Human factor VIII: purification from commercial factor VIII concentrate, characterization, identification and radiolabeling

Human factor VIII was purified from commercial factor VIII concentrate with a 12% yield. The specific coagulant activity of purified factor VIII was 8,000 units/mg. In the presence of SDS the purified factor VIII consisted of a variety of polypeptides on polyacrylamide gels, ranging between Mr 80,000 and Mr 208,000. In the absence of SDS the purified factor VIII showed an apparent molecular weight of 270,000 upon Sephadex G200 gel-filtration. The purified factor VIII could be activated by thrombin, which resulted in the disappearance of Mr 108,000-208,000 polypeptides in favor of an Mr 92,000 polypeptide. Treatment with factor Xa also activated factor VIII, whereas treatment with activated protein C resulted in the inactivation of coagulant activity. Coagulant-active 125I-factor VIII was prepared using a lactoperoxidase radioiodination procedure. This 125I-factor had the same characteristics as unlabeled factor VIII. All polypeptides could be precipitated with monoclonal antibodies directed against factor VIII. With 125I-factor VIII a pIapp of 5.7 was found in the presence of urea.     

The size of human factor VIII heterodimers and the effects produced by thrombin

The heterodimeric structure of factor VIII was demonstrated by two approaches. First, the native molecular weights of several partially purified fractions of factor VIII were determined by measurement of Stokes radii and sedimentation coefficients to be approx. 237 500, 201 000 and 141 000. These measured molecular weights correlated with those derived from polypeptide chain composition, in which each molecule would consist of a doublet polypeptide of Mr 83 000/81 000 plus one predominant high-Mr polypeptide of either 146 000, 120 000 or 93 000. In addition, immunoadsorption using a monoclonal antibody specific for the light-chain doublet removed all of the heavy chains. Separation of the heavy chains from the light chain by EDTA further illustrated the non-covalent nature of the heterodimers. All forms had coagulant activity which was potentiated 13-15-fold by an equimolar amount of human alpha-thrombin. Thrombin converted the Mr 83 000/81 000 doublet to one of Mr 73 000/71 000, and cleaved the largest polypeptides to a transient intermediate form of Mr 93 000 which was further cleaved to polypeptides of Mr 51 000 and 43 000. Potentiation of coagulant activity was correlated with proteolytic cleavage of either or both the doublet and the Mr 93 000 polypeptides. These data indicate that human factor VIII purified from plasma consists of a group of heterodimers, composed of a light chain of Mr 83 000 (81 000) and a heavy chain which varies in size between Mr 170 000 and 93 000, each form of which is similarly potentiated and cleaved by thrombin.     

Characterization of recombinant human factor VIII

Recently, complete human factor VIII DNA clones have been obtained and subsequently expressed in baby hamster kidney cells (Wood, W. I., Capon, D. J., Simonsen, C. C., Eaton, D. L., Gitschier, J., Keyt, B., Seeburg, P. H., Smith, D. H., Hollingshead, P., Wion, K. L., Delwart, E., Tuddenham, E. G. D., Vehar, G. A., and Lawn, R. M. (1984) Nature 312, 330-337). The recombinant factor VIII (rVIII) protein secreted from these cells has now been purified allowing its structural analysis and comparison to plasma-derived factor VIII (pdVIII). Analysis of purified rVIII by sodium dodecyl sulfate-polyacrylamide gel electrophoresis shows that it consists of multiple polypeptides with relative mobilities (Mr) ranging from 80,000-210,000. The same pattern of polypeptides is also observed for pdVIII resolved by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The proteins associated with rVIII are recognized by pdVIII antibodies in a Western blot. When rVIII and pdVIII are subjected to isoelectric focusing they are resolved into a similar pattern of protein bands. Thrombin, factor Xa, and activated protein C, which modulate factor VIII activity by proteolysis, process rVIII in the same manner they do pdVIII. As is the case for pdVIII, thrombin activation of rVIII coagulant activity correlates with the generation of subunits with Mr of 73,000, 50,000 and 43,000. These subunits appear to form a metal-(perhaps Ca2+) linked complex. EDTA inactivates thrombin-activated rVIII and pdVIII, with the activity being regenerated after the addition of a molar excess of MnCl2. The results suggest that rVIII is structurally and functionally very similar to pdVIII.     

