Platelet coagulation factor Va: the major secretory platelet phosphoprotein

Platelet-derived coagulation factor Va is the primary secreted substrate for a thrombin-stimulation-dependent platelet kinase. Human platelet factor Va, consisting of a molecular weight (M(r)) 105,000 heavy chain and an M(r) 74,000 light chain, incorporates phosphate in at least two sites on the light chain. Phosphorylated factor Va represents 50% of the secreted protein-associated phosphate. This modification occurs exclusively at serine residues and is inhibited by H-7 and staurosporine, which suggests a protein kinase C (PKC)-mediated event. Purified plasma factor V and Va are phosphorylated in the light chain region by rat brain PKC. The activity of platelet factor Va in prothrombinase on platelets is not altered when phosphorylation is inhibited by staurosporine. Plasma-derived factor Va in the presence of thrombin stimulated platelets is phosphorylated on both the heavy chain and the light chain. Plasma factor V and factor Va heavy chain phosphorylation occurs without light chain phosphorylation in the presence of added 32P gamma-ATP and non-stimulated or collagen- stimulated platelets or casein kinase II. This differential phosphorylation of factor Va heavy and light chain shows two independent platelet kinase activities that act on factor Va. The heavy chain factor V/Va kinase activity is similar to casein kinase II, which we have demonstrated previously to act on factor Va and accelerate activated protein C inactivation of the cofactor. Our data show platelet-dependent phosphorylation of platelet and plasma factor V and Va resulting in significant covalent modifications of the cofactor. These modifications may play a role in directing the extracellular distribution of factor V and factor Va.     

Proteolytic inactivation of human factor VIII procoagulant protein by activated human protein C and its analogy with factor V

Purified human factor VIII procoagulant protein (VIII:C) was treated with purified human activated protein C (APC) and the loss of VIII:C activity correlated with proteolysis of the VIII:C polypeptides. APC proteolyzed all VIII:C polypeptides with mol wt = 92,000 or greater, but not the doublet at mol wt = 79-80,000. These results and our previous thrombin activation studies of purified VIII:C, are analogous with similar studies of factor V and form the basis for the following hypothesis: activated VIII:C consists of heavy and light chain polypeptides [mol wt = 92,000 and mol wt = 79-80,000 (or 71-72,000), respectively] which are similar in Mr to the heavy and light chains of activated factor V. Thrombin activates VIII:C and V by generating these polypeptide chains from larger precursors and APC inactivates both molecules by cleavage at a site located in the heavy chain region of activated VIII:C and V.     

Myosin light chain and caldesmon phosphorylation in arterial muscle stimulated with endothelin-1

Endothelin-1 contracts porcine carotid arterial smooth muscle with an ED50 of 10 nM. Contraction is associated with phosphorylation of the 20,000 dalton-regulatory light chain subunits of vascular myosin. Phosphopeptide mapping of light chains isolated from 32PO4-loaded muscle strips stimulated by endothelin-1 (5 x 10(-8) M) and comparison with maps generated from light chains phosphorylated in vitro or muscles stimulated with KCl (110 mM) or angiotensin-II (5 x 10(-8) M) indicates that Ca2(+)-calmodulin activation of myosin light chain kinase is a biochemical pathway stimulated by all three agonists. However, a small amount of phosphate (17%) was detected in a light chain peptide phosphorylated by protein kinase C. Endothelin-1 also stimulated phosphorylation of the thin filament protein, caldesmon, (from 0.35 mol PO4/mol caldesmon to 0.52 mol PO4/mol). Collectively, these results provide evidence that the effects of endothelin-1 on force generation and maintenance in vascular muscle may be dependent upon myosin light chain phosphorylation by Ca2+ calmodulin--requiring myosin light chain kinase and upon a thin filament mechanism that is modulated by phosphorylation of caldesmon.     

Stimulation of casein kinase II by epidermal growth factor: relationship between the physiological activity of the kinase and the phosphorylation state of its beta subunit.

