Observation of an unusually facile fragmentation pathway of gas-phase peptide ions: a study on the gas-phase fragmentation mechanism and energetics of tryptic peptides modified with 4-sulfophenyl isothiocyanate (SPITC) and 4-chlorosulfophenyl isocyanate (SPC) and their 18-crown-6 complexes

Abstract

Various peptide modifications have been explored recently to facilitate the acquisition of sequence information. N‐terminal sulfonation is an interesting modification because it allows unambiguous de novo sequencing of peptides, especially in conjunction with MALDI‐PSD‐TOF analysis; such modified peptide ions undergo fragmentation at energies lower than those required conventionally for unmodified peptide ions. In this study, we systematically investigated the fragmentation mechanisms of N‐terminal sulfonated peptide ions prepared using two different N‐terminal sulfonation reagents: 4‐sulfophenyl isothiocyanate (SPITC) and 4‐chlorosulfophenyl isocyanate (SPC). Collision‐induced dissociation (CID) of the SPC‐modified peptide ions produced a set of y‐series ions that were more evenly distributed relative to those observed for the SPITC‐modified peptides; y~n−1~ ion peaks were consistently and significantly larger than the signals of the other y‐ions. We experimentally investigated the differences between the dissociation energies of the SPITC‐ and SPC‐modified peptide ions by comparing the MS/MS spectra of the complexes formed between the crown ether 18‐crown‐6 (CE) and the modified peptides. Upon CID, the complexes formed between 18‐crown‐6 ether and the protonated amino groups of C‐terminal lysine residues underwent either peptide backbone fragmentation or complex dissociation. Although the crown ether complexes of the unmodified ([M + CE + 2H]^2+^) and SPC‐modified ([M* + CE + 2H]^2+^) peptides underwent predominantly noncovalent complex dissociation upon CID, the low‐energy dissociations of the crown ether complexes of the SPITC‐modified peptides ([M′ + CE + 2H]^2+^) unexpectedly resulted in peptide backbone fragmentations, along with a degree of complex dissociation. We performed quantum mechanical calculations to address the energetics of fragmentations observed for the modified peptides. Copyright © 2007 John Wiley & Sons, Ltd.