The effect of plasma von Willebrand factor on the binding of human factor VIII to thrombin-activated human platelets

The binding of 35S-labeled recombinant human Factor VIII to activated human platelets was studied in the presence and absence of exogenous plasma von Willebrand factor. In the absence of added von Willebrand Factor, platelets bound 210 molecules of Factor VIII/platelet when the unbound Factor VIII concentration was 2.0 nM (Kd = 2.9 nM). As the von Willebrand factor concentration was increased, the number of Factor VIII molecules bound/platelet decreased to 10 molecules of Factor VIII bound/platelet at 24 micrograms/ml of added vWF. Addition of an anti-vWF monoclonal antibody that inhibits the vWF-Factor VIII interaction attenuated the ability of vWF to inhibit binding of Factor VIII to platelets. In contrast, addition of a control anti-vWF antibody that does not block the vWF-Factor VIII interaction did not affect the ability of vWF to inhibit Factor VIII binding to platelets. From the vWF concentration dependence of inhibition of Factor VIII-platelet binding, a dissociation constant for the Factor VIII-vWF interaction was calculated (Kd = 0.44 nM). To further elucidate the role that vWF may play in preventing the interaction of Factor VIII with platelets, the platelet binding properties of a Factor VIII deletion mutant (90-73) which lacks the primary vWF-binding site was studied. The binding of this mutant was unaffected by added exogenous vWF. These observations demonstrate that Factor VIII can interact with platelets in a manner independent of vWF but that excess vWF in plasma can effectively compete with platelets for the binding of Factor VIII. In addition, since cleavage of Factor VIII by thrombin separates a vWF-binding domain from Factor VIIIa, we propose that activation of Factor VIII by thrombin may elicit release of activated Factor VIII from vWF and thereby make it fully available for platelet binding.     

Thrombin cleavage analysis of a novel antihaemophilic factor variant, factor VIII delta II

Factor VIII delta II is a genetically engineered deletion variant of factor VIII expressed by recombinant Chinese hamster ovary cells, in which a major portion of the central (B) domain and a part of the light chain (Pro771-Asp1666) are missing. After immunoaffinity purification, the kinetics of thrombin cleavage of the novel molecule was analysed by SDS/PAGE, Western blotting and N-terminal amino acid sequencing. Thrombin first cleaves factor VIII delta II at Arg740-Ser741 to generate the 90-kDa heavy chain and an 80-kDa fusion polypeptide consisting of the remaining portion of the B domain and the 73-kDa light chain. The 90-kDa fragment is further cleaved, giving rise to 50-kDa and 40-kDa fragments while the 80-kDa fragment generates a 71/73-kDa doublet. The 71/73-kDa doublet, 50-kDa and 40-kDa fragments were further analysed by N-terminal amino acid sequencing and found to correspond to the predicted amino acid sequences. Our study shows that, in spite of the 900 amino acid deletion present in factor VIII delta II, the essential structural elements required for thrombin activation are conserved.     

Proteolysis at Arg740 facilitates subsequent bond cleavages during thrombin-catalyzed activation of factor VIII

Thrombin activates factor VIII by proteolysis at three P1 residues: Arg372, Arg740, and Arg1689. Cleavage at Arg372 and Arg1689 are essential for procofactor activation; however cleavage at Arg740 has not been rigorously studied. To evaluate the role for cleavage at Arg740, we prepared and stably expressed two recombinant B-domainless factor VIII mutants, R740H and R740Q to slow and eliminate, respectively, cleavage at this site. Specific activity values for the variants were approximately 50 and 20%, respectively, that of wild-type factor VIII. Activation of factor VIII R740H by thrombin showed an approximately 40-fold reduction in the rate of A2 subunit generation, which reflected an approximately 20-fold reduction in cleavage rate at Arg372. Similarly, a approximately 40-fold rate reduction in cleavage at Arg1689 and consequent generation of the A3-C1-C2 subunit were observed. Rate values for A2 and A3-C1-C2 subunit generation were reduced by >700-fold and approximately 140-fold, respectively, in the R740Q variant. These results suggest that initial cleavage at Arg740 affects cleavage at both Arg372 and Arg1689 sites. Results obtained evaluating proteolysis of the factor VIII mutants by factor Xa revealed more modest rate reductions (<10-fold) in generating A2 and A3-C1-C2 subunits from either variant, suggesting that factor Xa-catalyzed activation of factor VIII was significantly less dependent upon prior cleavage at residue 740 than thrombin. Overall, these results support a model whereby cleavage of factor VIII by thrombin is an ordered pathway with cleavage at Arg740 facilitating cleavages at Arg372 and Arg1689, which result in procofactor activation.     