To determine relationships between the hormonal activation of casein kinase II and its phosphorylation state, epidermal growth factor (EGF)-treated and EGF-naive human A-431 carcinoma cells were cultured in the presence of [32P]orthophosphate. Immunoprecipitation experiments indicated that casein kinase II in the cytosol of EGF-treated cells contained approximately 3-fold more incorporated [32P]phosphate than did its counterpart in untreated cells. Levels of kinase phosphorylation paralleled levels of kinase activity over a wide range of EGF concentrations as well as over a time course of hormone action. Approximately 97% of the incorporated [32P]phosphate was found in the beta subunit of casein kinase II. Both activated and hormone-naive kinase contained radioactive phosphoserine and phosphothreonine but no phosphotyrosine. On the basis of proteolytic mapping experiments, EGF treatment of A-431 cells led to an increase in the average [32P]phosphate content (i.e., hyperphosphorylation) of casein kinase II beta subunit peptides which were modified prior to hormone treatment. Finally, the effect of alkaline phosphatase on the reaction kinetics of activated casein kinase II indicated that hormonal stimulation of the kinase resulted from the increase in its phosphorylation state.     

Prothrombinase complex assembly on the platelet surface is mediated through the 74,000-dalton component of factor Va.

The blood coagulation protein factor Va forms the receptor for the serine protease factor Xa on the platelet surface. This membrane-bound complex of factor Va and factor Xa plus Ca2+ comprises the prothrombinase complex, the enzyme that catalyzes the proteolytic conversion of prothrombin to the clotting enzyme thrombin. Factor Va is a two-subunit protein composed of component D (Mr = 94,000) and component E (Mr = 74,000); subunit interaction is Ca2+ dependent. Factor Va bound to platelets consists of three peptides: component D, component E, and component D'(Mr = 90,000) which appears as the result of a platelet-associated protease cleavage of component D. The present studies were undertaken to determine which peptide(s) mediates the binding of factor Va to the platelet membrane surface and which peptide(s) serves as the binding site for factor Xa. These interactions were assessed by direct measurements of radiolabeled factor Va and factor Xa binding to platelets as well as autoradiographic visualization of the factor Va peptides associated with the platelet. Experiments were performed to determine the interaction of components D and E with platelets under reaction conditions in which components D and E were present as either the intact, functional two-subunit protein or as nonfunctional discrete peptides dissociated by the addition of Na2EDTA. The results suggest that component E mediates the binding of factor Va to the platelet and also serves as the binding site for the interaction of factor Xa with platelet-bound factor Va.     

Dopamine- and cAMP-regulated phosphoprotein DARPP-32: phosphorylation of Ser-137 by casein kinase I inhibits dephosphorylation of Thr-34 by calcineurin.

Although protein phosphatases appear to be highly controlled in intact cells, relatively little is known about the physiological regulation of their activity. DARPP-32, a dopamine- and cAMP-regulated phosphoprotein of apparent M(r) 32,000, is phosphorylated in vitro by casein kinase I, casein kinase II, and cAMP-dependent protein kinase on sites phosphorylated in vivo. DARPP-32 phosphorylated on Thr-34 by cAMP-dependent protein kinase is a potent inhibitor of protein phosphatase 1 and an excellent substrate for calcineurin, a Ca2+/calmodulin-dependent protein phosphatase. Here we provide evidence, using both purified proteins and brain slices, that phosphorylation of DARPP-32 on Ser-137 by casein kinase I inhibits the dephosphorylation of Thr-34 by calcineurin. This inhibition occurs only when phospho-Ser-137 and phospho-Thr-34 are located on the same DARPP-32 molecule and is not dependent on the mode of activation of calcineurin. The results demonstrate that the inhibition is due to a modification in the properties of the substrate which alters its dephosphorylation rate. Thus, casein kinase I may play a physiological role in striatonigral neurons as a modulator of the regulation of protein phosphatase 1 via DARPP-32.     

