Fractionation of human antibody to factor VIII:C: an IRMA for phospholipid binding sites on factor VIII C: Ag

Labelled Fab' fragments, derived from the plasma of a severe haemophiliac with antibody directed against factor VIII clotting antigen (VIII C:Ag), were fractionated by immunoabsorption with, first, a complex of phospholipid (PL) vesicles and factor VIII and, second, with factor VIII alone. Two pools of labelled anti-VIII C:Ag were obtained and were used in immunoradiometric assays (IRMAs) for VIII C:Ag. With one pool (non-PL-site antibody) VIII C:Ag assays were unaffected by pre-incubation of factor VIII with PL vesicles; however, binding of the second pool of antibody to VIII C:Ag was prevented by PL preincubation, indicating that these antibody molecules bind at or near a phospholipid binding site on VIII C:Ag (PL-site antibody). Assays of VIII C:Ag in an intermediate purity factor VIII concentrate with these two antibody pools indicate that more than one third of the VIII C:Ag may be bound to PL.     

Development of factor VIII:C antibodies in dogs with hemophilia A (factor VIII:C deficiency)

Classic hemophilia A (factor VIII:C deficiency) was diagnosed in a miniature Schnauzer dog and a breeding program established. Inbreeding and crossbreeding produced 16 hemophilic animals. All were initially treated with canine cryoprecipitate, as required, for sporadic hemorrhagic events. Five animals developed potent antibodies to canine factor VIII:C. All were the offspring of obligate carriers, resulting from the mating of a hemophilic purebred miniature Schnauzer male to a normal female Brittany spaniel. The mean age at first treatment and factor VIII exposure at the time of inhibitor development was 10.3 wk and 286.3 U, respectively. The remaining hemophilic animals have not developed antibodies, despite receiving a mean factor VIII dosage of 1.5 X 10(3) U. This group includes animals derived from a mating between the same purebred miniature Schnauzer hemophilic male and a purebred miniature Schnauzer carrier female. In each case, the antibodies recognize both canine and human but not porcine VIII:C. They are non-precipitating IgG immunoglobulins. Following inhibitor development, infusion of canine cryoprecipitate was hemostatically ineffective and factor VIII:C recovery at 30 min was negligible. Infusion of a concentrate of porcine factor VIII resulted in a correction of the hemostatic defect and optimal factor VIII:C recovery. All animals receiving porcine factor VIII:C subsequently developed antibodies to this protein. The chance occurrence of this complication should facilitate further studies directed at elucidating the pathogenesis and management of hemophilia complicated by the development of antibodies to factor VIII:C.     

Synthetic factor VIII peptides with amino acid sequences contained within the C2 domain of factor VIII inhibit factor VIII binding to phosphatidylserine

The effective activation of factor X by factor IXa requires the co-factor activity of activated factor VIII (FVIII). Factor Xa formation is also dependent on the presence of negatively charged phospholipid. A phospholipid binding domain of FVIII has been reported to be present on the FVIII light chain. Recent observations on a subset of human FVIII inhibitors have implicated the carboxyl-terminal C2 domain of FVIII as containing a possible phospholipid binding site. The purpose of this study was to investigate directly the role of the C2 domain in phospholipid binding. Twenty-six overlapping peptides, which span the entire C2 domain of FVIII, were synthesized. The ability of these peptides to inhibit the binding of purified human FVIII to immobilized phosphatidylserine was evaluated in an enzyme-linked immunosorbent assay. Three overlapping synthetic FVIII peptides, 2303-2317, 2305-2332, and 2308-2322, inhibited FVIII binding to phosphatidylserine by greater than 90% when tested at a concentration of 100 mumols/L. A fourth partially overlapping peptide, 2318-2332, inhibited FVIII binding by 65%. These results suggest that the area described by these peptides, residues 2303 to 2332, may play an important role in the mediation of FVIII binding to phospholipid.     

