von Willebrand factor complex (fVIII-vWf) decayed at a rate of 0.31 min-1, whereas factor Xa-activated fVIII-vWf decayed at 0.11 min-1 under the same conditions. Factor VIII free of von Willebrand factor (factor VIII: C), although decaying at a generally slower rate after activation, still showed a dependence of decay rate on activator: thrombin-activated factor VIII:C decaying at a rate of 0.06 min-1, and factor Xa-activated factor VIII: C at 0.01 min-1. Readdition of von Willebrand factor (18 micrograms/ml) to factor VIII:C did not alter the observed activity or decay rate. The decay of the two species of factor VIIIa was studied, using the fVIIIa-vWf complex, in the presence of varying levels of factor IXa. Plots of reciprocal decay rates vs factor IXa concentration were linear, and nearly parallel for the two factor VIIIa species, with a mean slope of 0.56 min.nM-1. In addition to these studies, we have confirmed previous studies showing that the two forms of factor VIIIa differ in cofactor activity, but they do so in the same ratio as in their decay rates. We suggest that this difference and that observed in decay rate have a common cause, and incorporate this into a potential kinetic model of factor VIII activation and decay.     

Role of P1 residues Arg336 and Arg562 in the activated-Protein-C-catalysed inactivation of Factor VIIIa

APC (activated Protein C) inactivates human Factor VIIIa following cleavage at residues Arg336 and Arg562 within the A1 and A2 subunits respectively. The role of the P1 arginine in APC-catalysed inactivation of Factor VIIIa was examined by employing recombinant Factor VIIIa molecules where residues 336 and 562 were replaced with alanine and/or glutamine. Stably expressed Factor VIII proteins were activated by thrombin and resultant Factor VIIIa was reacted at high concentration with APC to minimize cofactor inactivation due to A2 subunit dissociation. APC cleaved wild-type Factor VIIIa at the A1 site with a rate approximately 25-fold greater than that for the A2 site. A1 mutants R336A and R336Q were inactivated approximately 9-fold slower than wild-type Factor VIIIa, whereas the A2 mutant R562A was inactivated approximately 2-fold slower. No cleavage at the mutated sites was observed. Taken together, these results suggested that cleavage at the A1 site was the dominant mechanism for Factor VIIIa inactivation catalysed by the proteinase. On the basis of cleavage at Arg336, a K(m) value for wild-type Factor VIIIa of 102 nM was determined, and this value was significantly greater than K(i) values (approximately 9-18 nM) obtained for an R336Q/R562Q Factor VIIIa. Furthermore, evaluation of a series of cluster mutants in the C-terminal region of the A1 subunit revealed a role for acidic residues in segment 341-345 in the APC-catalysed proteolysis of Arg336. Thus, while P1 residues contribute to catalytic efficiency, residues removed from these sites make a primary contribution to the overall binding of APC to Factor VIIIa.     

Mechanisms of interactions of factor X and factor Xa with the acidic region in the factor VIII A1 domain

The 337-372 sequence of the factor VIIIa A1 subunit contains interactive sites for both zymogen factor X and the active enzyme, factor Xa. Solid phase binding studies indicated that factor Xa possessed a >20-fold higher affinity for the isolated A1 subunit of factor VIIIa compared with factor X. Heparin completely inhibited zero-length cross-linking of the 337-372 peptide to factor Xa but not to factor X. In the presence of calcium, factor Xa showed greater affinity for heparin than factor X. Studies using factor Xa mutants in which heparin-binding exosite residues were individually replaced by Ala showed that the R240A mutant was defective in recognition of the Lys36 cleavage site, generating the A137-372 intermediate with approximately 20% the catalytic efficiency of wild type. This defect likely resulted from an approximately 4-fold increase in Km for the A1 substrate because kcat values for the wild type and mutant were equivalent. Cleavage of the A1-A2 domain junction by factor Xa R240A was not blocked by the 337-372 peptide. Studies using mutant factor VIII where clustered acidic residues in the 337-372 segment were replaced by Ala showed that a factor VIIIa D361A/D362A/D363A mutant possessed a approximately 1.6-fold increase in Km for factor X compared with wild type. However, similar Km values were observed for recombinant factor X and R240A substrates. These results indicate that the binding regions of factor X and factor Xa for A1 domain overlap and that both utilize acidic residues 361-363. Furthermore, factor Xa but not factor X interacts with high affinity at this site via residues contained within the heparin-binding exosite of the proteinase.     

