Proteolytic cleavage of factor VIII heavy chain is required to expose the binding-site for low-density lipoprotein receptor-related protein within the A2 domain.

BACKGROUND: Low-density lipoprotein receptor-related protein (LRP) is an endocytic receptor that contributes to the clearance of coagulation factor (F) VIII from the circulation. Previously, we have demonstrated that region Glu(1811)-Lys(1818) within FVIII light chain constitutes an important binding region for this receptor. We have further found that FVIII light chain and intact FVIII are indistinguishable in their LRP-binding affinities. In apparent contrast to these observations, a second LRP-binding region has been identified within A2 domain region Arg(484)-Phe(509) of FVIII heavy chain. OBJECTIVE: In this study, we addressed the relative contribution of FVIII heavy chain in binding LRP. METHODS AND RESULTS: Surface plasmon resonance analysis unexpectedly showed that FVIII heavy chain poorly associated to the receptor. The binding to LRP was, however, markedly enhanced upon cleavage of the heavy chain by thrombin. The A2 domain, purified from thrombin-activated FVIII, also showed efficient binding to LRP. Competition studies employing a recombinant antibody fragment demonstrated that region Arg(484)-Phe(509) mediates the enhanced LRP binding after thrombin cleavage. CONCLUSIONS: We propose that LRP binding of non-activated FVIII is mediated via the FVIII light chain while in activated FVIII both the heavy and light chain contribute to LRP binding.

Substitution of Arg527 and Arg531 in factor VIII associated with mild haemophilia A: characterization in terms of subunit interaction and cofactor function.

The functional defect caused by substitution of Arg527 (--> Trp) and Arg531 (--> Gly, His) in factor VIII (FVIII), was explored by employing FVIII derived from patient plasma and recombinant FVIII variants. Mutation of these residues is associated with mild haemophilia A. For both FVIII-R527W and FVIII-R531H, activity was lower than antigen, indicating a functional defect for both variants. In contrast to FVIII-R527W, the amount of FVIII-R531H heterodimer present in plasma was reduced compared to heavy and light chain levels. Factor X (FX) activation experiments employing recombinant FVIII-R531G revealed that the activated FVIII-R531G heterotrimer was less stable than normal FVIIIa, apparently due to rapid dissociation of the A2 domain. These findings suggest that Arg531 is involved in maintaining the stability of both the heterodimer and the activated FVIII heterotrimer. Recombinant FVIII-R527W displayed reduced stimulation of FX activation, suggesting a defect in interaction with factor IXa (FIXa). The contribution of Arg527 in the interaction with FIXa was supported by the observation that FVIII-derived synthetic peptide Tyr511-Leu530 was able to inhibit FX activation and that this inhibition could be overcome by addition of increasing concentrations of FIXa. Furthermore, in the three-dimensional FVIII model residues Val517-Arg527 are located near the FIXa binding site Ser558-Gln565. Therefore we propose that Arg527 is part of an extended FIXa binding site, comprising residues Ser558-Gln565 and Val517-Arg527.

Enhanced thrombin sensitivity of a factor VIII-heparin cofactor II hybrid.

Generation of thrombin at a site of vascular injury is a key event in the arrest of bleeding. In addition to the conversion of fibrinogen into the insoluble fibrin, thrombin can initiate a number of positive and negative feedback mechanisms that either sustain or down-regulate clot formation. We have modulated the thrombin sensitivity of human blood coagulation factor VIII, an essential cofactor in the intrinsic pathway of blood coagulation. We have substituted an acidic region of factor VIII corresponding to amino acid sequence Asp712-Ala736 by amino acid sequence Ile51-Leu80 of the thrombin inhibitor heparin cofactor II. Functional analysis of the resulting factor VIII-heparin cofactor II hybrid, termed des-(868-1562)-factor VIII-HCII, revealed an increase in procoagulant activity as measured in a one-stage clotting assay. Incubation of purified des-(868-1562)-factor VIII-HCII with different amounts of thrombin showed that this protein was more readily activated by thrombin when compared with des-(868-1562)-factor VIII, a control protein lacking amino acid sequence Ile51-Leu80 of heparin cofactor II. This was manifested by an increase in the second order rate constant of activation by thrombin for des-(868-1562)-factor VIII-HCII (12.0 +/- 0.48 x 10(6) M-1 s-1) compared with des-(868-1562)-factor VIII (1.77 +/- 0.21 x 10(6) M-1 s-1). Our data suggest that amino acid sequence Ile51-Leu80 of heparin cofactor II endows factor VIII with increased sensitivity towards thrombin which results in accelerated clot formation.