Immunoprotective effect of von Willebrand factor towards therapeutic factor VIII in experimental haemophilia A.

The development of inhibitory anti-factor VIII (FVIII) antibodies in patients with haemophilia A following replacement therapy is associated with several types of risk factors. Among these, the purity of FVIII concentrates, and in particular the presence of von Willebrand factor (VWF), was controversially proposed to influence the immunogenicity of exogenous FVIII. We re-assessed in vivo and in vitro the immuno-protective effect of VWF towards FVIII. The immuno-protective effect of VWF towards FVIII was investigated in vivo, in a model of haemophilia A. We studied the endocytosis of FVIII by murine bone marrow-derived dendritic cells and evaluated the capacity of VWF to block the internalization of FVIII. We characterized the relevance of VWF for the accumulation of FVIII in the marginal zone of the spleen, a secondary lymphoid organ where the immune response to therapeutically administered FVIII initiates. Our results confirm that VWF reduces the immunogenicity of FVIII in FVIII-deficient mice. Paradoxically, VWF is important for the accumulation of FVIII in the marginal zone of the spleen. We propose that VWF exerts at least two non-mutually exclusive immunoprotective roles towards FVIII in haemophilic mice: VWF prevents the endocytosis of FVIII by professional antigen-presenting cells by blocking the interaction of FVIII with as yet unidentified endocytic receptor(s). Hypothetically, VWF, by virtue of increasing the half-life of FVIII in the circulation, may allow an increased contact time with tolerogenic marginal zone B cells in the spleen.

Bortezomib delays the onset of factor VIII inhibitors in experimental hemophilia A, but fails to eliminate established anti-factor VIII IgG-producing cells.

BACKGROUND: Replacement therapy with exogenous factor VIII to treat hemorrhages induces inhibitory anti-FVIII antibodies in up to 30% of patients with hemophilia A. Current approaches to eradicate FVIII inhibitors using high-dose FVIII injection protocols (immune tolerance induction) or anti-CD20 depleting antibodies (Rituximab) demonstrate limited efficacy; they are extremely expensive and/or require stringent compliance from the patients. OBJECTIVES: To investigate whether the proteasome inhibitor bortezomib, which depletes plasmocytes, modulates the anti-FVIII immune response in FVIII-deficient mice. METHODS AND RESULTS: Preventive 4-week treatment of naïve mice with bortezomib at the time of FVIII administration delayed the development of inhibitory anti-FVIII IgG, and depleted plasma cells as well as different lymphoid cell subsets. Conversely, curative treatment of inhibitor-positive mice for 10 weeks, along with FVIII administration, failed to eradicate FVIII inhibitors to extents that would be clinically relevant if achieved in patients. Accordingly, bortezomib did not eradicate anti-FVIII IgG-secreting plasmocytes that had homed to survival niches in the bone marrow, despite significant elimination of total plasma cells. CONCLUSIONS: The data suggest that strategies for the efficient reduction of anti-FVIII IgG titers in patients with hemophilia A should rely on competition for survival niches for plasmocytes in the bone marrow rather than the mere use of proteasome inhibitors.

A human FVIII inhibitor modulates FVIII surface electrostatics at a VWF-binding site distant from its epitope.

SUMMARY BACKGROUND: BO2C11 is a human monoclonal factor (F) VIII inhibitor. When bound to the C2 domain of FVIII, the Fab fragment of BO2C11 (Fab(BO2C11)) buries a surface of C2 that contains residues participating in a binding site for von Willebrand factor (VWF). BO2C11 has thus been proposed to neutralize FVIII by steric hindrance. OBJECTIVES: The BO2C11 epitope on C2 overlaps with residues located at the periphery of the putative VWF binding site; hence, most of the residues that constitute the VWF binding site on C2 and a3 remain accessible for VWF interaction following BO2C11/FVIII complex formation. We thus investigated the contribution of alternative molecular mechanisms to FVIII inactivation by BO2C11. METHODS: Continuum electrostatic calculations were applied to the crystal structure of C2, free or Fab(BO2C11)-complexed. In silico predictions were confirmed by site-directed mutagenesis and VWF-binding assays of the mutated FVIII. RESULTS: Binding of Fab(BO2C11) to C2 induced perturbations in the electrostatic potential of C2 and in the local electrostatic parameters of 18 charged residues in C2, which are distant from the BO2C11 epitope. Nine of the predicted electrostatic hotspots clustered on the VWF-binding site of C2. Mutation of some of the predicted electrostatic hotspots has been associated with hemophilia A and reduced VWF binding in vitro. CONCLUSIONS: Inhibitors may neutralize FVIII by alteration of protein surface electrostatics at a long distance from their epitope. Perturbation of the electrostatic environment of C2, either upon binding by anti-FVIII antibodies or consecutive to missense mutations in the F8 gene, may lead to hampered VWF binding and reduced FVIII residence time in circulation.