Abstract
The tyrosine residue of proteins participates in a wide range of activities including enzymatic catalysis, protein-protein interaction, and protein-ligand binding. However, the functional annotation of the tyrosine residues on a large scale is still very challenging. Here, we report a novel method integrating azo coupling, bioorthogonal chemistry, and multiplexed proteomics to globally investigate the tyrosine reactivity in the human proteome. Based on the azo-coupling reaction between aryl diazonium salt and the tyrosine residue, the two different probes were evaluated, and the probe with the best performance was employed to specifically target the tyrosine residues. After the reaction, tagged tyrosine containing peptides were selectively enriched using bioorthogonal chemistry, and a small tag on the peptides from the cleavage perfectly fits for site-specific analysis by MS. Coupling with multiplexed proteomics, we quantified over 5,000 tyrosine sites in MCF7 cells and these quantified sites displayed a wide range of reactivity. The tyrosine residues with high reactivity were found on functionally and structurally diverse proteins, including those with the catalytic activity and binding property. This method can be extensively applied to advance our understanding of protein functions and facilitate the development of covalent drugs to regulate protein activity.