Biological activity of recombinant factor VIII variants lacking the central B-domain and the heavy-chain sequence Lys713-Arg740: discordant in vitro and in vivo activity.

Recombinant factor VIII variants with overlapping deletions spanning the region Lys713-Ile1668 have been expressed in mammalian cells, and analysed for biological activity both in vitro and in vivo. Two distinct assay systems were used to measure the activity in vitro. The one-stage coagulation assay served to assess factor VIII procoagulant activity while a spectrophotometric assay was used for the quantification of factor VIII cofactor activity in factor IXa-dependent factor X activation. Deletion of the entire B-domain (Ser741-Arg1648) resulted in a protein with similar procoagulant and cofactor activity. In contrast, factor VIII-del(713-1637), which has a deletion that also comprises the heavy-chain sequence Lys713-Arg740, had lost factor VIII procoagulant activity while factor VIII cofactor activity was retained. This functional inconsistency was further addressed by comparing purified factor VIII-del(713-1637) with factor VIII-del(868-1562), a mutant with normal in vitro activity. Kinetic studies of factor Xa formation revealed that higher concentrations of thrombin were required to develop the cofactor activity from factor VIII-del(713-1637) than needed for factor VIII-del(868-1562) or plasma factor VIII. The physiological significance of this finding was assessed in dogs with haemophilia A. Both deletion mutants were similar to plasma factor VIII with regard to binding to von Willebrand factor and half-life and recovery. Employing the cuticle bleeding time model, factor VIII-del(868-1562) was found to be indistinguishable from plasma factor VIII, whereas factor VIII-del(713-1637) was less effective. The increased thrombin-resistance of factor VIII-del(713-1637) thus limits both procoagulant activity and haemostatic efficacy in cuticle bleeding. These observations suggest that the heavy-chain sequence Lys713-Arg740, although dispensable for factor VIII cofactor function per se, is involved in the proteolytic activation of factor VIII both in vitro and in vivo.

Inhibition of human coagulation factor VIII by monoclonal antibodies. Mapping of functional epitopes with the use of recombinant factor VIII fragments.

The epitopes of four monoclonal antibodies against coagulation Factor VIII were mapped with the use of recombinant DNA techniques. Full-length Factor VIII cDNA and parts thereof were inserted into the vector pSP64, permitting transcription in vitro with the use of a promoter specific for SP6 RNA polymerase. Factor VIII DNA inserts were truncated from their 3'-ends by selective restriction-enzyme digestion and used as templates for 'run-off' mRNA synthesis. Translation in vitro with rabbit reticulocyte lysate provided defined radiolabelled Factor VIII fragments for immunoprecipitation studies. Two antibodies are shown to be directed against epitopes on the 90 kDa chain of Factor VIII, between residues 712 and 741. The 80 kDa chain appeared to contain the epitopes of the other two antibodies, within the sequences 1649-1778 and 1779-1840 respectively. The effect of antibody binding to these sequences was evaluated at two distinct levels within the coagulation cascade. Both Factor VIII procoagulant activity and Factor VIII cofactor function in Factor Xa generation were neutralized upon binding to the region 1779-1840. The antibodies recognizing the region 713-740 or 1649-1778, though interfering with Factor VIII procoagulant activity, did not inhibit in Factor Xa generation. These findings demonstrate that antibodies that virtually inhibit Factor VIII in coagulation in vitro are not necessarily directed against epitopes involved in Factor VIII cofactor function. Inhibition of procoagulant activity rather than of cofactor function itself may be explained by interference in proteolytic activation of Factor VIII. This hypothesis is in agreement with the localization of the epitopes in the proximity of thrombin-cleavage or Factor Xa-cleavage sites.