Abstract
Post-translational modifications (PTMs) vastly expand the diversity of human proteome, dynamically reshaping protein activity, interactions, and localization in response to environmental, pharmacologic, and disease-associated cues. While it is well established that PTMs modulate protein function, structure, and biomolecular interactions, their proteome-wide impact on small-molecule recognition-and thus druggability-remains largely unexplored. Here, we introduce a chemical proteomic strategy to delineate how PTM states remodel protein ligandability in human cells. By deploying broad profiling photoaffinity probes, we identified over 400 functionally diverse proteins whose ability to engage small molecules is impacted by phosphorylation or N-linked glycosylation status. Integration of binding site mapping with structural analyses revealed a diverse array of PTM-dependent pockets. Among these targets, we discovered that the phosphorylation status of common oncogenic KRAS mutants impact the action of small molecules, including clinically approved inhibitors. These findings illuminate an underappreciated, PTM-governed layer of proteome plasticity and uncover opportunities for the development of chemical probes to selectively target proteins in defined modification states.