Hydrogens and hydrogen-bond networks in macromolecular MicroED data

Abstract

Microcrystal electron diffraction (MicroED) is a powerful technique utilizing electron cryo-microscopy (cryo-EM) for protein structure determination of crystalline samples too small for X-ray crystallography. Electrons interact with the electrostatic potential of the sample, which means that scattered electrons carry informing about the charged state of atoms and can provide strong contrast for visualizing hydrogen atoms. Accurately identifying the positions of hydrogen atoms, and by extension the hydrogen bonding networks, is of importance for drug discovery and electron microscopy can enable such visualization. Using subatomic resolution MicroED data obtained from triclinic hen egg-white lysozyme, we identified hundreds of individual hydrogen atom positions and directly visualize hydrogen bonding interactions and the charged states of residues. Over a third of all hydrogen atoms are identified from strong difference peaks, the most complete view of a macromolecular hydrogen network visualized by electron diffraction to date. These results show that MicroED can provide accurate structural information on hydrogen atoms and non-covalent hydrogen bonding interactions in macromolecules. Furthermore, we find that the hydrogen bond lengths are more accurately described by the inter-nuclei distances than the centers of mass of the corresponding electron clouds. We anticipate that MicroED, coupled with ongoing advances in data collection and refinement, can open further avenues for structural biology by uncovering and understanding the hydrogen bonding interactions underlying protein structure and function.