Binding of thrombin-activated human factor VIII to platelets

To study association of platelets with factor VIII, the purified protein was 125I-labelled with Bolton-Hunter reagent to a specific activity of 243,000-360,000 cpm/U. Autoradiographs of SDS polyacrylamide gels revealed polypeptides of VIII at Mr about 240 kDa, 90 kDa and intermediate values, as well as some radioactive contaminants, but the light chain (Mr 78/76) seen with silver stain was not labelled. After 2.5-5-fold activation with thrombin, the higher radioactive Mr band disappeared, the band at 90 kDa became more intense, and a band appeared at about 45 kDa. The radioactivity associated with platelets, studied in the presence of haemophilic BaSO4-treated plasma, was maximal after 6-8 min and increased 3-15-fold on activation with thrombin. With activated VIII, autoradiographs of platelet pellets showed only VIIIa but results are expressed as units of unactivated VIII bound. At 0.3-0-0.7 U/ml, 10(8) platelets bound 0.0008-0.004 U VIIIa. The amount bound was not affected by the ratio of unlabelled VIII to VIII labelled in the presence of a 50-fold molar excess of unlabelled Bolton-Hunter reagent. Binding increased to 1.5 U VIIIa/10(8) platelets (about 13,600 molecules per platelet) at 140 U/ml, with no evidence of saturation. Binding was not affected by monoclonal antibodies to platelet glycoproteins IIb/IIIa or Ib, quenching the thrombin before adding platelets, or aggregating the platelets with A23187 in the presence of thrombin. Qualitatively, binding of labelled VIIIa and factor Va studied by others are similar. Binding of 125I-VIIIa to aggregated and unaggregated platelets was normal in patient M.S. whose platelets were shown by others to be deficient in their ability to bind radiolabelled factor Xa and generate coagulant activity. This difference. and the fact that platelet coagulant activity is increased by platelet activation and/or aggregation, suggest that binding of Va or VIIIa alone does not determine the assembly of active proteolytic complexes on the platelet surface.     

Coagulation factors V and VIII and ceruloplasmin constitute a family of structurally related proteins.

Computer searches of the National Biomedical Research Foundation protein and nucleic acid sequence data bases using the NH2 terminus of the bovine factor Va 94-kilodalton heavy chain, the NH2 terminus of the 74-kilodalton factor Va light chain, and an internal 98-residue segment of porcine factor VIII revealed that both bovine factor V and porcine factor VIII are statistically homologous to human ceruloplasmin. The NH2-terminal segment of bovine factor Va heavy chain is homologous to three segments of ceruloplasmin sequence starting at residues 1, 351, and 713; the NH2-terminal sequence of bovine factor Va light chain is homologous to the same human ceruloplasmin sequence segments beginning at residues 1, 349, and 711. The longer porcine factor VIII sequence is homologous to three segments of human ceruloplasmin, residues 1-77, 400-433, and 683-791. These data indicate that factor V, factor VIII, and ceruloplasmin comprise a group of evolutionarily linked protein structures that possibly resulted from multiplication of ancestral precursor genes.     

Phosphorylation of the guanine nucleotide exchange factor from rabbit reticulocytes regulates its activity in polypeptide chain initiation.

We have demonstrated that the purified guanine nine nucleotide exchange factor (GEF) may be isolated as a complex with NADPH. Complete inhibition of the GEF-catalyzed exchange of eukaryotic initiation factor 2-bound GDP for GTP was observed in the presence of either 0.5-0.75 mM NAD+ or NADP+. Incubation of GEF with ATP results in the phosphorylation of its Mr 82,000 polypeptide. This phosphorylation is strongly inhibited by heparin but is not affected by heme or H8 (N-[2-(methylamino)ethyl]-5-isoquinolinesulfonamide dihydrochloride), an inhibitor of cAMP- and cGMP-dependent protein kinases and protein kinase C. The purification of GEF was modified to eliminate any contaminating kinase activity and the isolated protein appears to be homogeneous as judged by NaDodSO4/polyacrylamide gel electrophoresis and silver staining. The Mr 82,000 subunit of GEF is phosphorylated only upon addition of ATP and casein kinase II. The extent of phosphorylation is approximately equal to 0.55 mol of phosphate per mol of GEF, and this results in a 2.3-fold increase in the guanine nucleotide exchange activity. Following treatment of the phosphorylated GEF with alkaline phosphatase, the activity of the protein is reduced by a factor of 5. Rephosphorylation of GEF increases its specific activity to that of the phosphorylated protein. The results of this study suggest that phosphorylation/dephosphorylation of GEF plays a role in regulating polypeptide chain initiation.     

