Over-expression of Hsp70 in BHK-21 cells engineered to produce recombinant factor VIII promotes resistance to apoptosis and enhances secretion

Production of coagulation factor VIII (FVIII) by recombinant cell lines is limited by its failure to reach or maintain the native conformation in the endoplasmic reticulum. This results in significant cytoplasmic degradation and/or aggregation of the misfolded product. The molecular chaperone Hsp70 was overexpressed in an attempt to increase the recombinant FVIII (rFVIII) secretion. The characteristics of increased Hsp70 expression were investigated by comparing a clone of BHK-21 cells expressing rFVIII (rBHK-21(host)) to a chaperone clone derived by transfection of the host clone with human Hsp70 (rBHK-21(Hsp70)) in small-scale batch cell cultures. To aid this investigation a number of fluorescence based cellular apoptosis assays were developed and optimized. These assays demonstrated sub-populations of rBHK-21(host) cells that were apoptotic in nature and were identified prior to the loss in plasma membrane integrity. Dual staining for intracellular rFVIII and caspase-3 activation showed a reduction in intracellular rFVIII in rBHK-21(host) cells that correlated with a significant increase in active caspase-3, suggesting that apoptosis was a factor limiting rFVIII secretion. In sharp contrast there was more intracellular rFVIII and less active caspase-3 in rBHK-21(Hsp70) cell cultures. Moreover when grown in batch culture, rBHK-21(Hsp70) cells released rFVIII of higher specific activity (active FVIII protein/total FVIII protein), suggesting improved product quality. Thus, increased expression of HSP70 led to an increased yield of a secreted recombinant protein by inhibition of apoptosis and promoting proper conformational maturation of rFVIII in sub-optimal bioreactor conditions.     

A new recombinant procoagulant protein derived from the cDNA encoding human factor VIII

We have constructed new B domain deletion derivatives of human factor VIII (FVIII) by manipulating the cDNA using recombinant DNA techniques. One of these new derivatives, FVIII delta II, in which amino acids 771(pro)-1666(asp) have been deleted, no longer contains the protease cleavage site at amino acid position 1648(arg)-1649(glu) known to be involved in the initial step of FVIII processing. We have expressed this molecule in both baby hamster kidney (BHK) 21 cells using the vaccinia virus (VV) expression system and have established Chinese hamster ovary (CHO) derived permanent cell lines expressing either recombinant (r)FVIII or FVIII delta II. The characteristics of FVIII delta II have been compared to those of rFVIII and/or plasma derived (pd) FVIII. FVIII delta II has the following properties: (i) it exhibits FVIII procoagulant activity; (ii) it is expressed at 5-fold higher levels than is the complete molecule in comparable systems; (iii) it migrates for the most part as a single major band on SDS-PAGE, in contrast to the complete molecule; (iv) it is activated to a greater extent by thrombin than is either rFVIII or pdFVIII; and (v) it retains the ability to bind von Willebrand factor (vWf).     

Factor VIII hydrolysis mediated by anti-factor VIII autoantibodies in acquired hemophilia

Acquired hemophilia is a rare hemorrhagic disorder caused by the spontaneous appearance of inhibitory autoantibodies directed against endogenous coagulation factor VIII (FVIII). Inhibitory Abs also arise in patients with congenital hemophilia A as alloantibodies directed to therapeutic FVIII. Both autoimmune and alloimmune inhibitors neutralize FVIII by steric hindrance. We have described FVIII-hydrolyzing IgG in 50% of inhibitor-positive patients with severe hemophilia A that inactivate therapeutic FVIII. In this study, we investigated the presence of autoimmune FVIII-hydrolyzing IgG in patients with acquired hemophilia. Pooled IgG from healthy donors demonstrated moderate FVIII-hydrolyzing activity (56 +/- 26 micromol/min/mol). Purified IgG from 21 of 45 patients with acquired hemophilia demonstrated FVIII hydrolysis rates (mean 219 +/- 94 micromol/min/mol) significantly greater than that of control IgG. Three of four patients followed over the course of the disease had rates of FVIII hydrolysis that co-evolved with inhibitory titers in plasma, suggesting that IgG-mediated FVIII hydrolysis participates, in part, in FVIII inactivation. The present work extends the scope of the diseases associated with FVIII proteolysis and points toward the importance of FVIII as a key target substrate for hydrolytic immunoglobulins. Our data suggest that elevated levels of FVIII-hydrolyzing IgG in acquired hemophilia result from the exacerbation of a physiological catalytic immune response.     

