Source: http://smart.embl.de/smart/show_secondary.cgi?domain=FA58C
Timestamp: 2019-04-23 14:19:20+00:00

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Epitope mapping of factor VIII inhibitor antibodies of Chinese origin.
Epitopes recognized by factor VIII (FVIII) inhibitors of Chinese origin were analysed by immunoblotting with full-length recombinant FVIII (rFVIII), thrombin-activated FVIII (FVIIIa) and 16 FVIII fusion proteins synthesized by bacteria. Twenty-eight patients, 12 with haemophilia A and 16 with autoimmune diseases, were recruited. Antibodies from 22 patients showed reactivity with rFVIII, 20 with FVIIIa, and one reacted only with FVIII fusion proteins. Of these 22 cases, most were reactive with A2-a2 and A3-C1-C2 of FVIII(a). Of the nine cases that depicted binding to the fusion proteins, three were reactive with the A domains, three with only the B domain, and the other three with both the A and B (or C) domains. An epitope for a neutralizing antibody of a haemophilia A patient, designated TWN-112, was localized to residues 323-390, specified by FVIII fusion proteins. The same epitope also appeared on an FVIII-expression phage library screening. Immunoabsorption of antibodies from TWN-112 with the epitope reduced the neutralizing activity of the inhibitor by 33%. The incidence of a1 of FVIII is higher, and that of a3 is lower, than previously reported. Two novel epitopes, reported for the first time in this paper, were localized on the 8B2 (amino acid residues 1022-1204) and 8A2(V) (residues 673-740) fusion proteins. These two epitopes were able to reduce inhibitory antibody activity by 24% and 25% respectively. Changes of FVIII fragment specificity were also observed in one of six patients for whom multiple samples, collected at different times, were available. Our initial finding showed that the FVIII inhibitors in these Chinese patients shared epitopes with those of patients from very different genetic backgrounds, suggesting a common mechanism for the development of FVIII inhibitors.
Domain specific monoclonal anti-factor VIII antibodies generated by inclusion body-renatured factor VIII peptides.
Production of monoclonal anti-factor VIII (FVIII) antibodies was hampered by the availability of FVIII proteins devoid of albumin and the von Willebrand factor (vWF). We showed a successful way to generate domain specific anti-FVIII antibodies by using a series of Escherichia coli expressed FVIII fusion peptides. A total of eight fusion peptides were synthesized to cover almost the entire coding region of FVIII. All except one of the fusion peptides were insoluble and became aggregated as inclusion bodies. Purification and refolding of the peptides were accomplished by solublizing them with denaturants and dialyzing them in appropriate buffers, this being followed by chromatography of the refolded fractions on a metal-ion chelating column. These purified FVIII fusion peptides were used individually or as a pool to immunize mice and generate antibodies. Three monoclonal antibodies, D2, E6 and B12, were obtained. D2 recognizes a region (residues 1680-1703) of the light chain of FVIII, E6 recognizes a fragment (residues 744-1021) in the heavy chain, and B12, the A1 domain (residues 89-326). Both D2 and B12 inhibited >80% FVIII function. The affinities (k(A)) of the antibodies for FVIII were 1.62x10(7) M(-1) for D2 and 2.2x10(8) M(-1) for E6. Although B12 is inhibitory, it did not show a strong binding affinity with FVIII. The specificity of D2 and E6 for FVIII was demonstrated by immunoprecipitation of the FVIII protein in full-length recombinant FVIII (rFVIII) supplemented FVIII-deficient plasma, but not in FVIII-deficient plasma alone. An enzyme-linked immunosorbant assay (ELISA) using D2 or E6 was designed to detect plasma FVIII. The system may be useful in monitoring FVIII in cultured supernatants and in mouse models for gene therapy experiments.
Porcine factor V: cDNA cloning, gene mapping, three-dimensional protein modeling of membrane binding sites and comparative anatomy of domains.
Factor V is a plasma protein essential for blood coagulation. This protein is involved in activated protein C resistance, the most common inherited thrombotic disorder known. We utilized the polymerase chain reaction to clone the porcine factor V gene by generating overlapping clones amplified with primers chosen by comparison with known nucleotide sequences. The porcine factor V cDNA contig encodes a predicted 2258-amino acid protein, making it the largest in comparison to the bovine, human, and murine proteins. Porcine factor V has the highest level of homology with bovine factor V, but also has high levels of conservation of important residues with all the species. Radiation hybrid mapping assigned the porcine factor V gene to chromosome 4. Three-dimensional models of factor V were generated and used to analyze membrane-binding sites in terms of conserved, and therefore likely important residues.
Antigenicity of putative phospholipid membrane-binding residues in factor VIII.
Most inhibitory antibodies to human factor VIII (fVIII) bind to epitopes in the A2, ap-A3, or C2 domains. The anticoagulant action of antibodies to the C2 domain is due to inhibition of binding of fVIII to phospholipid. The x-ray structure of the human fVIII C2 domain shows a putative hydrophobic, 3-prong, phospholipid membrane-binding site consisting of Met2199/Phe2200, Val2223, and Leu2251/Leu2252. Additionally, Lys2227, near Val2223, is part of a ring of positively charged residues that may contribute to electrostatic interaction of fVIII with negatively charged phosphatidylserine. In this study, 8 active mutants of human fVIII (Met2199Ile, Leu2252Phe, Phe2200Leu, Val2223Ala, Lys2227Glu, Met2199Ile/Phe2200Leu, Val2223Ala/Lys2227Glu, and Met2199Ile/Phe2200Leu/Val2223Ala/Lys2227Glu), which were constructed on the basis of differences between human, porcine, murine, and canine fVIII at proposed phospholipid binding sites, were expressed. The antigenicity of the mutants toward 5 C2-specific polyclonal human antibodies was measured by using the Bethesda assay. A human monoclonal anti-C2 antibody, BO2C11, and a murine C2-specific monoclonal antibody, NMC VIII-5, were also included in the analysis. In comparison with wild-type, B-domainless fVIII, the Met2199Ile, Phe2200Leu, and Leu2252 single mutants had lower antigenicity toward most of the inhibitors. In contrast, the Val2223Ala and Lys2227Glu mutants usually showed increased antigenicity. These results suggest that C2 inhibitors frequently target the Met2199/Phe2200 and Leu2251/Leu2252 beta-hairpins and are consistent with the hypothesis that these residues participate in binding to phospholipid membranes. In contrast, Val2223 and Lys2227 may oppose antibody binding sterically or through stabilization of a low-affinity membrane-binding conformation of the C2 domain.
Soluble phosphatidylserine binds to a single identified site in the C2 domain of human factor V(a).
Factor V(a) (FV(a)) is a cofactor for the serine protease factor X(a) that activates prothrombin to thrombin in the presence of Ca(2+) and a membrane surface. FV(a) is a heterodimer composed of one heavy chain (A1 and A2 domains) and one light chain (A3, C1, and C2 domains). We use fluorescence, circular dichroism, and equilibrium dialysis to demonstrate that (1) the FV C2 domain expressed in Sf9 cells binds one molecule of C6PS with a k(d) of approximately 2 microM, (2) stabilizing changes occur in the FV C2 domain upon C6PS binding, (3) the C6PS binding site in the FV C2 domain is located near residue Cys(2113), which reacts with DTNB, and (4) binding to a PS-containing membrane is an order of magnitude tighter than that to soluble C6PS. Coupled with a recently published crystal structure of the C2 domain, these results support a model for the mechanism of C2-membrane interaction.
Factor VIII C2 domain contains the thrombin-binding site responsible for thrombin-catalyzed cleavage at Arg1689.
Thrombin-catalyzed factor VIII activation is an essential positive feedback mechanism regulating intrinsic blood coagulation. A factor VIII human antibody, A-FF, with C2 epitope, exclusively inhibited factor VIII activation and cleavage at Arg(1689) by thrombin. The results suggested that A-FF prevented the interaction of thrombin with factor VIII and that the C2 domain was involved in the interaction with thrombin. We performed direct binding assays using anhydro-thrombin, a catalytically inactive derivative of thrombin in which the active-site serine is converted to dehydroalanine. Intact factor VIII, 80-kDa light chain, 72-kDa light chain, and heavy chain fragments bound dose-dependently to anhydro-thrombin, and the K(d) values were 48, 150, 106, and 180 nm, respectively. The C2 and A2 domains also dose-dependently bound to anhydro-thrombin, and the K(d) values were 440 and 488 nm, respectively. The A1 domain did not bind to anhydro-thrombin. A-FF completely inhibited C2 domain binding to anhydro-thrombin (IC(50), 18 nm), whereas it did not inhibit A2 domain binding. Furthermore, C2-specific affinity purified F(ab)'(2) of A-FF, and the recombinant C2 domain inhibited thrombin cleavage at Arg(1689). Our results indicate that the C2 domain contains the thrombin-binding site responsible for the cleavage at Arg(1689).
How much factor V is enough?
Identification of functionally important amino acid residues within the C2-domain of human factor V using alanine-scanning mutagenesis.