Identification of a factor Xa-interactive site within residues 337-372 of the factor VIII heavy chain

We recently demonstrated that the residues 337-372, comprising the acidic C-terminal region in A1 subunit, interact with factor Xa during the proteolytic inactivation of factor VIIIa (Nogami, K., Wakabayashi, H., and Fay, P. J. (2003) J. Biol. Chem. 278, 16502-16509). We now show this sequence is important for factor Xa-catalyzed activation of factor VIII. Peptide 337-372 markedly inhibited cofactor activation, consistent with a delay in the rate of cleavage at the A1-A2 junction. Studies using the isolated factor VIII heavy chain indicated that the peptide completely blocked cleavage at the A1-A2 junction (IC50 = 11 microm) and partially blocked cleavage at the A2-B junction (IC50 = 100 microm). Covalent cross-linking was observed between the 337-372 peptide and factor Xa following reaction with 1-ethyl-3-(3-dimethylaminopropyl)-carbodiimide, and the peptide quenched the fluorescence of dansyl-Glu-Gly-Arg active site-modified factor Xa, suggesting that residues 337-372 directly interact with factor Xa. Studies using a monoclonal antibody recognizing residues 351-365 as well as the peptide to this sequence further restricted the interactive region. Mutant factor VIII molecules in which clustered acidic residues in the 337-372 segment were converted to alanine were evaluated for activation by factor Xa. Of the mutants tested, only factor Xa-catalyzed activation of the D361A/D362A/D363A mutant was inhibited with peak activity of approximately 50% and an activation rate constant of approximately 30% of the wild type values. These results indicate that the 337-372 acidic region separating A1 and A2 domains and, in particular, a cluster of acidic residues at position 361-363 contribute to a unique factor Xa-interactive site within the factor VIII heavy chain that promotes factor Xa docking during cofactor activation.     

Factor VIII A1 domain residues 97-105 represent a light chain-interactive site

Results from a recent study on subunit association in factor VIIIa indicated that the A1 and A3C1C2 domains contribute approximately 90% of the interchain binding energy in factor VIII and that A3 domain residues 1954-1961 participate in the interaction with A1 domain (Ansong, C., and Fay, P. J. (2005) Biochemistry 44, 8850-8857). Enhanced trypsin-accessibility at four sites within residues 89-142 in free A1 compared with that of A3C1C2-bound A1, as determined by mass spectrometry, suggested that residues within this region are interactive with the A3C1C2 domains. A synthetic peptide to A1 domain residues 97-105, predicted to be A3 domain-interactive from molecular modeling, inhibited the formation of a functional A1/A3C1C2 dimer (apparent K(i) = 0.64 +/- 0.21 microM) and reduced the efficiency of energy transfer between a fluorescein-labeled A1 subunit and an acrylodan-labeled A3C1C2 subunit. B-domainless factor VIII point mutants, His99Ala, Val101Ala, and Gly102Ser, exhibited reduced specific activity (32%, 51%, and 45%, respectively) compared with that of factor VIII wild type. Furthermore, the activity of factor VIII His99Ala was less stable (t(1/2) = 2.3 +/- 0.2 min) compared with that of factor VIII wild type (t(1/)(2) = 6.2 +/- 0.7 min) following heat denaturation analysis. This reduced stability appeared to result from an approximately 40% increase in the dissociation rate for the mutant factor VIII heterodimer as judged by solid-phase binding assays. These results indicate that residues within segment 97-105 of the A1 domain interact with residues within the A3C1C2 domains of the light chain and contribute to the interface in the factor VIII heterodimer.     