Discrepant in vivo recovery of factor VIII:C following infusion of two different monoclonal factor VIII preparations

Background: We experienced decreased recovery of factor VIII:C after commercial monoclonal factor VIII infusions. We report the recovery data obtained from infusing two brands of monoclonal factor VIII.Methods: Factor VIII:C activity was measured before and after an infusion of one of two monoclonal factor VIII preparations. The increments were calculated and expressed as a function of units of factor VIII administered per kilogram.Results: Monoclate increments averaged 2.3% (range: 1.6–3.2%). Antihemophilic factor (human) method M (AHFM) yielded an average increment of 1.4% (range: 1–1.7%).Conclusions: The two monoclonal factor VIII preparations used are not equivalent in activity. In switching brands, one must recalculate the prescribed dose based on the institution's experience in recovery of VIII:C from the particular brand to be prescribed. Cost calculations and comparisons should be based on the recovered factor VIII:C increments rather the unit purchase price.     

A human antibody directed to the factor VIII C1 domain inhibits factor VIII cofactor activity and binding to von Willebrand factor

The occurrence of factor VIII (fVIII) inhibitory antibodies is a rare complication of fVIII substitution therapy in mild/moderate hemophilia A patients. fVIII mutations in certain regions such as the C1 domain are, however, more frequently associated with inhibitor, for reasons which remain unclear. To determine whether inhibitors could map to the mutation site, we analyzed at the clonal level the immune response of such a patient with an inhibitor to wild-type but not self-fVIII and an Arg2150His substitution in the C1 domain. Immortalization of the patient B lymphocytes provided a cell line producing an anti-fVIII IgG4kappa antibody, LE2E9, that inhibited fVIII cofactor activity, following type 2 kinetics and prevented fVIII binding to von Willebrand factor. Epitope mapping with recombinant fVIII fragments indicated that LE2E9 recognized the fVIII C1 domain, but not the Arg2150His-substituted C1 domain. Accordingly, LE2E9 did not inhibit Arg2150His fVIII activity. These observations identify C1 as a novel target for fVIII inhibitors and demonstrate that Arg2150His substitution alters a B-cell epitope in the C1 domain, which may contribute to the higher inhibitor incidence in patients carrying such substitution. (Blood. 2000; 95:156-163)     

Relationships between factor VIII:Ag and factor VIII in recombinant and plasma-derived factor VIII concentrates

A variety of plasma-derived (pd) and recombinant (r) factor VIII (FVIII) concentrates are used to prevent and treat bleeding in severe hemophilia A patients. A significant side effect of FVIII replacement is the development of FVIII neutralizing antibodies (inhibitors) in up to 30% of patients receiving FVIII concentrates. The FVIII protein content (FVIII:Ag) per unit of FVIII:C in FVIII concentrates, and how effectively the FVIII:Ag in FVIII concentrates binds to von Willebrand factor (VWF) may provide information relevant for the survival of FVIII:C in vivo and for estimating the risk for inhibitor development. The FVIII:Ag content of nine r-FVIII and nine pd-FVIII concentrates were quantified in this study using two enzyme-linked immunosorbent assay (ELISA) platforms. The two ELISA platforms were based on the use of a monoclonal anti-(FVIII light chain)-IgG and polyclonal anti-FVIII antibodies as capture antibodies and both ELISAs were equally able to detect > or =0.005 IU of FVIII:Ag. Measured in international units, the r-FVIII concentrates contained significantly higher FVIII:Ag per unit of FVIII:C than the pd-FVIII concentrates. The VWF-binding profiles of the r-FVIII and pd-FVIII concentrates were also determined by gel filtration chromatography. Unlike the plasma-derived products, the r-FVIII concentrates invariably contained a fraction of FVIII:Ag molecules (approximately 20%) which was unable to associate with VWF. Given that VWF regulates both factor VIII proteolysis and survival of FVIII:Ag in vivo, the fraction of FVIII:Ag unable to bind to VWF may have a reduced survival and be more susceptible to proteolytic degradation in vivo. The extent to which the fractions of FVIII:Ag in concentrates able and unable to bind to VWF contribute to inhibitor development in severe FVIII-deficient patients is unknown.     

