H-D exchange kinetics of alcohols and protonated peptides: Effects of structure and proton affinity

Abstract

The kinetics of gas‐phase HD exchange reactions of a series of protonated amino acids and peptides with deuterium‐substituted alcohols (D₂O, CH₃OD, C₂H₅OD and 1‐C₄H₉OD) were studied in an external source Fourier transform mass spectrometer. The number of exchanges observed on the time‐scale of these experiments ranged from one to the total number of ‘labile’ substrate hydrogens, depending on the amino acid and the deuterating reagent. Exchange efficiencies, k/k_ADO, varied from k/k_ADO) with proton affinity difference (ΔPA = PA of unprotonated substrate ‐ PA of reagent) was observed. The amino acids lysine and histidine and the dipeptides alanylglycine and diglycine showed higher reactivity and greater tendency for multiple exchange, with a weaker dependence on ΔPA. The ability of a peptide and an alcohol to exchange efficiently even when ΔPA is larger is attributed to the occurrence of exchange within a cyclic hydrogen‐bonded complex, in which the deuterating agent forms a bridge between the site of protonation and a basic site on the substrate.