Glycoproteomics in Cerebrospinal Fluid Reveals Brain-Specific Glycosylation Changes

Melissa Baerenfaenger; Merel A. Post; Pieter Langerhorst; Karin Huijben; Fokje Zijlstra; Joannes F.M. Jacobs; Marcel M. Verbeek; Hans J.C.T. Wessels; Dirk J. Lefeber

doi:10.3390/ijms24031937

Glycoproteomics in Cerebrospinal Fluid Reveals Brain-Specific Glycosylation Changes

Melissa Baerenfaenger, Merel A. Post, Pieter Langerhorst, Karin Huijben, Fokje Zijlstra, Joannes F.M. Jacobs, Marcel M. Verbeek, Hans J.C.T. Wessels, Dirk J. Lefeber^*

^*Corresponding author for this work

AIMMS

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

Abstract

The glycosylation of proteins plays an important role in neurological development and disease. Glycoproteomic studies on cerebrospinal fluid (CSF) are a valuable tool to gain insight into brain glycosylation and its changes in disease. However, it is important to consider that most proteins in CSFs originate from the blood and enter the CSF across the blood–CSF barrier, thus not reflecting the glycosylation status of the brain. Here, we apply a glycoproteomics method to human CSF, focusing on differences between brain- and blood-derived proteins. To facilitate the analysis of the glycan site occupancy, we refrain from glycopeptide enrichment. In healthy individuals, we describe the presence of heterogeneous brain-type N-glycans on prostaglandin H2-D isomerase alongside the dominant plasma-type N-glycans for proteins such as transferrin or haptoglobin, showing the tissue specificity of protein glycosylation. We apply our methodology to patients diagnosed with various genetic glycosylation disorders who have neurological impairments. In patients with severe glycosylation alterations, we observe that heavily truncated glycans and a complete loss of glycans are more pronounced in brain-derived proteins. We speculate that a similar effect can be observed in other neurological diseases where a focus on brain-derived proteins in the CSF could be similarly beneficial to gain insight into disease-related changes.

Original language	English
Article number	1937
Pages (from-to)	1-17
Number of pages	17
Journal	International Journal of Molecular Sciences
Volume	24
Issue number	3
Early online date	18 Jan 2023
DOIs	https://doi.org/10.3390/ijms24031937
Publication status	Published - 1 Feb 2023

Bibliographical note

This article belongs to the Special Issue: Recent Advances in Glycoproteomics: Theory, Methods and Applications.

Funding Information:
This research was supported by the ZonMw Medium Investment Grant (40-00506-98-9001) and the collaboration project “EnFORCE” (LSHM21032) which is co-funded by the PPP Allowance made available by Health~Holland, Top Sector Life Sciences & Health, to stimulate public–private partnerships. This work was part of the Netherlands X-omics Initiative (NWO project 184.034.019) and EUROGLYCAN-omics (ERARE18-117) by ZonMw (90030376501), under the frame of E-Rare-3, the ERA-Net for Research on Rare Diseases. MMV received funding from the BIONIC project (no. 733050822, which has been made possible by ZonMW as part of ‘Memorabel’, the research and innovation program for dementia, as part of the Dutch national ‘Deltaplan for Dementia’: zonmw.nl/dementiaresearch); the SCALA project, funded by “The Galen and Hilary Weston Foundation” (NR170024); and the CAFÉ project (the National Institutes of Health, USA, grant number 5R01NS104147-02). The BIONIC project is a consortium of Radboudumc, LUMC, ADX Neurosciences, and Rhode Island University.

Publisher Copyright:
© 2023 by the authors.

Funding

This research was supported by the ZonMw Medium Investment Grant (40-00506-98-9001) and the collaboration project “EnFORCE” (LSHM21032) which is co-funded by the PPP Allowance made available by Health~Holland, Top Sector Life Sciences & Health, to stimulate public–private partnerships. This work was part of the Netherlands X-omics Initiative (NWO project 184.034.019) and EUROGLYCAN-omics (ERARE18-117) by ZonMw (90030376501), under the frame of E-Rare-3, the ERA-Net for Research on Rare Diseases. MMV received funding from the BIONIC project (no. 733050822, which has been made possible by ZonMW as part of ‘Memorabel’, the research and innovation program for dementia, as part of the Dutch national ‘Deltaplan for Dementia’: zonmw.nl/dementiaresearch); the SCALA project, funded by “The Galen and Hilary Weston Foundation” (NR170024); and the CAFÉ project (the National Institutes of Health, USA, grant number 5R01NS104147-02). The BIONIC project is a consortium of Radboudumc, LUMC, ADX Neurosciences, and Rhode Island University.

