Expanding the mass range for UVPD-based native top-down mass spectrometry

Jean François Greisch; Sem Tamara; Richard A. Scheltema; Howard W.R. Maxwell; Robert D. Fagerlund; Peter C. Fineran; Stephan Tetter; Donald Hilvert; Albert J.R. Heck

doi:10.1039/c9sc01857c

Expanding the mass range for UVPD-based native top-down mass spectrometry

Jean François Greisch, Sem Tamara, Richard A. Scheltema, Howard W.R. Maxwell, Robert D. Fagerlund, Peter C. Fineran, Stephan Tetter, Donald Hilvert, Albert J.R. Heck^*

^*Corresponding author for this work

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

Abstract

Native top-down mass spectrometry is emerging as a methodology that can be used to structurally investigate protein assemblies. To extend the possibilities of native top-down mass spectrometry to larger and more heterogeneous biomolecular assemblies, advances in both the mass analyzer and applied fragmentation techniques are still essential. Here, we explore ultraviolet photodissociation (UVPD) of protein assemblies on an Orbitrap with extended mass range, expanding its usage to large and heterogeneous macromolecular complexes, reaching masses above 1 million Da. We demonstrate that UVPD can lead not only to the ejection of intact subunits directly from such large intact complexes, but also to backbone fragmentation of these subunits, providing enough sequence information for subunit identification. The Orbitrap mass analyzer enables simultaneous monitoring of the precursor, the subunits, and the subunit fragments formed upon UVPD activation. While only partial sequence coverage of the subunits is observed, the UVPD data yields information about the localization of chromophores covalently attached to the subunits of the light harvesting complex B-phycoerythrin, extensive backbone fragmentation in a subunit of a CRISPR-Cas Csy (type I-F Cascade) complex, and sequence modifications in a virus-like proteinaceous nano-container. Through these multiple applications we demonstrate for the first time that UVPD based native top-down mass spectrometry is feasible for large and heterogeneous particles, including ribonucleoprotein complexes and MDa virus-like particles.

Original language	English
Pages (from-to)	7163-7171
Number of pages	9
Journal	Chemical Science
Volume	10
Issue number	30
DOIs	https://doi.org/10.1039/c9sc01857c
Publication status	Published - 1 Jan 2019

Funding

We thank the members of the Heck laboratory for the support, especially Arjan Barendregt and Barbara A. Steigenberger. JFG thanks Paulo C. Carvalho (FIOCRUZ/PR, Brazil) for providing the latest Y.A.D.A. version (2.0). This research received funding through The Netherlands Organization for Scientic Research (NWO) TTW project 15575 (Structural analysis and position-resolved imaging of macromolecular structures using novel mass spectrometry-based approaches) and SPI.2017.028; Spinoza Award to AJRH, and was further supported by the large-scale proteomics facility Proteins@Work (project 184.032.201) embedded in The Netherlands Proteomics Centre. This project received additional funding from the European Union's Horizon 2020 research and innovation program under the grant agreement 686547 (MSMed) for AJRH, and European Research Council Advanced Grant ERC-AdG-2012-321295 to DH. The Fineran laboratory was supported by the Marsden Fund, Royal Society of New Zealand (RSNZ) and a Rutherford Discovery Fellowship (RSNZ) to PCF. HWRM was supported by a contract from the Health Research Council of New Zealand.

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Expanding the mass rangeFinal published version, 1.57 MBLicence: CC BY-NC

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title = "Expanding the mass range for UVPD-based native top-down mass spectrometry",

abstract = "Native top-down mass spectrometry is emerging as a methodology that can be used to structurally investigate protein assemblies. To extend the possibilities of native top-down mass spectrometry to larger and more heterogeneous biomolecular assemblies, advances in both the mass analyzer and applied fragmentation techniques are still essential. Here, we explore ultraviolet photodissociation (UVPD) of protein assemblies on an Orbitrap with extended mass range, expanding its usage to large and heterogeneous macromolecular complexes, reaching masses above 1 million Da. We demonstrate that UVPD can lead not only to the ejection of intact subunits directly from such large intact complexes, but also to backbone fragmentation of these subunits, providing enough sequence information for subunit identification. The Orbitrap mass analyzer enables simultaneous monitoring of the precursor, the subunits, and the subunit fragments formed upon UVPD activation. While only partial sequence coverage of the subunits is observed, the UVPD data yields information about the localization of chromophores covalently attached to the subunits of the light harvesting complex B-phycoerythrin, extensive backbone fragmentation in a subunit of a CRISPR-Cas Csy (type I-F Cascade) complex, and sequence modifications in a virus-like proteinaceous nano-container. Through these multiple applications we demonstrate for the first time that UVPD based native top-down mass spectrometry is feasible for large and heterogeneous particles, including ribonucleoprotein complexes and MDa virus-like particles.",

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Expanding the mass range for UVPD-based native top-down mass spectrometry

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