Factor V activation and inactivation by venom proteases

Blood coagulation factor V is a single-chain glycoprotein with M(r) = 330,000 which plays an important role in the procoagulant and anticoagulant pathways. Thrombin activates factor V into factor Va, a two-chain molecule which is composed of a heavy (M(r) = 105,000) and a light chain (M(r) = 71,000/74,000). Factor Va accelerates factor Xa-catalysed prothrombin activation more than 1,000-fold and under physiological conditions the cofactor activity of factor Va in prothrombin activation is down-regulated by activated protein C. Factor V can also be activated by a wide variety of snake venoms (e.g. from Vipera species, Naja naja oxiana, Bothrops atrox) and by proteases present in the bristles of a South American caterpillar (Lonomia achelous). Some venoms, notably of Vipera lebetina turanica and Lonomia achelous, contain proteases that are able to inactivate factor V or factor Va. Venom factor V activators are excellent tools in studying the structure-function relationship of factor V(a) and they are also used in diagnostic tests for quantification of plasma factor V levels and for the screening of defects in the protein C pathway. In this review, the structural and functional properties of animal venom factor V activators and inactivators is described.     

Regulatory interactions of calmodulin-binding proteins: phosphorylation of calcineurin by autophosphorylated Ca2+/calmodulin-dependent protein kinase II.

The Ca2+/calmodulin (CaM)-dependent protein phosphatase calcineurin is rapidly phosphorylated (0.8 mol of 32PO4 per mol of 60-kDa subunit of calcineurin) by brain Ca2+/CaM-dependent protein kinase II (CaM-kinase II). This reaction requires the autophosphorylated, Ca2+-independent form of CaM-kinase II since Ca2+/CaM binding to calcineurin inhibits phosphorylation. However, the phosphorylation reaction does require Ca2+, presumably acting through the 19-kDa subunit of calcineurin. Calcineurin is a good substrate for CaM-kinase II, with a Km of 19 microM and Vmax of 2.4 mumol/min per mg. Phosphorylation of calcineurin changed its phosphatase activity with either a 2-fold increase in Km (32P-labeled myosin light chain as substrate) or a 50% decrease in Vmax (p-nitrophenyl phosphate as substrate). The phosphorylated calcineurin exhibited very slow autodephosphorylation (0.09 nmol/min per mg) but was effectively dephosphorylated by brain protein phosphatase IIA. Dephosphorylation, like phosphorylation, was blocked by high concentrations of Ca2+/CaM and stimulated by Ca2+ alone. Thus calcineurin has a regulatory phosphorylation site that is phosphorylated by the Ca2+-independent form of CaM-kinase II and blocked by high concentrations of Ca2+/CaM.     

