Differential compartmentalization of myeloid cell phenotypes and responses towards the CNS in Alzheimer's disease
Fernández Zapata, Camila; Giacomello, Ginevra; Spruth, Eike J; Middeldorp, Jinte; Gallaccio, Gerardina; Dehlinger, Adeline; Dames, Claudia; Leman, Julia K H; van Dijk, Roland E; Meisel, Andreas; Schlickeiser, Stephan; Kunkel, Desiree; Hol, Elly M; Paul, Friedemann; Parr, Maria Kristina; Priller, Josef; Böttcher, Chotima
(2022) Nature Communications, volume 13, issue 1
(Article)
Abstract
Myeloid cells are suggested as an important player in Alzheimer´s disease (AD). However, its continuum of phenotypic and functional changes across different body compartments and their use as a biomarker in AD remains elusive. Here, we perform multiple state-of-the-art analyses to phenotypically and metabolically characterize immune cells between peripheral blood
... read more
(n = 117), cerebrospinal fluid (CSF, n = 117), choroid plexus (CP, n = 13) and brain parenchyma (n = 13). We find that CSF cells increase expression of markers involved in inflammation, phagocytosis, and metabolism. Changes in phenotype of myeloid cells from AD patients are more pronounced in CP and brain parenchyma and upon in vitro stimulation, suggesting that AD-myeloid cells are more vulnerable to environmental changes. Our findings underscore the importance of myeloid cells in AD and the detailed characterization across body compartments may serve as a resource for future studies focusing on the assessment of these cells as biomarkers in AD.
show less
Download/Full Text
Keywords: Alzheimer Disease/metabolism, Biomarkers/metabolism, Choroid Plexus/metabolism, Humans, Myeloid Cells/metabolism, Myeloid Progenitor Cells/metabolism, Phenotype, Journal Article
ISSN: 2041-1723
Publisher: Nature Publishing Group
Note: Funding Information: We thank Jasmin Jamal El-Din and Christian Böttcher for excellent technical assistance with sample collection and ex vivo experiments. We would also like to acknowledge the assistance of the Flow & Mass Cytometry Core Facility (BIH at Charité—Universitätsmedizin Berlin, Germany) and the Netherlands Brain Bank (Amsterdam, The Netherlands). G.Gi. was funded by the Elsa-Neumann scholarship of the State of Berlin. G.Gi. and G.Ga. received the PhD scholarship from the NeuroMac School (DFG, the German Research Foundation—Project-ID 259373024—CRC/TRR 167 (B05)). A.M. and C.D. were were funded by the Deutsche Forschungsgemeinschaft (DFG, the German Research Foundation—Project-ID 259373024—CRC/TRR 167 (B12)), and the Leducq Foundation (19CVD01). R.E.v.D., J.M. and E.M.H. were funded by ZonMW 733050107. C.B. and J.P. were funded by the Deutsche Forschungsgemeinschaft (DFG, the German Research Foundation—Project-ID 259373024—CRC/TRR 167 (B05 and B07)). Funding Information: We thank Jasmin Jamal El-Din and Christian Böttcher for excellent technical assistance with sample collection and ex vivo experiments. We would also like to acknowledge the assistance of the Flow & Mass Cytometry Core Facility (BIH at Charité—Universitätsmedizin Berlin, Germany) and the Netherlands Brain Bank (Amsterdam, The Netherlands). G.Gi. was funded by the Elsa-Neumann scholarship of the State of Berlin. G.Gi. and G.Ga. received the PhD scholarship from the NeuroMac School (DFG, the German Research Foundation—Project-ID 259373024—CRC/TRR 167 (B05)). A.M. and C.D. were were funded by the Deutsche Forschungsgemeinschaft (DFG, the German Research Foundation—Project-ID 259373024—CRC/TRR 167 (B12)), and the Leducq Foundation (19CVD01). R.E.v.D., J.M. and E.M.H. were funded by ZonMW 733050107. C.B. and J.P. were funded by the Deutsche Forschungsgemeinschaft (DFG, the German Research Foundation—Project-ID 259373024—CRC/TRR 167 (B05 and B07)). Publisher Copyright: © 2022, The Author(s).
(Peer reviewed)
