Transgenic pigs produce functional human factor VIII in milk.

Deficiency or abnormality of coagulation factor VIII (FVIII) causes a bleeding disorder called hemophilia A. Treatment involves FVIII concentrates prepared from pooled human plasma or recombinant FVIII (rFVIII) prepared from mammalian cell culture. The cost of highly purified FVIII or rFVIII is a major factor in hemophilia therapy and restricts prophylaxis. We have sought to generate a new source of rFVIII by targeting expression of the human FVIII cDNA to the mammary gland of transgenic pigs using the regulatory sequences of the mouse whey acidic protein gene. The identity of processed heterodimeric rFVIII was confirmed using specific antibodies, by thrombin digestion and activity assays. The secretion of as much as 2.7 micrograms/ml of rFVIII in milk was over tenfold higher than in normal plasma. Up to 0.62 U/ml of rFVIII was detected in an assay in which rFVIII restored normal clotting activity to FVIII-deficient human plasma.

In hemophilia A and autoantibody inhibitor patients: the factor VIII A2 domain and light chain are most immunogenic.

Factor VIII (fVIII) is a protein cofactor essential for blood coagulation, and it binds in the factor Xase complex to factors IXa, X, and phospholipid. In about 30% of severe hemophilia A patients, treatment with fVIII leads to production of anti-fVIII antibodies. Anti-fVIII autoantibodies also rarely appear in normal individuals. Those antibodies that inactivate fVIII (inhibitors) prevent optimal fVIII therapy. Inhibitor epitopes were previously localized to the fVIII A2, A3, and C2 domains and to an acidic amino acid region between A1 and A2. Such anti-fVIII antibodies interfere with fVIII binding to components of the factor Xase complex and prevent blood coagulation. When total anti-fVIII titers were determined for each fVIII domain in 43 inhibitor plasmas by immunoprecipitation (IP) and inhibitor neutralization assays, the anti-light chain (LCh) antibody titer was highest, anti-A2 was intermediate, and anti-A1 and anti-B were low. The relative immunogenicity of the fVIII domains in hemophilic and autoantibody inhibitor patients was similar.

Properties of anti-factor VIII inhibitor antibodies in hemophilia A patients.

Blood coagulation factor VIII functions in the intrinsic pathway of blood coagulation as a cofactor by enhancing the assembly of its complex with factors IX and X on the surface of activated platelets. This requires factor VIII interaction with these two proteins, von Willebrand factor (vWF), and phospholipids on the platelet surface. Once factor VIII and factor IX are activated by proteolytic cleavage, the complex is able to activate factor X to factor Xa by proteolysis. In hemophilia A patients with severe factor VIII deficiency, about 30% respond to factor VIII infusion therapy immunologically to produce antibodies that inactivate the infused factor VIII and others that are noninhibitory. An assay that measures only the inhibitor antibodies demonstrated that the factor VIII A2, A3, and C2 domains are the most immunogenic, and domains A1 and B are poorly immunogenic or not immunogenic. The specific antibody responses to A2, A3, and C2 vary considerably among individuals, and epitopes for inhibitor antibodies have been determined for all three. The anti-C2 inhibitors prevent factor VIII binding to phospholipids and vWF, and anti-A3 inhibitors prevent binding to factor IX (IXa). An inhibitor binding site for factor X has been localized to the A1 domain acidic region, leading to inhibition of factor VIII/factor X binding by antibodies. This inhibitor mechanism is rare. Because a second binding site for factor IX was localized to the factor VIII A2 domain, it is likely but not proven that prevention of factor IX binding to factor VIII is the inhibitor mechanism for this epitope.