Catalytic activity of antibodies against factor VIII in patients with hemophilia A.

Hemophilia A is an X chromosome-linked recessive disorder resulting in defective or deficient factor VIII (FVIII) molecules, which, in its severe form, is a life-threatening and crippling hemorrhagic disease. Infusion of homologous FVIII to patients with severe hemophilia A results, in 25% of patients, in the emergence of alloantibodies against FVIII (inhibitors)( ref. 1) that inhibit FVIII procoagulant activity by steric hindrance of the interaction of FVIII either with stabilizing molecules, with molecules essential for its activity or with activating molecules. Here, we report on the proteolysis of FVIII by alloantibodies of two patients with severe hemophilia A, demonstrating a previously unknown mechanism by which FVIII inhibitors may prevent the pro-coagulant function of FVIII. The kinetic parameters of FVIII hydrolysis indicate a functional role for the catalytic immune response in the inactivation of FVIII in vivo. The characterization of alloantibodies against FVIII as site-specific proteases may provide new approaches to the treatment of FVIII inhibitors.     

The light chain of factor VIII comprises a binding site for low density lipoprotein receptor-related protein.

In the present study, the interaction between the endocytic receptor low density lipoprotein receptor-related protein (LRP) and coagulation factor VIII (FVIII) was investigated. Using purified components, FVIII was found to bind to LRP in a reversible and dose-dependent manner (K(d) approximately 60 nM). The interaction appeared to be specific because the LRP antagonist receptor-associated protein readily inhibited binding of FVIII to LRP (IC(50) approximately 1 nM). In addition, a 12-fold molar excess of the physiological carrier of FVIII, i.e. von Willebrand factor (vWF), reduced the binding of FVIII to LRP by over 90%. Cellular degradation of (125)I-labeled FVIII by LRP-expressing cells ( approximately 8 fmol/10(5) cells after a 4.5-h incubation) was reduced by approximately 70% in the presence of receptor-associated protein. LRP-directed antibodies inhibited degradation to a similar extent, indicating that LRP indeed contributes to binding and transport of FVIII to the intracellular degradation pathway. Degradation of FVIII was completely inhibited by vWF. Because vWF binding by FVIII involves its light chain, LRP binding to this subunit was studied. In ligand blotting experiments, binding of FVIII light chain to LRP could be visualized. More detailed analysis revealed that FVIII light chain interacts with LRP with moderate affinity (k(on) approximately 5 x 10(4) M(-1) s(-1); k(off) approximately 2.5 x 10(-3) s(-1); K(d) approximately 50 nM). Furthermore, experiments using recombinant FVIII C2 domain showed that this domain contributes to the interaction with LRP. In contrast, no association of FVIII heavy chain to LRP could be detected under the same experimental conditions. Collectively, our data demonstrate that in vitro LRP is able to bind FVIII at the cell surface and to mediate its transport to the intracellular degradation pathway. FVIII-LRP interaction involves the FVIII light chain, and FVIII-vWF complex formation plays a regulatory role in LRP binding. Our findings may explain the beneficial effect of vWF on the in vivo survival of FVIII.     

