As an orthogonal principle to the established (hetero)aryl halides, we herein highlight the usefulness of CFX (X = Cl, Br, or I) moieties. Using tool compounds bearing CFX moieties, we study their chemical/metabolic stability and their logP/solubility, as well as the role of XB in their small molecular crystal structures. Employing QM techniques, we analyze the observed interactions, provide insights into the conformational flexibilities and preferences in the potential interaction space. For their application in molecular design, we characterize their XB donor capacities and its interaction strength dependent on geometric parameters. Implementation of CFX acetamides into our HEFLibs and biophysical evaluation (STD-NMR/ITC), followed by X-ray analysis, reveals a highly interesting binding mode for fragment in JNK3, featuring an XB of CFBr toward the P-loop, as well as chalcogen bonds. We suggest that underexplored chemical space combined with unconventional binding modes provides excellent opportunities for patentable chemotypes for therapeutic intervention.
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| http://dx.doi.org/10.1021/acs.jmedchem.3c00634 | DOI Listing |
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