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Mechanical properties of VWF in single molecule and cell adhesion force experiments using AFM

Antragsteller Dr. Martin Benoit
Fachliche Zuordnung Biophysik
Förderung Förderung von 2011 bis 2019
Projektkennung Deutsche Forschungsgemeinschaft (DFG) - Projektnummer 172540668
 
Erstellungsjahr 2018

Zusammenfassung der Projektergebnisse

Excessive blood loss at a site of vascular injury is prevented by recruitment of platelets to the injured vessel wall and the formation of a platelet plug. These processes are critically mediated by the plasma glycoprotein von Willebrand factor (VWF), which circulates in the blood in the form of long, linear multimers. Remarkably, VWF’s activation for hemostasis is force-induced: When subjected to elevated hydrodynamic forces in the blood flow, which primarily occur in connection with blood vessel injury, VWF undergoes several conformational changes – both on the level of single domains and of the overall protein conformation – that lead to increased affinity for binding collagen and platelets. Furthermore, also VWF’s down-regulation is force-regulated, as it relies on enzymatic cleavage of a cleavage site that is accessible only upon force-induced unfolding of VWF’s A2 domains. In order to elucidate the molecular mechanisms that underlie VWF’s extraordinary response to force and the associated conformational changes, we combined atomic force microscope (AFM)-based single-molecule force spectroscopy and AFM imaging to directly probe the mechanics and structure of VWF dimers under a variety of different conditions. Key results were the discovery of a strong intermonomer interaction in VWF mediated by its D4 domains that is expected to tune VWF’s ability to sense hydrodynamic forces in the bloodstream, and the finding that even minute pH changes markedly affect VWF’s conformation and its response to force. In addition, our combined approach indicated the existence of further physiologically relevant interactions of the C-domains within VWF dimers that, however, dissociate at forces too low to be resolved directly by the AFM. Therefore, we currently employ magnetic tweezers-based singlemolecule force spectroscopy to probe VWF’s behavior at very low forces of ≈1 pN, at which first conformational transitions of VWF multimers are thought to occur. Taken together, our data refined our picture of VWF’s conformational transitions under elevated hydrodynamic forces. They will thus help to comprehend the force-induced activation of VWF and provide clues for understanding clotting disorders, such as von Willebrand disease and thrombosis, at the single-molecule level.

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