The factor VIII C1 domain contributes to platelet binding

Activated factor VIII (FVIIIa) forms a procoagulant complex with factor IXa on negatively charged membranes, including activated platelet surfaces. Membrane attachment involves the FVIII C2 domain; involvement of the adjacent C1 domain has not been established. Binding of recombinant FVIII C1C2 and C2 proteins to platelets was detected by flow cytometry using (1) anti-C2 monoclonal antibody ESH8 followed by a phycoerythrin-labeled secondary antibody; (2) biotinylated C1C2 detected by phycoerythrin-labeled streptavidin, and (3) C1C2 and C2 site-specifically labeled with fluorescein. Highest binding and lowest background were obtained using fluorescein-conjugated proteins. More than 90% of activated platelets bound C1C2, compared with approximately 50% for equimolar C2. Estimates using fluorescent microbeads indicated approximately 7,000 C1C2-binding sites per platelet, approximately 1,400 for C2, and approximately 3,000 for fluorescein-labeled FVIIIa. Unlike C2 or FVIII(a), C1C2 bound to approximately 700 sites/platelet before activation. C1C2 binding to activated platelets appeared independent of von Willebrand factor and was competed effectively by FVIII(a), but only partially by excess C2. Fluorescein-labeled FVIIIa was competed much more effectively by C1C2 than C2 for binding to activated platelets. Two monoclonal antibodies that inhibit C2 binding to membranes competed platelet binding of C2 more effectively than C1C2. Thus, the C1 domain of FVIII contributes to platelet-binding affinity.     

Stabilization of thrombin-activated porcine factor VIII:C by factor IXa phospholipid

The activation of porcine factor X by an enzymatic complex consisting of activated factor IX (factor IXa), thrombin-activated factor VIII:C (factor VIII:Ca), phospholipid vesicles, and calcium was studied in the presence of an irreversible inhibitor of factor Xa, 5-dimethylamino- naphthalene-1-sulfonyl-glutamyl-glycyl-arginyl- chloro met hyl ketone ( DEGR -CK). The formation of factor Xa was measured continuously by monitoring the increase in solution fluorescence intensity that occurs upon formation of DEGR -factor Xa. Omission of any component from the enzymatic complex reduced the reaction rate to a negligible level. In the presence of fixed excess factor IXa, the velocity of factor X activation was linearly dependent on the concentration of factor VIII:C, and thus, provided a plasma-free assay of factor VIII:C. Activation of factor VIII:C by 0.1 NIH U/ml thrombin in the presence of factor IXa, phospholipid vesicles, and calcium, followed at variable time intervals by the addition of factor X and DEGR -CK, was complete within 5 min, as judged by the fluorometric assay, and resulted in little or no loss of factor VIII:C activity over a period of 20 min; whereas, activation in the absence of either IXa or phospholipid vesicles decreased the half-life of factor VIII:C to approximately 5 min. Analysis of 125I-factor VIII:C-derived activation peptides by sodium dodecyl sulfate polyacrylamide gel radioelectrophoresis revealed identical results, regardless of whether factor IXa and/or phospholipid vesicles were included in the activation, suggesting that the lability of factor VIII:Ca is not due to a major alteration of its primary structure. We conclude that the activated porcine factor VIII:C molecule is stabilized markedly because of its interaction with factor IXa and phospholipid.     

Binding of factor VIII inhibitors to discrete regions of the factor VIII C2 domain disrupt phospholipid binding.

We characterized seven factor VIII inhibitors with epitopes in the C2 domain of factor VIII using a series of factor V C2 domain chimeras that substituted exon-sized fragments of the C2 domain of factor VIII for the corresponding regions of factor V. All inhibited co-factor activity of factor VIII and six inhibited binding of factor VIII to phosphatidylserine. Inhibitors Hz, JN and GK32 bound epitopes within amino acids S2173-K2281; inhibitors GK24 and TO bound epitopes within amino acids V2223-Y2332; and inhibitors UNC11 and UNC12 bound epitopes throughout the C2 domain (amino acids S2173-Y2332). Inhibitors Hz, JN and UNC12 inhibited the co-factor activity of chimera 5A, which substituted amino acids S2173-Q2222 of factor VIII for the corresponding region of factor V, in a prothrombinase assay. This inhibition could be partially reversed by pre-incubation of chimera 5A with phospholipid vesicles, suggesting that these antibodies interfered with phospholipid binding. Inhibitors UNC11 and UNC12, on the other hand, did not inhibit the binding of chimera 1 A to phosphatidylserine, suggesting that binding to the segment spanning amino acids V2282-Y2332 does not necessarily block phospholipid binding. These results agree with the model of the phospholipid-binding site determined by crystal structure of the C2 domain of factor VIII.     