Monoclonal antibodies to human coagulation factor V and factor Va

BALB/c mice were immunized with human factor V. The immunogen was a mixture of procofactor (factor V) and thrombin-activated cofactor (factor Va). Spleen cells were obtained from an immunized animal and fused with NS-1 murine myeloma cells. Hybrid cell cultures were assayed for the production of antibodies to human factor V and factor Va by a solid-phase radioimmunoassay. Factor V and/or factor-Va-specific antibodies were detected in 38 of the 96 cultures assayed. The cells from 10 of these positive cultures were subcloned by limiting dilution and grown as ascites tumors in BALB/c mice. Ascitic fluids were obtained and characterized with respect to their binding interaction with human factor V and factor Va. Three hybridoma cell lines produce monoclonal antibodies that react equally well with factor V and factor Va. Another antibody reacts with both antigens, but the reactivity with factor V is better than with factor Va. An additional two antibodies react with factor Va better than factor V in the radioimmunoassay (RIA). The remaining four antibodies react exclusively with factor V. A previously described murine monoclonal antibody to human factor V (alpha HFV-1) has been used to study the peptides produced during the thrombin-catalyzed activation of human factor V. This antibody binds both factor V and factor Va, releases them at high ionic strength, and has an apparent dissociation constant for factor Va of 3 x 10(-9)M. When human factor V (mol wt 330,000) is activated by thrombin and passed over an alpha HFV-1-Sepharose affinity resin, factor Va binds and subsequently can be eluted. The eluate in 1.2 M NaCl contains two fragments of apparent mol wt 93,000 and 70,000. EDTA, which inactivates factor Va, promotes release of the mol wt 93,000 fragment from factor Va bound to the antibody. Subsequent elution with 1.2 M NaCl releases the mol wt 70,000 fragment. These observations indicate that human factor Va is a two subunit protein and that the epitope for alpha HFV-1 is on the mol wt 70,000 fragment.     

Regulation of myosin self-assembly: phosphorylation of Dictyostelium heavy chain inhibits formation of thick filaments.

Dictyostelium myosin is composed of two heavy chains and two pairs of light chains in a 1:1:1 stoichiometry. Myosin purified from amoebae grown in medium containing [32P]phosphate had two of the subunits labeled (0.2-0.3 mol of phosphate per mol of 210,000-dalton heavy chains and approximately 0.1 mol of phosphate per mol of 18,000-dalton light chain). Kinase activities specific for the 210,000-dalton and for the 18,000-dalton subunits have been identified in extracts of Dictyostelium amoebae, and the heavy chain kinase has been purified 50-fold. This kinase phosphorylated Dictyostelium myosin to a maximum of 0.5-1.0 mol of phosphate per mol of heavy chain. Heavy chain phosphate, but not light chain phosphate, can be removed with bacterial alkaline phosphatase. Actin-activated myosin ATPase increased 80% when phosphorylated myosin was dephosphorylated to a level of approximately 0.06 mol of phosphate per mol of heavy chain. This effect could be reversed by rephosphorylating the myosin. The ability of myosin to self-assemble into thick filaments was inhibited by heavy chain phosphorylation. For example, in 80-100 mM KCl, only 10-20% of the myosin was assembled into thick filaments when the heavy chains were fully phosphorylated. Removal of the heavy chain phosphate resulted in 70-90% thick filament formation. This effect on self-assembly could be reversed by rephosphorylating the dephosphorylated myosin. These findings suggest that heavy chain phosphorylation may regulate cell contractile events by altering the state of myosin assembly.     

Influence of factor VIII/von Willebrand complex on the activated protein C-resistance phenotype and on the risk for venous thromboembolism in heterozygous carriers of the factor V Leiden mutation.

High factor VIII plasma levels have been shown to represent a common increased risk for venous thromboembolism (VTE) and may cause an activated protein C (APC) resistance in the absence of the factor V Leiden mutation, but there are no studies specifically aimed to establish if high factor VIII and von Willebrand factor (vWF) concentrations may influence the APC sensitivity ratio (APC-SR) and increase the risk for VTE in the presence of the factor V Leiden mutation. For this purpose, we performed a retrospective case-control study to investigate the influence of the procoagulant factor VIII (VIII:C) and the antigen of vWF (vWF:Ag) on the normalized APC-SR (n-APC-SR) and on the risk for VTE, in two selected groups of 30 symptomatic (Group I) and 32 asymptomatic (Group II) related heterozygotes for the factor V Leiden mutation. Differences between the two groups (Group I versus Group II) were: n-APC-SR, 0.57+/-0.06 versus 0.63+/-0.08, P = 0.001; factor VIII:C, 1.49+/-0.42 versus 1.13+/-0.28 IU/ml, P<0.001; vWF:Ag, 1.46+/-0.53 versus 1.26+/-0.32 IU/ml, NS. As a whole (Group I + Group II), Pearson correlation coefficients were: n-APC-SR versus factor VIII:C, r = -0.410, P = 0.001; n-APC-SR versus vWF:Ag, r = -0.309, P = 0.01; factor VIII:C versus vWF:Ag, r = +0.640, P<0.0001. The relative risk for VTE in individuals with the factor VIII:C concentration > 1.5 IU/ml was 2.5 (95% confidence interval 1.6-3.9). We concluded that high factor VIII:C levels, probably in the effect of vWF, play a determinant role in worsening the APC-resistance phenotype and represent a common additional risk factor for VTE in heterozygous carriers of the factor V Leiden mutation.     