Funders	Funder number
Adx Neurosciences
CAFÉ
Dutch national ‘Deltaplan for Dementia
EUROGLYCAN-omics	ERARE18-117
Galen and Hilary Weston Foundation	NR170024
Health~Holland, Top Sector Life Sciences & Health
Netherlands X-omics Initiative
ZonMw Medium Investment	40-00506-98-9001, LSHM21032
National Institutes of Health	5R01NS104147-02
University of Rhode Island
ZonMw	733050822, 90030376501
Nederlandse Organisatie voor Wetenschappelijk Onderzoek	184.034.019

Keywords

biomarkers
brain-type glycosylation
cerebrospinal fluid
glycoproteomics
neurodegenerative disease

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10.3390/ijms24031937

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Cite this

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title = "Glycoproteomics in Cerebrospinal Fluid Reveals Brain-Specific Glycosylation Changes",

abstract = "The glycosylation of proteins plays an important role in neurological development and disease. Glycoproteomic studies on cerebrospinal fluid (CSF) are a valuable tool to gain insight into brain glycosylation and its changes in disease. However, it is important to consider that most proteins in CSFs originate from the blood and enter the CSF across the blood–CSF barrier, thus not reflecting the glycosylation status of the brain. Here, we apply a glycoproteomics method to human CSF, focusing on differences between brain- and blood-derived proteins. To facilitate the analysis of the glycan site occupancy, we refrain from glycopeptide enrichment. In healthy individuals, we describe the presence of heterogeneous brain-type N-glycans on prostaglandin H2-D isomerase alongside the dominant plasma-type N-glycans for proteins such as transferrin or haptoglobin, showing the tissue specificity of protein glycosylation. We apply our methodology to patients diagnosed with various genetic glycosylation disorders who have neurological impairments. In patients with severe glycosylation alterations, we observe that heavily truncated glycans and a complete loss of glycans are more pronounced in brain-derived proteins. We speculate that a similar effect can be observed in other neurological diseases where a focus on brain-derived proteins in the CSF could be similarly beneficial to gain insight into disease-related changes.",

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note = "This article belongs to the Special Issue: Recent Advances in Glycoproteomics: Theory, Methods and Applications. Funding Information: This research was supported by the ZonMw Medium Investment Grant (40-00506-98-9001) and the collaboration project “EnFORCE” (LSHM21032) which is co-funded by the PPP Allowance made available by Health~Holland, Top Sector Life Sciences & Health, to stimulate public–private partnerships. This work was part of the Netherlands X-omics Initiative (NWO project 184.034.019) and EUROGLYCAN-omics (ERARE18-117) by ZonMw (90030376501), under the frame of E-Rare-3, the ERA-Net for Research on Rare Diseases. MMV received funding from the BIONIC project (no. 733050822, which has been made possible by ZonMW as part of {\textquoteleft}Memorabel{\textquoteright}, the research and innovation program for dementia, as part of the Dutch national {\textquoteleft}Deltaplan for Dementia{\textquoteright}: zonmw.nl/dementiaresearch); the SCALA project, funded by “The Galen and Hilary Weston Foundation” (NR170024); and the CAF{\'E} project (the National Institutes of Health, USA, grant number 5R01NS104147-02). The BIONIC project is a consortium of Radboudumc, LUMC, ADX Neurosciences, and Rhode Island University. Publisher Copyright: {\textcopyright} 2023 by the authors.",

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AU - Wessels, Hans J.C.T.

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Glycoproteomics in Cerebrospinal Fluid Reveals Brain-Specific Glycosylation Changes

Abstract

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Keywords

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