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.     

Proteolysis of blood coagulation factor VIII by the factor VIIa-tissue factor complex: generation of an inactive factor VIII cofactor.

Activation of factor VIII by thrombin occurs via limited proteolysis at R372, R740, and R1689. The resultant active factor VIIIa molecule consists of three noncovalently associated subunits: A1-a1, A2-a2, and A3-C1-C2 (50, 45, and 73 kDa respectively). Further proteolysis of factor VIIIa at R336 and R562 by activated protein C subsequently inactivates this cofactor. We now find that the factor VIIa-tissue factor complex (VIIa-TF/PL), the trigger of blood coagulation with restricted substrate specificity, can also catalyze limited proteolysis of factor VIII. Proteolysis of factor VIII was observed at 10 sites, producing 2 major fragments (47 and 45 kDa) recognized by an anti-factor VIII A2 domain antibody. Time courses indicated the slow conversion of the large fragment to 45 kDa, followed by further degradation into at least two smaller fragments. N-Terminal sequencing along with time courses of proteolysis indicated that VIIa-TF/PL cleaved factor VIII first at R740, followed by concomitant cleavage at R336 and R372. Although cleavage of the light chain at R1689 was observed, the majority remained uncleaved after 17 h. Consistent with this, only a transient 2-fold increase in factor VIII clotting activity was observed. Thus, heavy chain cleavage of factor VIII by VIIa-TF/PL produces an inactive factor VIII cofactor no longer capable of activation by thrombin. In addition, VIIa-TF/PL was found to inactivate thrombin-activated factor VIII. We hypothesize that these proteolyses may constitute an alternative pathway to regulate coagulation under certain conditions. In addition, the ability of VIIa-TF/PL to cleave factor VIII at 10 sites greatly expands the known protein substrate sequences recognized by this enzyme-cofactor complex.     

The binding of 35S-labeled recombinant factor VIII to activated and unactivated human platelets

Recombinant-derived human Factor VIII was labeled intrinsically with [35S]methionine, and its binding to washed human platelets was studied. Binding measurements were performed by incubating Factor VIII and platelets for 15 min at room temperature in Tyrode's solution supplemented with Ca2+ (5.0 mM), 4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid (5.0 mM), 0.50% bovine serum albumin, and the Factor Xa and thrombin inhibitors 5-dimethylaminonaphthalene-1-sulfonylglutamylglycinylarginyl chloromethyl ketone and 5-dimethylaminonaphthalene-1-sulfonyl-arginine-N-(3-ethyl-1, 5-pentanediyl)amide. Separation of free from bound Factor VIII was accomplished by centrifugation through oil, and nonspecific binding was determined with excess unlabeled Factor VIII. Binding was saturable, reversible, and stimulated 20-fold after platelet activation with thrombin. Furthermore, binding was specific in that bound labeled Factor VIII could be displaced by excess unlabeled Factor VIII, but not by Factor V. Scatchard analysis indicated a single class of binding sites with Kd = 2.9 nM and 450 sites/activated platelet. The time course of displacement indicated a t1/2 of bound Factor VIII of approximately 5 min. When platelets were incubated in Ca2+, both the heavy and light chains of Factor VIII were bound, whereas exposure to EDTA resulted in the binding of the light chain only. These results demonstrate the specific reversible binding of Factor VIII to human platelets, likely mediated through the light chain.     