A novel cause of mild/moderate hemophilia A: mutations scattered in the factor VIII C1 domain reduce factor VIII binding to von Willebrand factor

The mechanisms responsible for the low factor VIII (fVIII) activity in the plasma of patients with mild/moderate hemophilia A are poorly understood. In such patients, we have identified a series of fVIII mutations (Ile2098Ser, Ser2119Tyr, Asn2129Ser, Arg2150His, and Pro2153Gln) clustered in the C1 domain and associated with reduced binding of fVIII to von Willebrand factor (vWf). For each patient plasma, the specific activity of mutated fVIII was close to that of normal fVIII. Scatchard analysis showed that the affinity for vWf of recombinant Ile2098Ser, Ser2119Tyr, and Arg2150His fVIII mutants was reduced 8-fold, 80-fold, and 3-fold, respectively, when compared with normal fVIII. Given the importance of vWf for the stability of fVIII in plasma, these findings suggested that the reduction of fVIII binding to vWf resulting from the above-mentioned mutations could contribute to patients' low fVIII plasma levels. We, therefore, analyzed the effect of vWf on fVIII production by Chinese hamster ovary (CHO) cells transfected with expression vectors for recombinant B domain-deleted normal, Ile2098Ser, Ser2119Tyr, and Arg2150His fVIII. These 3 mutations impaired the vWf-dependent accumulation of functional fVIII in culture medium. Analysis of fVIII production by transiently transfected CHO cells indicated that, in addition to the impaired stabilization by vWf, the secretion of functional Ile2098Ser and Arg2150His fVIII was reduced about 2-fold and 6-fold, respectively, by comparison to Ser2119Tyr and normal fVIII. These findings indicate that C1-domain mutations resulting in reduced fVIII binding to vWf are an important cause of mild/moderate hemophilia A.     

Studies on the stability of factor VIII coagulant antigen (VIII: CAg) in the presence of VIII: C antibodies

S ummary . The stability of factor VIII coagulant antigens (VIII:CAg) at 56°C was investigated using an immunoradiometric assay for VIII: CAg. In normal or CRM⁺ haemophilic plasmas VIII: CAg was rapidly inactivated at 56°C. VIII: CAg in spontaneous VIII: C inhibitor plasmas and in post-treatment samples from haemophiliacs with VIII: C inhibitor was resistant to inactivation at 56°C, indicating the presence of heat stable VIII: CAg-anti VIII: CAg complexes.
In vitro VIII: CAg-anti VIII: CAg complexes were formed by incubation of diluted VIII: C antibodies and normal plasma and the stability of these complexes at 56°C was studied. Haemophilic VIII: CAg antibodies formed heat stable immune complexes over a narrow range of inhibitor dilutions whilst some spontaneous VIII: CAg antibodies formed these stable complexes over a much wider range of dilutions emphasizing the difference in the properties of these antibodies.     

Cardiac tamponade in a patient with moderate hemophilia A and factor VIII Inhibitors

Cardiac tamponade is a rare, life-threatening complication of hemophilia. The management of pericardial bleeding in hemophilia A patients with inhibitors is particularly challenging because antibodies to factor (F) VIII render the use of high-dose FVIII ineffective. Fortunately, the management of uncontrollable bleeding in patients with hemophilia and inhibitors has improved since the introduction of treatments that bypass the need for FVIII and FIX. A case of hemopericardium complicated by cardiac tamponade occurring one month following an upper respiratory tract infection in a patient with hemophilia and FVIII inhibitors is presented. Management of the present case was based on current guidelines on the use of recombinant FVIIa for acute bleeding in patients with hemophilia and inhibitors. The subsequent development of hemothorax in the present case indicates that a more protracted course of recombinant FVIIa is justified following pericardiocentesis for pericardial bleeding in hemophilia with inhibitors. Alternative approaches to the management of this complication are also reviewed.     

