Single-molecule imaging of von Willebrand factor reveals tension-dependent self-association

Single-molecule imaging of von Willebrand factor reveals tension-dependent self-association

von Willebrand factor (VWF) is an ultralong concatemeric protein important in hemostasis and thrombosis. VWF molecules can associate with other VWF molecules, but little is known about the mechanism. Hydrodynamic drag exerts tensile force on surface-tethered VWF that extends it and is maximal at the...

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Bibliographic Details
Published in:Blood 2021-12, Vol.138 (23), p.2425-2434
Main Authors: Fu, Hongxia, Jiang, Yan, Wong, Wesley P., Springer, Timothy A.
Format: Article
Language:eng
Subjects:
Humans
Hydrodynamics
Kinetics
Protein Multimerization
Recombinant Proteins - analysis
Single Molecule Imaging
Thrombosis and Hemostasis
von Willebrand Factor - analysis
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Summary:von Willebrand factor (VWF) is an ultralong concatemeric protein important in hemostasis and thrombosis. VWF molecules can associate with other VWF molecules, but little is known about the mechanism. Hydrodynamic drag exerts tensile force on surface-tethered VWF that extends it and is maximal at the tether point and declines linearly to 0 at the downstream free end. Using single-molecule fluorescence microscopy, we directly visualized the kinetics of binding of free VWF in flow to surface-tethered single VWF molecules. We showed that self-association requires elongation of tethered VWF and that association increases with tension in tethered VWF, reaches half maximum at a characteristic tension of ∼10 pN, and plateaus above ∼25 pN. Association is reversible and hence noncovalent; a sharp decrease in shear flow results in rapid dissociation of bound VWF. Tethered primary VWF molecules can recruit more than their own mass of secondary VWF molecules from the flow stream. Kinetics show that instead of accelerating, the rate of accumulation decreases with time, revealing an inherently self-limiting self-association mechanism. We propose that this may occur because multiple tether points between secondary and primary VWF result in lower tension on the secondary VWF, which shields more highly tensioned primary VWF from further association. Glycoprotein Ibα (GPIbα) binding and VWF self-association occur in the same region of high tension in tethered VWF concatemers; however, the half-maximal tension required for activation of GPIbα is higher, suggesting differences in molecular mechanisms. These results have important implications for the mechanism of platelet plug formation in hemostasis and thrombosis. •Hydrodynamic drag on tethered VWF induces elongation and imparts mechanical tension that activates binding of free VWF at a tension of 10 pN.•Decrease in flow and hence tension on tethered VWF reverses VWF self-association. [Display omitted]
ISSN:0006-4971
1528-0020