Mechanisms of plasmin-catalyzed inactivation of factor VIII: a crucial role for proteolytic cleavage at Arg336 responsible for plasmin-catalyzed factor VIII inactivation

Plasmin not only functions as a key enzyme in the fibrinolytic system but also directly inactivates factor VIII and other clotting factors such as factor V. However, the mechanisms of plasmin-catalyzed factor VIII inactivation are poorly understood. In this study, levels of factor VIII activity increased approximately 2-fold within 3 min in the presence of plasmin, and subsequently decreased to undetectable levels within 45 min. This time-dependent reaction was not affected by von Willebrand factor and phospholipid. The rate constant of plasmin-catalyzed factor VIIIa inactivation was approximately 12- and approximately 3.7-fold greater than those mediated by factor Xa and activated protein C, respectively. SDS-PAGE analysis showed that plasmin cleaved the heavy chain of factor VIII into two terminal products, A1(37-336) and A2 subunits, by limited proteolysis at Lys(36), Arg(336), Arg(372), and Arg(740). The 80-kDa light chain was converted into a 67-kDa subunit by cleavage at Arg(1689) and Arg(1721), identical to the pattern induced by factor Xa. Plasmin-catalyzed cleavage at Arg(336) proceeded faster than that at Arg(372), in contrast to proteolysis by factor Xa. Furthermore, breakdown was faster than that in the presence of activated protein C, consistent with rapid inactivation of factor VIII. The cleavages at Arg(336) and Lys(36) occurred rapidly in the presence of A2 and A3-C1-C2 subunits, respectively. These results strongly indicated that cleavage at Arg(336) was a central mechanism of plasmin-catalyzed factor VIII inactivation. Furthermore, the cleavages at Arg(336) and Lys(36) appeared to be selectively regulated by the A2 and A3-C1-C2 domains, respectively, interacting with plasmin.     

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.     

The effect of carbohydrate depletion on procoagulant activity and in vivo survival of highly purified human factor VIII

Human factor VIII procoagulant protein (factor VIII) was purified using a modification of our previously described method, in which Sephacryl S-400 elution, rather than QAE-cellulose chromatography, served as the final purification step. The protein had a specific activity of more than 2500 U/mg and consisted of a single polypeptide (Mr 100 000) when analyzed by SDS-polyacrylamide gel electrophoresis. Factor VIII was shown to be a glycoprotein by staining with periodic acid-Schiff's reagent following electrophoresis. Treatment of factor VIII with a mixture of exo- and endoglycosidases caused a reduction by about 50% in the intensity of periodic acid-Schiff staining, as determined by scanning densitometry, and an increase in electrophoretic mobility (equivalent to a new Mr 95 000). Removal of this portion of the total carbohydrate had no significant effect on factor VIII clotting activity or on thrombin potentiation of clotting activity. The in vivo survival curves of a native and sugar-depleted 125I-labeled factor VIII both showed similar patterns of initial rapid decay to 60 and 40% activity, respectively, followed by a one-half decay time of 4 h for both. These results suggest that the carbohydrate portion of human factor VIII does not contribute significantly to either clotting function in vitro or to biological turnover in vivo.     

Acidic residues C-terminal to the A2 domain facilitate thrombin-catalyzed activation of factor VIII

Factor VIII is activated by thrombin through proteolysis at Arg740, Arg372, and Arg1689. One region implicated in this exosite-dependent interaction is the factor VIII a2 segment (residues 711-740) separating the A2 and B domains. Residues 717-725 (DYYEDSYED) within this region consist of five acidic residues and three sulfo-Tyr residues, thus representing a high density of negative charge potential. The contributions of these residues to thrombin-catalyzed activation of factor VIII were assessed following mutagenesis of acidic residues to Ala or Tyr residues to Phe and expression and purification of the B-domainless proteins from stable-expressing cell lines. All mutations showed reduced specific activity from approximately 30% to approximately 70% of the wild-type value. While replacement of the Tyr residues showed little, if any, effect on rates of thrombin-catalyzed proteolysis of factor VIII and consequent activation, the acidic to Ala mutations Glu720Ala, Asp721Ala, Glu724Ala, and Asp725Ala showed decreased rates of proteolysis at each of the three P1 residues. Mutations at residues Glu724 and Asp725 were most affected with double mutations at these sites showing approximately 10-fold and approximately 30-fold reduced rates of cleavage at Arg372 and Arg1689, respectively. Factor VIII activation profiles paralleled the results assessing rates of proteolysis. Kinetic analyses revealed these mutations minimally affected apparent V max for thrombin-catalyzed cleavage but variably increased the K m for procofactor up to 7-fold, suggesting the latter parameter was dominant in reducing catalytic efficiency. These results suggest that residues Glu720, Asp721, Glu724, and Asp725 likely constitute an exosite-interactive region in factor VIII facilitating cleavages for procofactor activation.     

