Protein footprinting mass spectrometry
probes protein higher order
structure and dynamics by labeling amino acid side-chains or backbone
amides as a function of solvent accessibility. One category of footprinting
uses residue-specific, irreversible covalent modifications, affording
flexibility of sample processing for bottom-up analysis. Although
several specific amino acid footprinting technologies are becoming
established in structural proteomics, there remains a need to assess
fundamental properties of new reagents before their application. Often,
footprinting reagents are applied to complex or novel protein systems
soon after their discovery and sometimes without a thorough investigation
of potential downsides of the reagent. In this work, we assemble and
test a validation workflow that utilizes cyclic peptides and a model
protein to characterize benzoyl fluoride, a recently published, next-generation
nucleophile footprinter. The workflow includes the characterization
of potential side-chain reactive groups, reaction “quench”
efficacies, reagent considerations and caveats (e.g., buffer pH),
residue-specific kinetics compared to those of established reagents,
and protein-wide characterization of modification sites with considerations
for proteolysis. The proposed workflow serves as a starting point
for improved footprinting reagent discovery, validation, and introduction,
the aspects of which we recommend before applying to unknown protein
systems.