# Interrogating Low Barrier Hydrogen Bonds with Neutrons, X-rays, and Computation

**Authors:** Jiusheng Lin, Oksana Gerlits, Daniel W. Kneller, Kevin L. Weiss, Leighton Coates, Mark A. Hix, Solomon Y. Effah, Andrey Kovalevsky, Alice R. Walker, Mark A. Wilson

PMC · DOI: 10.1063/4.0001112 · 2025-10-27

## TL;DR

This paper explores how the environment around hydrogen bonds affects proton delocalization in proteins using neutron diffraction, X-rays, and simulations.

## Contribution

The study introduces a paired protein model and QM/MM simulations to demonstrate how distant residues influence low barrier hydrogen bonds.

## Key findings

- Neutron diffraction and X-ray analysis reveal distinct hydrogen bond types in homologous proteins.
- QM/MM simulations show distant residues can impact proton delocalization in low barrier hydrogen bonds.
- Combining simulations and structural analysis could enable engineering of desired hydrogen bond properties.

## Abstract

Low barrier hydrogen bonds (LBHBs) are H-bonds where the barrier to proton transfer from the donor to the acceptor atom is comparable to the quantum mechanical zero-point energy of the interaction, resulting in proton delocalization. Facile proton transfer makes LBHBs effective mechanisms for facilitating acid-base catalysis in certain enzymes, creating favored pathways of allosteric communication between distant sites during catalysis, and imparting a high degree of selectivity in binding certain substrates. How the microenvironment of H-bonded residues affects the degree of proton delocalization in a candidate LBHB is not fully understood. We use two homologous proteins, human DJ-1 and E. coli YajL, as a paired model system to investigate microenvironmental effects on LBHB formation. Neutron diffraction demonstrates that YajL has an Asp- Glu LBHB while the analogous residues in DJ-1 form a conventional H-bond, validating bond length analysis of atomic resolution X-ray crystal structures. We explored the influence of the microenvironment on LBHB character by using large quantum mechanics-molecular mechanics (QM/MM) simulations where the QM region spanned several residues. These simulations support the neutron and X-ray crystallography results, demonstrating that surprisingly distant H-bonding residues can influence the degree of proton delocalization in candidate LBHBs. With the greater accessibility of QM/MM methods, combining simulation and structurally guided sequence analysis may permit the engineering of H-bonds with desired degrees of proton delocalization.

## Linked entities

- **Proteins:** PARK7 (Parkinsonism associated deglycase), yajL (oxidative stress resistance chaperone)
- **Species:** Homo sapiens (taxon 9606)

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Source: https://tomesphere.com/paper/PMC12585636