The generation of cell traction forces plays an important role in tissue morphogenesis. Platelets self-assemble into a layered thrombus structure with a tightly packed core close to the vascular injury site and a looser shell towards the vessel lumen. The mechanical and proteolytic stability of the thrombus core might be linked to increased platelet contractility, reinforced by reciprocal interactions with the local microenvironment. How this spatially regulates platelet contractility is thus a clinically important question. The aim of this in vitro study was to clarify how platelet agonists that are present at different locations in a thrombus co-regulate actomyosin contractility. In single platelet contractile force measurements, thrombin led to ~50% higher traction forces after an hour than adenosine diphosphate or collagen-related peptide. Stimulation of protease-activated receptor (PAR) 1 in combination with PAR4 maximized platelet contractility, without changing adhesion signaling. Only thrombin induced persistent phosphorylation of Rho-associated protein kinase ROCK2 and myosin regulatory light chain MYL9 in adherent platelets, consistent with PARGα13RhoA signaling. Thrombin further induced elevated protein expression of MYL9 and led to splicing of ROCK1 pre-mRNA. Anti-platelet drugs counteracted clot contraction in vitro in a thrombin concentration-dependent manner, more potently at low thrombin concentrations. Our findings demonstrate a mechanism in which thrombin maximizes sustained platelet contractility. They further delineate the intimate spatiotemporal and functional relationship between thrombin and platelets during the stabilization of the hemostatic plug. Our results also caution against the combined usage of anti-platelet and anti-coagulation treatments which might increase bleeding diathesis due to defective clot contraction.
Hiebner et al. (Tue,) studied this question.