Detailed mechanisms of the inactivation of factor VIIIa by activated protein C in the presence of its cofactors, protein S and factor V

Factor VIIIa is inactivated by a combination of two mechanisms. Activation of factor VIII by thrombin results in a heterotrimeric factor VIIIa that spontaneously inactivates due to dissociation of the A2 subunit. Additionally, factor VIIIa is cleaved by the anticoagulant serine protease, activated protein C, at two cleavage sites, Arg(336) in the A1 subunit and Arg(562) in the A2 subunit. We previously characterized an engineered variant of factor VIII which contains a disulfide bond between the A2 and the A3 subunits that prevents the spontaneous dissociation of the A2 subunit following thrombin activation. Thus, in the absence of activated protein C, this variant has stable activity following activation by thrombin. To isolate the effects of the individual activated protein C cleavage sites on factor VIIIa, we engineered mutations of the activated protein C cleavage sites into the disulfide bond-cross-linked factor VIII variant. Arg(336) cleavage is 6-fold faster than Arg(562) cleavage, and the Arg(336) cleavage does not fully inactivate factor VIIIa when A2 subunit dissociation is blocked. Protein S enhances both cleavage rates but enhances Arg(562) cleavage more than Arg(336) cleavage. Factor V also enhances both cleavage rates when protein S is present. Factor V enhances Arg(562) cleavage more than Arg(336) cleavage as well. As a result, in the presence of both activated protein C cofactors, Arg(336) cleavage is only twice as fast as Arg(562) cleavage. Therefore, both cleavages contribute significantly to factor VIIIa inactivation.     

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.     

Structural investigation of the A domains of human blood coagulation factor V by molecular modeling.

Factor V (FV) is a large (2,196 amino acids) nonenzymatic cofactor in the coagulation cascade with a domain organization (A1-A2-B-A3-C1-C2) similar to the one of factor VIII (FVIII). FV is activated to factor Va (FVa) by thrombin, which cleaves away the B domain leaving a heterodimeric structure composed of a heavy chain (A1-A2) and a light chain (A3-C1-C2). Activated protein C (APC), together with its cofactor protein S (PS), inhibits the coagulation cascade via limited proteolysis of FVa and FVIIIa (APC cleaves FVa at residues R306, R506, and R679). The A domains of FV and FVIII share important sequence identity with the plasma copper-binding protein ceruloplasmin (CP). The X-ray structure of CP and theoretical models for FVIII have been recently reported. This information allowed us to build a theoretical model (994 residues) for the A domains of human FV/FVa (residues 1-656 and 1546-1883). Structural analysis of the FV model indicates that: (a) the three A domains are arranged in a triangular fashion as in the case of CP and the organization of these domains should remain essentially the same before and after activation; (b) a Type II copper ion is located at the A1-A3 interface; (c) residues R306 and R506 (cleavage sites for APC) are both solvent exposed; (d) residues 1667-1765 within the A3 domain, expected to interact with the membrane, are essentially buried; (e) APC does not bind to FVa residues 1865-1874. Several other features of factor V/Va, like the R506Q and A221V mutations; factor Xa (FXa) and human neutrophil elastase (HNE) cleavages; protein S, prothrombin and FXa binding, are also investigated.     

Human factor VIIIa subunit structure. Reconstruction of factor VIIIa from the isolated A1/A3-C1-C2 dimer and A2 subunit

Heterodimeric human factor VIII was proteolytically activated by catalytic levels of thrombin to yield the (labile) active cofactor factor VIIIa possessing an initial specific activity of approximately 80 units/microgram. Activation paralleled the generation of fragments A1 and A2 derived from the heavy chain and A3-C1-C2 derived from the light chain. Chromatography of factor VIIIa, on Mono-S buffered at pH 6.0 resulted in separation of the bulk of the A2 fragment from a fraction composed predominantly of A1/A3-C1-C2 dimer plus low levels of A2 fragment. Only the latter fraction contained clotting activity (approximately 20 units/microgram) which was stable and represented a less than 10% yield when compared with the peak activity of unfractionated factor VIIIa. Further depletion of A2 fragment from Mono-S-purified factor VIIIA, achieved using an immobilized monoclonal antibody to the A2 domain, yielded a relatively inactive A1/A3-C1-C2 dimer (less than 0.4 unit/microgram). Factor VIIIa (greater than 40 units/microgram) was reconstituted from the A1/A3-C1-C2 dimer plus the A2 fragment in a reaction that was Me(2+)-independent and inhibited by moderate ionic strength. Reassociation of A2 required the A1 subunit in that the A2 subunit associated weakly if at all to A3-C1-C2 in the absence of A1. These results indicated that human factor VIIIa is a trimer represented by the subunits A1/A2/A3-C1-C2 and that the A2 subunit is required for expression of factor VIIIa activity.     

