Radiation Damage on Selenomethionine-Substituted Single-Domain Substrate-Binding Protein

Abstract

Radiation damage is an inherent challenge in macromolecular crystallography (MX). This diminishes the diffraction quality and also compromises the accuracy of the crystal structure. Investigating the impact of radiation damage on the crystal quality and structure can offer valuable insights into the structural interpretation and data collection strategy. Selenomethionine (SeMet, Mse) is an amino acid that exists in nature and contains a high-Z atom, i.e., selenium (Se), which is sensitive to radiation damage; however, little is known regarding the radiation damage of this amino acid. To better understand the radiation damage that affects SeMet, we investigated the radiation damage to a SeMet-substituted substrate-binding protein from Rhodothermus marinus. As the X-ray dose increased, the quality of the data statistics deteriorated. In particular, an increase in the X-ray dose increased the negative Fo-Fc electron density map near the Se atom of the Mse residue, while no negative Fo-Fc electron density map was observed in the other atoms (O, C, and N). Radiation damage increased the absolute B-factor value of the Se atom in the Mse residue, which was higher than that of the other atoms. This indicates that Se is more sensitive to radiation damage than other atoms. These results will contribute to advancing our knowledge of the radiation damage that can occur in MX.