We have previously determined that the C2-domain of human factor V (residues 2037-2196) is required for expression of cofactor activity and binding to phosphatidylserine (PS)-containing membranes. Naturally occurring factor V inhibitors and a monoclonal antibody (HV-1) recognized epitopes in the amino terminus of the C2-domain (residues 2037-2087) and blocked PS binding. We have now investigated the function of individual amino acids within the C2-domain using charge to alanine mutagenesis. Charged residues located within the C2-domain were changed to alanine in clusters of 1-3 mutations per construct. In addition, mutants W2063A, W2064A, (W2063, W2064)A, and L2116A were constructed as well. The resultant 30 mutants were expressed in COS cells using a B-domain deleted factor V construct (rHFV des B). All mutants were expressed efficiently based on the polyclonal antibody ELISA. The charged residues, Arg(2074), Asp(2098), Arg(2171), Arg(2174), and Glu(2189) are required for maintaining the structural integrity of the C2-domain of factor V. Four of these residues (Arg(2074), Asp(2098), Arg(2171), and Arg(2174)) correspond to positions in the factor VIII C-type domains that have been identified as point mutations in patients with hemophilia A. The epitope for the inhibitory monoclonal antibody HV-1 has been localized to Lys(2060) through Glu(2069) in the factor V C2-domain. The epitope for the inhibitory monoclonal antibody 6A5 is composed of amino acids His(2128) through Lys(2137). The PS-binding site in the factor V C2-domain includes amino acid residues Trp(2063) and Trp(2064). This site overlaps with the epitope for monoclonal antibody HV-1. These factor V C2-domain mutants should provide valuable tools for further defining the molecular interactions responsible for factor V binding to phospholipid membranes.
Role of the low density lipoprotein-related protein receptor in mediation of factor VIII catabolism.
In the present study, we found that catabolism of coagulation factor VIII (fVIII) is mediated by the low density lipoprotein receptor-related protein (LPR), a liver multiligand endocytic receptor. In a solid phase assay, fVIII was shown to bind to LRP (K(d) 116 nM). The specificity was confirmed by a complete inhibition of fVIII/LRP binding by 39-kDa receptor-associated protein (RAP), an antagonist of all LRP ligands. The region of fVIII involved in its binding to LRP was localized within the A2 domain residues 484-509, based on the ability of the isolated A2 domain and the synthetic A2 domain peptide 484-509 to prevent fVIII interaction with LRP. Since vWf did not inhibit fVIII binding to LRP, we proposed that LRP receptor may internalize fVIII from its complex with vWf. Consistent with this hypothesis, mouse embryonic fibroblasts that express LRP, but not fibroblasts genetically deficient in LRP, were able to catabolize (125)I-fVIII complexed with vWf, which was not internalized by the cells. These processes could be inhibited by RAP and A2 subunit of fVIII, indicating that cellular internalization and degradation were mediated by interaction of the A2 domain of fVIII with LRP. In vivo studies of (125)I-fVIII.vWf complex clearance in mice demonstrated that RAP completely inhibited the fast phase of the biphasic (125)I-fVIII clearance that is responsible for removal of 60% of fVIII from circulation. Inhibition of the RAP-sensitive phase prolonged the half-life of (125)I-fVIII in circulation by 3.3-fold, indicating that LRP receptor plays an important role in fVIII clearance.
Role of factor VIII C2 domain in factor VIII binding to factor Xa.
Factor VIII (FVIII) is activated by proteolytic cleavages with thrombin and factor Xa (FXa) in the intrinsic blood coagulation pathway. The anti-C2 monoclonal antibody ESH8, which recognizes residues 2248-2285 and does not inhibit FVIII binding to von Willebrand factor or phospholipid, inhibited FVIII activation by FXa in a clotting assay. Furthermore, analysis by SDS-polyacrylamide gel electrophoresis showed that ESH8 inhibited FXa cleavage in the presence or absence of phospholipid. The light chain (LCh) fragments (both 80 and 72 kDa) and the recombinant C2 domain dose-dependently bound to immobilized anhydro-FXa, a catalytically inactive derivative of FXa in which dehydroalanine replaces the active-site serine. The affinity (K(d)) values for the 80- and 72-kDa LCh fragments and the C2 domain were 55, 51, and 560 nM, respectively. The heavy chain of FVIII did not bind to anhydro-FXa. Similarly, competitive assays using overlapping synthetic peptides corresponding to ESH8 epitopes (residues 2248-2285) demonstrated that a peptide designated EP-2 (residues 2253-2270; TSMYVKEFLISSSQDGHQ) inhibited the binding of the C2 domain or the 72-kDa LCh to anhydro-FXa by more than 95 and 84%, respectively. Our results provide the first evidence for a direct role of the C2 domain in the association between FVIII and FXa.
Identification of a factor VIII peptide, residues 2315-2330, which neutralizes human factor VIII C2 inhibitor alloantibodies: requirement of Cys2326 and Glu2327 for maximum effect.
Factor VIII (FVIII) inhibitor alloantibodies react with combinations of the A2, C2 and A3-C1 domains of the FVIII molecule. Some inhibitors block binding of FVIII to both von Willebrand factor (VWF) and phospholipid, and recognize a C2 domain epitope which overlaps both binding sites. In order to determine the essential binding regions for alloantibodies inhibitory for FVIII activity, we have performed inhibitor neutralization assays and competitive inhibition assays using 10 overlapping synthetic peptides spanning the carboxy-terminal region of the C2 domain (residues 2288-2332). We found one peptide (2315-2330, L9) which neutralized the anti-FVIII activity of four out of five different C2 alloantibodies by 50%, 39%, 47% and 57%, respectively. Neutralization of these alloantibodies by recombinant C2 domain (residues 2173-2332) was 68%, 50%, 59%, 86% and >95%, respectively. The inhibitor which was not neutralized by L9 peptide and reacted by immunoblotting with peptide 2218-2307, did not prevent binding of FVIII to VWF and only partially inhibited binding of FVIII to phosphatidylserine. Mutants of the L9 peptide were prepared in which each residue from 2315-2330 was sequentially substituted by glycine. Inhibitor neutralization experiments using these peptides demonstrated that Arg2320 and Cys2326 or Glu2327 are important for the effect of L9 peptide, since their substitution by glycine reduced its neutralizing effect by 60% to >90%, suggesting that they are crucial for formation of the one of the C2 inhibitor epitopes.
Peptide affinity chromatography of human clotting factor VIII. Screening of the vWF-binding domain.
The region of von Willebrand factor, which is involved in the complex formation with factor VIII, was used to generate a panel of octapeptides. A peptide ladder was generated from the von Willebrand factor region aa40 to aa100 and was synthesized on cellulose membranes by spot technology. Four peptides with affinity for factor VIII were identified by incubation with plasma derived factor VIII and recombinant factor VIII. The peptides denoted as 010 (LCPPGMVRHE), 011 (RCPCFHQGK), 014 (CFHQGKEYA) and 015 (RDRKWNCTDHVC) were further characterized by real-time interaction analysis and small scale affinity chromatography. Biotinylated peptides were used for blotting assays. These experiments showed that the peptides are directed against the light chain of FVIII. We consider these peptides as valuable tools for in situ labeling and also as ligands suitable for affinity chromatography.
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.
The structure and function of murine factor V and its inactivation by protein C.
Factor V (FV) is a central regulator of hemostasis, serving both as a critical cofactor for the prothrombinase activity of factor Xa and the target for proteolytic inactivation by the anticoagulant, activated protein C (APC). To examine the evolutionary conservation of FV procoagulant activity and functional inactivation by APC, we cloned and sequenced the coding region of murine FV cDNA and generated recombinant wild-type and mutant murine FV proteins. The murine FV cDNA encodes a 2,183-amino acid protein. Sequence comparison shows that the A1-A3 and C1-C2 domains of FV are highly conserved, demonstrating greater than 84% sequence identity between murine and human, and 60% overall amino acid identity among human, bovine, and murine FV sequences. In contrast, only 35% identity among all three species is observed for the poorly conserved B domain. The arginines at all thrombin cleavage sites and the R305 and R504 APC cleavage sites (corresponding to amino acid residues R306 and R506 in human FV) are invariant in all three species. Point mutants were generated to substitute glutamine at R305, R504, or both (R305/R504). Wild-type and all three mutant FV recombinant proteins show equivalent FV procoagulant activity. Single mutations at R305 or R504 result in partial resistance of FV to APC inactivation, whereas recombinant murine FV carrying both mutations (R305Q/R504Q) is nearly completely APC resistant. Thus, the structure and function of FV and its interaction with APC are highly conserved across mammalian species.
The evaluation of factor VIII binding activity of von Willebrand factor by means of an ELISA method: significance and practical implications.
One of the functions of von Willebrand factor (vWF) is to serve as a carrier of clotting factor VIII (FVIII). Deficiency of this function results in the von Willebrand disease (vWD) variant type 2N, which resembles hemophilia A. We describe a new sandwich enzyme-linked immunosorbent assay (ELISA) to study the ability of vWF to bind exogenous recombinant FVIII (rFVIII), in which anti-vWF-coated plates are incubated with plasma vWF, followed by exogenous FVIII and a peroxidase-coupled anti-FVIII antibody. Dose-response curves obtained using normal plasma vWF and purified normal vWF revealed a hyperbolic relationship between the optical density and the vWF concentration. The assay allows the quantification of FVIII binding with values expressed in U/dL; 100 U/dL was the amount present in normal plasma. The sensitivity and specificity of the method are demonstrated by its ability to measure binding levels as low as 1 to 2 U/dL and the fact that no FVIII binding was observed using plasma known to contain less than 1 U/dL vWF. To verify the accuracy of the assay, three patients with type 2N vWD with characterized vWF gene mutations were studied using an existing chromogenic assay and our ELISA. A patient who was homozygous for the R53W mutation and had no FVIII binding capacity according to the chromogenic method showed undetectable FVIII binding by ELISA. The remaining two patients, one who was homozygous for the R91Q mutation and one with compound heterozygosity for the R91Q and R53W mutations, showed markedly decreased FVIII binding by the chromogenic method and yielded ELISA values ranging from 4 to 8 U/dL. Therefore, although the two methods produce qualitatively similar results, the ELISA method offers the advantage of allowing quantification of the FVIII binding function. FVIII binding was also analyzed in 20 patients with type 1 vWD; we found a decrease of FVIII binding that was proportionate to the decrease in vWF levels, showing a normal FVIII binding activity/vWF molecule ratio. We define the binding activity measured by this assay as vWF:FVIII binding activity and propose its use in the functional analysis of vWF.