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.     

Increasing hydrophobicity or disulfide bridging at the factor VIII A1 and C2 domain interface enhances procofactor stability

Factor VIII (FVIII) consists of a heavy (A1A2B domains) and light chain (A3C1C2 domains), whereas the contiguous A1A2 domains are separate subunits in the cofactor, FVIIIa. FVIII x-ray structures show close contacts between A1 and C2 domains. To explore the role of this region in FVIII(a) stability, we generated a variant containing a disulfide bond between A1 and C2 domains by mutating Arg-121 and Leu-2302 to Cys (R121C/L2302C) and a second variant with a bulkier hydrophobic group (A108I) to better occupy a cavity between A1 and C2 domains. Disulfide bonding in the R121C/L2302C variant was >90% efficient as judged by Western blots. Binding affinity between the A108I A1 and A3C1C2 subunits was increased ～3.7-fold in the variant as compared with WT as judged by changes in fluorescence of acrylodan-labeled A1 subunits. FVIII thermal and chemical stability were monitored following rates of loss of FVIII activity at 57 °C or in guanidinium by factor Xa generation assays. The rate of decay of FVIIIa activity was monitored at 23 °C following activation by thrombin. Both R121C/L2302C and A108I variants showed up to ～4-fold increases in thermal stability but minimal improvements in chemical stability. The purified A1 subunit of A108I reconstituted with the A3C1C2 subunit showed an ～4.6-fold increase in thermal stability, whereas reconstitution of the variant A1 with a truncated A3C1 subunit showed similar stability values as compared with WT A1. Together, these results suggest that altering contacts at this A1-C2 junction by covalent modification or increasing hydrophobicity increases inter-chain affinity and functionally enhances FVIII stability.     

Cleavage of factor VIII heavy chain is required for the functional interaction of a2 subunit with factor IXA

Factor VIII circulates as a noncovalent heterodimer consisting of a heavy chain (HC, contiguous A1-A2-B domains) and light chain (LC). Cleavage of HC at the A1-A2 and A2-B junctions generates the A1 and A2 subunits of factor VIIIa. Although the isolated A2 subunit stimulates factor IXa-catalyzed generation of factor Xa by approximately 100-fold, the isolated HC, free from the LC, showed no effect in this assay. However, extended reaction of HC with factors IXa and X resulted in an increase in factor IXa activity because of conversion of the HC to A1 and A2 subunits by factor Xa. HC cleavage by thrombin or factor Xa yielded similar products, although factor Xa cleaved at a rate of approximately 1% observed for thrombin. HC showed little inhibition of the A2 subunit-dependent stimulation of factor IXa activity, suggesting that factor IXa-interactive sites are masked in the A2 domain of HC. Furthermore, HC showed no effect on the fluorescence anisotropy of fluorescein-Phe-Phe-Arg-factor IXa in the presence of factor X, whereas thrombin-cleaved HC yielded a marked increase in this parameter. These results indicate that HC cleavage by either thrombin or factor Xa is essential to expose the factor IXa-interactive site(s) in the A2 subunit required to modulate protease activity.     

