Basic biochemical mechanisms fundamental to human health arise from understanding the structure of large biological molecules, both proteins and nucleic acids. X-ray crystallography has been a key method for uncovering their structure and function. This project will develop computational methods needed to enable the use of serial X-ray crystallography techniques. Serial crystallography, performed at either third generation synchrotron beamlines or X-ray free-electron lasers, is emerging as a way to determine molecular structure using crystals that are probed once with a short X-ray pulse and then exchanged for a new sample. This a departure from traditional single-crystal experiments where the crystal is rotated in the beam to assemble a full data set, but which require large crystals, coupled with cryocooling to slow down the effects of radiation damage. Serial crystallography, in contrast, is performed with an extremely short X-ray pulse, which probes the structure before radiation damage occurs, and at normal physiological temperatures, where the full range of available molecular conformations can be revealed. The program DIALS (Diffraction Integration for Advanced Light Sources) reduces crystal diffraction patterns to a list of Bragg spot intensities, which are needed to compute the electron density map leading to an atomic model. Because the diffraction pattern in serial crystallography is sampled from still crystals rather than rotating ones, the analysis of Bragg spot intensities is entirely different. Frst, a correction must be applied to convert the intensity to the equivalent observation from a single rotating crystal, then duplicate Bragg spot measurements from potentially thousands of crystals must be merged to derive a single complete data set. This project will explore the assumptions made during this data reduction process, and identify optimal physical models and algorithms for deriving the best merged data. At the same time, DIALS will be released as a general data reduction package for all synchrotron-based crystallography (for both serial and single-crystal methods). DIALS is built around an open- source, community-oriented software architecture that can be adapted by beamline scientists to accommodate new instrumentation, in a field where rapid hardware advances are expected to continue for many years.

Public Health Relevance

Basic biochemical mechanisms fundamental to human health arise from understanding the structure of large biological molecules, both proteins and nucleic acids. X-ray crystallography has been a key method for uncovering their function, and it continues to grow in importance as brighter X-ray sources and more sensitive detectors are developed. This is a computational technology project intended to provide a sharper picture than previously available, allowing some reactions to be followed with snapshots over time, and other experiments to avoid X-ray damage that interfered with the measurement.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
5R01GM117126-03
Application #
9438543
Study Section
Macromolecular Structure and Function D Study Section (MSFD)
Program Officer
Smith, Ward
Project Start
2016-03-01
Project End
2020-02-29
Budget Start
2018-03-01
Budget End
2019-02-28
Support Year
3
Fiscal Year
2018
Total Cost
Indirect Cost
Name
Lawrence Berkeley National Laboratory
Department
Type
DUNS #
078576738
City
Berkeley
State
CA
Country
United States
Zip Code
94720
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