Investigation of amide hydrogen back-exchange in Asp and His repeats measured by hydrogen (1H/2H) exchange mass spectrometry

Abstract

Hydrogen/deuterium exchange (HDX) monitored by mass spectrometry (HDX-MS) has become a valuable tool in studies of protein dynamics and protein interactions. Isotopic exchange is typically initiated by diluting a protein solution into deuterated buffer at physiological conditions. For MS analysis, the exchange reaction is quenched by acidification and cooling and the labeled protein (or a digest thereof) is analyzed by mass spectrometry. An inevitable deuterium loss occurs during quench conditions (i.e., back-exchange). The primary structure of the peptide influences the back-exchange rate due to steric hindrance by bulky side groups and by inductive and charge effects. Here we show that the back-exchange in histidine repeats (His6) at HDX-MS quench conditions is complete within a few seconds using either acetic acid or formic acid in the quench solution, while aspartic acid repeats (Asp6) retain deuterons for several minutes using formic acid. We employ electron transfer dissociation to obtain residue-specific deuterium levels of the Asp repeat in K2D6IIKIIK using a hybrid linear ion trap-Orbitrap mass spectrometer. Our results show an unexpected uneven distribution of deuterium in the Asp repeat. The implication of the rapid back-exchange of His repeats for HDX-MS protein hydrogen exchange studies is discussed. We also discuss the implications of retained deuterons in the Asp repeat of K2D6IIKIIK when this peptide is used as a probe for the occurrence of hydrogen scrambling.