X-ray spectroscopy meets native mass spectrometry: probing gas-phase protein complexes

Jocky C K Kung; Alan Kádek; Knut Kölbel; Steffi Bandelow; Sadia Bari; Jens Buck; Carl Caleman; Jan Commandeur; Tomislav Damjanović; Simon Dörner; Karim Fahmy; Lara Flacht; Johannes Heidemann; Khon Huynh; Janine-Denise Kopicki; Boris Krichel; Julia Lockhauserbäumer; Kristina Lorenzen; Yinfei Lu; Ronja Pogan; Jasmin Rehmann; Kira Schamoni-Kast; Lucas Schwob; Lutz Schweikhard; Sebastian Springer; Pamela H W Svensson; Florian Simke; Florian Trinter; Sven Toleikis; Thomas Kierspel; Charlotte Uetrecht

X-ray spectroscopy meets native mass spectrometry: probing gas-phase protein complexes

Jocky C K Kung, Alan Kádek, Knut Kölbel, Steffi Bandelow, Sadia Bari, Jens Buck, Carl Caleman, Jan Commandeur, Tomislav Damjanović, Simon Dörner, Karim Fahmy, Lara Flacht, Johannes Heidemann, Khon Huynh, Janine-Denise Kopicki, Boris Krichel, Julia Lockhauserbäumer, Kristina Lorenzen, Yinfei Lu, Ronja PoganJasmin Rehmann, Kira Schamoni-Kast, Lucas Schwob, Lutz Schweikhard, Sebastian Springer, Pamela H W Svensson, Florian Simke, Florian Trinter, Sven Toleikis, Thomas Kierspel, Charlotte Uetrecht

Institute of Chemistry and Metabolomics

1 Citation (Scopus)

Abstract

Gas-phase activation and dissociation studies of biomolecules, proteins and their non-covalent complexes using X-rays hold great promise for revealing new insights into the structure and function of biological samples. This is due to the unique properties of X-ray molecular interactions, such as site-specific and rapid ionization. In this perspective, we report and discuss the promise of first proof-of-principle studies of X-ray-induced dissociation of native (structurally preserved) biological samples ranging from small 17 kDa monomeric proteins up to large 808 kDa non-covalent protein assemblies conducted at a synchrotron (PETRA III) and a free-electron laser (FLASH2). A commercially available quadrupole time-of-flight mass spectrometer (Q-Tof Ultima US, Micromass/Waters), modified for high-mass analysis by MS Vision, was further adapted for integration with the open ports at the corresponding beamlines. The protein complexes were transferred natively into the gas phase via nano-electrospray ionization and subsequently probed by extreme ultraviolet (FLASH2) or soft X-ray (PETRA III) radiation, in either their folded state or following collision-induced activation in the gas phase. Depending on the size of the biomolecule and the activation method, protein fragmentation, dissociation, or enhanced ionization were observed. Additionally, an extension of the setup by ion mobility is described, which can serve as a powerful tool for structural separation of biomolecules prior to X-ray probing. The first experimental results are discussed in the broader context of current and upcoming X-ray sources, highlighting their potential for advancing structural biology in the future.

Original language	English
Journal	Physical Chemistry Chemical Physics
Volume	27
Issue number	25
Pages (from-to)	13234-13242
Number of pages	9
ISSN	1463-9076
Publication status	Published - 25.06.2025

Funding

Funders	Funder number
Universität Hamburg
Free and Hanseatic City of Hamburg
Helmholtz Initiative and Networking Fund
Joachim Herz Stiftung
Deutsches Elektronen-Synchrotron
Bundesministerium für Gesundheit
Uetrecht group
Vetenskapsrådet
Helmholtz Association	I-20180927, F-20150009, F-20171103, I-20221192, I-20190534, 13GW0622
Horizon 2020 Framework Programme	801406
European Research Council	759661
Deutsche Forschungsgemeinschaft	509471550, 2018-00740, 390715994
Alexander von Humboldt-Stiftung	05K16BH1, 05K2016, 05K16HG1, 1196583-HFST-P
Bundesministerium für Bildung und Forschung	2021-05988, 05K22PSA

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Cite this

Kung, J. C. K., Kádek, A., Kölbel, K., Bandelow, S., Bari, S., Buck, J., Caleman, C., Commandeur, J., Damjanović, T., Dörner, S., Fahmy, K., Flacht, L., Heidemann, J., Huynh, K., Kopicki, J.-D., Krichel, B., Lockhauserbäumer, J., Lorenzen, K., Lu, Y., ... Uetrecht, C. (2025). X-ray spectroscopy meets native mass spectrometry: probing gas-phase protein complexes. Physical Chemistry Chemical Physics, 27(25), 13234-13242.

