Modelling ADAMTS13-vWF Interaction: Implications for Oxidative Stress-Related Cardiovascular Diseases and Type-2A von Willebrand Disease

The haemostatic potential of von Willebrand factor, a glycoprotein expressed by endothelial cells as ultra-large polymers (UL-vWF)(1), increases with its length, which in turn is regulated proteolytically by ADAMTS13, a zinc-metalloprotease selectively cleaving vWF at the Tyr1605-Met1606 bond. We have recently shown that in vitro oxidation of Met1606, under conditions mimicking those found in diseases characterized by high oxidative stress, severely impairs proteolysis by ADAMTS13, with a resulting pro-thrombotic effect caused by the accumulation of UL-vWF species. Conversely, Val1607Asp mutation, found in vWF from patients with type 2A von Willebrand disease, accelerates proteolysis of vWF, with a final hemorrhagic effect. Considering the physio-pathological importance of ADAMTS13-vWF interaction and the absence of experimental structural data, here we produced by homology modeling techniques a three-dimensional model of ADAMTS13 metalloprotease domain (M13). Thereafter, the vWF(1604-1607) peptide, containing the cleavable Tyr1605-Met1606 bond, was manually docked into the protease active site and the resulting model complex provided us key information for interpreting on structural grounds the variable effects that chemical modifications/mutations in vWF have on proteolysis by ADAMTS13.