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Megahertz data collection from protein microcrystals at an X-ray free-electron laser

Author

Listed:
  • Marie Luise Grünbein

    (Max Planck Institute for Medical Research)

  • Johan Bielecki

    (European XFEL GmbH)

  • Alexander Gorel

    (Max Planck Institute for Medical Research)

  • Miriam Stricker

    (Max Planck Institute for Medical Research)

  • Richard Bean

    (European XFEL GmbH)

  • Marco Cammarata

    (University of Rennes 1)

  • Katerina Dörner

    (European XFEL GmbH)

  • Lars Fröhlich

    (Deutsches Elektronensynchrotron DESY)

  • Elisabeth Hartmann

    (Max Planck Institute for Medical Research)

  • Steffen Hauf

    (European XFEL GmbH)

  • Mario Hilpert

    (Max Planck Institute for Medical Research)

  • Yoonhee Kim

    (European XFEL GmbH)

  • Marco Kloos

    (Max Planck Institute for Medical Research)

  • Romain Letrun

    (European XFEL GmbH)

  • Marc Messerschmidt

    (European XFEL GmbH
    BioXFEL STC)

  • Grant Mills

    (European XFEL GmbH
    La Trobe Institute for Molecular Science, La Trobe University)

  • Gabriela Nass Kovacs

    (Max Planck Institute for Medical Research)

  • Marco Ramilli

    (European XFEL GmbH)

  • Christopher M. Roome

    (Max Planck Institute for Medical Research)

  • Tokushi Sato

    (European XFEL GmbH
    Center for Free-Electron Laser Science, Deutsches Elektronensynchrotron)

  • Matthias Scholz

    (Deutsches Elektronensynchrotron DESY)

  • Michel Sliwa

    (Université de Lille)

  • Jolanta Sztuk-Dambietz

    (European XFEL GmbH)

  • Martin Weik

    (Institut de Biologie Structurale, Université Grenoble Alpes, CEA, CNRS)

  • Britta Weinhausen

    (European XFEL GmbH)

  • Nasser Al-Qudami

    (European XFEL GmbH)

  • Djelloul Boukhelef

    (European XFEL GmbH)

  • Sandor Brockhauser

    (European XFEL GmbH
    Biological Research Centre (BRC), Hungarian Academy of Sciences)

  • Wajid Ehsan

    (European XFEL GmbH)

  • Moritz Emons

    (European XFEL GmbH)

  • Sergey Esenov

    (European XFEL GmbH)

  • Hans Fangohr

    (European XFEL GmbH)

  • Alexander Kaukher

    (European XFEL GmbH)

  • Thomas Kluyver

    (European XFEL GmbH)

  • Max Lederer

    (European XFEL GmbH)

  • Luis Maia

    (European XFEL GmbH)

  • Maurizio Manetti

    (European XFEL GmbH)

  • Thomas Michelat

    (European XFEL GmbH)

  • Astrid Münnich

    (European XFEL GmbH)

  • Florent Pallas

    (European XFEL GmbH)

  • Guido Palmer

    (European XFEL GmbH)

  • Gianpietro Previtali

    (European XFEL GmbH)

  • Natascha Raab

    (European XFEL GmbH)

  • Alessandro Silenzi

    (European XFEL GmbH)

  • Janusz Szuba

    (European XFEL GmbH)

  • Sandhya Venkatesan

    (European XFEL GmbH)

  • Krzysztof Wrona

    (European XFEL GmbH)

  • Jun Zhu

    (European XFEL GmbH)

  • R. Bruce Doak

    (Max Planck Institute for Medical Research)

  • Robert L. Shoeman

    (Max Planck Institute for Medical Research)

  • Lutz Foucar

    (Max Planck Institute for Medical Research)

  • Jacques-Philippe Colletier

    (Institut de Biologie Structurale, Université Grenoble Alpes, CEA, CNRS)

  • Adrian P. Mancuso

    (European XFEL GmbH)

  • Thomas R. M. Barends

    (Max Planck Institute for Medical Research)

  • Claudiu A. Stan

    (Rutgers University Newark)

  • Ilme Schlichting

    (Max Planck Institute for Medical Research)

Abstract

X-ray free-electron lasers (XFELs) enable novel experiments because of their high peak brilliance and femtosecond pulse duration. However, non-superconducting XFELs offer repetition rates of only 10–120 Hz, placing significant demands on beam time and sample consumption. We describe serial femtosecond crystallography experiments performed at the European XFEL, the first MHz repetition rate XFEL, delivering 1.128 MHz X-ray pulse trains at 10 Hz. Given the short spacing between pulses, damage caused by shock waves launched by one XFEL pulse on sample probed by subsequent pulses is a concern. To investigate this issue, we collected data from lysozyme microcrystals, exposed to a ~15 μm XFEL beam. Under these conditions, data quality is independent of whether the first or subsequent pulses of the train were used for data collection. We also analyzed a mixture of microcrystals of jack bean proteins, from which the structure of native, magnesium-containing concanavalin A was determined.

Suggested Citation

  • Marie Luise Grünbein & Johan Bielecki & Alexander Gorel & Miriam Stricker & Richard Bean & Marco Cammarata & Katerina Dörner & Lars Fröhlich & Elisabeth Hartmann & Steffen Hauf & Mario Hilpert & Yoonh, 2018. "Megahertz data collection from protein microcrystals at an X-ray free-electron laser," Nature Communications, Nature, vol. 9(1), pages 1-9, December.
    • Handle: RePEc:nat:natcom:v:9:y:2018:i:1:d:10.1038_s41467-018-05953-4
    DOI: 10.1038/s41467-018-05953-4
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    Cited by:

    1. Susannah Holmes & Henry J. Kirkwood & Richard Bean & Klaus Giewekemeyer & Andrew V. Martin & Marjan Hadian-Jazi & Max O. Wiedorn & Dominik Oberthür & Hugh Marman & Luigi Adriano & Nasser Al-Qudami & S, 2022. "Megahertz pulse trains enable multi-hit serial femtosecond crystallography experiments at X-ray free electron lasers," Nature Communications, Nature, vol. 13(1), pages 1-13, December.

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