Mesenchymal stem cells contribute to endogenous FVIII:c production

Besides the liver, it has been difficult to identify which organ(s) and/or cellular component(s) contribute significantly to the production of human FVIII:c (FVIII). Thus far, only endothelial cells have been shown to constitute a robust extrahepatic source of FVIII, possibly explaining both the diverse presence of FVIII mRNA in the body, and the observed increase in FVIII levels during liver failure. Here, we investigate whether human mesenchymal stem cells (MSC), ubiquitously present in different organs, could also contribute to FVIII production. MSC isolated from human lung, liver, brain, and bone marrow expressed FVIII message as determined by quantitative‐RT‐PCR. Using an antibody specific for FVIII, confocal microscopy, and umbilical cord‐derived endothelial cells (HUVEC) as a negative control, we demonstrated that, in MSC, FVIII protein was not stored in granules; rather, it localized to the perinuclear region. Furthermore, functional FVIII was detected in MSC supernatants and cell lysates by aPTT and chromogenic assays. These results demonstrate that MSC can contribute at low levels to the functional FVIII pool, and advance the understanding of the physiology of FVIII production and secretion. J. Cell. Physiol. © 2012 Wiley Periodicals, Inc.     

Mass spectrometry-assisted study reveals that lysine residues 1967 and 1968 have opposite contribution to stability of activated factor VIII

The A2 domain rapidly dissociates from activated factor VIII (FVIIIa) resulting in a dampening of the activity of the activated factor X-generating complex. The amino acid residues that affect A2 domain dissociation are therefore critical for FVIII cofactor function. We have now employed chemical footprinting in conjunction with mass spectrometry to identify lysine residues that contribute to the stability of activated FVIII. We hypothesized that lysine residues, which are buried in FVIII and surface-exposed in dissociated activated FVIII (dis-FVIIIa), may contribute to interdomain interactions. Mass spectrometry analysis revealed that residues Lys(1967) and Lys(1968) of region Thr(1964)-Tyr(1971) are buried in FVIII and exposed to the surface in dis-FVIIIa. This result, combined with the observation that the FVIII variant K1967I is associated with hemophilia A, suggests that these residues contribute to the stability of activated FVIII. Kinetic analysis revealed that the FVIII variants K1967A and K1967I exhibit an almost normal cofactor activity. However, these variants also showed an increased loss in cofactor activity over time compared with that of FVIII WT. Remarkably, the cofactor activity of a K1968A variant was enhanced and sustained for a prolonged time relative to that of FVIII WT. Surface plasmon resonance analysis demonstrated that A2 domain dissociation from activated FVIII was reduced for K1968A and enhanced for K1967A. In conclusion, mass spectrometry analysis combined with site-directed mutagenesis studies revealed that the lysine couple Lys(1967)-Lys(1968) within region Thr(1964)-Tyr(1971) has an opposite contribution to the stability of FVIIIa.     

Quantitative Influence of ABO Blood Groups on Factor VIII and Its Ratio to von Willebrand Factor,Novel Observations from an ARIC Study of 11,673 Subjects

ABO blood groups are known to influence the plasma level of von Willebrand factor (VWF), but little is known about the relationship between ABO and coagulation factor VIII (FVIII). We analyzed the influence of ABO genotypes on VWF antigen, FVIII activity, and their quantitative relationship in 11,673 participants in the Atherosclerosis Risk in Communities (ARIC) study. VWF, FVIII, and FVIII/VWF levels varied significantly among O, A (A1 and A2), B and AB subjects, and the extent of which varied between Americans of European (EA) and African (AA) descent. We validated a strong influence of ABO blood type on VWF levels (15.2%), but also detected a direct ABO influence on FVIII activity (0.6%) and FVIII/VWF ratio (3.8%) after adjustment for VWF. We determined that FVIII activity changed 0.54% for every 1% change in VWF antigen level. This VWF-FVIII relationship differed between subjects with O and B blood types in EA, AA, and in male, but not female subjects. Variations in FVIII activity were primarily detected at low VWF levels. These new quantitative influences on VWF, FVIII and the FVIII/VWF ratio help understand how ABO genotypes differentially influence VWF, FVIII and their ratio, particularly in racial and gender specific manners.     

