Single-cell RNA and protein profiling of immune cells from the mouse brain and its border tissues

Isabelle Scheyltjens; Hannah Van Hove; Karen De Vlaminck; Daliya Kancheva; Jonathan Bastos; Mónica Vara-Pérez; Ana Rita Pombo Antunes; Liesbet Martens; Charlotte L Scott; Jo A Van Ginderachter; Yvan Saeys; Martin Guilliams; Niels Vandamme; Kiavash Movahedi

doi:10.1038/s41596-022-00716-4

Single-cell RNA and protein profiling of immune cells from the mouse brain and its border tissues

Isabelle Scheyltjens, Hannah Van Hove, Karen De Vlaminck, Daliya Kancheva, Jonathan Bastos, Mónica Vara-Pérez, Ana Rita Pombo Antunes, Liesbet Martens, Charlotte L Scott, Jo A Van Ginderachter, Yvan Saeys, Martin Guilliams, Niels Vandamme, Kiavash Movahedi

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Brain-immune cross-talk and neuroinflammation critically shape brain physiology in health and disease. A detailed understanding of the brain immune landscape is essential for developing new treatments for neurological disorders. Single-cell technologies offer an unbiased assessment of the heterogeneity, dynamics and functions of immune cells. Here we provide a protocol that outlines all the steps involved in performing single-cell multi-omic analysis of the brain immune compartment. This includes a step-by-step description on how to microdissect the border regions of the mouse brain, together with dissociation protocols tailored to each of these tissues. These combine a high yield with minimal dissociation-induced gene expression changes. Next, we outline the steps involved for high-dimensional flow cytometry and droplet-based single-cell RNA sequencing via the 10x Genomics platform, which can be combined with cellular indexing of transcriptomes and epitopes by sequencing (CITE-seq) and offers a higher throughput than plate-based methods. Importantly, we detail how to implement CITE-seq with large antibody panels to obtain unbiased protein-expression screening coupled to transcriptome analysis. Finally, we describe the main steps involved in the analysis and interpretation of the data. This optimized workflow allows for a detailed assessment of immune cell heterogeneity and activation in the whole brain or specific border regions, at RNA and protein level. The wet lab workflow can be completed by properly trained researchers (with basic proficiency in cell and molecular biology) and takes between 6 and 11 h, depending on the chosen procedures. The computational analysis requires a background in bioinformatics and programming in R.

Originele taal-2	English
Pagina's (van-tot)	2354-2388
Aantal pagina's	35
Tijdschrift	Nature Protocols
Volume	17
Nummer van het tijdschrift	10
Vroegere onlinedatum	5 aug 2022
DOI's	https://doi.org/10.1038/s41596-022-00716-4
Status	Published - okt 2022

Bibliografische nota

Funding Information:
This work was supported by Innoviris (Attract grant BB2B 2015−2), Fonds Wetenschappelijk Onderzoek (grant no. 1506316 N) to K.M., a VLAIO grant (no. ImmCyte HBC.2016.0889) to K.M. and JAVG. K.M. is a Collen-Franqui research professor. I.S. is supported by an FWO postdoctoral fellowship. H.V.H. is supported by an FWO predoctoral fellowship. We thank Y. Elkrim, G. van Isterdael, the VIB Flow Core and the VIB Nucleomics Core for technical assistance, VIB Tech Watch and the single-cell accelerator program for support regarding single-cell technologies.

Funding Information:
This work was supported by Innoviris (Attract grant BB2B 2015−2), Fonds Wetenschappelijk Onderzoek (grant no. 1506316 N) to K.M., a VLAIO grant (no. ImmCyte HBC.2016.0889) to K.M. and JAVG. K.M. is a Collen-Franqui research professor. I.S. is supported by an FWO postdoctoral fellowship. H.V.H. is supported by an FWO predoctoral fellowship. We thank Y. Elkrim, G. van Isterdael, the VIB Flow Core and the VIB Nucleomics Core for technical assistance, VIB Tech Watch and the single-cell accelerator program for support regarding single-cell technologies.

Publisher Copyright:
© 2022, Springer Nature Limited.

Copyright:
Copyright 2022 Elsevier B.V., All rights reserved.

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10.1038/s41596-022-00716-4

Scheyltjens 2022 Nature Protocols -accepted manuscript with figuresAccepted author manuscript, 6,84 MBLicentie: Unspecified

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SRP83: SRP-Onderzoekszwaartepunt: Immunoregulatoire cellen als doelwit voor moleculaire beeldvorming en therapie in inflammatoire ziekten en kanker
Van Ginderachter, J., Lahoutte, T., Lahoutte, T., Van Ginderachter, J., Devoogdt, N., Raes, G., Stijlemans, B., Vincke, C. & De Groof, T.
1/11/22 → 31/10/27
Project: Fundamenteel

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Scheyltjens, I., Van Hove, H., De Vlaminck, K., Kancheva, D., Bastos, J., Vara-Pérez, M., Pombo Antunes, A. R., Martens, L., Scott, C. L., Van Ginderachter, J. A., Saeys, Y., Guilliams, M., Vandamme, N., & Movahedi, K. (2022). Single-cell RNA and protein profiling of immune cells from the mouse brain and its border tissues. Nature Protocols, 17(10), 2354-2388. https://doi.org/10.1038/s41596-022-00716-4

Scheyltjens, Isabelle ; Van Hove, Hannah ; De Vlaminck, Karen ; Kancheva, Daliya ; Bastos, Jonathan ; Vara-Pérez, Mónica ; Pombo Antunes, Ana Rita ; Martens, Liesbet ; Scott, Charlotte L ; Van Ginderachter, Jo A ; Saeys, Yvan ; Guilliams, Martin ; Vandamme, Niels ; Movahedi, Kiavash. / Single-cell RNA and protein profiling of immune cells from the mouse brain and its border tissues. In: Nature Protocols. 2022 ; Vol. 17, Nr. 10. blz. 2354-2388.

