Kocaturk, N. M.; Pinto, A. L.; Izert-Nowakowska, M.; Wilhelm, L. P.; Sathe, G.; Ashraf, Q.; Ganley, I. G.; Rousseau, A.; Farnaby, W.

Kinases have proven to be one of the most fertile target classes for new drug approvals. However, classical reversible inhibitors may not be capable of the levels of specificity or target modulation required across a broad spectrum of disease areas. Approaches that chemically modify kinase inhibitors in solvent exposed regions are unveiling a swathe of mechanisms to address kinase function in new ways. For example, by either covalently recruiting nucleophilic residues outside of the ATP-binding pocket to inhibit, or by recruiting secondary effector proteins to degrade. Here, we systematically assessed the impact of minimal electrophilic modifications to ATP-site binding scaffolds, leading us to identify molecules that can control the activity and abundance of the master autophagy regulator, Unc-51-like autophagy activating kinase 1 (ULK1).