A Glu113Ala mutation within a factor VIII Ca2+-binding site enhances cofactor interactions in factor Xase

We recently identified an acidic-rich segment in the A1 domain of factor VIII (residues 110-126) that functions in the coordination of Ca(2+), an ion necessary for cofactor activity [Wakabayashi et al. (2004) J. Biol. Chem. 279, 12677-12684]. Mutagenesis studies showed that replacement of residue Glu113 with Ala (E113A) yielded a factor VIII point mutant possessing increased specific activity as determined by a one-stage clotting assay. Mutagenesis at this site suggested that substitution with relatively small, nonpolar residues was well tolerated, whereas replacement with a number of polar or charged residues appeared detrimental to activity. Ala substitution resulted in the greatest enhancement, yielding an approximately 2-fold increased specific activity. Time course experiments following reaction with thrombin revealed similar rates of activation and inactivation of E113A as observed for the wild type. Results from factor Xa generation assays showed minimal differences in kinetic parameters and factor IXa affinity for E113A and wild-type factor VIIIa when run in the presence of synthetic phospholipid vesicles, whereas factor VIIIa E113A displayed an approximately 4-fold greater affinity for factor IXa compared with factor VIIIa wild type in reactions run on the platelet membrane surface. This latter effect may be attributed, in part, to a 2-fold increased affinity of factor VIIIa E113A for the platelet membrane. Considering that low levels of factors VIIIa and IXa are generated during clotting in plasma, the increased cofactor specific activity observed for E113A factor VIII may result from its enhanced affinity for factor IXa on the physiological membrane.     

Cleavage at Arg-1689 Influences Heavy Chain Cleavages during Thrombin-catalyzed Activation of Factor VIII

