Intradimer forces and their implication for conformations of von Willebrand factor multimers

The largest blood glycoprotein von Willebrand factor (VWF) responds to hydrodynamic stresses in the bloodstream with abrupt conformation changes, thus increasing its adhesivity to platelets and collagen. Arterial and microvascular hemostasis relies on mechanical and physicochemical properties of this macromolecule. Recently, it was discovered that the mechanical properties of VWF are controlled by multiple pH-dependent interactions with opposite trends within dimeric subunits. In this work, computer simulations reveal the effect of these intradimer forces on the conformation of VWF multimers in various hydrodynamic conditions. A coarse-grained computer model of VWF has been proposed and parameterized to give a good agreement with experimental data. The simulations suggest that strong attraction between VWF D4 domains increases the resistance to elongation under shear stress, whereas even intermediate attraction between VWF C domains contributes to VWF compaction in nonsheared fluid. It is hypothesized that the detailed subdimer dynamics of VWF concatamers may be one of the biophysical regulators of initial hemostasis and arterial thrombosis. © 2021 Biophysical Society

Авторы
Журнал
Издательство
Biophysical Society
Номер выпуска
5
Язык
Английский
Страницы
899-911
Статус
Опубликовано
Том
120
Год
2021
Организации
  • 1 Lomonosov Moscow State University, Faculty of Physics, Moscow, Russian Federation
  • 2 IRC Mathematical modelling in Biomedicine, S.M. Nikolskii Mathematical Institute, RUDN University, Moscow, Russian Federation
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