Development of Highly Potent and Selective Covalent FGFR4 Inhibitors Based on SNAr Electrophiles.

Fibroblast growth factor receptor 4 (FGFR4) is thought to be a driver in several cancer types, most notably in hepatocellular carcinoma. One way to achieve high potency and isoform selectivity for FGFR4 is covalently targeting a rare cysteine (C552) in the hinge region of its kinase domain that is not present in other FGFR family members (FGFR1-3). Typically, this cysteine is addressed via classical acrylamide electrophiles. We demonstrate that noncanonical covalent "warheads" based on nucleophilic aromatic substitution (SNAr) chemistry can be employed in a rational manner to generate highly potent and (isoform-)selective FGFR4 inhibitors with a low intrinsic reactivity. Key compounds showed low to subnanomolar potency, efficient covalent inactivation kinetics, and excellent selectivity against the other FGFRs, the kinases with an equivalent cysteine, and a representative subset of the kinome. Moreover, these compounds achieved nanomolar potencies in cellular assays and demonstrated good microsomal stability, highlighting the potential of SNAr-based approaches in covalent inhibitor design.

Development of novel urea-based ATM kinase inhibitors with subnanomolar cellular potency and high kinome selectivity.

The ATM kinase is a key molecule regulating DNA damage response and can be targeted resulting in efficient radio- or chemosensitization. Due to the enormous size of this protein and the associated difficulties in obtaining high-quality crystal structures, we sought to develop an accurate in silico model to identify new targeting possibilities. We identified a urea group as the most beneficial chemical anchor point, which could undergo multiple interactions in the aspartate-rich hydrophobic region I of the atypical ATM kinase domain. Based on in silico data, we designed and synthesized a comprehensive set of novel urea-based inhibitors and characterized them in diverse biochemical assays. Using this strategy, we identified inhibitors with subnanomolar potency, which were further evaluated in cellular models, selectivity and early DMPK properties. Finally, the two lead compounds 34 and 39 exhibited subnanomolar cellular activity along with an excellent selectivity profile and favorable metabolic stability.