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title = "X-ray spectroscopy meets native mass spectrometry: probing gas-phase protein complexes",

abstract = "Gas-phase activation and dissociation studies of biomolecules, proteins and their non-covalent complexes using X-rays hold great promise for revealing new insights into the structure and function of biological samples. This is due to the unique properties of X-ray molecular interactions, such as site-specific and rapid ionization. In this perspective, we report and discuss the promise of first proof-of-principle studies of X-ray-induced dissociation of native (structurally preserved) biological samples ranging from small 17 kDa monomeric proteins up to large 808 kDa non-covalent protein assemblies conducted at a synchrotron (PETRA III) and a free-electron laser (FLASH2). A commercially available quadrupole time-of-flight mass spectrometer (Q-Tof Ultima US, Micromass/Waters), modified for high-mass analysis by MS Vision, was further adapted for integration with the open ports at the corresponding beamlines. The protein complexes were transferred natively into the gas phase via nano-electrospray ionization and subsequently probed by extreme ultraviolet (FLASH2) or soft X-ray (PETRA III) radiation, in either their folded state or following collision-induced activation in the gas phase. Depending on the size of the biomolecule and the activation method, protein fragmentation, dissociation, or enhanced ionization were observed. Additionally, an extension of the setup by ion mobility is described, which can serve as a powerful tool for structural separation of biomolecules prior to X-ray probing. The first experimental results are discussed in the broader context of current and upcoming X-ray sources, highlighting their potential for advancing structural biology in the future.",

author = "Kung, \{Jocky C K\} and Alan K{\'a}dek and Knut K{\"o}lbel and Steffi Bandelow and Sadia Bari and Jens Buck and Carl Caleman and Jan Commandeur and Tomislav Damjanovi{\'c} and Simon D{\"o}rner and Karim Fahmy and Lara Flacht and Johannes Heidemann and Khon Huynh and Janine-Denise Kopicki and Boris Krichel and Julia Lockhauserb{\"a}umer and Kristina Lorenzen and Yinfei Lu and Ronja Pogan and Jasmin Rehmann and Kira Schamoni-Kast and Lucas Schwob and Lutz Schweikhard and Sebastian Springer and Svensson, \{Pamela H W\} and Florian Simke and Florian Trinter and Sven Toleikis and Thomas Kierspel and Charlotte Uetrecht",

note = "Publisher Copyright: {\textcopyright} 2025 The Royal Society of Chemistry.",

year = "2025",

month = jun,

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language = "English",

volume = "27",

pages = "13234--13242",

journal = "Physical Chemistry Chemical Physics",

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Kung, JCK, Kádek, A, Kölbel, K, Bandelow, S, Bari, S, Buck, J, Caleman, C, Commandeur, J, Damjanović, T, Dörner, S, Fahmy, K, Flacht, L, Heidemann, J, Huynh, K, Kopicki, J-D , Krichel, B, Lockhauserbäumer, J, Lorenzen, K, Lu, Y, Pogan, R, Rehmann, J, Schamoni-Kast, K, Schwob, L, Schweikhard, L, Springer, S, Svensson, PHW, Simke, F, Trinter, F, Toleikis, S, Kierspel, T & Uetrecht, C 2025, 'X-ray spectroscopy meets native mass spectrometry: probing gas-phase protein complexes', Physical Chemistry Chemical Physics, vol. 27, no. 25, pp. 13234-13242.