Neoantigens and antibodies to factor VIII.
It is well known that 10-20% of severe haemophiliacs are likely to develop inhibitors to factor VIII, usually soon after the commencement of therapy. Two recent inhibitor outbreaks have occurred in patients treated for a number of years on switching to a product subjected to additional virus inactivation. Hence the incidence of inhibitor formation may be affected by the type of product used for treatment and the potential for processing to result in 'neoantigens'. Examination of the parts of factor VIII interacting with inhibiting antibodies, and the effect of various therapies on these, can teach us something about the mechanisms involved in antibody formation. However, the development of pre-clinical assays to assess products and processes for neoantigen formation should allow the prevention of inhibitor outbreaks. This review summarizes current in vitro and in vivo approaches to this problem, concluding that most available assays are inadequate for this purpose, with competitive immunoassay and phospholipid binding providing the most hopeful route forward.
Factor VIII Ise (R2159C) in a patient with mild hemophilia A, an abnormal factor VIII with retention of function but modification of C2 epitopes.
We found a patient with mild hemophilia A who had no detectable factor VIII antigen (FVIII:Ag), as shown by two-site ELISA using inhibitor alloantibodies (TK). We then analyzed A2, A2/B, and C2 antigen of the patient's DDAVP-induced FVIII using several anti-FVIII monoclonal antibodies. Factor VIII activity (FVIII:C) was increased from 12 to 42 U/dl by the administration of DDAVP. The DDAVP-induced increases in the A2 and A2/B antigens were 40 and 36 U/dl, respectively. However, the increase in the C2 antigen was only 7.5 U/dl. SSCP analysis and subsequent sequencing demonstrated an Arg to Cys transition at codon 2159. The anti-FVIII:C titer of monoclonal antibody, NMC-VIII/5 which recognized the C2 domain, against normal plasma was 450 Bethesda U/mg of IgG. However, the titer against DDAVP-treated patient's plasma was only 15 Bethesda U/mg. We also tested DDAVP-induced increase in the FVIII:Ag in another mild hemophilia A patient with the same mutation at Arg2159. Increase in his C2 antigen levels was only 19% of those in the A2 and A2/B antigen. We designate this abnormal FVIII as FVIII Ise. Our results show that a missense mutation at Arg2159 to Cys modifies the antigenicity of the C2 domain.
Factor VIII inhibitor antibodies with C2 domain specificity are less inhibitory to factor VIII complexed with von Willebrand factor.
In order to clarify the potential role of von Willebrand factor (vWf) in attenuating the inactivation of factor VIII (fVIII) by those antibodies with C2 domain specificity, we investigated a panel of 14 human antibodies to fVIII. Immunoblotting analysis localized light chain (C2 domain) epitopes for four cases, heavy chain (A2 domain) epitopes in five cases, while the remaining five cases were both light and heavy chains. The inhibitor titer was considerably higher for Kogenate, a recombinant fVIII concentrate, than for Haemate P, a fVIII/vWf complex concentrate, in all inhibitor plasmas that had C2 domain specificity. In five inhibitor plasmas with A2 domain specificity and in five with both A2 and C2 domain specificities, Kogenate gave titers similar to or lower than those with Haemate P. The inhibitory effect of IgG of each inhibitor plasma was then compared with recombinant fVIII and its complex with vWf. When compared to the other 10 inhibitor IgGs, IgG concentration, which inhibited 50% of fVIII activity (IC50), was remarkably higher for the fVIII/vWf complex than for fVIII in all the inhibitor IgGs that had C2 domain reactivity. Competition of inhibitor IgG and vWf for fVIII binding was observed in an ELISA system. In 10 inhibitors that had C2 domain reactivity, the dose dependent inhibition of fVIII-vWf complex formation was observed, while, in the group of inhibitors with A2 domain specificity, there was no inhibition of the complex formation except one case. We conclude that a subset of fVIII inhibitors, those that bind to C2 domain determinants, are less inhibitory to fVIII when it is complexed with vWf that binds to overlapping region in the C2 domain.
The sequence Glu1811-Lys1818 of human blood coagulation factor VIII comprises a binding site for activated factor IX.
In previous studies have shown that the interaction between factor IXa and VIII involves the light chain of factor VIII and that this interaction inhibited by the monoclonal antibody CLB-CAg A against the factor VIII region Gln1778-Asp1840 (Lenting, P.J., Donath, M.J.S.H., van Mourik, J.A., and Mertens, K. (1994) J. Biol. Chem. 269, 7150-7155). Employing distinct recombinant factor VIII fragments, we now have localized the epitope of this antibody more precisely between the A3 domain residues Glu1801 and Met1823. Hydropathy analysis indicated that this region is part of a major hydrophilic exosite within the A3 domain. The interaction of factor IXa with this exosite was studied by employing overlapping synthetic peptides encompassing the factor VII region Tyr1786-Ala1834. Factor IXa binding was found to be particularly efficient to peptide corresponding to the factor VIII sequences Lys1804-Lys1818 and Glu1811-Gln1820. The same peptides proved effective in binding antibody CLB-CAg A. Further analysis revealed that peptides Lys1804-Lys1818 and Glu1811-Gln1820 interfere with binding of factor IXa to immobilized factor VIII light chain (Ki approximately 0.2 mM and 0.3 mM, respectively). Moreover, these peptides inhibit factor X activation by factor IXa in the presence of factor VIIIa (Ki approximately 0.2 mM and 0.3 mM, respectively) but not in its absence. Equilibrium binding studies revealed that these two peptides bind to the factor IX zymogen and its activated form, factor IXa, with the same affinity (apparent Kd approximately 0.2 mM), whereas the complete factor VIII light chain displays preferential binding to factor IXa. In conclusion, our results demonstrate that peptides consisting of the factor VIII light chain residues Lys1804-Lys1818 and Glu1811-Gln1820 share a factor IXa binding site that is essential for the assembly of the factor X-activating factor IXa-factor VIIIa complex. We propose that the overlapping sequence Glu1811-Lys1818 comprises the minimal requirements for binding to activated factor IX.
Slowed release of thrombin-cleaved factor VIII from von Willebrand factor by a monoclonal and a human antibody is a novel mechanism for factor VIII inhibition.
The anti-factor VIII (fVIII) C2 domain monoclonal antibody ESH8 inhibits fVIII activity only when fVIII is bound to von Willebrand factor (vWf). However, ESH8 binds with similar affinity to fVIII and fVIII.vWf complex, and it does not affect the kinetics of thrombin cleavage at positions 372 and 740 within the fVIII heavy chain and at 1689 within the light chain. The latter is required for fVIII release from vWf. We showed that ESH8 reduced the initial rate of thrombin-activated fVIII (fVIIIa) release from vWf by 4.3-fold compared to that in the absence of antibody. The complex of vWf. fVIII.ESH8 was activated, and the rate constant determined for fVIIIa dissociation from vWf was 4 x 10(-3) s-1. We constructed a mathematical model incorporating the measured rates for fVIIIa release from vWf and for inactivation of heterotrimeric fVIIIa due to the spontaneous loss of the A2 subunit and found that the decreased release rate is sufficient to explain our experimentally observed inhibition of fVIII activity by ESH8. We hypothesize that the slowed rate of fVIIIa release from vWf in the presence of ESH8 allows time for inactivation of unstable fVIIIa prior its participation in the formation of the factor Xase complex. The relevance of these findings is illustrated by our observation that reduction of fVIIIa release from vWf represents an additional mechanism of fVIII inhibition by an anti-C2 domain antibody (epitope 2218-2307) from a hemophilia A patient. This rare antibody binds to a more amino-terminal epitope than other human anti-C2 inhibitors, resulting in its lack of inhibition of fVIII binding to vWf but not to phospholipid. These two fVIII ligands therefore bind to C2 sites which do not overlap completely.
The cDNA and derived amino acid sequence of porcine factor VIII.
The cDNA corresponding to 137 bp of the 5' untranslated region, the signal peptide, and the A1, A3, C1, and C2 domains of porcine factor VIII (fVIII) have been cloned and sequenced. Along with previously determined sequences of the porcine fVIII B domain and the A2 domain, this completes the sequence determination of the cDNA corresponding to the translated protein. Alignments of the derived amino acid sequence of porcine fVIII with human and murine fVIII indicate that the A1, A2, A3, C1, and C2 domains are more conserved than the B domains or the proteolytic cleavage peptides corresponding to residues 337-372 and 1649-1689. The knowledge of the porcine fVIII cDNA may be useful to understand functional and immunological differences between human and porcine fVIII and may lead to improved fVIII replacement products for hemophilia. A patients through the development of recombinant porcine fVIII or hybrid human/porcine fVIII derivatives.
