Abstract
Hydrogen-deuterium exchange combined with mass spectrometry (HDX-MS) is a widely applied biophysical technique that probes the structure and dynamics of biomolecules without the need for site-directed modifications or bio-orthogonal labels. The mechanistic interpretation of HDX data, however, is often qualitative and subjective, owing to a lack of quantitative methods to rigorously translate observed deuteration levels into atomistic structural information. To help address this problem, we have developed a methodology to generate structural ensembles that faithfully reproduce HDX-MS measurements. In this approach, an ensemble of protein conformations is first generated, typically using molecular dynamics simulations. A maximum-entropy bias is then applied post hoc to the resulting ensemble such that averaged peptide-deuteration levels, as predicted by an empirical model, agree with target values within a given level of uncertainty. We evaluate this approach, referred to as HDX ensemble reweighting (HDXer), for artificial target data reflecting the two major conformational states of a binding protein. We demonstrate that the information provided by HDX-MS experiments and by the model of exchange are sufficient to recover correctly weighted structural ensembles from simulations, even when the relevant conformations are rarely observed. Degrading the information content of the target data—e.g., by reducing sequence coverage, by averaging exchange levels over longer peptide segments, or by incorporating different sources of uncertainty—reduces the structural accuracy of the reweighted ensemble but still allows for useful insights into the distinctive structural features reflected by the target data. Finally, we describe a quantitative metric to rank candidate structural ensembles according to their correspondence with target data and illustrate the use of HDXer to describe changes in the conformational ensemble of the membrane protein LeuT. In summary, HDXer is designed to facilitate objective structural interpretations of HDX-MS data and to inform experimental approaches and further developments of theoretical exchange models.
Highlights
We have developed a computational approach to construct structural ensembles that are maximally diverse while reproducing target experimental Hydrogen-deuterium exchange combined with mass spectrometry (HDX-MS) data within a given level of uncertainty
hydrogen-deuterium exchange (HDX)-MS is carried out using so-called bottom-up and continuous labeling strategies, in which proteins are deuterated for varying amounts of time, quenched, proteolytically fragmented, and purified in the solution phase before analysis of the individual peptide fragments by mass spectrometry
Larger errors may arise from differences in experimental protocol and biological replicates [61], but our results suggest such errors may only impact the structural insights provided by HDX ensemble reweighting (HDXer) if they are at least an order of magnitude larger than those typically measured between replicates
Summary
Because side-chain and terminal-amine deuterons exchange back relatively rapidly with protons during analysis, HDX-MS data reports exclusively on backbone-amide exchange This ability to directly probe protein dynamics has led to diverse applications [4], including studies of allostery [5,6,7], epitope mapping for protein-protein or protein-lipid interactions [8,9,10,11], effects of ligand binding [12,13,14,15], mechanisms of membrane proteins [16,17,18,19,20,21,22], and dynamics of large macromolecular complexes [23,24,25,26]. This progress notwithstanding, the interpretation of HDXMS data in structural and mechanistic terms has been, generally speaking, largely qualitative and lacking objective metrics
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