Applications of hydrogen deuterium exchange ensemble reweighting to model native protein ensembles, macromolecular interactions and protein drug interactions.

Abstract

Hydrogen-deuterium exchange mass spectrometry (HDX-MS) is a powerful approach to probe the structural dynamics of a protein in solution. It simultaneously provides time-resolved information on the structural environment of the amide hydrogen of every residue of a protein except Prolines. As such, HDX-MS has been successfully applied to provide insight into the characterization of native state ensembles of proteins, macromolecular interactions, protein-small molecule interactions or protein folding and unfolding studies. However, it remains largely limited to peptide-level resolution information. On the other hand, molecular dynamics (MD) simulations provide a high-resolution view of a protein's structural dynamics by simulating the motion of a protein's atoms over time starting from a high-resolution structure. However, the time scales accessible to MD simulations are limited and can lead to inadequate exploration of a protein's conformational landscape. To bridge this gap, efforts have aimed at developing quantitative and integrative approaches that leverage HDX-MS data to assess and refine computationally generated structural ensembles. HDX ensemble reweighting (HDXer) is one such approach which uses a post hoc maximum entropy approach to adjusts the weights of individual frames of a structural ensemble to conform to HDX-MS data. We had previously applied HDXer to model the native ensemble of the cytoplasmic heme binding protein, PhuS. Here, we have validated the proposed model ensemble by using structure-based drug design approach to successfully target novel, cryptic drug binding sites that would have otherwise not been targetable using HDX-MS or MD simulations alone. Finally, we demonstrate the broader applicability of such HDX-MS guided integrative approach to model macromolecular interactions, missing electron density and protein-small molecule drug interactions