New Reagents and Methods for Mass Spectrometry-based Proteomics Investigations

Abstract

New chemical reagents and methods have been employed for mass spectrometry (MS)-based proteomics investigations. Many chemical reagents are synthesized to be covalently attached to biomolecules, especially peptides and proteins. The properties of the resulting peptide conjugates are characterized by various tandem mass spectrometric techniques (e.g., collision-induced dissociation (CID), electron capture dissociation (ECD), electron transfer dissociation (ETD), infrared multiphoton dissociation (IRMPD), and free radical initiated peptide sequencing (FRIPS)). In Chapter 2, the effect of high electron affinity tags in ECD and ETD is investigated using their peptide conjugates. The initial intramolecular electron transfer from the high-lying Rydberg states to the covalently attached high electron affinity tag occurs in competition with the Coulomb stabilized π* orbitals of the amide bonds in the model peptides. This leads to the inhibition of the normal sequence of ECD and ETD processes, yielding no backbone fragmentations. In Chapter 3, selective disulfide bond cleavages are observed by the FRIPS method. A newly prepared TEMPO-based FRIPS reagent is labeled to model peptides containing disulfide bonds and subject to CID to monitor free radical induced cleavages. Highly selective C–S and S–S bond cleavages are observed and their reaction mechanisms are proposed. In Chapter 4, novel Caltech isobaric tags (CITs) for protein quantification are developed and validated using various model samples. A newly discovered low-energy gas-phase fragmentation pathway, a nucleophilic substitution of the N3 in the 1,2,3-triazole ring generated by copper-catalyzed azide-alkyne cycloaddition (CuAAC) inspired us to create CITs. This selective cleavage is applied to the formation of the reporter ions to quantify protein expression level in cells. Chapter 5 describes clickable cross-linkers (CXLs) developed for elucidation of three-dimensional protein structures and protein-protein interactions (PPIs). In CXLs, cross-linking reactions are separated from the conjugation of affinity tags, avoiding steric hindrance. Cross-linked peptides are enriched from the complex mixture of yeast lysate and cross-linked ubiquitin digests using avidin affinity chromatography, showing high sensitivity of the CXL-based analysis. The low-energy pathway used for CIT reagents is also adopted to produce the reporter ion, filtering MS/MS scans of cross-linked peptides from those of unmodified peptides.