Abstract
Von Willebrand Factor (vWf) is a giant multimeric extracellular blood plasma involved in hemostasis. In this work we present multi-scale simulations of its three-domains fragment A1A2A3. These three domains are essential for the functional regulation of vWf. Namely the A2 domain hosts the site where the protease ADAMTS13 cleavages the multimeric vWf allowing for its length control that prevents thrombotic conditions. The exposure of the cleavage site follows the elongation/unfolding of the domain that is caused by an increased shear stress in blood. By deploying Lattice Boltzmann molecular dynamics simulations based on the OPEP coarse-grained model for proteins, we investigated at molecular level the unfolding of the A2 domain under the action of a perturbing shear flow. We described the structural steps of this unfolding that mainly concerns the -strand structures of the domain, and we compared the process occurring under shear with that produced by the action of a directional pulling force, a typical condition of single molecule experiments. We observe, that under the action of shear flow, the competition among the elongational and rotational components of the fluid field leads to a complex behaviour of the domain, where elongated structures can be followed by partially collapsed melted globule structures with a very different degree of exposure of the cleavage site. Our simulations pose the base for the development of a multi-scale in-silico description of vWf dynamics and functionality in physiological conditions, including high resolution details for molecular relevant events, e.g., the binding to platelets and collagen during coagulation or thrombosis.
Highlights
Von Willebrand Factor is a giant extracellular blood plasma protein that plays a key role in arterial hemostasis and thrombosis
We first present the flexible coarse-grained model OPEP that we exploited to investigate the unfolding of the A2 domain under tensile force and shear, and the simplified representations introduced to model the elementary three-domains construct A1A2A3 simulated in shear flow
We carried out steered Molecular Dynamics simulations at 300 K on the A2 domain of Von Willebrand Factor (vWf) modelled using the OPEP force-field
Summary
Von Willebrand Factor (vWf) is a giant extracellular blood plasma protein that plays a key role in arterial hemostasis and thrombosis. One of the essential features of vWf is that these proteins can expand in the bloodstream [2,3,4,5] and capture the blood platelets in hydrodynamically adverse conditions, i.e., under extreme forces and mechanical stresses [6]. Wound, plaque rupture, or inflammation are rapidly followed by the vWf-mediated adhesion and aggregation of blood platelets at the surface of damaged endothelium or exposed collagen [7,8,9,10]. After a mechanical stimulus (e.g., elevated shear, elongational stress, attachment to surface) the vWf multimers change shape from compact to extended, providing adhesive sites for platelets [4,11,12]. Ultra-long vWf concatamers may cause thrombotic conditions [16]
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