The procofactor, factor VIII, is activated by thrombin or factor Xa-catalyzed cleavage at three P1 residues: Arg-372, Arg-740, and Arg-1689. The catalytic efficiency for thrombin cleavage at Arg-740 is greater than at either Arg-1689 or Arg-372 and influences reaction rates at these sites. Because cleavage at Arg-372 appears rate-limiting and dependent upon initial cleavage at Arg-740, we investigated whether cleavage at Arg-1689 influences catalysis at this step. Recombinant B-domainless factor VIII mutants, R1689H and R1689Q were prepared and stably expressed to slow and eliminate cleavage, respectively. Specific activity values for the His and Gln mutations were ∼50 and ∼10%, respectively, that of wild type. Thrombin activation of the R1689H variant showed an ∼340-fold reduction in the rate of Arg-1689 cleavage, whereas the R1689Q variant was resistant to thrombin cleavage at this site. Examination of heavy chain cleavages showed ∼4- and 11-fold reductions in A2 subunit generation and ∼3- and 7-fold reductions in A1 subunit generation for the R1689H and R1689Q mutants, respectively. These results suggest a linkage between light chain cleavage and cleavages in heavy chain. Results obtained evaluating proteolysis of the factor VIII mutants by factor Xa revealed modest rate reductions (<5-fold) in generating A2 and A1 subunits and in cleaving light chain at Arg-1721 from either variant, suggesting little dependence upon prior cleavage at residue 1689 as compared with thrombin. Overall, these results are consistent with a competition between heavy and light chains for thrombin exosite binding and subsequent proteolysis with binding of the former chain preferred.Factor VIII, a plasma protein missing or defective in individuals with hemophilia A, is synthesized as an ∼300-kDa single chain polypeptide corresponding to 2332 amino acids. Within the protein are six domains based on internal homologies and ordered as NH₂-A1-A2-B-A3-C1-C2-COOH (1, 2). Bordering the A domains are short segments containing high concentrations of acidic residues that follow the A1 and A2 domains and precede the A3 domain and are designated a1 (residues 337–372), a2 (residues 711–740), and a3 (1649–1689). Factor VIII is processed by cleavage at the B-A3 junction to generate a divalent metal ion-dependent heterodimeric protein composed of a heavy chain (A1-a1-A2-a2-B domains) and a light chain (a3-A3-C1-C2 domains) (3).The activated form of factor VIII, factor VIIIa, functions as a cofactor for factor IXa, increasing its catalytic efficiency by several orders of magnitude in the phospholipid- and Ca²⁺-dependent conversion of factor X to factor Xa (4). The factor VIII procofactor is converted to factor VIIIa through limited proteolysis catalyzed by thrombin or factor Xa (5, 6). Thrombin is believed to act as the physiological activator of factor VIII, as association of factor VIII with von Willebrand factor impairs the capacity for the membrane-dependent factor Xa to efficiently activate the procofactor (5, 7). Activation of factor VIII occurs through proteolysis by either protease via cleavage of three P1 residues at Arg-740 (A2-B domain junction), Arg-372 (A1-A2 domain junction), and Arg-1689 (a3-A3 junction) (5). After factor VIII activation, there is a weak electrostatic interaction between the A1 and A2 domains of factor VIIIa (8, 9) and spontaneous inactivation of the cofactor occurs through A2 subunit dissociation from the A1/A3-C1-C2 dimer, consequently dampening factor Xase (3).Thrombin cleavage of factor VIII appears to be an ordered pathway, with relative rates at Arg-740 > Arg-1689 > Arg-372 and the initial proteolysis at Arg-740 facilitating proteolysis at Arg-372 as well as Arg-1689 (10). This latter observation was based upon results showing that mutations at Arg-740, impairing this cleavage, significantly reduced cleavage rates at the two other P1 sites. Thrombin-catalyzed activation of factor VIII is dependent upon interactions involving the anion binding exosites of the proteinase (11, 12). Exosite binding is believed to determine substrate affinity, whereas subsequent active site docking primarily affects V_max (13). Furthermore, the complex interactions involving multiple cleavages within a single substrate may utilize a ratcheting mechanism (14) where presentation of the scissile bond is facilitated by a prior cleavage event.Cleavage at Arg-372 is a critical step in thrombin activation of factor VIII as it exposes a cryptic functional factor IXa-interactive site in the A2 domain (15), whereas cleavage at Arg-1689 liberates factor VIII from von Willebrand factor (16) and contributes to factor VIIIa specific activity (17, 18). Although cleavage at Arg-740 represents a fast step relative to cleavages at other P1 residues in the activation of factor VIII (19), the influence of Arg-1689 cleavage on cleavages in the heavy chain remains unknown. In the present study cleavage at Arg-1689 is examined using recombinant factor VIII variants possessing single point mutations of R1689Q and R1689H. Results indicating reduced rates of A1 and A2 subunit generation, which are dependent upon the residue at position 1689, suggest that cleavage at Arg-1689 affects rates of proteolysis at Arg-740 and Arg-372. These observations are consistent with a mechanism whereby heavy chain and light chain compete for a binding thrombin exosite(s), with heavy chain preferred over light chain. In this competition mechanism, cleavage at Arg-740 is favored over Arg-1689. Subsequent cleavage at Arg-372 in heavy chain may involve a ratcheting mechanism after initial cleavage at Arg-740. On the other hand, the mechanism for factor Xa-catalyzed activation of factor VIII appears to be less dependent on cleavage at the Arg-1689 site as compared with thrombin.     

Coordinate binding studies of the substrate (factor X) with the cofactor (factor VIII) in the assembly of the factor X activating complex on the activated platelet surface

The assembly of the factor X activating complex on the platelet surface requires the occupancy of three receptors: (1) enzyme factor IXa, (2) cofactor factor VIII(a), and (3) substrate factor X. To further evaluate this three-receptor model, simultaneous binding isotherms of (125)I-factor X and (131)I-factor VIII(a) to activated platelets were determined as a function of time and also as a function of the concentrations of both ligands in the presence of active site-inhibited factor IXa (45 nM) and 5 mM CaCl(2). In the presence of active site-inhibited factor IXa and factor VIIIa there are two independent factor X binding sites: (1) low affinity, high capacity (approximately 9000 sites/platelet; K(d) approximately 380 nM) and (2) low capacity, high affinity (1700 sites/platelet; K(d) approximately 30 nM). A single specific and selective factor X binding site was expressed (1200 sites/platelet; K(d) approximately 9 nM) when the shared factor X/factor II site was blocked by excess factor II (4 microM). In the presence of active site-inhibited factor IXa (4 nM) and factor II (4 microM), factor X binds to 3-fold more platelet sites than procofactor VIII with relatively low affinity (K(d) approximately 250 nM). The activation of procofactor VIII to factor VIIIa increases the affinity of binding to platelets of both factor VIIIa ( approximately 4-fold to K(d) approximately 0.8-1.5 nM) and factor X ( approximately 25-50-fold to K(d) approximately 5-9 nM). In the presence of excess zymogen factor IX, which blocks the shared factor IX/factor IXa binding site, the substrate, factor X, and the active cofactor, factor VIIIa, form a 1:1 stoichiometric complex. These coordinate binding studies support the conclusion that factor X initially binds to a high-capacity, low-affinity platelet binding site shared with prothrombin, which then presents factor X to a specific high-affinity site consisting of factor VIIIa bound to a high-affinity, low-capacity receptor on activated platelets.     

