The diversity of factor VIII (fVIII) C2 domain antibody epitopes was investigated by competition enzyme-linked immunosorbent assay (ELISA) using a panel of 56 antibodies. The overlap patterns produced 5 groups of monoclonal antibodies (MAbs), designated A, AB, B, BC, and C, and yielded a set of 18 distinct epitopes. Group-specific loss of antigenicity was associated with mutations at the Met2199/ Phe2200 phospholipid binding -hairpin (group AB MAbs) and at Lys2227 (group BC MAbs), which allowed orientation of the epitope structure as a continuum that covers one face of the C2 -sandwich.
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.
Factor VIII (fVIII) is the procoagulant plasma glycoprotein that is missing or decreased in hemophilia A. The cellular origin of fVIII synthesis is controversial. Liver transplantation cures hemophilia A, demonstrating that the liver is a major site of fVIII synthesis. We detected fVIII mRNA in purified populations of murine liver sinusoidal endothelial cells (LSECs) and hepatocytes, but not Kupffer cells. LSECs and hepatocytes contained comparable numbers of fVIII mRNA (40 and 70 transcripts per cell, respectively) by quantitative competitive reverse transcriptase-polymerase chain reaction analysis. There was not detectable mRNA for factor IX, a hepatocyte marker, in the LSEC preparation, nor was there detectable mRNA for von Willebrand factor, an endothelial cell marker, in the hepatocyte preparation. This excludes the possibility that detectable fVIII mRNA is due to cross-contamination in the hepatocyte or LSEC preparations. Primary cultures of LSECs were established in which fVIII mRNA levels were indistinguishable from purified LSECs. LSECs secreted active fVIII into the culture medium. This finding represents the first demonstration of homologous expression of fVIII mRNA and protein in cell culture and should facilitate studies of fVIII gene regulation. Additionally, LSECs potentially are targets for a fVIII transgene during gene therapy of hemophilia A.The site of the cellular origin for the biosynthesis of fVIII 1 remains controversial despite studies that date back nearly 50 years (see Refs. 1 and 2, for reviews). Human and canine hemophilia A are cured by liver transplantation (3-6), which demonstrates that the liver contributes significantly to fVIII synthesis. Hepatocytes (7,8), liver sinusoidal endothelial cells (LSECs) (9 -11), or both (12), have been proposed as sites of fVIII synthesis. In this study, we isolated hepatocytes, LSECs, and Kupffer cells and measured steady-state levels of fVIII mRNA in these preparations. Our results indicate that both LSECs and hepatocytes synthesize fVIII mRNA. Additionally, LSECs in culture secrete active fVIII, providing a model for studies of the regulation of homologous fVIII gene expression. EXPERIMENTAL PROCEDURESMaterials-Gey's balanced salt solution, Hank's balanced salt solution (HBSS), Dulbecco's phosphate-buffered saline (PBS), Liver Digest Medium, DMEM/F-12 medium, and AIM-V medium were purchased from Life Technologies, Inc. (Gaithersburg, MD). Penicillin (50 units/ ml) and streptomycin (50 g/ml) were added to DMEM/F-12 medium. Collagenase (type IV), gelatin, and dibutyryl cAMP were purchased from Sigma. DNase I was purchased from Roche Molecular Biochemicals (Indianapolis, IN). The following murine monoclonal IgG 1 antibodies were purchased from Pharmigen (San Diego, CA): FITC-conjugated anti-PECAM-1 (anti-CD31), FITC-conjugated anti-VCAM-1 (anti-CD106), PE-conjugated anti-ICAM-1 (anti-CD54), the corresponding FITC-conjugated-and PE-conjugated isotype-specific control antibodies, and biotinylated anti-ICAM-1. FITC-conjugated wheat germ agglutinin was ...
