Abstract
‘Bottom up’ proteomic studies typically use tandem mass spectrometry data to infer peptide ion sequence, enabling identification of the protein whence they derive. The majority of such studies employ collision-induced dissociation (CID) to induce fragmentation of the peptide structure giving diagnostic b-, y-, and a- ions. Recently, rearrangement processes that result in scrambling of the original peptide sequence during CID have been reported for these ions. Such processes have the potential to adversely affect ion accounting (and thus scores from automated search algorithms) in tandem mass spectra, and in extreme cases could lead to false peptide identification. Here, analysis of peptide species produced by Lys-N proteolysis of standard proteins is performed and sequences that exhibit such rearrangement processes identified. The effect of increasing the gas-phase basicity of the N-terminal lysine residue through derivatization to homoarginine toward such sequence scrambling is then assessed. The presence of a highly basic homoarginine (or arginine) residue at the N-terminus is found to disfavor/inhibit sequence scrambling with a coincident increase in the formation of b(n-1)+H2O product ions. Finally, further analysis of a sequence produced by Lys-C proteolysis provides evidence toward a potential mechanism for the apparent inhibition of sequence scrambling during resonance excitation CID. Graphical ᅟ
Highlights
Proteomic studies typically use tandem mass spectrometry (MS/MS) employing collision-induced dissociation (CID) for identification of large numbers of peptides and proteins [1, 2]
This suggests that the common depletion of rearrangement ion products in the presence of a strongly basic residue may be associated with one of two effects, namely (1) the diversion of N-terminal product ion current to b(n-1)+H2O species, depleting the population of macrocycle precursors, and (2) the disfavoring of macrocyclic cleavage by the presence of a proton-sequestering site, unless the presence of a glutamic acid residue promotes cleavage by local proton transfer
The presence of an arginine/ homoarginine side chain within a peptide sequence will, in most cases preclude the formation of scrambled product ions, in accordance with previously published studies [38, 49]
Summary
Proteomic studies typically use tandem mass spectrometry (MS/MS) employing collision-induced dissociation (CID) for identification (and quantification) of large numbers of peptides and proteins [1, 2]. In each example following derivatization, the peptide ion containing the Nterminal homoarginine residue dissociates to produce a significantly more abundant b(n-1)+H2O species, with no sequence scrambled species being observed (Figures 2b and 3b).
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