Factor IXa enhances reconstitution of factor VIIIa from isolated A2 subunit and A1/A3-C1-C2 dimer.

Heterotrimeric factor VIIIa was reconstituted from isolated A2 subunit and A1/A3-C1-C2 dimer of thrombin-activated human factor VIII in a reaction that was sensitive to pH. Maximal levels of reconstituted factor VIIIa at pH 6.0 were as much as 20-fold greater than were values observed at pH 7.5. The presence of factor IXa and phospholipid resulted in a marked increase in factor VIIIa reconstituted at physiologic pH. However, the resultant factor VIIIa was unstable due to slow proteolysis of the A1 subunit. Factor IXa modified by the active site-specific reagent dansyl-glutamyl-glycyl-arginyl-chloromethyl ketone (DEGR-IXa) increased the level of factor VIIIa reconstituted from subunits to a similar extent as was observed for unmodified factor IXa and yielded stable factor VIIIa. This enhancement was saturated above a 1:1 molar ratio of DEGR-IXa to factor VIIIa subunits and could be blocked by an anti-factor IX antibody, suggesting that the DEGR-IXa-dependent increase in factor VIIIa reconstitution correlated with assembly of the factor X-ase complex. At a saturating amount of DEGR-IXa, the level of factor VIIIa reconstitution at pH 7.5 approached values obtained at pH 6.0. Fluorescence polarization measurements indicated that factor VIIIa altered binding of DEGR-IXa to phospholipid. However, neither the A2 subunit nor the A1/A3-C1-C2 dimer alone produced this effect. This result suggested that both A2 and A1/A3-C1-C2 were necessary for association of the cofactor with factor IXa. These results suggest a model in which assembly of the intrinsic factor X-ase complex stabilizes factor VIIIa through inhibition of subunit dissociation.     

The connecting segment between both epidermal growth factor-like domains in blood coagulation factor IX contributes to stimulation by factor VIIIa and its isolated A2 domain

The light chain of activated factor IX comprises multiple interactions between both epidermal growth factor-like domains that contribute to enzymatic activity and binding of factor IXa to its cofactor factor VIIIa. To investigate the association between factor IXa-specific properties and surface-exposed structure elements, chimeras were constructed in which the interconnection between the modules Leu(84)-Thr(87) and the factor IX-specific loop Asn(89)-Lys(91) were exchanged for corresponding regions of factor X and factor VII. In absence of factor VIIIa, all chimeras displayed normal enzymatic activity. In the presence of factor VIIIa, replacement of loop Asn(89)-Lys(91) resulted in a minor reduction in factor IXa activity. However, chimeras with substitutions or insertions in the spacer between the epidermal growth factor-like domains showed a major defect in response to factor VIIIa. Of these chimeras, some displayed a normal response to isolated factor VIII A2 domain as a cofactor in factor X activation. Surprisingly, chimeras containing elongated inter-domain spacers from factor X or VII displayed reduced response to both complete factor VIIIa and the isolated A2 domain. Moreover, these chimeras still displayed effective association with immobilized A2 domain as assessed by surface plasmon resonance. We conclude that both sequence and length of the junction Leu(84)-Thr(87) between both epidermal growth factor-like domains contribute to the enhancement of factor IXa enzymatic activity that occurs upon assembly with factor VIIIa.