The action of factor Xa, thrombin and trypsin on human factor II

The proteolytic action of human and bovine Factor Xa, bovine thrombin and bovine pancreatic trypsin Factor II at pH 7.5 and 25°C was monitored by sodium dodecylsulfate gel electrophoresis and thrombin assays. Purified human and bovine Factor Xa, and trypsin, were found to activate Factor II to thrombin. The conversion of Factor II to thrombin by either Factor Xa or trypsin was found to proceed through two thrombogenic intermediates. The reaction pathway appears to be sequential in that the Factor II (75 000 daltons) is first cleaved to a 55 000-dalton thrombogenic product (Intermediate 1) and a 25 000-dalton non-thrombogenic product (Fragment 1). Intermediate 1 is subsequently converted to an inactive 37 000-dalton thrombogenic protein (Intermediate 2) and a 16 000-dalton protein (Fragment 2). Intermediate 2 is finally converted to an active 37 000-dalton thrombin (α-thrombin). Purified bovine thrombin readily converted Factor II to Intermediate 1 and Fragment 1, but possessed little capacity to catalyze subsequent cleavages to produce active thrombin. The ability of thrombin to cleave Factor II was entirely obviated in the presence of hirudin. Under the conditions of the incubation, the maximum thrombin yield obtainable by Factor Xa or trypsin activation was 50% when compared to the two-stage potential thrombin.     

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.     

Activation of human factor V by factor Xa and thrombin

The activation of human factor V by factor Xa and thrombin was studied by functional assessment of cofactor activity and sodium dodecyl sulfate-polyacrylamide gel electrophoresis followed by either autoradiography of 125I-labeled factor V activation products or Western blot analyses of unlabeled factor V activation products. Cofactor activity was measured by the ability of the factor V/Va peptides to support the activation of prothrombin. The factor Xa catalyzed cleavage of factor V was observed to be time, phospholipid, and calcium ion dependent, yielding a cofactor with activity equal to that of thrombin-activated factor V (factor Va). The cleavage pattern differed markedly from the one observed in the bovine system. The factor Xa activated factor V subunits expressing cofactor activity were isolated and found to consist of peptides of Mr 220,000 and 105,000. Although thrombin cleaved the Mr 220,000 peptide to yield peptides previously shown to be products of thrombin activation, cofactor activity did not increase. N-Terminal sequence analysis confirmed that both factor Xa and thrombin cleave factor V at the same bond to generate the Mr 220,000 peptide. The factor Xa dependent functional assessment of 125I-labeled factor V coupled with densitometric analyses of the cleavage products indicated that the cofactor activity of factor Xa activated factor V closely paralleled the appearance of the Mr 220,000 peptide. This observation facilitated the study of the kinetics of factor V activation by allowing the activation of factor V to be monitored by the appearance of the Mr 220,000 peptide (factor Xa activation) or the Mr 105,000 peptide (thrombin activation). Factor Xa catalyzed activation of factor V obeyed Michaelis-Menten kinetics and was characterized by a Km of 10.4 nM, a kcat of 2.6 min-1, and a catalytic efficiency (kcat/Km) of 4.14 X 10(6) M-1 s-1. The thrombin-catalyzed activation of factor V was characterized by a Km of 71.7 nM, a kcat of 14.0 min-1, and a catalytic efficiency of 3.26 X 10(6) M-1 s-1. This indicates that factor Xa is as efficient an enzyme toward factor V as thrombin.     