Alloantibodies to therapeutic factor VIII in hemophilia A: the role of von Willebrand factor in regulating factor VIII immunogenicity

The rising incidence of neutralizing antibodies (inhibitors) against therapeutic factor VIII prompted the conduct of studies to answer the question as to whether this rise is related to the introduction of recombinant factor VIII products. The present article summarizes current opinions and results of non-clinical and clinical studies on the immunogenic potential of recombinant compared to plasma-derived factor VIII concentrates. Numerous studies provided circumstantial evidence that von Willebrand factor, the natural chaperone protein present in plasma-derived factor VIII products, plays an important role in protecting exogenous factor VIII from uptake by antigen presenting cells and from recognition by immune effectors. However, the definite contribution of von Willebrand factor in reducing the inhibitor risk and in the achievement of immune tolerance is still under debate.     

Alloantibodies to factor VIII in haemophilia

Summary. Up to one‐third of haemophilia A patients develop factor VIII (FVIII) alloantibodies (inhibitors). The Bethesda assay detects inhibitors but is relatively insensitive. Recently, a new fluorescence‐based immunoassay (FLI) was developed for antibody detection. The aim of this study was to assess the prevalence of inhibitors as measured by FLI. Assays of FVIII, FVIII inhibitor by Bethesda assay with Nijmegen modification, and FVIII inhibitor by FLI were performed on adult patients with haemophilia A. Data were complete for 46 patients (median age 39), of whom 72% were severe, 7% moderate and 22% mild. The Bethesda assay was positive in only two patients (4%), while FLI was positive in 23 of 46 patients (50%), with values ranging from 0.4 to 33.7 nm (median 3.5 nm ). FLI titres exceeded 7.0 nm in 19.5% of patients, all but one of whom had severe haemophilia. FLI antibody‐positive patients were less likely to be HIV positive (30% vs. 70%, P = 0.02). The use of a prophylaxis regimen was associated with a lower incidence of antibody; only two of 23 patients with detectable antibody and none of those with antibody >7 nm were on a prophylaxis regimen, while nine of 23 patients without antibody were on prophylaxis, (P = 0.03). There was no difference in inhibitor presence in patients using recombinant versus plasma‐derived factor. Antibodies detected by FLI are frequent in patients with haemophilia A, but are less common in those who are HIV positive or are receiving regular FVIII prophylaxis.     

Inhibitor antibodies to factor VIII and factor IX: management

Inhibitor antibodies directed against factor VIII or factor IX present challenges to the clinician. Fortunately, several management options are available, although each has disadvantages as well as advantages. Alloantibodies against factor VIII (which develop in 25 to 50% of children with severe hemophilia A, as well as in a small percentage of children with mild or moderate hemophilia A) may be low titer and transient or may be high titer. Most patients with high-titer problematic inhibitors now try to eliminate the inhibitor by using one of several immune tolerance induction (ITI) regimens. For treatment of bleeding episodes in patients who have high-titer (> or = 5 Bethesda units) inhibitors, one can use a prothrombin complex concentrate (PCC) (preferably an activated PCC [APCC]), recombinant (r) factor VIIa, or porcine factor VIII. The choice of product is generally dependent on the type and severity of the patient's bleeding, degree of cross-reactivity of the patient's inhibitor with porcine factor VIII, physician familiarity with the product, product availability, and cost. In persons with hemophilia B, alloantibodies occur in only 1 to 3% of severely affected individuals. However, in roughly half of those who develop inhibitors, anaphylaxis or severe allergic reactions occur on infusion of any type of factor IX-containing product. This phenomenon usually develops after relatively few exposures to factor IX; thus it is recommended that the first 10 to 20 infusions of factor IX given to children with severe hemophilia B be given in a setting equipped for treatment of shock. For treatment of bleeding episodes in patients with severe allergic reactions, rF VIIa is the treatment of choice. ITI has been less successful in hemophilia B patients with inhibitors than in those with hemophilia A, and in a subgroup of patients with severe allergic reactions who were desensitized to factor IX and then tried on ITI, results were even poorer. Additionally, several developed nephrotic syndrome while on ITI. For hemophilia B patients with inhibitors who do not have allergic reactions to factor IX, bleeding episodes can be treated with PCC or APCC or with rF VIIa. Autoantibodies directed against factor VIII are rare but can occur in a variety of settings. They occur mainly in adults, and bleeding is often severe and life threatening. Although some factor VIII autoantibodies disappear spontaneously, most require immunosuppression. Corticosteroids and cyclophosphamide are generally recommended. For treatment of bleeding, therapeutic options include (human) factor VIII concentrates, porcine factor VIII, APCC, and rFVIIa. The choice of product is generally determined by the consulting hematologist's familiarity with the product, product availability and cost, as well as response to treatment.     

