Litcius/Paper detail

Function-guided proximity mapping unveils electrophilic-metabolite sensing by proteins not present in their canonical locales

Yi Zhao, Pierre A. Miranda Herrera, Dalu Chang, Romain Hamelin, Marcus J. C. Long, Yimon Aye

2022Proceedings of the National Academy of Sciences30 citationsDOIOpen Access PDF

Abstract

Enzyme-assisted posttranslational modifications (PTMs) constitute a major means of signaling across different cellular compartments. However, how nonenzymatic PTMs-despite their direct relevance to covalent drug development-impinge on cross-compartment signaling remains inaccessible as current target-identification (target-ID) technologies offer limited spatiotemporal resolution, and proximity mapping tools are also not guided by specific, biologically-relevant, ligand chemotypes. Here we establish a quantitative and direct profiling platform (Localis-rex) that ranks responsivity of compartmentalized subproteomes to nonenzymatic PTMs. In a setup that contrasts nucleus- vs. cytoplasm-specific responsivity to reactive-metabolite modification (hydroxynonenylation), ∼40% of the top-enriched protein sensors investigated respond in compartments of nonprimary origin or where the canonical activity of the protein sensor is inoperative. CDK9-a primarily nuclear-localized kinase-was hydroxynonenylated only in the cytoplasm. Site-specific CDK9 hydroxynonenylation-which we identified in untreated cells-drives its nuclear translocation, downregulating RNA-polymerase-II activity, through a mechanism distinct from that of commonly used CDK9 inhibitors. Taken together, this work documents an unmet approach to quantitatively profile and decode localized and context-specific signaling/signal-propagation programs orchestrated by reactive covalent ligands.

Topics & Concepts

CytoplasmComputational biologyCell biologyNuclear export signalChemistryBiologyBiochemistryCell nucleusClick Chemistry and ApplicationsRNA and protein synthesis mechanismsProtein Degradation and Inhibitors