SAXS studies of X-ray induced disulfide bond damage: Engineering high-resolution insight from a low-resolution technique

By Timothy R. Stachowski, Mary E. Snell, Edward Snell1

1. Hauptman-Woodward Medical Research Institute - SUNY Buffalo

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Type

journal-article

Author

Timothy R. Stachowski and Mary E. Snell and Edward H. Snell

Citation

Stachowski, T.R., Snell, M.E. & Snell, E.H., 2020. SAXS studies of X-ray induced disulfide bond damage: Engineering high-resolution insight from a low-resolution technique T. J. Boggon, ed. PLOS ONE, 15(11), p.e0239702. Available at: http://dx.doi.org/10.1371/journal.pone.0239702.

Abstract

A significant problem in biological X-ray crystallography is the radiation chemistry caused by the incident X-ray beam. This produces both global and site-specific damage. Site specific damage can misdirect the biological interpretation of the structural models produced. Cryo-cooling crystals has been successful in mitigating damage but not eliminating it altogether; however, cryo-cooling can be difficult in some cases and has also been shown to limit functionally relevant protein conformations. The doses used for X-ray crystallography are typically in the kilo-gray to mega-gray range. While disulfide bonds are among the most significantly affected species in proteins in the crystalline state at both cryogenic and higher temperatures, there is limited information on their response to low X-ray doses in solution, the details of which might inform biomedical applications of X-rays. In this work we engineered a protein that dimerizes through a susceptible disulfide bond to relate the radiation damage processes seen in cryo-cooled crystals to those closer to physiologic conditions. This approach enables a low-resolution technique, small angle X-ray scattering (SAXS), to detect and monitor a residue specific process. A dose dependent fragmentation of the engineered protein was seen that can be explained by a dimer to monomer transition through disulfide bond cleavage. This supports the crystallographically derived mechanism and demonstrates that results obtained crystallographically can be usefully extrapolated to physiologic conditions. Fragmentation was influenced by pH and the conformation of the dimer, providing information on mechanism and pointing to future routes for investigation and potential mitigation. The novel engineered protein approach to generate a large-scale change through a site-specific interaction represents a promising tool for advancing radiation damage studies under solution conditions.

DOI

Funding

NSF-STC Biology with X-ray Lasers (NSF-1231306)