Dissociation of copper(ii) ternary complexes containing cystine

Abstract: The collision-induced dissociations are reported for Cu(II) complexes containing 1,4,7-triazacyclononane (tacn) as the auxiliary ligand and a peptide containing one cystine residue. For six of the complexes examined, cleavage of the S-S bond in the peptide was the dominant fragmentation pathway. The exceptions were for complexes containing the largest peptides, (GlyCys'Gly)(2) and (GlyGlyCys')(2) (Cys' = NHCH(CH(2)S)CO, one half of the cystine residue; terminal H and OH are implicit), for which proton transfer… Show more

“…There are several competing processes that influence the yield of intact peptide radical, including proton transfer and peptide fragmentation. A number of papers have been published utilizing this general method for radical production. ,− ,− The nature of the auxiliary metal ligands and the metal itself can significantly influence the prominence of these alternate channels, which has been covered in a recent review . A survey of the publications utilizing this approach reveals that the vast majority report results based on very small peptides, that is, dipeptides and tripeptides, with an 11-mer representing the largest peptide examined to date.…”

Peptide Radicals and Cation Radicals in the Gas Phase

“…There are several competing processes that influence the yield of intact peptide radical, including proton transfer and peptide fragmentation. A number of papers have been published utilizing this general method for radical production. ,− ,− The nature of the auxiliary metal ligands and the metal itself can significantly influence the prominence of these alternate channels, which has been covered in a recent review . A survey of the publications utilizing this approach reveals that the vast majority report results based on very small peptides, that is, dipeptides and tripeptides, with an 11-mer representing the largest peptide examined to date.…”

Peptide Radicals and Cation Radicals in the Gas Phase

“…One of the most straightforward ways to generate radical cations in the gas phase was developed by Siu and coworkers [18,19] and has been applied extensively to the creation of radical cations of amino acids [20] and peptides [21,22], including methionineand disulfide-based radicals [23,24]. In this method, an analyte molecule is complexed with a RedOx-active metal ion and an auxiliary ligand, subsequent CID of the ternary complex often results in the electron transfer from the analyte M (see Eq.…”

The formation of resonance-stabilized sulfur-based radical cations and their gas-phase reactivity

Mass spectrometry reflects key aspects of copper-amyloid β chemistry