Distinct Roles of Ser-764 and Lys-773 at the N Terminus of von Willebrand Factor in Complex Assembly with Coagulation Factor VIII

Complex formation between coagulation factor VIII (FVIII) and von Willebrand factor (VWF) is of critical importance to protect FVIII from rapid in vivo clearance and degradation. We have now employed a chemical footprinting approach to identify regions on VWF involved in FVIII binding. To this end, lysine amino acid residues of VWF were chemically modified in the presence of FVIII or activated FVIII, which does not bind VWF. Nano-LC-MS analysis showed that the lysine residues of almost all identified VWF peptides were not differentially modified upon incubation of VWF with FVIII or activated FVIII. However, Lys-773 of peptide Ser-766–Leu-774 was protected from chemical modification in the presence of FVIII. In addition, peptide Ser-764–Arg-782, which comprises the first 19 amino acid residues of mature VWF, showed a differential modification of both Lys-773 and the α-amino group of Ser-764. To verify the role of Lys-773 and the N-terminal Ser-764 in FVIII binding, we employed VWF variants in which either Lys-773 or Ser-764 was replaced with Ala. Surface plasmon resonance analysis and competition studies revealed that VWF(K773A) exhibited reduced binding to FVIII and the FVIII light chain, which harbors the VWF-binding site. In contrast, VWF(S764A) revealed more effective binding to FVIII and the FVIII light chain compared with WT VWF. The results of our study show that the N terminus of VWF is critical for the interaction with FVIII and that Ser-764 and Lys-773 have opposite roles in the binding mechanism.     

Low density lipoprotein receptor-related protein and factor IXa share structural requirements for binding to the A3 domain of coagulation factor VIII

Low-density lipoprotein receptor-related protein (LRP) is an endocytic receptor that binds multiple distinct ligands, including blood coagulation factor VIII (FVIII). FVIII is a heterodimeric multidomain protein that consists of a heavy chain (domains A1, a1, A2, a2, and B) and a light chain (domains a3, A3, C1, and C2). Both chains contribute to high-affinity interaction with LRP. One LRP-interactive region has previously been located in the C2 domain, but its affinity is low in comparison with that of the entire FVIII light chain. We now have compared a variety of FVIII light chain derivatives with the light chain of its homolog FVa for LRP binding. In surface plasmon resonance studies employing LRP cluster II, the FVa and FVIII light chains proved different in that only FVIII displayed high-affinity binding. Because the FVIII a3-A3-C1 fragment was effective in associating with LRP, this region was explored for structural elements that are exposed but not conserved in FV. Competition studies using synthetic peptides suggested that LRP binding involves the FVIII-specific region Lys(1804)-Ala(1834) in the A3 domain. In line with this observation, LRP binding was inhibited by a recombinant antibody fragment that specifically binds to the FVIII sequence Glu(1811)-Lys(1818). The role of this sequence in LRP binding was further tested using a FVIII/FV chimera in which sequence Glu(1811)-Lys(1818) was replaced with the corresponding sequence of FV. Although this chimera still displayed residual binding to LRP cluster II, its affinity was reduced. This suggests that multiple sites in FVIII contribute to high-affinity LRP binding, one of which is the FVIII A3 domain region Glu(1811)-Lys(1818). This suggests that LRP binding to the FVIII A3 domain involves the same structural elements that also contribute to the assembly of FVIII with FIXa.     

Expression of blood clotting factor VIII:C gene in capillary endothelial cells.

The essential role of Factor VIII:C (FVIII:C, anti-hemophilia factor A) as a cofactor for Factor IXa-dependent activation of Factor X has been established. In this paper, we describe that capillary endothelial cells from bovine adrenal medulla express active FVIII:C gene. Accumulation of FVIII:C in conditioned media from an 8-day-old culture is approximately twice as high as that stored in the cell when immunoprecipitated FVIII:C was analyzed for its ability to convert Factor X to Factor Xa. Analysis of [35S]methionine-labeled and immunoprecipitated FVIII:C from cells or conditioned media on SDS-PAGE under fully denatured conditions indicated that the newly synthesized FVIII:C consists of heavy chain of M(r) 200,000 and light chain of M(r) 46,000. The secreted FVIII:C in the non-reduced condition however, has a molecular weight of 270,000 which suggests that in native protein, the heavy and light chains are held together by S-S bonds. Furthermore, susceptibility of the immunoprecipitated FVIII:C to N-glycanase digestion establishes that the endothelial cells derived FVIII:C contains asparagine-linked carbohydrate side chains.     

