High-Energy Electron Transfer Dissociation (HE-ETD) Using Alkali Metal Targets for Sequence Analysis of Post-Translational Peptides

Post-translational modifications (PTMs) of proteins are important in the activation, localization, and regulation of protein function in vivo. The usefulness of electron capture dissociation (ECD) and electron-transfer dissociation (ETD) in tandem mass spectrometry (MS/MS) using low-energy (LE) trap type mass spectrometer is associated with no loss of a labile PTM group regarding peptide and protein sequencing. The experimental results of high-energy (HE) collision induced dissociation (CID) using the Xe and Cs targets and LE-ETD were compared for doubly-phosphorylated peptides TGFLT(p)EY(p)VATR (1). Although HE-CID using the Xe target did not provide information on the amino acid sequence, HE-CID using the Cs target provided all the z-type ions without loss of the phosphate groups as a result of HE-ETD process, while LE-ETD using fluoranthene anion gave only z-type ions from z5 to z11. The difference in the results of HE-CID between the Xe and Cs targets demonstrated that HE-ETD process with the Cs target took place much more dominantly than collisional activation. The difference between HE-ETD using Cs targets and LE-ETD using the anion demonstrated that mass discrimination was much weaker in the high-energy process. HE-ETD was also applied to three other phosphopeptides YGGMHRQEX(p)VDC (2: X = S, 3: X = T, 4: X = Y). The HE-CID spectra of the doubly-protonated phosphopeptides (= [M + 2H]2+) of 2, 3, and 4 using the Cs target showed a very similar feature that the c-type ions from c7 to c11 and the z-type ions from z7 to z11 were formed via N–Cα bond cleavage without a loss of the phosphate group.

Graphical AbstractHigh-energy (HE) collision induced dissociation (CID) using the Xe and Cs targets and LE-ETD were compared for phosphorylated peptides TGFLT(p)EY(p)VATR and YGGMHRQEX(p)VDC (2: X = S, 3: X = T, 4: X = Y).Figure optionsDownload full-size imageDownload high-quality image (163 K)Download as PowerPoint slide