Effect of heterologous factor V heavy chain sequences on the secretion of recombinant human factor VIII.
Factor VIII and factor V share a repetitive domain structure of A1-A2-B-A3-C1-C2. To define the region(s) within the factor VIII heavy chain that result in inefficient expression of the recombinant protein, we expressed a series of factor VIII/factor V chimeras that contained heterologous sequences from the A1 and/or A2 domains. Substitution of the factor VIII A1 domain dramatically reduced secretion of factor V approximately 500-fold, whereas substitution of the factor VIII A2 domain had minimal effect on secretion. Conversely, substitution of the factor V A1 domain increased secretion of factor VIII approximately 3-fold, whereas substitution of the factor V A2 domain actually reduced secretion approximately 4-fold. Pulse chase experiments confirmed that reduced expression levels were due to decreased secretion rather than instability of secreted protein. Smaller substitutions did not further localize within the A1 domain the regions responsible for inefficient secretion.
Amino acid residues 721-729 are required for full factor VIII activity.
Recombinant two-chain factor VIII, from which the B domain had been deleted, was expressed in Chinese hamster ovary cells. In addition to the major product, three minor factor VIII forms were isolated. The A2 domains generated by thrombin cleavage showed different electrophoretic mobilities. Peptide mapping of the A2 domains showed that two of the factor VIII forms had the expected C-terminus of the heavy chain at Arg740 [FVIII-(1-740)] and that the other factor VIII forms had C-termini at Tyr729 [FVIII-(1-729)] or Glu720 [FVIII-(1-720)]. The major FVIII-(1-740) form, FVIII-(1-729), and FVIII-(1-720) contained sulfated tyrosine residues at Tyr718, Tyr719 and Tyr723. The minor FVIII-(1-740) form was shown to lack sulfation at these positions. The specific clotting activity was approximately 1 x 10(4) U/mg for FVIII-(1-740) (both forms) and FVIII-(1-729), but twofold lower for FVIII-(1-720). A time study of thrombin activation showed that FVIII-(1-720) was activated slower than FVIII-(1-740), FVIII-(1-729) and plasma-derived factor VIII. Partially sulfated FVIII-(1-740) was activated at the same rate as the fully sulfated FVIII-(1-740). The equilibrium dissociation constant for binding of factor VIII to inactivated immobilized thrombin was the same for all factor VIII forms, showing that the slower activation of FVIII-(1-720) was not due to a lower affinity for the anion-binding exosite in thrombin.
Structure and function of Factor VIII.
The factor V B-domain provides two functions to facilitate thrombin cleavage and release of the light chain.
Influence of factor V and factor Va on APC-induced cleavage of human factor VIII.
Locations of disulfide bonds and free cysteines in the heavy and light chains of recombinant human factor VIII (antihemophilic factor A).
The locations of disulfide bonds and free cysteines in the heavy and light chains of recombinant human factor VIII were determined by sequence analysis of fragments produced by chemical and enzymatic digestions. The A1 and A2 domains of the heavy chain and the A3 domain of the light chain contain one free cysteine and two disulfide bonds, whereas the C1 and C2 domains of the light chain have one disulfide bond and no free cysteine. The positions of these disulfide bonds are conserved in factor V and ceruloplasmin except that the second disulfide bond in the A3 domain is missing in both factor V and ceruloplasmin. The positions of the three free cysteines of factor VIII are the same as three of the four cysteines present in ceruloplasmin. However, the positions of the free cysteines in factor VIII and ceruloplasmin are not conserved in factor V.
A 110-amino acid region within the A1-domain of coagulation factor VIII inhibits secretion from mammalian cells.
Factor VIII is the coagulation factor deficient in the X-chromosome-linked bleeding disorder hemophilia A. Factor VIII is homologous to blood coagulation factor V, both having a domain structure of A1-A2-B-A3-C1-C2. Previous transfection studies demonstrated that factor VIII is 10-fold less efficiently expressed than the homologous coagulation factor, factor V. The inefficient expression correlated with interaction of the factor VIII primary translation product with the protein chaperonin BiP in the lumen of the endoplasmic reticulum. In contrast, factor V was not detected in association with BiP and was secreted efficiently. To determine whether specific amino acid sequences within factor VIII inhibit secretion, we have studied the secretion of factor VIII deletion and factor VIII/factor V chimeric proteins upon transient transfection of COS-1 monkey cells. A chimeric factor VIII protein that contained the A1- and A2-domains of factor V was secreted with a similar efficiency as wild-type factor V, whereas the complementary chimera having the A1- and A2-domains of factor VIII was secreted with low efficiency, similar to wild-type factor VIII. These results suggested that sequences within the A1- and A2-domains were responsible for the low secretion efficiency of factor VIII. Secretion of A1-domain-deleted factor VIII was increased approximately 10-fold compared to wild-type factor VIII or A2-domain-deleted factor VIII. Expression of the factor VIII A1-domain alone did not yield secreted protein, whereas expression of the factor VIII A2-domain alone or the factor V A1-domain or A2-domain alone directed synthesis of secreted protein. Secretion of a hybrid in which the carboxyl-terminal 110 amino acids of the A1-domain were replaced by homologous sequences from the factor V A1-domain was also increased 10-fold compared to wild-type factor VIII, however, the secreted protein was not functional and the heavy and light chains were not associated. These results localize a 110-amino acid region within the A1-domain that inhibits factor VIII secretion. This region is clustered with multiple short peptide sequences that have potential to bind BiP.
Common inhibitory effects of human anti-C2 domain inhibitor alloantibodies on factor VIII binding to von Willebrand factor.
Factor VIII (FVIII) inhibitor alloantibodies obtained from seven severe haemophilia A patients were examined for their binding regions and their effects on FVIII binding to von Willebrand factor (vWF). Immunoblotting analysis with a panel of recombinant fragments demonstrated that the binding regions of antibodies in cases 1-5 were contained in the C2 domain of the light chain. Antibodies from cases 1 and 2, which recognized an epitope within residues 2248-2312, completely inhibited FVIII/vWF binding in an ELISA (IC50: 5.0 and 9.0 micrograms/ml, respectively). Antibodies from case 3 recognizing 2170-2312 and case 5 recognizing 2170-2327 also inhibited FVIII/vWF binding (IC50: 110 and 400 micrograms/ml, respectively). Case 4 antibodies recognizing 2218-2307 showed barely detectable inhibition and cases 6 and 7 antibodies recognizing the 44 kD heavy chain, did not inhibit. Our results demonstrate that all anti-C2 alloantibodies with epitopes that extend to the residue 2312 inhibit vWF binding and that an overlap of the inhibitor epitope with residues 2308-2312 is critical for maximal inhibition of vWF binding. Prevention of FVIII/vWF binding appears to be a common property of anti-C2 domain inhibitor alloantibodies.
A mechanism for inhibition of factor VIII binding to phospholipid by von Willebrand factor.
von Willebrand factor (vWf) acts as a carrier for blood coagulation factor VIII (fVIII) in the circulation. The amino-terminal 272 residues of mature vWf contain a high affinity fVIII binding site. Upon thrombin activation, fVIII is released from vWf, thereby allowing its binding to phospholipid which is required for its procoagulant activity. Although phospholipid and vWf compete for fVIII binding, it was previously suggested that their binding sites are not closely juxtaposed within the fVIII protein because only amino-terminal vWf proteolytic fragments larger than SPIII-T4 (1-272) were able to block the binding of fVIII to phospholipid. We have demonstrated, however, that SPIII-T4 is able to inhibit fVIII binding to phosphatidylserine (PS) in a dose-dependent fashion, but only at concentrations higher than those used in previous experiments. Our demonstration that the Kd values for vWf and SPIII-T4 for fVIII are 0.52 nM and 48 nM, respectively, explain this discrepancy. Inhibition (> 95%) of SPIII-T4 binding to fVIII by a purified recombinant fVIII C2 domain polypeptide demonstrated that SPIII-T4 binds directly to C2, as we had previously shown for vWf. The similarity of the C2 binding sites for vWf and SPIII-T4 was further confirmed by the identical inhibitory effects of synthetic peptides and monoclonal antibodies (mAbs) on vWf-fVIII or SPIII-T4 fVIII binding. In both cases, binding was inhibited by synthetic peptide 2303-2332, containing a PS binding site, and by mAb NMC-VIII/5 Fab' (epitope within C2 residues 2170-2327). We propose that vWf, via residues 1-272, and PS compete for fVIII binding because they recognize overlapping sites within fVIII C2 domain residues 2303-2332.
Some factor VIII inhibitor antibodies recognize a common epitope corresponding to C2 domain amino acids 2248 through 2312, which overlap a phospholipid-binding site.
