Negative ion cleavages of (M–H)− anions of peptides. Part 3. Post‐translational modifications

It is now 25 years since we commenced the study of the negative‐ion fragmentations of peptides and we have recently concluded this research with investigations of the negative‐ion chemistry of most post‐translational functional groups. Our first negative‐ion peptide review (Bowie, Brinkworth, & Dua, 2002) dealt with the characteristic backbone fragmentations and side‐chain cleavages from (M–H)^? ions of underivatized peptides, while the second (Bilusich & Bowie, 2009) included negative‐ion backbone cleavages for Ser and Cys and some initial data on some post‐translational groups including disulfides. This third and final review provides a brief summary of the major backbone and side chain cleavages outlined before (Bowie, Brinkworth, & Dua, 2002) and describes the quantum mechanical hydrogen tunneling associated with some proton transfers in enolate anion/enolate systems. The review then describes, in more depth, the negative‐ion cleavages of the post‐translational groups Kyn, isoAsp, pyroglu, disulfides, phosphates, and sulfates. Particular emphasis is devoted to disulfides (both intra‐ and intermolecular) and phosphates because of the extensive and spectacular anion chemistry shown by these groups. © 2016 Wiley Periodicals, Inc. Mass Spec Rev     

Collision-induced fragmentations of the (M-H)- parent anions of underivatized peptides: an aid to structure determination and some unusual negative ion cleavages

This article describes the fundamental cleavage reactions of (M-H)(-) anions of underivatized peptides that contain up to 25 amino acid residues. The experimental observations of these cleavages have been backed up by molecular modeling, generally at the AM1 level of theory. The basic cleavages are the ubiquitous alpha- and beta-backbone cleavage reactions, which provide information similar to that of the B and Y + 2 cleavages of MH(+) ions of peptides. The residues Asp and Asn also effect cleavages of the backbone (called delta- and gamma-cleavages), by reactions initiated from side chain enolate anions, causing elimination reactions that cleave the backbone between the Asp (Asn) N bond;C backbone bond. Glu and Gln also direct analogous delta- and gamma-cleavages of the backbone, but in this case the processes are initiated by attack of the side chain CO(2) (-) (CONH(-)) to form a lactone (lactam). Ser and Thr residues undergo characteristic fragmentations of the side chain. These processes, losses of CH(2)O (Ser) and MeCHO (Thr), convert these residues into Gly. In larger peptides, Ser and Thr can effect two backbone cleavage reactions, called gamma- and epsilon -processes. The C-terminal CO(2) (-) (or CONH(-)) forms a hydrogen bond with the side chain OH (of Ser or Thr), placing the C-terminal residue in a position where it may affect S(N) (2) attack at the electrophilic backbone CH of Ser, with concomitant cleavage of the backbone. All of the above negative ion cleavages require the peptide backbone to be conformationally flexible. However, there is a backbone cleavage that requires the peptide to have an alpha-helical conformation in order for the two reacting centers to approach. This cleavage is illustrated for the Glu 23-initiated backbone cleavage at Ile 21 for the (M-H)(-) anion of the antimicrobial peptide caerin 1.1.