Recombinant human factor VIII expression levels, in vitro and in vivo, are significantly lower than levels obtained for other recombinant coagulation proteins. Here we describe the generation, high level expression and characterization of a recombinant B-domain-deleted porcine factor VIII molecule. Recombinant B-domaindeleted porcine factor VIII expression levels are 10-to 14-fold greater than recombinant B-domain-deleted human factor VIII levels by transient and stable expression in multiple cell lines. Peak expression of 140 units⅐10 6 cells ؊1 ⅐24 h ؊1 was observed from a baby hamster kidneyderived cell line stably expressing recombinant porcine factor VIII. Factor VIII expression was performed in serum-free culture medium and in the absence of exogenous von Willebrand factor, thus greatly simplifying protein purification. Real time reverse transcription-PCR analysis demonstrated that the differences in protein production were not caused by differences in steady-state factor VIII mRNA levels. The identification of sequence(s) in porcine factor VIII responsible for high level expression may lead to a better understanding of the mechanisms that limit factor VIII expression.Factor VIII (fVIII) 1 is a large (ϳ 300 kDa) glycoprotein that functions as an integral component of the intrinsic pathway of blood coagulation. Mutations in the fVIII gene that result in decreased or defective fVIII protein give rise to the genetic disease, hemophilia A, which is phenotypically characterized by recurrent bleeding episodes. Treatment of hemophilia A entails intravenous infusion of either human plasma-derived or recombinant fVIII material. Approximately 25% of all hemophilia A patients treated with fVIII products develop antibodies that inhibit fVIII activity and limit treatment efficacy (1). Patients with fVIII-inhibitory antibodies can be treated using porcine plasma-derived fVIII products, which generally display low cross-reactivity with the human fVIII antibodies (2, 3). Currently there is not a recombinant porcine fVIII product available for clinical use.Since the introduction of recombinant fVIII for the treatment of hemophilia A, commercial suppliers have struggled to keep up with high patient demand (4). The shortage of recombinant fVIII material has precluded prophylactic treatment of severely affected patients, limited the implementation of immune-tolerance regimens, and kept treatment costs high. Unfortunately, fVIII is expressed and recovered at low levels in the heterologous mammalian cell culture systems used for commercial manufacture. The importance of this problem has fueled significant research efforts to overcome the low fVIII expression barrier, and several basic mechanisms have been identified that limit fVIII expression (for review, see Kaufman et al. (5)) Despite these findings, fVIII expression levels remain low, and a product shortage persists.The porcine fVIII cDNA sequence has been reported and shown to encode the homology-defined internal protein domain structure, A1-A2-B-ap-A3-C1-C2 (6, 7). Porcin...
A culture of human blood outgrowth endothelial cells (BOECs) was established from a sample of peripheral blood and was transfected using a nonviral plasmid carrying complementary DNA for modified human coagulation factor VIII (B domain deleted and replaced with green fluorescence protein). BOECs were then chemically selected, expanded, cryopreserved, and re-expanded in culture. Stably transfected BOECs were administered intravenously daily for 3 days to NOD/SCID mice at 4 cell dose levels (from 5 ؋ 10 4 to 40 ؋ 10 4 cells per injection). In 156 days of observation, mice showed levels of human FVIII that increased with cell dose and time. Mice in all cell dose groups achieved therapeutic levels (more than 10 ng/mL) of human FVIII, and mice in the 3 highest dose groups acquired levels that were normal (100-200 ng/mL) or even above the normal range (highest observed value, 1174 ng/mL). These levels indicate that the BOECs expanded in vivo after administration. When the mice were killed, it was found that BOEC accumulated only in bone marrow and spleen and that these cells retained endothelial phenotype and transgene expression. Cell doses used here would make scale-up to humans feasible. Thus, the use of engineered autologous BOECs, which here resulted in sustained and therapeutic levels of FVIII, may comprise an effective therapeutic strategy for use in gene therapy for hemophilia A. (Blood. 2002; 99:457-462)
Blood coagulation factor VIII has a domain structure designated A1-A2-B-ap-A3-C1-C2. Human factor VIII is present at low concentration in normal plasma and, comparably, is produced at low levels in vitro and in vivo using transgenic expression techniques. Heterologous expression of B domain-deleted porcine factor VIII in mammalian cell culture is significantly greater than B domain-deleted human or murine factor VIII. Novel hybrid human/porcine factor VIII molecules were constructed to identify porcine factor VIII domains that confer high level expression. Hybrid human/porcine factor VIII constructs containing the porcine factor VIII A1 and ap-A3 domains expressed at levels comparable with recombinant porcine factor VIII. A hybrid construct containing only the porcine A1 domain expressed at intermediate levels between human and porcine factor VIII, whereas a hybrid construct