Spontaneous Inhibitors of Factor VIII

Factor-VIII inhibitors accompanying severe allergic reactions to penicillin have now been described in six patients. The inhibitor in the present case was identified as an IgG-globulin, and seemed to originate from the altered immunologic state induced by the allergic reaction, rather than being specifically related to penicillin or penicillin antibody. During the performance of these experiments it was observed that unusually strong solutions of penicillin were capable of removing antibody globulin from plasma. After incubation with penicillin, the Factor-VIII inhibitors of non-haemophilic origin (designated ‘spontaneous’inhibitors) appeared to retain greater activity than did those of haemophiliacs. The reason for this greater activity was made clear by an examination of the kinetics of the reaction between spontaneous inhibitors and Factor VIII. Spontaneous inhibitors were capable of inactivating amounts of Factor VIII out of proportion to their degree of dilution. They also inactivated the Factor VIII more rapidly than did haemophilic inhibitors, but permitted more residual Factor-VIII activity. This residual activity was reduced more than expected by subsequent incubation with haemophilic inhibitors, and less than expected with spontaneous inhibitors. It was suggested that one molecule of a spontaneous inhibitor was capable of complexing more than one molecule of Factor VIII, but that the Factor-VIII molecules in the complex retained some degree of Factor-VIII activity. This activity could be removed by subsequent incubation with haemophilic inhibitors but not with spontaneous ones. Identification of the type of inhibitor was important from a therapeutic standpoint. While repeated additions of Factor VIII to the plasma of patients with inhibitors of haemophilic origin resulted in increasing levels of Factor VIII, such was not the case with spontaneous inhibitors. If the initial addition of Factor VIII failed to provide a therapeutic level, repeated additions were not likely to do so. Although the kinetics of the reaction between spontaneous inhibitors and porcine AHG were similar to those described with human Factor VIII, the inhibitors were always less active against the animal preparation. Treatment with d -penicillamine, high concentrations of penicillin, immunosuppressive agents, and corticosteroids proved to be of limited value in patients with spontaneous inhibitors. It was concluded that a vigorous attack on the coexistent disorder responsible for stimulating the production of the inhibitor offered the best prognosis for the patient.     

Characterization of Factor VIII Inhibitors

Factor VIII (FVIII) inhibitors develop as either alloantibodies against exogenous FVIII in patients with congenital hemophilia A after FVIII-replacement therapy or as autoantibodies against endogenous FVIII in previously healthy, nonhemophilic individuals. The predominant immunoglobulin G (IgG) subclass of FVIII inhibitors is IgG(4). The main epitopic regions are known to be located, however, in the A2, A3, and C2 domains. The A2 and A3 epitopes have been identified between amino acid residues 484 and 509 and residues 558 and 565, respectively. Both of these regions are close to the binding sites for activated FIX (FIXa). Two regions have been identified in the C2 domain, one in the amino-terminal portion of the domain (residues 2181-2243) and the other in the carboxy-terminal portion of the domain (residues 2248-2312 and residues 2315-2330). In addition, a crystallographic analysis of a complex of the C2 domain and a human monoclonal IgG(4)(K) Fab revealed that this type of antibody is in direct contact with hydrophobic and basic residues of the membrane-binding surface. Inactivated FVIII is rapidly cleared from the circulation in the presence of inhibitors. The inhibitors also bind to essential FVIII ligand proteins, including von Willebrand factor, FIXa, FXa, and thrombin, and to surface membrane phospholipid. Some type 2 inhibitors interfere with binding to activated protein C.