Time-Resolved Crystallography: Principles, Problems and Practice [and Discussion]

Time-resolved crystallography is founded on the belief that a complete understanding of mechanism at the molecular level demands knowledge, not just of long-lived, readily observable structures, but also of short-lived intermediates in processes such as catalysis, ligand binding and release, and pro...

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Bibliographic Details
Published in:Philosophical transactions of the Royal Society of London. Series A: Mathematical, physical, and engineering sciences physical, and engineering sciences, 1992-08, Vol.340 (1657), p.175-190
Main Authors: Moffat, Keith, Chen, Ying, Ng, Kingman, McRee, Duncan, Getzoff, Elizabeth D., Rossmann, M., Hajdu, J., Petsko, G. A.
Format: Article
Language:English
Subjects:
Crystal lattices
Crystal structure
Crystallography
Crystals
Kinetics
Lasers
Photons
Single crystals
Synchrotrons
X ray diffraction
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Summary:Time-resolved crystallography is founded on the belief that a complete understanding of mechanism at the molecular level demands knowledge, not just of long-lived, readily observable structures, but also of short-lived intermediates in processes such as catalysis, ligand binding and release, and protein unfolding. Synchrotron X-ray sources enable X-ray diffraction patterns of high quality to be obtained from single crystals with exposure times that are often commensurate with the lifetime of the desired intermediates. The basic tools are therefore in place. How shall they be applied effectively? Can crystallography, long regarded as a static technique, in fact encompass dynamic processes? What pitfalls remain to be overcome? A time-resolved crystallographic experiment has five main components: the X-ray source; reaction initiation; reaction monitoring by optical or other techniques; X-ray data acquisition in real time; and data reduction and analysis. These are illustrated by our recent work on photoactive yellow protein, and on the acquisition and analysis of crystallographic data using 120 ps exposures.
ISSN:1364-503X
0962-8428
1471-2962
2054-0299
DOI:10.1098/rsta.1992.0059