Prehydration and the Reversibility of Solid-State Hydrogen-Deuterium Exchange.

Abstract

The reversibility of solid-state hydrogen-deuterium exchange (ssHDX) and the effects of prehydration on the rate and extent of deuterium incorporation were evaluated using poly-d,l-alanine (PDLA) peptides colyophilized with various excipients. In prehydration studies, samples were equilibrated at a controlled relative humidity (6% or 11% RH) for 12 h and then transferred to corresponding D2O humidity conditions (6% or 11% RD) for deuterium labeling. In amorphous samples, the rate and extent of deuterium incorporation were similar in prehydrated samples and controls not subjected to prehydration. In reversibility studies, PDLA samples were maximally deuterated in controlled D2O humidity conditions (6% or 11% RD) and then transferred to corresponding H2O relative humidity (0%, 6%, 11%, or 43% RH). Hysteresis in deuterium removal was observed when compared with the deuterium incorporation kinetics for all formulations and conditions, confirming that the reaction is reversible in the solid state and that the forward and reverse processes differ. The extent of deuterium loss reached a plateau that depended on the delabeling relative humidity. Reverse reaction rate constants were quantified using a first-order kinetic model, a limiting case of the reversible first-order model applicable under sink conditions. For other conditions, plateau (steady-state) deuteration levels were related to forward and reverse rate constants in a reversible first-order kinetic model. The results support a mechanistic interpretation of ssHDX kinetics as a reversible first-order process, in which the forward (deuteration) rate depends on the activity of the deuterium donor.