The finding that human factor VIII (fVIII) inhibitor antibodies with C2 domain epitopes interfere with the binding of fVIII to phosphatidylserine (PS) suggested that this is the mechanism by which they inactivate fVIII. We constructed a recombinant C2 domain polypeptide and demonstrated that it bound to all six human inhibitors with fVIII light chain specificity. Thus, some antibodies within the polyclonal anti-light chain population require only amino acids within C2 for binding. Recombinant C2 also partially or completely neutralized the inhibitor titer of these plasmas, demonstrating that anti-C2 antibodies inhibit fVIII activity. Immunoblotting of a series of C2 deletion polypeptides, expressed in Escherichia coli, with inhibitor plasmas showed that the epitopes for human inhibitors consist of a common core of amino acid residues 2248 through 2312 with differing extensions for individual inhibitors. The epitope of inhibitory monoclonal antibody (MoAb) ESH8 was localized to residues 2248 through 2285. Three human antibodies and anti-C2 MoAb NMC-VIII/5 bound to a synthetic peptide consisting of amino acids 2303 through 2332, a PS-binding site, but MoAb ESH8 did not. These antibodies also inhibited the binding of fVIII to synthetic phospholipid membranes of PS and phosphatidylcholine, confirming that the blocked epitopes contribute to membrane binding as well as binding to PS. In contrast, MoAb ESH8 did not inhibit binding. As the maximal function of activated fVIII in the intrinsic factor Xase complex requires its binding to a phospholipid membrane, we propose that fVIII inhibition by anti-C2 antibodies is related to the overlap of their epitopes with the PS-binding site. MoAb ESH8 did not inhibit fVIII binding to PS-containing membranes, suggesting the existence of a second mechanism of fVIII inhibition by anti-C2 antibodies.
Residues 484-508 contain a major determinant of the inhibitory epitope in the A2 domain of human factor VIII.
The A2 domain (residues 373-740) of human blood coagulation factor VIII (fVIII) contains a major epitope for inhibitory alloantibodies and autoantibodies. We took advantage of the differential reactivity of inhibitory antibodies with human and porcine fVIII and mapped a major determinant of the A2 epitope by using a series of active recombinant hybrid human/porcine fVIII molecules. Hybrids containing a substitution of porcine sequence at segment 410-508, 445-508, or 484-508 of the human A2 domain were not inhibited by a murine monoclonal antibody A2 inhibitory, mAb 413, whereas hybrids containing substitutions at 387-403, 387-444, and 387-468 were inhibited by mAb 413. This indicates that the segment bounded by Arg484 and Ile508 contains a major determinant of the A2 epitope. mAb 413 did not inhibit two more hybrids that contained porcine substitutions at residues 484-488 and 489-508, indicating that amino acid side chains on both sides of the Ser488-Arg489 bond within the Arg484-Ile508 segment contribute to the A2 epitope. The 484-508, 484-488, and 489-508 porcine substitution hybrids displayed decreased inhibition by A2 inhibitors from four patient plasmas, suggesting that there is little variation in the structure of the A2 epitope in the inhibitor population.
Role of the B domain for factor VIII and factor V expression and function.
Factor V and factor VIII are homologous cofactors in the blood coagulation cascade that have the domain structure A1-A2-B-A3-C1-C2, of which the B domain has extensively diverged. In transfected COS-1 monkey cells, expression of factor VIII is approximately 10-fold less efficient than that of factor V, primarily because of inefficient protein secretion and, to a lesser extent, reduced mRNA expression. To study the functional significance and effect of the B domain on expression and activity, chimeric cDNAs were constructed in which the B domains of factor V and factor VIII were exchanged. Expression of a factor VIII chimera harboring the B-domain of factor V yielded a fully functional factor VIII molecule that was expressed twofold more efficiently than wild-type factor VIII because of increased mRNA expression. Thus, sequences within the factor VIII B domain were not responsible for the inefficient secretion of factor VIII compared with factor V. Expression of a factor V chimera harboring the B domain of factor VIII was slightly reduced compared with wild-type factor V, although the secreted molecule had significantly reduced procoagulant activity correlating with dissociated heavy and light chains and resistance to thrombin activation. Interestingly, the factor V chimera containing the factor VIII B domain was efficiently activated by Russell's viper venum (RVV). A factor V B domain deletion (residues 710-1545) molecule also exhibited significantly reduced procoagulant activity caused by resistance to thrombin cleavage and activation, although this molecule was activatable by RVV. These results show that, in contrast to factor VIII, thrombin activation of factor V requires sequences within the B domain. In addition, thrombin activation of factor V occurs through a different mechanism than activation by RVV.
Elimination of a major inhibitor epitope in factor VIII.
The A2 and C2 domains of human blood coagulation factor VIII (fVIII) contain the epitopes targeted by most inhibitory allo- and autoantibodies. Human inhibitors usually display limited or no reaction with porcine fVIII. We constructed an active, recombinant hybrid human/porcine fVIII molecule by replacing the putative human fVIII A2 domain epitope with the homologous porcine sequence. The hybrid retained full activity in the presence of antibodies with specificity restricted to the human A2 epitope. In contrast, the hybrid was neutralized by an anti-C2 antibody. These findings provide a basis for fine epitope mapping and for therapy of the inhibitor patient.
Localization of functionally important epitopes within the second C-type domain of coagulation factor V using recombinant chimeras.
Coagulation factor V, an integral component of the prothrombinase complex, possesses two C-type domains at the carboxyl-terminal end of the molecule. Homologous C-type domains are present in factor VIII as well as several non-coagulation proteins. Deletion of the second C-type domain of factor V results in the loss of procoagulant activity and the ability to bind phosphatidylserine. We now report the effect of substitution of all or a portion of the C2 domain of factor V with the corresponding regions of factor VIII or the human breast carcinoma protein BA46. Substitution of the entire domain with a heterologous C2 domain does not restore significant procoagulant activity, although smaller, exon-size substitutions do result in chimeras with partial activity (approximately 10% of factor Va). Using chimeras with partial substitutions, we determined that the amino-terminal region of the domain is involved in binding to phosphatidylserine. In contrast, the central region of the domain is not involved in phosphatidylserine binding, but an antibody binding at or near this site inhibits procoagulant activity, suggesting that this region is involved in a separate function. Lastly, the molecular basis for the light chain doublet, which is important in the expression of full procoagulant activity, is located within the carboxyl-terminal region of the C2 domain.
Expression of biologically active human factor VIII using a baculovirus vector.
Factor VIII is a complex, plasma glycoprotein involved in the process of blood coagulation. Production of the recombinant molecule has largely been confined to mammalian cell systems which have, in general, proven to be inefficient producers of factor VIII. The use of a baculovirus expression system may provide increased levels of this glycoprotein, although it is not certain that insect cell-derived factor VIII will be biologically active. The N-linked glycosylation patterns in insect cells, until recently thought to be less complex than in mammalian cells, may influence activity and/or secretory ability. To this end we engineered a B domain-deleted factor VIII cDNA sequence for expression in Spodoptera frugiperda cells. The construct retained the native signal sequence to allow secretion of recombinant protein into the culture medium. Initial studies revealed the production of secreted factor VIII, and this protein was shown to possess coagulation activity. The presence of N-linked oligosaccharide residues was demonstrated, the glycosylated molecule being of a similar size to that expressed in mammalian cells.
Sequence of the murine factor VIII cDNA.
DNA clones corresponding to the mouse homolog of the human factor VIII gene have been isolated and sequenced. The murine gene is expressed in most tissues examined and the mRNA is approximately 1.8 kb smaller than the human transcript, primarily due to a shorter 3' untranslated region. The mouse cDNA encodes a protein of 2319 amino acids, 32 amino acids shorter than human factor VIII, with 74% identity to the human sequence. Further comparison shows that amino acid sequences in the functionally important A and C domains are highly conserved (84-93% identity), whereas the B domains and the two acidic domains are more divergent (42-70% identity). All thrombin/factor Xa cleavages sites and all but one activated protein C cleavage site are conserved in mouse factor VIII, as well as a tyrosine residue needed for von Willebrand factor binding. These findings suggest that mouse factor VIII operates in the clotting cascade much like the human protein, but reveal some differences that may have functional significance.
A factor VIII neutralizing monoclonal antibody and a human inhibitor alloantibody recognizing epitopes in the C2 domain inhibit factor VIII binding to von Willebrand factor and to phosphatidylserine.
A neutralizing monoclonal antibody, NMC-VIII/5, recognizing the 72 kDa thrombin-proteolytic fragment of factor VIII light chain was obtained. Binding of the antibody to immobilized factor VIII (FVIII) was completely blocked by a light chain-specific human alloantibody, TK, which inhibits FVIII activity. Immunoblotting analysis with a panel of recombinant protein fragments of the C2 domain deleted from the amino-terminal or the carboxy-terminal ends demonstrated binding of NMC-VIII/5 to an epitope located between amino acid residues 2170 and 2327. On the other hand, the epitope of the inhibitor alloantibody, TK, was localized to 64 amino acid residues from 2248 to 2312 using the same recombinant fragments. NMC-VIII/5 and TK inhibited FVIII binding to immobilized von Willebrand factor (vWF). The IC50 of NMC-VIII/5 for the inhibition of binding to vWF was 0.23 micrograms/ml for IgG and 0.2 micrograms/ml for F(ab)'2. This concentration was 100-fold lower than that of a monoclonal antibody NMC-VIII/10 which recognizes the amino acid residues 1675 to 1684 within the amino-terminal portion of the light chain. The IC50 of TK was 11 micrograms/ml by IgG and 6.3 micrograms/ml by F(ab)'2. Furthermore, NMC-VIII/5 and TK also inhibited FVIII binding to immobilized phosphatidylserine. The IC50 for inhibition of phospholipid binding of NMC-VIII/5 and TK (anti-FVIII inhibitor titer of 300 Bethesda units/mg of IgG) was 10 micrograms/ml.
