Benedict-Tilman Berger, Marta Amaral, Daria B Kokh, Ariane Nunes-Alves, Djordje Musil, Timo Heinrich, Martin Schröder, Rebecca Neil, Jing Wang, Iva Navratilova, Joerg Bomke, Jonathan M Elkins, Susanne Müller, Matthias Frech, Rebecca C Wade, and Stefan Knapp (2021).
Cell chemical biology, 28, 686-698.e7.   (PubMed)

There is increasing evidence of a significant correlation between prolonged drug-target residence time and increased drug efficacy. Here, we report a structural rationale for kinetic selectivity between two closely related kinases: focal adhesion kinase (FAK) and proline-rich tyrosine kinase 2 (PYK2). We found that slowly dissociating FAK inhibitors induce helical structure at the DFG motif of FAK but not PYK2. Binding kinetic data, high-resolution structures and mutagenesis data support the role of hydrophobic interactions of inhibitors with the DFG-helical region, providing a structural rationale for slow dissociation rates from FAK and kinetic selectivity over PYK2. Our experimental data correlate well with computed relative residence times from molecular simulations, supporting a feasible strategy for rationally optimizing ligand residence times. We suggest that the interplay between the protein structural mobility and ligand-induced effects is a key regulator of the kinetic selectivity of inhibitors of FAK versus PYK2.

This work describes an example of using τ-Random Acceleration Molecular Dynamics (τRAMD) in kinetic calculations.