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RationaleThe function of a protein or the binding affinity of an antibody can be substantially altered by the replacement of leucine (Leu) with isoleucine (Ile), and vice versa, so the ability to identify the correct isomer using mass spectrometry can help resolve important biological questions. Tandem mass spectrometry approaches for Leu/Ile (Xle) discrimination have been developed, but they all have certain limitations. MethodsFour model peptides and two wild‐type peptide sequences containing either Leu or Ile residues were subjected to charge transfer dissociation (CTD) mass spectrometry on a modified three‐dimensional ion trap. The peptides were analyzed in both the 1+ and 2+ charge states, and the results were compared to conventional collision‐induced dissociation spectra of the same peptides obtained using the same instrument. ResultsCTD resulted in 100% sequence coverage for each of the studied peptides and provided a variety of side‐chain cleavages, includingd,wandvions. Using CTD, reliabledandwions of Xle residues were observed more than 80% of the time. When present,dions are typically greater than 10% of the abundance of the correspondingaions from which they derive, andwions are typically more abundant than thezions from which they derive. ConclusionsCTD has the benefit of being applicable to both 1+ and 2+ precursor ions, and the overall performance is comparable to that of other high‐energy activation techniques like hot electron capture dissociation and UV photodissociation. CTD does not require chemical modifications of the precursor peptides, nor does it require additional levels of isolation and fragmentation.