Abstract
Protein oxidative footprinting, using hydroxyl radical labeling detected by bottom-up proteomics, has progressed from an emerging method to a widely used approach in structural biology. Hydroxyl radicals generated from hydrogen peroxide (via photolysis, Fenton chemistry or electrochemistry) or directly from water (via X-rays, plasma or gamma rays) irreversibly encode structural information within protein side chains, which is read out using standard liquid chromatography-mass spectrometry workflows. Quantitative changes in labeling report on solvent accessibility and reveal effects of protein-protein interactions, ligand binding, protein folding, conformational changes or applied stress. Comparing labeling patterns between states provides detailed maps of structural changes and interaction sites. Over the past decade, oxidative footprinting has proven valuable as a solution-phase and in-cell method for protein structure analysis. This Perspective summarizes best practices for experimental design, sample processing, data analysis, interpretation and integration with orthogonal data, offering a consensus framework to guide application of oxidative footprinting in academic and biopharmaceutical research.