Sequence of the human factor VIII-associated gene is conserved in mouse.
cDNA and genomic clones corresponding to the human factor VIII-associated gene (F8A) were isolated from mouse cDNA and F8A-enriched genomic libraries. The sequences of these clones revealed an intronless gene coding for 380 amino acids, with 85% identity to the predicted human sequence. The single murine gene copy is genetically linked to factor VIII, but appears to lie outside the factor VIII gene by physical mapping. Like the human gene, the mouse F8A gene is highly expressed in a wide variety of tissues. This evolutionary comparison has helped to clarify the derived amino acid sequence in the human and strongly supports the hypothesis that the F8A gene encodes a protein.
Interaction of factor VIII with phospholipids: role of composition and negative charge.
Radiolabelled human anti-FVIII:C antibody was affinity-purified according to its ability to bind to factor VIII-phospholipid (FVIII-PL) complexes, yielding a fraction directed against the phospholipid binding-site (PL-site antibody). This antibody was used as a specific probe for FVIII binding to PL vesicles containing a variety of natural and synthetic PLs. Of purified PLs tested for FVIII binding, phosphatidyl serine (PS) and phosphatidic acid (PA) were highly active, phosphatidyl inositol (PI) much less so, and both phosphatidyl ethanolamine (PE) and phosphatidyl choline (PC) inactive: the apparent dissociation constant (Kd app) for FVIII binding to PS:PC vesicles showed a strong dependence on PS content. Free-flow electrophoresis of vesicles confirmed FVIII binding to PS:PC required both net negative charge and specific head-group: neither PS vesicles given a positive charge with stearylamine nor PC vesicles made negative with dicetyl phosphate bound FVIII. It is concluded that the negative charge required for FVIII binding must be presented on the phospholipid surface in the correct orientation: phosphatidyl serine supplies this charge in coagulant-active PL preparations.
The complete cDNA sequence of bovine coagulation factor V.
Lack of availability of a primary structure for bovine factor V has hindered detailed analysis of a vast majority of structure-function correlations on this molecule. To determine the primary structure of bovine factor V, we used liver mRNA as a template for the synthesis of three cDNA libraries. The sequences of seven overlapping cDNA clones infer two bovine factor V variants. Variant 1 results in a 6910-basepair (bp) cDNA including 103 bp of 5'-untranslated sequence, 6633 bp of coding sequence and 171 bp of 3'-untranslated sequence with a putative polyadenylation site. Variant 2 differs only in the size of the coding sequence (6618 bp). The open reading frame translates to factor V consisting of 2211 (or 2206) amino acids including a 28-amino acid signal peptide. Comparison of the amino acid sequences with human factor Va reveals 84% identity for the heavy and 86% for the light chains. In contrast, the B domain (connecting region) exhibits only 59% identity relative to the human molecule. The bovine B domain contains two repeats of a 14-amino acid structure that is contained only once in the human sequence. Bovine factor V lacks one of the nine amino acid repeats and one of the 17 amino acid repeats present in the human B domain. Factor V has little homology to the factor VIII molecule in the B domain. The 17-amino acid repeat missing in bovine factor V allows identification of an 18-amino acid sequence that is homologous to the B domain of human factor VIII. These 18 amino acids may either constitute the unique vestige of a divergent evolution between the B domains of factors V and VIII or reveal the convergent evolution toward a critical epitope involved in the activation of both procofactors.
Deletion analysis of recombinant human factor V. Evidence for a phosphatidylserine binding site in the second C-type domain.
Human coagulation factor V is an integral component of the prothrombinase complex. Rapid activation of prothrombin is dependent on the interactions of this nonenzymatic cofactor with factor Xa and prothrombin in the presence of calcium ions and a phospholipid or platelet surface. Factor V is similar structurally and functionally to the homologous cofactor, factor VIII, which interacts with factor IXa to accelerate factor X activation in the presence of calcium and phospholipids. Both of these cofactors, when activated, possess homologous heavy and light chains. Binding to anionic phospholipids is mediated by the light chains of these two cofactors. In bovine factor Va, a phosphatidylserine-specific binding site has been localized to the amino-terminal A3 domain of the light chain. In human factor VIII, on the other hand, a region within the carboxyl-terminal C2 domain of the light chain has been shown to interact with anionic phospholipids. We have constructed a series of recombinant deletion mutants lacking domain-size fragments of the light chain of human factor V (rHFV). These mutants are expressed and secreted as single-chain proteins by COS cells. Thrombin and the factor V activator from Russell's viper venom process these deletion mutants as expected. The light chain deletion mutants possess essentially no procoagulant activity, nor are they activated by treatment with factor V activator from Russell's viper venom. Deletion of the second C-type domain results in essentially complete loss of phosphatidylserine-specific binding whereas the presence of the C2 domain alone (rHFV des-A3C1, which lacks the A3 and C1 domains of the light chain) results in significant phosphatidylserine-specific binding. The presence of the A3 domain alone (rHFV des-C1C2) does not mediate binding to immobilized phosphatidylserine. Increasing calcium ion concentrations result in decreased binding of recombinant human factor V and the mutant rHFV des-A3C1 to phosphatidylserine, similar to previous studies with purified plasma factor V and phospholipid vesicles. These results indicate that human factor V, similar to human factor VIII, possesses a phosphatidylserine-specific binding site within the C2 domain of the light chain.
Structure of the gene for human coagulation factor V.
A soluble recombinant factor VIII fragment containing the A2 domain binds to some human anti-factor VIII antibodies that are not detected by immunoblotting.
Human factor VIII (fVIII) inhibitors are pathologic antibodies that inactivate fVIII. A cDNA clone was modified to encode fVIII amino acid residues 373-740 for expression in a baculovirus vector in insect cells. The encoded protein fragment H2 was produced as a soluble, secreted protein, and it was used to test inhibitor plasmas for the presence of antibodies that were not detected by immunoblotting. Seven of 13 inhibitors that bound only to the fVIII light chain by immunoblotting also bound to fragment H2 in an immunoprecipitation assay. Thus multi-chain inhibitor reactivity of inhibitors is more frequent than previously reported. One of these inhibitors was shown to share the epitope for other inhibitors that bind to H2 within amino acid residues 373-541 in immunoblotting assays. The sensitive immunoprecipitation assay described allows determination of relative H2 binding capacity of the total IgG and epitope localization of inhibitors that cannot be similarly characterized by immunoblotting.
Characterization of a factor VIII immunogenic site using factor VIII synthetic peptide 1687-1695 and rabbit anti-peptide antibodies.
A 9 amino acid peptide, Ser-Pro-Arg-Ser-Phe-Gln-Lys-Lys-Thr, corresponding to the clotting factor VIII (FVIII) sequence Ser1687-Thr1695, was synthesized in order to analyze a site on FVIII to which antibody inhibitors of FVIII may be directed. This sequence contained a thrombin cleavage site. It was predicted to be immunogenic because a Hopp-Woods hydrophilicity analysis of the amino acid sequence of FVIII showed it to be very hydrophilic, and it contained a proline. The HPLC-purified peptide was cleaved by thrombin at Arg1689-Ser1690, as determined by amino acid sequencing of the cleavage product. Thrombin which had been treated with a specific chloromethyl ketone inhibitor, did not cleave the peptide. Two rabbits immunized with the peptide/keyhole limpet hemocyanin conjugate generated FVIII inhibitory sera with titers of 5.4 and 4.8 Bethesda units. These rabbit anti-peptide antibodies reacted with a peptide/-BSA conjugate on immunodot blot analyses and with native, affinity-purified FVIII in Western blots. In competitive immunoradiometric assays, cryosupernatants of 38/82 patients with FVIII inhibitors reacted with the synthetic peptide. We conclude that FVIII peptide Ser1687-Thr1695 is cleaved by thrombin at the same peptide bond which is cleaved in FVIII, and the peptide contains a site to which patients' inhibitory antibodies can be directed.
A murine monoclonal anti-factor VIII inhibitory antibody and two human factor VIII inhibitors bind to different areas within a twenty amino acid segment of the acidic region of factor VIII heavy chain.
The factor VIII (FVIII) binding regions of the monoclonal anti-FVIII inhibitory antibody C5 and a human FVIII inhibitor antibody have previously been reported to be contained within amino acid residues 351-365 of FVIII. Localization of the binding regions of these two antibodies was based on their reactivity with four synthetic FVIII peptides. Nineteen synthetic FVIII peptides spanning the entire acidic region of the FVIII heavy chain have now been evaluated for the ability to inhibit the binding of C5 to FVIII in an ELISA assay. The smallest peptide tested that inhibited C5 binding to FVIII consisted of residues 351-361. Those peptides that were able to inhibit C5 binding in the ELISA assay were also able to neutralize the FVIII inhibitory activity of C5 in plasma. The FVIII inhibitory activity of two human FVIII inhibitor antibodies was also partially neutralized by peptides from this region. Evaluation of the pattern of peptides reactive with the three antibodies indicates that the binding regions of these antibodies are in very close proximity to each other, but are not identical. Their respective binding regions are contained within residues 351-361 (C5), 354-362 (inhibitor 1), and 342-354 (inhibitor 2). These results suggest that this 20 amino acid segment of the acidic region of the heavy chain of FVIII may be functionally important in the expression of FVIII procoagulant activity.