Purification of human factor VIII:C and its characterization by Western blotting using monoclonal antibodies

Human factor VIII:C has been purified over 300 000-fold from cryoprecipitate by polyelectrolyte purification followed by affinity chromatography on Sepharose linked to antibody to factor VIIIR:Ag (monoclonal or polyclonal) and Sepharose linked to monoclonal antibody to factor VIII:C. The purified material has been analyzed by polyacrylamide gel electrophoresis (PAGE) and Western blotting using monoclonal antibodies. PAGE shows predominant bands at 360K (unreduced), 210K, and 90K and an 80K/79K doublet; Western blotting showed all the monoclonal antibodies used bound the 360K form. In a small-scale purification, plasma from blood taken directly into thrombin inhibitor Kabi S-2581 was applied directly to the monoclonal anti-factor VIII:C column. Western blot analysis of this material showed the 360K band on reduction. The purified factor VIII:C could be activated 13-fold by human thrombin. Gel analysis of the activated material showed intensification followed by fading of the band at 90K and generation of bands at 70K/69K, 55K, and 40K. Western blotting shows that the 70K/69K doublet derives from the 80K/79K moiety and the 40K peptide derives from the 90K and is presumed to contain the active site. From these studies an epitope map of the factor VIII:C molecule has been constructed.     

Platelet-derived microparticles express high affinity receptors for factor VIII.

Factor VIII is a cofactor in the tenase enzyme complex which assembles on the membrane of activated platelets. A critical step in tenase assembly is membrane binding of factor VIII. Platelet membrane factor VIII-binding sites were characterized by flow cytometry using either fluorescein maleimide-labeled recombinant factor VIII or a fluorescein-labeled monoclonal antibody against factor VIII. Following activation by thrombin, most platelets bound factor VIII within 90 s. In addition, over the course of several minutes, membranous vesicles (microparticles) were shed from the platelet plasma membrane and each microparticle bound as much factor VIII as a stimulated platelet. Over 30 min, stimulated platelets (but not microparticles) lost the capacity to bind factor VIII. Factor VIII bound saturably to microparticles from platelets stimulated with thrombin, thrombin plus collagen, or the complement proteins C5b-9. The binding of factor VIII was compared to factor V, a structurally homologous coagulation cofactor. Analysis of microparticle binding kinetics yielded similar on and off rates for factor VIII and factor Va and KD values of 2-10 nM. In the presence of 20 nM factor Va, the binding of factor VIII to microparticles was increased, and there was a comparable increase in platelet tenase activity. At higher factor Va concentrations, factor VIII binding and tenase activity were inhibited. Conversely, factor VIII had a similar dose-dependent effect on factor Va binding and platelet prothrombinase activity. Synthetic phospholipid vesicles containing phosphatidylserine competed with microparticles for binding of factor VIII and factor Va. These studies indicate that activated platelets express a transient increase in high affinity receptors for factor VIII, whereas platelet-derived microparticles express a sustained increase in receptors. The binding characteristics of platelet membrane receptors for factor VIII are similar to those for factor Va.     

Inactivation of human factor VIII by activated protein C: evidence that the factor VIII light chain contains the activated protein C binding site

Factor VIII is represented as a series of heterodimers composed of an 83(81) kDa light chain noncovalently bound to a variable size (93 to 210 kDa) heavy chain. Activated protein C inactivates factor VIII causing several cleavages of the factor VIII heavy chain(s). When factor VIII subunits were dissociated and component heavy and light chains isolated, the heavy chains were no longer a substrate for proteolysis by activated protein C. However, when factor VIII heavy chains were recombined with light chain, the reconstituted factor VIII activity was inactivated by activated protein C. The rate of factor VIII inactivation catalyzed by activated protein C was reduced by the presence of free light chain. The extent of this inhibition was dependent upon the concentration of light chain. Control experiments indicated that this protective effect of free light chain was not the result of inhibition of the activated protein C - lipid interaction. Fluorescence analysis demonstrated binding between the factor VIII light chain, chemically modified with eosin maleimide, and activated protein C, modified at its active site by dansyl-Glu-Gly-Arg chloromethyl ketone. Similar to proteolysis of factor VIII by activated protein C, this binding was dependent upon a lipid surface. Based upon the degree of fluorescence quenching, a spatial distance of 26 A was calculated separating the two fluorophores. These results demonstrate direct binding of activated protein C to the factor VIII light chain and suggest that this binding is an obligate step for activated protein C-catalyzed inactivation of factor VIII.