Durable engraftment of genetically modified FVIII‐secreting autologous bone marrow stromal cells in the intramedullary microenvironment

Genetically modified FVIII‐expressing autologous bone marrow‐derived mesenchymal stromal cells (BMSCs) could cure haemophilia A. However, culture‐expanded BMSCs engraft poorly in extramedullary sites. Here, we compared the intramedullary cavity, skeletal muscle, subcutaneous tissue and systemic circulation as tissue microenvironments that could support durable engraftment of FVIII‐secreting BMSC in vivo. A zinc finger nuclease integrated human FVIII transgene into PPP1R12C (intron 1) of culture‐expanded primary canine BMSCs. FVIII‐secretory capacity of implanted BMSCs in each dog was expressed as an individualized therapy index (number of viable BMSCs implanted × FVIII activity secreted/million BMSCs/24 hours). Plasma samples before and after implantation were assayed for transgenic FVIII protein using an anti‐human FVIII antibody having negligible cross‐reactivity with canine FVIII. Plasma transgenic FVIII persisted for at least 48 weeks after implantation in the intramedullary cavity. Transgenic FVIII protein levels were low after intramuscular implantation and undetectable after both intravenous infusion and subcutaneous implantation. All plasma samples were negative for anti‐human FVIII antibodies. Plasma concentrations and durability of transgenic FVIII secretion showed no correlation with the therapy index. Thus, the implantation site microenvironment is crucial. The intramedullary microenvironment, but not extramedullary tissues, supported durable engraftment of genetically modified autologous FVIII‐secreting BMSCs.     

Heterogeneity of the immune response to adenovirus-mediated factor VIII gene therapy in different inbred hemophilic mouse strains

BACKGROUND: The development of anti-factor VIII (FVIII) antibodies (inhibitors) is a critical concern when considering gene therapy as a potential treatment modality for hemophilia A. We used a hemophilia A mouse model bred on different genetic backgrounds to explore genetically controlled differences in the immune response to FVIII gene therapy. METHODS: C57BL/6 FVIII knockout (C57-FVIIIKO) mice were bred with normal BALB/c (BAL) mice, to generate a recombinant congenic BAL-FVIIIKO model of hemophilia A. Early generation adenoviral (Ad) vectors containing the canine FVIII B-domain-deleted transgene under the control of either the CMV promoter or a tissue-restricted (TR) promoter were administered to C57-FVIIIKO, C57xBAL(F1)-FVIIIKO crosses, and BAL-FVIIIKO mice. FVIII expression, inhibitor development, inflammation, and vector-mediated toxicity were assessed. RESULTS: In response to administration of Ad-CMV-cFVIII, C57-FVIIIKO mice attain 3-fold higher levels of FVIII expression than BAL-FVIIIKO. All strains injected with Ad-CMV-FVIII displayed FVIII expression lasting only 2 weeks, with associated inhibitor development. C57-FVIII-KO mice that received Ad-TR-FVIII expressed FVIII for 12 months post-injection, whereas FVIII expression was limited to 1 week in C57xBAL(F1)-FVIIIKO and BAL-FVIIIKO mice. This loss of expression was associated with anti-FVIII inhibitor development. BAL-FVIIIKO mice showed increased hepatotoxicity with alanine aminotransferase levels reaching 4-fold higher levels than C57-FVIIIKO mice. However, C57-FVIIIKO mice initiate a more rapid and effective cell-mediated clearance of virally transduced cells than BAL-FVIIIKO, as evidenced by real-time PCR analysis of transduced tissues. Overall, strain-dependent differences in the immune response to FVIII gene delivery were only noted in the adaptive response, and not in the innate response. CONCLUSIONS: Our results indicate that the genetic background of the murine model of hemophilia A influences FVIII expression levels, the development of anti-FVIII inhibitors, clearance of transduced cells, and the severity of vector-mediated hepatotoxicity.     