Expression and characterization of recombinant human factor V and a mutant lacking a major portion of the connecting region.
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.
A synthetic factor VIII peptide of eight amino acid residues (1677-1684) contains the binding region of an anti-factor VIII antibody which inhibits the binding of factor VIII to von Willebrand factor.
The monoclonal anti-factor VIII (FVIII) antibody C4 has previously been reported to inhibit the binding of purified FVIII to immobilized von Willebrand factor (vWF). The binding area of C4 was identified to be within fifteen amino acid residues (1670-1684) based on the ability of a synthetic FVIII peptide consisting of amino acid residues 1670-1684 to completely inhibit the binding of C4 to FVIII. We now report the further localization of the binding region of C4 to within eight amino acid residues (1677-1684) of FVIII light chain. Nine new overlapping FVIII peptides were synthesized based on the amino acid sequence of the acidic region of FVIII light chain and tested, along with seven previously tested peptides, for the ability to inhibit C4 binding to FVIII in an ELISA assay. Three synthetic FVIII peptides 1670-1684, 1675-1690, and 1677-1684 demonstrated dose dependent inhibition of C4 binding to FVIII. The three reactive peptides contain residues 1677-1684 in common. Since C4 can completely inhibit the binding of FVIII to vWF, this report further localizes an eight amino acid residue region of FVIII which may be important in the mediation of vWF binding.
The interaction between human blood-coagulation factor VIII and von Willebrand factor. Characterization of a high-affinity binding site on factor VIII.
The interaction between human Factor VIII and immobilized multimeric von Willebrand Factor (vWF) was characterized. Equilibrium binding studies indicated the presence of multiple classes of Factor VIII-binding sites on vWF. The high-affinity binding (Kd = 2.1 x 10(-10) M) was restricted to only 1-2% of the vWF subunits. Competition studies with monoclonal antibodies with known epitopes demonstrated that the Factor VIII sequence Lys1673-Arg1689 is involved in the high-affinity interaction with vWF.
Blood coagulation factors V and VIII: structural and functional similarities and their relationship to hemorrhagic and thrombotic disorders.
Localization of the binding regions of a murine monoclonal anti-factor VIII antibody and a human anti-factor VIII alloantibody, both of which inhibit factor VIII procoagulant activity, to amino acid residues threonine351-serine365 of the factor VIII heavy chain.
We have localized the binding region of a previously described monoclonal anti-factor VIII (FVIII) inhibitory antibody (C5) to amino acid residues Thr351-Ser365 of the thrombin-generated 54-kD fragment of the heavy chain of FVIII. Synthetic FVIII peptides were examined for the ability to competitively inhibit the binding of C5 to FVIII in an ELISA system. The synthetic FVIII peptide Thr351-Ser365 blocked C5 binding to FVIII in a dose-dependent manner in this system. Two other synthetic FVIII peptides, Asn340-Glu354 and Glu342-Asp356, which partially overlapped Thr351-Ser365, also blocked C5 binding to FVIII. Blocking of C5 binding with these peptides, however, required much greater concentrations (greater than 100 times stronger) than that required for Thr351-Ser365. The Thr351-Ser365 peptide also neutralized the FVIII inhibitory activity of C5 in plasma. A human FVIII inhibitor (anti-FVIII heavy chain alloantibody) was also partially neutralized by Thr351-Ser365. Thr351-Ser365 lies between a thrombin cleavage site (Arg372) and an activated protein C cleavage site (Arg336) and may be at or near a region of functional importance in the expression of FVIII procoagulant activity.
Localization of a factor VIII-inhibiting antibody epitope to a region between residues 338 and 362 of factor VIII heavy chain.
We have used a recombinant DNA epitope library to localize the binding region of a factor VIII (FVIII) monoclonal antibody that neutralizes coagulant activity. The antibody, C5, has previously been described and has been shown to have a FVIII neutralizing potency of 1488 Bethesda units per mg of purified immunoglobulin. A recombinant DNA epitope library was constructed from short, random FVIII cDNA fragments and immunologically screened with C5 to identify bacteriophage expressing the antigenic determinant. The isolation and characterization of immunoreactive bacteriophage restricted the C5 epitope to the overlapping or shared DNA sequence of nine different clones and corresponded to amino acid residues 338-362 of the mature FVIII peptide. The defined epitope is between the proposed activated protein C cleavage site (Arg-336) and thrombin cleavage site (Arg-372) on the amino-terminal 90-kDa FVIII heavy-chain subunit. The identification of the epitope of an inhibiting anti-FVIII antibody between two critical cleavage sites suggests that this amino acid sequence plays a role in regulating FVIII coagulant activity.
The alpha and beta chains of human platelet glycoprotein Ib are both transmembrane proteins containing a leucine-rich amino acid sequence.
The primary structure of the beta chain of human glycoprotein Ib (GPIb), the platelet receptor for von Willebrand factor, has been established by a combination of cDNA cloning and amino acid sequence analysis. A lambda phage cDNA expression library prepared from human erythroleukemia cells (HEL cells) was screened with a radiolabeled affinity-purified rabbit polyclonal antibody to the beta chain of GPIb. Eighteen positive clones were isolated and plaque-purified and the nucleotide sequences of three were determined. The composite sequence spanned 968 nucleotides and included a 5' untranslated region of 22 nucleotides, an open reading frame of 618 nucleotides encoding a signal peptide of 28 amino acids and a mature protein of 181 amino acids, a stop codon, and a 3' noncoding region of 307 nucleotides. The 3' noncoding sequence also contained a polyadenylylation signal (AATAAA) 14 nucleotides upstream from the poly(A) tail of 18 nucleotides. Edman degradation of the intact beta chain and of peptides produced by chemical cleavage yielded amino acid sequences spanning 76 residues that were identical to those predicted from the cDNA. The amino-terminal region of the beta chain contains a leucine-rich sequence of 24 amino acids that is similar to a sequence that occurs as seven tandem repeats in the alpha chain of GPIb and nine tandem repeats in leucine-rich alpha 2-glycoprotein. The leucine-rich sequence in the beta chain of GPIb is flanked on both sides by amino acid sequences that are similar to those flanking the leucine-rich tandem repeats of the alpha chain of GPIb and leucine-rich alpha 2-glycoprotein. The amino-terminal region of the beta chain of GPIb is followed by a transmembrane segment of 25 amino acids and an intracellular segment of 34 amino acids at the carboxyl terminus of the protein. The intracellular segment contains an unpaired cysteine and two potential sites for phosphorylation by cAMP-dependent protein kinase.
Synthesis of factor VIII in human hepatocytes in culture.
An immunogenic region within residues Val1670-Glu1684 of the factor VIII light chain induces antibodies which inhibit binding of factor VIII to von Willebrand factor.
We have identified a monoclonal anti-factor VIII (FVIII) antibody, C4, which inhibits the binding of purified human FVIII to purified human von Willebrand factor (vWF). Both whole immunoglobulin C4 and its Fab fragment demonstrated dose-dependent inhibition of FVIII binding to vWF immobilized on the surface of polystyrene beads. Synthetic peptides based on the amino acid sequence of FVIII were tested for the ability to block the binding of C4 to FVIII in an enzyme-linked immunosorbent assay system. A single synthetic FVIII pentadecapeptide, consisting of residues Val1670-Glu1684, was able to inhibit C4 binding to FVIII. Under the conditions used, the Val1670-Glu1684 peptide demonstrated total inhibition of C4 binding at a concentration of 1 microM. Synthetic FVIII peptides flanking and overlapping the Val1670-Glu1684 peptide had no significant inhibitory activity on C4 binding in concentrations up to 100 microM. A polyclonal antibody made to the Val1670-Glu1684 peptide also demonstrated inhibition of FVIII binding to vWF. Polyclonal antibodies made to synthetic FVIII peptides flanking and partially overlapping the Val1670-Glu1684 sequence did not demonstrate such inhibition. Localization of the binding region of the monoclonal anti-FVIII antibody C4 to residues Val1670-Glu1684 suggests that this site is at, or near, a major vWF binding domain of FVIII.
Cloning of cDNAs coding for the heavy chain region and connecting region of human factor V, a blood coagulation factor with four types of internal repeats.
A major factor VIII binding domain resides within the amino-terminal 272 amino acid residues of von Willebrand factor.
We have identified a Factor VIII (FVIII) binding domain residing within the amino-terminal 272 amino acid residues of the mature von Willebrand Factor (vWF) subunit. Two-dimensional crossed immunoelectrophoresis showed direct binding of purified human FVIII to purified human vWF. After proteolytic digestion of vWF with Staphylococcus aureus V8 protease (SP), FVIII binding was seen only with the amino-terminal SP fragment III and not with the carboxyl-terminal SP fragment II. A monoclonal anti-vWF antibody (C3) partially blocked FVIII binding to vWF and SP fragment III. FVIII also bound to vWF which had been adsorbed to polystyrene beads. This binding was inhibited in a dose-dependent manner by whole vWF, SP fragment III, and by monoclonal antibody C3. Binding could not be inhibited by SP fragment I, which contains the middle portion of the vWF molecule, or by reduced and alkylated whole vWF. SP fragment II caused only minimal inhibition. Trypsin cleavage of SP fragment III produced a monomeric 35-kDa fragment containing the amino-terminal 272 amino acid residues of vWF. This fragment reacted with monoclonal antibody C3 and inhibited the binding of FVIII to vWF in a dose-dependent manner. These studies demonstrate that a major FVIII binding site resides within the amino-terminal 272 amino acid residues of vWF.