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abstract = "Brain-immune cross-talk and neuroinflammation critically shape brain physiology in health and disease. A detailed understanding of the brain immune landscape is essential for developing new treatments for neurological disorders. Single-cell technologies offer an unbiased assessment of the heterogeneity, dynamics and functions of immune cells. Here we provide a protocol that outlines all the steps involved in performing single-cell multi-omic analysis of the brain immune compartment. This includes a step-by-step description on how to microdissect the border regions of the mouse brain, together with dissociation protocols tailored to each of these tissues. These combine a high yield with minimal dissociation-induced gene expression changes. Next, we outline the steps involved for high-dimensional flow cytometry and droplet-based single-cell RNA sequencing via the 10x Genomics platform, which can be combined with cellular indexing of transcriptomes and epitopes by sequencing (CITE-seq) and offers a higher throughput than plate-based methods. Importantly, we detail how to implement CITE-seq with large antibody panels to obtain unbiased protein-expression screening coupled to transcriptome analysis. Finally, we describe the main steps involved in the analysis and interpretation of the data. This optimized workflow allows for a detailed assessment of immune cell heterogeneity and activation in the whole brain or specific border regions, at RNA and protein level. The wet lab workflow can be completed by properly trained researchers (with basic proficiency in cell and molecular biology) and takes between 6 and 11 h, depending on the chosen procedures. The computational analysis requires a background in bioinformatics and programming in R.",

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note = "Funding Information: This work was supported by Innoviris (Attract grant BB2B 2015−2), Fonds Wetenschappelijk Onderzoek (grant no. 1506316 N) to K.M., a VLAIO grant (no. ImmCyte HBC.2016.0889) to K.M. and JAVG. K.M. is a Collen-Franqui research professor. I.S. is supported by an FWO postdoctoral fellowship. H.V.H. is supported by an FWO predoctoral fellowship. We thank Y. Elkrim, G. van Isterdael, the VIB Flow Core and the VIB Nucleomics Core for technical assistance, VIB Tech Watch and the single-cell accelerator program for support regarding single-cell technologies. Funding Information: This work was supported by Innoviris (Attract grant BB2B 2015−2), Fonds Wetenschappelijk Onderzoek (grant no. 1506316 N) to K.M., a VLAIO grant (no. ImmCyte HBC.2016.0889) to K.M. and JAVG. K.M. is a Collen-Franqui research professor. I.S. is supported by an FWO postdoctoral fellowship. H.V.H. is supported by an FWO predoctoral fellowship. We thank Y. Elkrim, G. van Isterdael, the VIB Flow Core and the VIB Nucleomics Core for technical assistance, VIB Tech Watch and the single-cell accelerator program for support regarding single-cell technologies. Publisher Copyright: {\textcopyright} 2022, Springer Nature Limited. Copyright: Copyright 2022 Elsevier B.V., All rights reserved.",

year = "2022",

month = oct,

doi = "10.1038/s41596-022-00716-4",

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Scheyltjens, I, Van Hove, H, De Vlaminck, K, Kancheva, D , Bastos, J , Vara-Pérez, M , Pombo Antunes, AR, Martens, L, Scott, CL, Van Ginderachter, JA, Saeys, Y, Guilliams, M, Vandamme, N & Movahedi, K 2022, 'Single-cell RNA and protein profiling of immune cells from the mouse brain and its border tissues', Nature Protocols, vol. 17, nr. 10, blz. 2354-2388. https://doi.org/10.1038/s41596-022-00716-4

Single-cell RNA and protein profiling of immune cells from the mouse brain and its border tissues. / Scheyltjens, Isabelle; Van Hove, Hannah; De Vlaminck, Karen; Kancheva, Daliya ; Bastos, Jonathan ; Vara-Pérez, Mónica ; Pombo Antunes, Ana Rita; Martens, Liesbet; Scott, Charlotte L; Van Ginderachter, Jo A; Saeys, Yvan; Guilliams, Martin; Vandamme, Niels; Movahedi, Kiavash.

In: Nature Protocols, Vol. 17, Nr. 10, 10.2022, blz. 2354-2388.

Onderzoeksoutput: Article › peer review

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Single-cell RNA and protein profiling of immune cells from the mouse brain and its border tissues

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SRP83: SRP-Onderzoekszwaartepunt: Immunoregulatoire cellen als doelwit voor moleculaire beeldvorming en therapie in inflammatoire ziekten en kanker

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