Domain organization of membrane‐bound factor VIII

Factor VIII (FVIII) is the blood coagulation protein which when defective or deficient causes for hemophilia A, a severe hereditary bleeding disorder. Activated FVIII (FVIIIa) is the cofactor to the serine protease factor IXa (FIXa) within the membrane‐bound Tenase complex, responsible for amplifying its proteolytic activity more than 100,000 times, necessary for normal clot formation. FVIII is composed of two noncovalently linked peptide chains: a light chain (LC) holding the membrane interaction sites and a heavy chain (HC) holding the main FIXa interaction sites. The interplay between the light and heavy chains (HCs) in the membrane‐bound state is critical for the biological efficiency of FVIII. Here, we present our cryo‐electron microscopy (EM) and structure analysis studies of human FVIII‐LC, when helically assembled onto negatively charged single lipid bilayer nanotubes. The resolved FVIII‐LC membrane‐bound structure supports aspects of our previously proposed FVIII structure from membrane‐bound two‐dimensional (2D) crystals, such as only the C2 domain interacts directly with the membrane. The LC is oriented differently in the FVIII membrane‐bound helical and 2D crystal structures based on EM data, and the existing X‐ray structures. This flexibility of the FVIII‐LC domain organization in different states is discussed in the light of the FVIIIa–FIXa complex assembly and function. © 2013 Wiley Periodicals, Inc. Biopolymers 99: 448–459, 2013.     

Storage of factor VIII variants with impaired von Willebrand factor binding in Weibel-Palade bodies in endothelial cells

Background

Point mutations resulting in reduced factor VIII (FVIII) binding to von Willebrand factor (VWF) are an important cause of mild/moderate hemophilia A. Treatment includes desmopressin infusion, which concomitantly increases VWF and FVIII plasma levels, apparently from storage pools containing both proteins. The source of these VWF/FVIII co-storage pools and the mechanism of granule biogenesis are not fully understood.

Methodology/Principal Findings

We studied intracellular trafficking of FVIII variants implicated in mild/moderate hemophilia A together with VWF in HEK293 cells and primary endothelial cells. The role of VWF binding was addressed using FVIII variants displaying reduced VWF interaction. Binding studies using purified FVIII proteins revealed moderate (Arg2150His, Del2201, Pro2300Ser) to severe (Tyr1680Phe, Ser2119Tyr) VWF binding defects. Expression studies in HEK293 cells and primary endothelial cells revealed that all FVIII variants were present within VWF-containing organelles. Quantitative studies showed that the relative amount of FVIII storage was independent of various mutations. Substantial amounts of FVIII variants are co-stored in VWF-containing storage organelles, presumably by virtue of their ability to interact with VWF at low pH.

Conclusions

Our data suggest that the potential of FVIII co-storage with VWF is not affected in mild/moderate hemophilia A caused by reduced FVIII/VWF interaction in the circulation. These data support the hypothesis that Weibel-Palade bodies comprise the desmopressin-releasable FVIII storage pool in vivo.     

Chemical Chaperones Improve Protein Secretion and Rescue Mutant Factor VIII in Mice with Hemophilia A