Phosphorylation of Human Platelet Myosin

A preparation extracted from human blood platelets, which incorporates (32)P from gamma-labeled AT(32)P into one of the two light chains of platelet myosin and platelet myosin head is described. This phosphorylation, which appears to be due to an endogenous kinase, is specific for the myosin light chain in that no other protein extracted in 0.6 M KCl-15 mM Tris.HCl (pH 7.5) is phosphorylated. The phosphorylated light chain, which has been purified by gel filtration, releases the covalently bound phosphate after incubation in alkali and not after incubation in acid.     

Activation of factor VIII and mechanisms of cofactor action

The factor VIII procofactor circulates as a metal ion-dependent heterodimer of a heavy chain and light chain. Activation of factor VIII results from limited proteolysis catalyzed by thrombin or factor Xa, which binds the factor VIII substrate over extended interactive surfaces. The proteases efficiently cleave factor VIII at three sites, two within the heavy and one within the light chain resulting in alteration of its covalent structure and conformation and yielding the active cofactor, factor VIIIa. The role of factor VIIIa is to markedly increase the catalytic efficiency of factor IXa in the activation of factor X. This effect is manifested in a dramatic increase in the catalytic rate constant, k(cat), by mechanisms that remain poorly understood.     

Loss of membrane-dependent factor Va cleavage: a mechanistic interpretation of the pathology of protein CVermont

Clinical manifestations of arterial and venous thrombosis in a family with protein C deficiency was associated with two mutations in the light chain of protein C: Glu20-->Ala and Val34-->Met. Further studies showed that the mutation Glu20-->Ala which eliminated a gamma- carboxylation site was exclusively responsible for the anticoagulant defect of activated protein C (APC). Membrane-bound human factor Va is inactivated by APC after two sequential cleavages of the heavy chain at Arg506 and Arg306. Human factor Va inactivation by human recombinant APC (rAPC) and a mutant molecule with an alanine instead of a glutamic acid at position 20 (rAPC(gamma 20A)) was investigated in the presence and absence of phospholipid vesicles. During a 2-hour incubation period of the cofactor with either rAPC or rAPC(gamma 20A). In the absence of a membrane surface, factor Va is cleaved quantitatively at Arg506 and retains approximately 60% of its initial cofactor activity. After a 2- hour incubation period with rAPC membrane-bound factor Va has no cofactor activity, whereas in the presence of a membrane surface and rAPC(gamma 20A) factor Va retains 60% of its initial cofactor activity. The completed loss in factor Va cofactor activity upon incubation of the membrane-bound cofactor with phospholipid vesicles and rAPC is associated with cleavages at Arg506 and Arg306, whereas membrane-bound factor Va cleavage at Arg306 by rAPC(gamma 20A) is impaired, resulting in a cofactor that is cleaved at Arg506. Slow cleavage at Arg306 occurs when membrane-bound factor Va is incubated with rAPC(gamma 20A) and only small amounts of fragments of M(r) = 45,000 and 30,000 are noticed. Our data show that the genetic defect which leads to the absence of a gamma-carboxylation site at Glu20 impairs membrane binding of human APC, which in turn is required for cleavage of factor Va at Arg306 and inactivation of the cofactor. The consequence of impaired membrane-dependent cleavage at Arg306 is manifested in vivo by venous and arterial thrombosis.     

