Status and perspective of protein crystallography at the first multi-bend achromat based synchrotron MAX IV

Ana Gonzalez; Tobias Krojer; Jie Nan; Monika Bjelčić; Swati Aggarwal; Ishkan Gorgisyan; Mirko Milas; Mikel Eguiraun; Cecilia Casadei; Manoop Chenchiliyan; Andrius Jurgilaitis; David Kroon; Byungnam Ahn; John Carl Ekström; Oskar Aurelius; Dean Lang; Thomas Ursby; Marjolein M.G.M. Thunnissen

doi:10.1107/S1600577525002255

Status and perspective of protein crystallography at the first multi-bend achromat based synchrotron MAX IV

Ana Gonzalez, Tobias Krojer, Jie Nan, Monika Bjelčić, Swati Aggarwal, Ishkan Gorgisyan, Mirko Milas, Mikel Eguiraun, Cecilia Casadei, Manoop Chenchiliyan, Andrius Jurgilaitis, David Kroon, Byungnam Ahn, John Carl Ekström, Oskar Aurelius, Dean Lang, Thomas Ursby, Marjolein M.G.M. Thunnissen

Lund University

Research output: Contribution to journal › Article › peer-review

Abstract

The first multi-bend achromat based synchrotron MAX IV operates two protein crystallography beamlines, BioMAX and MicroMAX. BioMAX is designed as a versatile, stable, high-throughput beamline catering for most protein crystallography experiments. MicroMAX is a more ambitious beamline dedicated to serial crystallography including time-resolved experiments. Both beamlines exploit the special characteristics of fourth-generation beamlines provided by the 3 GeV ring of MAX IV. In addition, the fragment-based drug discovery platform, FragMAX, is hosted and, at the FemtoMAX beamline, protein diffraction experiments exploring ultrafast time resolution can be performed. A technical and operational overview of the different beamlines and the platform is given as well as an outlook for protein crystallography embedded in the wider possibilities that MAX IV offers to users in the life sciences.

Original language	English
Pages (from-to)	779-791
Number of pages	13
Journal	Journal of Synchrotron Radiation
Volume	32
Issue number	Pt 3
DOIs	https://doi.org/10.1107/S1600577525002255
State	Published - 1 May 2025
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2025 International Union of Crystallography. All rights reserved.

Keywords

BioMAX
FemtoMAX
FragMAX
MicroMAX
beamlines
drug discovery
protein crystallography
synchrotrons
time-resolved crystallography

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10.1107/S1600577525002255

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Gonzalez, A., Krojer, T., Nan, J., Bjelčić, M., Aggarwal, S., Gorgisyan, I., Milas, M., Eguiraun, M., Casadei, C., Chenchiliyan, M., Jurgilaitis, A., Kroon, D., Ahn, B., Ekström, J. C., Aurelius, O., Lang, D., Ursby, T., & Thunnissen, M. M. G. M. (2025). Status and perspective of protein crystallography at the first multi-bend achromat based synchrotron MAX IV. Journal of Synchrotron Radiation, 32(Pt 3), 779-791. https://doi.org/10.1107/S1600577525002255

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abstract = "The first multi-bend achromat based synchrotron MAX IV operates two protein crystallography beamlines, BioMAX and MicroMAX. BioMAX is designed as a versatile, stable, high-throughput beamline catering for most protein crystallography experiments. MicroMAX is a more ambitious beamline dedicated to serial crystallography including time-resolved experiments. Both beamlines exploit the special characteristics of fourth-generation beamlines provided by the 3 GeV ring of MAX IV. In addition, the fragment-based drug discovery platform, FragMAX, is hosted and, at the FemtoMAX beamline, protein diffraction experiments exploring ultrafast time resolution can be performed. A technical and operational overview of the different beamlines and the platform is given as well as an outlook for protein crystallography embedded in the wider possibilities that MAX IV offers to users in the life sciences.",

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author = "Ana Gonzalez and Tobias Krojer and Jie Nan and Monika Bjel{\v c}i{\'c} and Swati Aggarwal and Ishkan Gorgisyan and Mirko Milas and Mikel Eguiraun and Cecilia Casadei and Manoop Chenchiliyan and Andrius Jurgilaitis and David Kroon and Byungnam Ahn and Ekstr{\"o}m, \{John Carl\} and Oskar Aurelius and Dean Lang and Thomas Ursby and Thunnissen, \{Marjolein M.G.M.\}",

year = "2025",

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day = "1",

doi = "10.1107/S1600577525002255",

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Gonzalez, A, Krojer, T, Nan, J, Bjelčić, M, Aggarwal, S, Gorgisyan, I, Milas, M, Eguiraun, M, Casadei, C, Chenchiliyan, M, Jurgilaitis, A, Kroon, D, Ahn, B, Ekström, JC, Aurelius, O, Lang, D, Ursby, T & Thunnissen, MMGM 2025, 'Status and perspective of protein crystallography at the first multi-bend achromat based synchrotron MAX IV', Journal of Synchrotron Radiation, vol. 32, no. Pt 3, pp. 779-791. https://doi.org/10.1107/S1600577525002255

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AU - Krojer, Tobias

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AU - Bjelčić, Monika

AU - Aggarwal, Swati

AU - Gorgisyan, Ishkan

AU - Milas, Mirko

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AU - Casadei, Cecilia

AU - Chenchiliyan, Manoop

AU - Jurgilaitis, Andrius

AU - Kroon, David

AU - Ahn, Byungnam

AU - Ekström, John Carl

AU - Aurelius, Oskar

AU - Lang, Dean

AU - Ursby, Thomas

AU - Thunnissen, Marjolein M.G.M.

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IS - Pt 3

ER -

Status and perspective of protein crystallography at the first multi-bend achromat based synchrotron MAX IV

Abstract

Bibliographical note

Keywords

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