C Zhang1,2, A Kelkar1,2, M Nasirikenari3, J T Y Lau3, M Sveinsson2, U C Sharma2, S Pokharel4, S Neelamegham1,2. 1. Department of Chemical and Biological Engineering, State University of New York, Buffalo, NY, USA. 2. Clinical and Translational Research Center, State University of New York, Buffalo, NY, USA. 3. Molecular and Cellular Biology, Roswell Park Cancer Institute, Buffalo, NY, USA. 4. Pathology and Laboratory Medicine, Roswell Park Cancer Institute, Buffalo, NY, USA.
Abstract
Essentials The role of von Willebrand factor (VWF) domains in regulating platelet adhesion was studied in vivo. Multimeric VWF with spacers at the N- and C-terminus of VWF-A1 were systematically tested. N-terminal modified VWF avidly bound platelet GpIbα, causing VWD Type2B like phenotype in mice. Novel anti-D'D3 mAbs suggest that changes at the D'D3-A1 interface may be biologically relevant. SUMMARY: Background Previous ex vivo studies using truncated VWF (von Willebrand factor) suggest that domain-level molecular architecture may control platelet-GpIbα binding function. Objective We determined if this is the case with multimeric VWF in vivo. Methods Full-length human VWF ('hV') was modified with a 22-amino acid mucinous stretch at either the N-terminus of VWF-A1 to create 'hNV' or C-terminus to yield 'hCV'. This extends the physical distance between VWF-A1 and the adjacent domains by ~6 nm. Similar mucin inserts were also introduced into a human-murine chimera ('h[mA1]V') where murine-A1 replaced human-A1 in hV. This yielded 'h[mA1]NV' and 'h[mA1]CV', with N- and C-terminal inserts. The constructs were tested ex vivo and in vivo. Results Mucin insertion at the N-terminus, but not C-terminus, in both types of constructs resulted in >50-fold increase in binding to immobilized GpIbα. N-terminal insertion also resulted in greater shear-induced platelet activation, more thrombus formation on collagen, enhanced platelet accumulation and slower platelet translocation on immobilized VWF in microfluidics assays. Hydrodynamic injection-based expression of h[mA1]NV, but not h[mA1]V or h[mA1]CV, in VWF-/- mice caused profound thrombocytopenia, reduced plasma VWF concentrations, lower multimer distribution, and incessant tail bleeding that is reminiscent of von Willebrand disease type 2B. Platelet plugs were noted in the portal veins and hepatic arteries. An anti-D'D3 mAb DD3.3 that displays enhanced binding to VWF containing the N-terminal mucin insert also exhibited increased binding to wild-type VWF under shear and upon ristocetin addition. Conclusion Conformation changes at the VWF D'D3-A1 interface may be a key regulator of thrombosis in vivo. Structural features at the A1-A2 interface are likely of less significance.
Essentials The role of von Willebrand factor (VWF) domains in regulating platelet adhesion was studied in vivo. Multimeric VWF with spacers at the N- and C-terminus of VWF-A1 were systematically tested. N-terminal modified VWF avidly bound platelet GpIbα, causing VWD Type2B like phenotype in mice. Novel anti-D'D3 mAbs suggest that changes at the D'D3-A1 interface may be biologically relevant. SUMMARY: Background Previous ex vivo studies using truncated VWF (von Willebrand factor) suggest that domain-level molecular architecture may control platelet-GpIbα binding function. Objective We determined if this is the case with multimeric VWF in vivo. Methods Full-length humanVWF ('hV') was modified with a 22-amino acid mucinous stretch at either the N-terminus of VWF-A1 to create 'hNV' or C-terminus to yield 'hCV'. This extends the physical distance between VWF-A1 and the adjacent domains by ~6 nm. Similar mucin inserts were also introduced into a human-murine chimera ('h[mA1]V') where murine-A1 replaced human-A1 in hV. This yielded 'h[mA1]NV' and 'h[mA1]CV', with N- and C-terminal inserts. The constructs were tested ex vivo and in vivo. Results Mucin insertion at the N-terminus, but not C-terminus, in both types of constructs resulted in >50-fold increase in binding to immobilized GpIbα. N-terminal insertion also resulted in greater shear-induced platelet activation, more thrombus formation on collagen, enhanced platelet accumulation and slower platelet translocation on immobilized VWF in microfluidics assays. Hydrodynamic injection-based expression of h[mA1]NV, but not h[mA1]V or h[mA1]CV, in VWF-/- mice caused profound thrombocytopenia, reduced plasma VWF concentrations, lower multimer distribution, and incessant tail bleeding that is reminiscent of von Willebrand disease type 2B. Platelet plugs were noted in the portal veins and hepatic arteries. An anti-D'D3 mAb DD3.3 that displays enhanced binding to VWF containing the N-terminal mucin insert also exhibited increased binding to wild-type VWF under shear and upon ristocetin addition. Conclusion Conformation changes at the VWF D'D3-A1 interface may be a key regulator of thrombosis in vivo. Structural features at the A1-A2 interface are likely of less significance.
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