TY - JOUR

T1 - X-ray spectroscopy meets native mass spectrometry

T2 - probing gas-phase protein complexes

AU - Kung, Jocky C K

AU - Kádek, Alan

AU - Kölbel, Knut

AU - Bandelow, Steffi

AU - Bari, Sadia

AU - Buck, Jens

AU - Caleman, Carl

AU - Commandeur, Jan

AU - Damjanović, Tomislav

AU - Dörner, Simon

AU - Fahmy, Karim

AU - Flacht, Lara

AU - Heidemann, Johannes

AU - Huynh, Khon

AU - Kopicki, Janine-Denise

AU - Krichel, Boris

AU - Lockhauserbäumer, Julia

AU - Lorenzen, Kristina

AU - Lu, Yinfei

AU - Pogan, Ronja

AU - Rehmann, Jasmin

AU - Schamoni-Kast, Kira

AU - Schwob, Lucas

AU - Schweikhard, Lutz

AU - Springer, Sebastian

AU - Svensson, Pamela H W

AU - Simke, Florian

AU - Trinter, Florian

AU - Toleikis, Sven

AU - Kierspel, Thomas

AU - Uetrecht, Charlotte

PY - 2025/6/25

Y1 - 2025/6/25

N2 - Gas-phase activation and dissociation studies of biomolecules, proteins and their non-covalent complexes using X-rays hold great promise for revealing new insights into the structure and function of biological samples. This is due to the unique properties of X-ray molecular interactions, such as site-specific and rapid ionization. In this perspective, we report and discuss the promise of first proof-of-principle studies of X-ray-induced dissociation of native (structurally preserved) biological samples ranging from small 17 kDa monomeric proteins up to large 808 kDa non-covalent protein assemblies conducted at a synchrotron (PETRA III) and a free-electron laser (FLASH2). A commercially available quadrupole time-of-flight mass spectrometer (Q-Tof Ultima US, Micromass/Waters), modified for high-mass analysis by MS Vision, was further adapted for integration with the open ports at the corresponding beamlines. The protein complexes were transferred natively into the gas phase via nano-electrospray ionization and subsequently probed by extreme ultraviolet (FLASH2) or soft X-ray (PETRA III) radiation, in either their folded state or following collision-induced activation in the gas phase. Depending on the size of the biomolecule and the activation method, protein fragmentation, dissociation, or enhanced ionization were observed. Additionally, an extension of the setup by ion mobility is described, which can serve as a powerful tool for structural separation of biomolecules prior to X-ray probing. The first experimental results are discussed in the broader context of current and upcoming X-ray sources, highlighting their potential for advancing structural biology in the future.

AB - Gas-phase activation and dissociation studies of biomolecules, proteins and their non-covalent complexes using X-rays hold great promise for revealing new insights into the structure and function of biological samples. This is due to the unique properties of X-ray molecular interactions, such as site-specific and rapid ionization. In this perspective, we report and discuss the promise of first proof-of-principle studies of X-ray-induced dissociation of native (structurally preserved) biological samples ranging from small 17 kDa monomeric proteins up to large 808 kDa non-covalent protein assemblies conducted at a synchrotron (PETRA III) and a free-electron laser (FLASH2). A commercially available quadrupole time-of-flight mass spectrometer (Q-Tof Ultima US, Micromass/Waters), modified for high-mass analysis by MS Vision, was further adapted for integration with the open ports at the corresponding beamlines. The protein complexes were transferred natively into the gas phase via nano-electrospray ionization and subsequently probed by extreme ultraviolet (FLASH2) or soft X-ray (PETRA III) radiation, in either their folded state or following collision-induced activation in the gas phase. Depending on the size of the biomolecule and the activation method, protein fragmentation, dissociation, or enhanced ionization were observed. Additionally, an extension of the setup by ion mobility is described, which can serve as a powerful tool for structural separation of biomolecules prior to X-ray probing. The first experimental results are discussed in the broader context of current and upcoming X-ray sources, highlighting their potential for advancing structural biology in the future.

UR - https://www.scopus.com/pages/publications/105004049724

UR - https://www.mendeley.com/catalogue/3d4cc77e-ceea-351b-a0d5-8fb16f6e823c/

M3 - Scientific review articles

C2 - 40304431

SN - 1463-9076

VL - 27

SP - 13234

EP - 13242

JO - Physical Chemistry Chemical Physics

JF - Physical Chemistry Chemical Physics

IS - 25

ER -

X-ray spectroscopy meets native mass spectrometry: probing gas-phase protein complexes

Abstract

Funding

UN SDGs

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