Inefficient intracellular protein trafficking is a critical issue in the pathogenesis of a variety of diseases and in recombinant protein production. Here we investigated the trafficking of factor VIII (FVIII), which is affected in the coagulation disorder hemophilia A. We hypothesized that chemical chaperones may be useful to enhance folding and processing of FVIII in recombinant protein production, and as a therapeutic approach in patients with impaired FVIII secretion. A tagged B-domain-deleted version of human FVIII was expressed in cultured Chinese Hamster Ovary cells to mimic the industrial production of this important protein. Of several chemical chaperones tested, the addition of betaine resulted in increased secretion of FVIII, by increasing solubility of intracellular FVIII aggregates and improving transport from endoplasmic reticulum to Golgi. Similar results were obtained in experiments monitoring recombinant full-length FVIII. Oral betaine administration also increased FVIII and factor IX (FIX) plasma levels in FVIII or FIX knockout mice following gene transfer. Moreover, in vitro and in vivo applications of betaine were also able to rescue a trafficking-defective FVIII mutant (FVIIIQ305P). We conclude that chemical chaperones such as betaine might represent a useful treatment concept for hemophilia and other diseases caused by deficient intracellular protein trafficking.     

Mapping the Binding Region on the Low Density Lipoprotein Receptor for Blood Coagulation Factor VIII

Low density lipoprotein receptor (LDLR) was shown to mediate clearance of blood coagulation factor VIII (FVIII) from the circulation. To elucidate the mechanism of interaction of LDLR and FVIII, our objective was to identify the region of the receptor necessary for binding FVIII. Using surface plasmon resonance, we found that LDLR exodomain and its cluster of complement-type repeats (CRs) bind FVIII in the same mode. This indicated that the LDLR site for FVIII is located within the LDLR cluster. Similar results were obtained for another ligand of LDLR, α-2-macroglobulin receptor-associated protein (RAP), a common ligand of receptors from the LDLR family. We further generated a set of recombinant fragments of the LDLR cluster and assessed their structural integrity by binding to RAP and by circular dichroism. A number of fragments overlapping CR.2-5 of the cluster were positive for binding RAP and FVIII. The specificity of these interactions was tested by site-directed mutagenesis of conserved tryptophans within the LDLR fragments. For FVIII, the specificity was also tested using a single-chain variable antibody fragment directed against the FVIII light chain as a competitor. Both cases resulted in decreased binding, thus confirming its specificity. The mutagenic study also showed an importance of the conserved tryptophans in LDLR for both ligands, and the competitive binding results showed an involvement of the light chain of FVIII in its interaction with LDLR. In conclusion, the region of CR.2-5 of LDLR was defined as the binding site for FVIII and RAP.     

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.     

Structural and functional characterization of platelet receptor-mediated factor VIII binding

Optimal rates of factor X (FX) activation require occupancy of receptors for factor IXa (FIXa), factor VIII (FVIII), and FX on the activated platelet surface. The presence of FVIII and FX increases 5-fold the affinity of FIXa for the surface of activated platelets, and the presence of FVIII or FVIIIa generates a high affinity, low capacity specific FX-binding site on activated platelets. We have now examined the effects of FX and active site-inhibited FIXa (EGR-FIXa) on the binding of both FVIII and FVIIIa to activated platelets and show the following: (a) von Willebrand factor inhibits FVIII binding (K(i) = 0.54 nM) but not FVIIIa binding; (b) thrombin and the thrombin receptor activation peptide (SFLLRN amide) are the most potent agonists required for FVIII-binding site expression, whereas ADP is inert; (c) FVa does not compete with FVIIIa or FVIII for functional platelet-binding sites; and (d) Annexin V is a potent inhibitor of FVIIIa binding (IC(50) = 10 nM) to activated platelets. The A2 domain of FVIII significantly increases the affinity and stoichiometry of FVIIIa binding to platelets and contributes to the stability of the FX-activating complex. Both FVIII and FVIIIa binding were specific, saturable, and reversible. FVIII binds to specific, high affinity receptors on activated platelets (n = 484 +/- 59; K(d) = 3.7 +/- 0.31 nM) and FVIIIa interacts with an additional 300-500 sites per platelet with enhanced affinity (K(d) = 1.5 +/- 0.11 nM). FVIIIa binding to activated platelets in the presence of FIXa and FX is closely coupled with rates of F-X activation. The presence of EGR-FIXa and FX increases both the number and the affinity of binding sites on activated platelets for both FVIII and FVIIIa, emphasizing the validity of a three-receptor model in the assembly of the F-X-activating complex on the platelet surface.