Characterization of primary amino acid sequence of human complement control protein factor I from an analysis of cDNA clones.
A cDNA clone of the mRNA coding for the human complement system control protein Factor I has been isolated. The predicted amino acid sequence obtained from the DNA sequence demonstrates a protein consisting of a heavy chain (Mr 35,400) linked to a light chain (Mr 27,600), both of which contain three sites for N-linked glycosylation. The light chain has clear homology with other serine proteinases, most notably in the region of the catalytically active and structurally important amino acids and shares some of the features characteristic of the plasminogen activators. The heavy chain has a clear 'mosaic' nature typical of the plasma serine proteinases; in particular it contains class A and class B LDL (low-density lipoprotein) receptor repeats with conserved cysteine residues similar to those found in other complement proteins.
Factor VIII binds to von Willebrand factor via its Mr-80,000 light chain.
The formation of a complex between factor VIII (FVIII) and von Willebrand factor (vWF) was studied using purified radiolabeled human FVIII and purified human vWF. A binding assay was developed in which vWF was coated on microtiter wells. FVIII was shown to bind specifically and reversibly to the immobilized vWF. At a coating of 70 pg vWF/well, binding was half-maximal at a FVIII concentration of 70 +/- 10 pM. In order to ascertain which part of FVIII interacted with vWF, eight monoclonal antibodies, directed against FVIII, were tested for their ability to inhibit FVIII-vWF interaction. One of the eight antibodies, CLB-CAg:58, inhibited binding completely. This antibody was demonstrated to react with the Mr-80,000 light chain of FVIII. Direct evidence for the involvement of this chain in vWF binding was obtained by studying the binding of isolated, radiolabeled FVIII heavy and light chains. In a typical experiment 23-30% of the radioactivity bound when the FVIII light chain was added and less than 1% when the FVIII heavy chain was added.
The interaction of rDNA factor VIII, factor VIIIdes-797-1562 and factor VIIIdes-797-1562-derived peptides with phospholipid.
The interaction of rDNA factor VIII, factor VIIIdes-797-1562 and factor VIIIdes-797-1562-derived peptides with phospholipid were studied with an ELISA system. Factor VIII was observed to bind to phosphatidylserine but not to phosphatidylcholine or phosphatidylethanolamine. Factor VIIIdes-797-1562 also bound to phosphatidylserine with the same affinity, suggesting that residues 797-1562 of the factor VIII molecule are not required for phospholipid binding. In addition, the binding of the purified factor VIII carboxy-terminal Mr 80,000 and amino-terminal Mr 90,000/115,000 polypeptides to phosphatidylserine was investigated. Only the Mr 80,000 polypeptide was observed to bind, suggesting that the carboxy-terminal of factor VIII contains the lipid binding domain.
A large region (approximately equal to 95 kDa) of human factor VIII is dispensable for in vitro procoagulant activity.
Factor VIII (antihemophilic factor) is a high molecular weight plasma glycoprotein that participates in the blood clotting cascade. The recent cloning and sequence analysis of the cDNA encoding human factor VIII revealed an obvious domain structure for the protein, which can be represented as A1-A2-B-A3-C1-C2. We now report the DNA sequence analysis of porcine exons encoding the entire B domain and part of the A2 and A3 domains. We found an unusually high degree of porcine-human amino acid sequence divergence in the B region compared with the limited sequence available for other regions of the porcine factor VIII molecule. In addition to sequence divergence, there are numerous gaps in the porcine B domain totalling over 200 amino acids. Recombinant DNA techniques were used to effect the removal of large segments of DNA encoding the B domain from the full-length human factor VIII cDNA. These constructs directed the synthesis of biologically active factor VIII when introduced into mammalian cells despite the deletion of up to 38% of the factor VIII molecule.
The cloning of factor VIII and the genetics of hemophilia A.
Internal duplication and sequence homology in factors V and VIII.
Blood coagulation factors V and VIII each serve cofactor functions with different vitamin K-dependent serine proteases of the coagulation cascade. Physical, physiologic, and kinetic data suggest analogous structures and functions for these two proteins. Proteolytically activated factor V (factor Va) is required for the efficient production of thrombin from prothrombin by factor Xa. Similarly, activated factor VIII (factor VIIIa) performs its cofactor activity with factor IXa to produce the activated form of factor X (factor Xa). The studies reported here on the sequences from the thrombin-activated and unactivated cofactors provide evidence that factor V and factor VIII are chemically related and that the structures of both cofactors involve some tandem duplication.
Characterization of the polypeptide composition of human factor VIII:C and the nucleotide sequence and expression of the human kidney cDNA.
Human coagulation factor VIII:C has been purified approximately 5000-fold from commercial preparations with an average activity yield of 35%. Proteins of 92 kD and 77-80 kD enriched during purification are precipitated by a human serum polyclonal antibody which inhibits factor VIII:C activity. Evidence suggests that these polypeptides are linked by a calcium ion bridge. Partial amino acid sequence information from these proteins has been obtained from the intact polypeptides and from products of digestion with thrombin, endoproteinase lysC, or trypsin after citraconylation. An oligonucleotide probe designed from one of the amino acid sequences was used to isolate a partial genomic clone from a human 4X chromosome library in bacteriophage lambda. The genomic segment was used to isolate two cDNA molecules encompassing the entire human kidney factor VIII:C mRNA. Biologically active factor VIII:C has been produced in a mammalian cell line utilizing a complete cDNA construction.
Characterization of human blood coagulation factor XII cDNA. Prediction of the primary structure of factor XII and the tertiary structure of beta-factor XIIa.
A human liver cDNA library was screened by colony hybridization with two mixtures of synthetic oligodeoxyribonucleotides as probes. These oligonucleotides encoded regions of beta-factor XIIa as predicted from the amino acid sequence. Four positive clones were isolated that contained DNA coding for most of factor XII mRNA. DNA sequence analysis of these overlapping clones showed that they contained DNA coding for part of an amino-terminal extension, the complete amino acid sequence of plasma factor XII, a TGA stop codon, a 3' untranslated region of 150 nucleotides, and a poly(A)+ tail. The cDNA sequence predicts that plasma factor XII consists of 596 amino acid residues. Within the predicted amino acid sequence of factor XII, we have identified three peptide bonds that are cleaved by kallikrein during the formation of beta-factor XIIa. Comparison of the structure of factor XII with other proteins revealed extensive sequence identity with regions of tissue-type plasminogen activator (the epidermal growth factor-like region and the kringle region) and fibronectin (type I and type II homologies). As the type II region of fibronectin contains a collagen-binding site, the homologous region in factor XII may be responsible for the binding of factor XII to collagen. The carboxyl-terminal region of factor XII shares considerable amino acid sequence homology with other serine proteases including trypsin and many clotting factors. A preliminary structural model of beta-factor XIIa is proposed based on the known high resolution x-ray diffraction structures of trypsin, chymotrypsin, and elastase.
Characterization of the human factor VIII gene.
The complete 186,000 base-pair (bp) human factor VIII gene has been isolated and consists of 26 exons ranging in size from 69 to 3,106 bp and introns as large as 32.4 kilobases (kb). Nine kb of mRNA and protein-coding DNA has been sequenced and the mRNA termini have been mapped. The relationship between internal duplications in factor VIII and evolution of the gene is discussed.
Molecular cloning of a cDNA encoding human antihaemophilic factor.
A complete copy of the mRNA sequences encoding human coagulation factor VIII:C has been cloned and expressed. The DNA sequence predicts a single chain precursor of 2,351 amino acids with a relative molecular mass (Mr) 267,039. The protein has an obvious domain structure, contains sequence repeats and is structurally related to factor V and ceruloplasmin.
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.
Characterization of a cDNA coding for human factor X.
A lambda gt11 cDNA library containing DNA inserts prepared from human liver mRNA has been screened with an antibody to human factor X, a plasma protein participating in the middle phase of the blood coagulation cascade. Ten positive clones were isolated from 2 X 10(6) phage and plaque purified. The cDNA in the phage containing the largest insert has been sequenced and shown to code for human factor X. This cDNA insert contained 1137 base pairs coding for a portion of the light chain of the molecule, a connecting region, the heavy chain, a stop codon, a short 3' noncoding region, and a poly(A) tail. The sequence of A-T-T-A-A-A, which functions as a potential recognition site for polyadenylylation or processing, was present in the 3' end of the coding sequence and preceded the stop codon of TGA by 1 base pair and the poly(A) tail by 14 base pairs. The amino acid sequence deduced from the cDNA indicated that factor X is synthesized as a single-chain polypeptide containing the light and heavy chains connected by an Arg-Lys-Arg tripeptide. The single-chain molecule is then converted to the light and heavy chains by cleavage of two (or more) internal peptide bonds. In plasma, these two chains are linked together by a disulfide bond. The DNA sequence coding for the active site of human factor X showed a high degree of identity with prothrombin and factor IX, two other vitamin K-dependent serine proteases that participate in blood coagulation. These data along with the protein sequence data previously published for the light chain of human factor X establish the complete amino acid sequence for the mature protein present in plasma.
Structure and function of protein C.
Effects of ultrasonication on Factor VIII.

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