containing the porcine ap-A3 domain expressed at levels comparable with human factor VIII. Additionally, hybrid murine/porcine factor VIII constructs containing the porcine factor VIII A1 and ap-A3 domain sequences expressed at levels significantly higher than recombinant murine factor VIII. Therefore, the porcine A1 and ap-A3 domains are necessary and sufficient for the high level expression associated with porcine factor VIII. Metabolic radiolabeling experiments demonstrated that high level expression was attributable to enhanced secretory efficiency. Factor VIII (fVIII)1 is a plasma protein that functions in proteolytically activated form as a cofactor within the intrinsic pathway of blood coagulation to increase the rate of proteolytic activation of factor X by activated factor IX. fVIII contains a domain structure designated A1-A2-B-ap-A3-C1-C2 that is defined based on internal sequence homology (1, 2). The fVIII A domains share homology with the copper-binding protein ceruloplasmin (3, 4), which has an A1-A2-A3 domain structure in which the three A domains are arranged along a pseudo-3-fold axis of symmetry (5). Before cell secretion, fVIII is cleaved at the B/ap-A3 domain junction into A1-A2-B (heavy chain) and ap-A3-C1-C2 (light chain) subunits. fVIII circulates in the plasma as an inactive heavy chain/light chain heterodimeric procofactor that is non-covalently bound to von Willebrand factor. Proteolytic activation of fVIII by thrombin results from cleavages at Arg-372 between the A1 and A2 domains, Arg-740 between the A2 and B domains, and Arg-1689 between the ap and A3 domains. During this process, the covalent linkage between the A1 and A2 domains is lost, and the B domain and 41-residue ap are released, producing a heterotrimeric,
Summary Background How von Willebrand factor (VWF) senses and responds to shear flow remains unclear. In the absence of shear VWF or its fragments can be induced to bind spontaneously to platelet GPIbα. Objectives To elucidate the auto-inhibition mechanism of VWF. Methods Hydrogen-deuterium exchange (HDX) of two recombinant VWF fragments expressed from baby hamster kidney cells were measured and compared. Results The shortA1 protein contains VWF residues 1261–1472 and binds GPIbα with a significantly higher affinity than the longA1 protein that contains VWF residues 1238–1472. Both proteins contain the VWF A1 domain (residues 1272–1458). Many residues in longA1, particularly those in the N- and C-terminal sequences flanking the A1 domain, and in helix α1, loops α1β2 and β3α2, reported markedly reduced HDX than their counterparts in shortA1. The HDX-protected region in longA1 overlaps with the GPIbα-binding interface and is clustered with type 2B von Willebrand disease (VWD) mutations. Additional comparison with the HDX of denatured longA1 and ristocetin-bound longA1 indicates the N- and C-terminal sequences flanking the A1 domain form cooperatively an integrated autoinhibitory module (AIM) that interacts with the HDX-protected region. Binding of ristocetin to the C-terminal part of the AIM desorbs the AIM from A1 and enables longA1 binding to GPIbα. Conclusion The discontinuous AIM binds the A1 domain and prevents it from binding to GPIbα, which has significant implications for the pathogenesis of type 2B VWD and the shear-induced activation of VWF activity.
A 42-year-old patient with mild hemophilia A developed spontaneous muscle hematomas 1 month after intense therapy with factor VIII concentrates. Factor VIII clotting activity was less than 1% and his factor VIII inhibitor was 10 Bethesda units (BU)/mL. The titer peaked at 128 BU despite daily infusions of factor VIII; 1 year later, the titer was 13 BU with no spontaneous bleeding for 4 months. The plasma inhibitor was 95% neutralized by factor VIII A2 domain but less than 15% neutralized by light-chain or C2 domain. His inhibitor did not cross-react with porcine factor VIII and was at least 10-fold less reactive to a series of hybrid factor VIII proteins in which human residues 484-508 are replaced by the homologous porcine sequence (Healey et al, J Biol Chem 270:14505, 1995). The inhibitor patient's DNA encoding his A2 domain and flanking sequences showed a C-T transition predicting Arg593 to Cys. Thirteen patients from 5 unrelated families with Cys593 have not developed inhibitors. Factor VIII clotting activity from one of them was inhibited similarly to diluted normal plasma by inhibitor patient plasma. In an homologous structure, ceruloplasmin (Zaitseva et al, J Biol Inorgan Chem 1:15,1996), the residue equivalent to Arg593, is in a loop distinct from residues 484-508. On solution phase immunoprecipitation with labeled factor VIII fragments, A2, light chain, and C2 domains bound. In contrast to typical immune responses to factor VIII in patients with severe hemophilia A, this patient's inhibitor was almost entirely reactive with common epitopes within the A2 domain whereas by more sensitive immunoprecipitation testing antibodies to light chain epitopes were also present. Accordingly, immune responsiveness to exogenous factor VIII (antigen burden) appears to be more critical than his endogenous, hemophilic factor VIII to his developing high-titer anti–factor VIII antibodies and loss of tolerance to both native and hemophilic factor VIII proteins.
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