Production of factor VIII deficient plasma by immunodepletion using three monoclonal antibodies

Factor VIII deficient plasma was made from pooled, HIV antibody and hepatitis B antigen screened, normal human plasma by cryoprecipitation and immuno-depletion, using three different monoclonal antibodies bound to Sepharose columns, in series. These monoclonal antibodies are specific respectively for von Willebrand factor, factor VIII heavy chain and factor VIII light chain. The immunodepleted plasma contained less than 0.002 u/ml factor VIII coagulation activity (VIII:C) less than 0.0001 u/ml von Willebrand factor antigen and 1-2 g/l fibrinogen, while the levels of other clotting factors were unchanged. This immunodepleted plasma was compared with commercial factor VIII deficient plasma obtained from a severe haemophilia A patient as substrate in the one-stage factor VIII assay. Plasmas obtained from 20 normal subjects and 28 patients with von Willebrand's disease or haemophilia A were assayed for VIII:C using the two substrates. The results were very highly correlated (r = 0.96). The columns have high capacity and can be regenerated at least 10 times. Large-scale production of a substrate for factor VIII assays free of virus contamination is now feasible.     

Proteolytic interactions of factor IXa with human factor VIII and factor VIIIa.

Factor IXa was shown to inactivate both factor VIII and factor VIIIa in a phospholipid-dependent reaction that could be blocked by an antifactor IX antibody. Factor IXa-catalyzed inactivation correlated with proteolytic cleavages within the A1 subunit of factor VIIIa and within the heavy chain (contiguous A1-A2-B domains) of factor VIII. Furthermore, a relatively slow conversion of factor VIII light chain to a 68-Kd fragment was observed after prolonged incubation. Sites of cleavage were identified within the A1 domain at Arg336-Met337 and within the factor VIII light chain at Arg1719-Asn1720. Factor IXa failed to cleave isolated factor VIII heavy chains, yet cleaved isolated factor VIII light chain. In addition, the purified A1/A3-C1-C2 dimer derived from factor VIIIa was a substrate for factor IXa; however, cleavage of the A1 subunit occurred at less than 30% the rate of cleavage of A1 in trimeric factor VIIIa. These data suggest that factor VIII light chain contributes to the binding site for factor IXa and also support a role for a heavy chain determinant located within the A2 subunit in the association of factor VIIIa with factor IXa. Furthermore, the capacity of factor IXa to proteolytically inactivate its cofactor, factor VIIIa, suggests a mode of regulation within the intrinsic tenase complex.     

Electron microscopy of human factor V and factor VIII: correlation of morphology with domain structure and localization of factor V activation fragments.

Clotting factor V and factor VIII are each represented by the domain structure A1-A2-B-A3-C1-C2 and share 40% sequence homology in the A and C domains. Rotary-shadowed samples of human factor V and factor VIII were examined in the electron microscope. Single-chain factor V molecules exhibited a globular "head" domain 12-14 nm in diameter. In addition, up to 25% of these molecules showed a rod-like "tail" of up to 50 nm. Glycerol-gradient centrifugation of factor V treated with thrombin partially resolved the factor Va heterodimer from a larger activation peptide of 150 kDa, as determined by gel electrophoresis. Electron microscopy of factor Va revealed globular molecules with several smaller appendicular structures but lacking the tails seen in factor V. Images of the 150-kDa activation peptide showed rod-like structures, similar in width to the tail of intact factor V and approximately 34 nm long. Rotary shadowing was also used to visualize factor VIII that had been fractionated into heterodimers containing heavy chains of distinct sizes. Each factor VIII preparation showed a globular structure approximately 14 nm in diameter, but the associated tails were observed much more frequently with factor VIII heterodimers containing the higher-molecular-weight heavy chains. These results, in conjunction with results of studies using other biophysical techniques, suggest a model in which the A and C domains of each cofactor constitute a globular head and the connecting B domain is contained in a two-stranded tail that is released by thrombin cleavage.