Parenchymal border macrophages regulate the flow dynamics of the cerebrospinal fluid

Dominantly Inherited Alzheimer Network

doi:10.1038/s41586-022-05397-3

Parenchymal border macrophages regulate the flow dynamics of the cerebrospinal fluid

Dominantly Inherited Alzheimer Network

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

21 Scopus citations

Abstract

Macrophages are important players in the maintenance of tissue homeostasis¹. Perivascular and leptomeningeal macrophages reside near the central nervous system (CNS) parenchyma², and their role in CNS physiology has not been sufficiently well studied. Given their continuous interaction with the cerebrospinal fluid (CSF) and strategic positioning, we refer to these cells collectively as parenchymal border macrophages (PBMs). Here we demonstrate that PBMs regulate CSF flow dynamics. We identify a subpopulation of PBMs that express high levels of CD163 and LYVE1 (scavenger receptor proteins), closely associated with the brain arterial tree, and show that LYVE1⁺ PBMs regulate arterial motion that drives CSF flow. Pharmacological or genetic depletion of PBMs led to accumulation of extracellular matrix proteins, obstructing CSF access to perivascular spaces and impairing CNS perfusion and clearance. Ageing-associated alterations in PBMs and impairment of CSF dynamics were restored after intracisternal injection of macrophage colony-stimulating factor. Single-nucleus RNA sequencing data obtained from patients with Alzheimer’s disease (AD) and from non-AD individuals point to changes in phagocytosis, endocytosis and interferon-γ signalling on PBMs, pathways that are corroborated in a mouse model of AD. Collectively, our results identify PBMs as new cellular regulators of CSF flow dynamics, which could be targeted pharmacologically to alleviate brain clearance deficits associated with ageing and AD.

Original language	English
Pages (from-to)	585-593
Number of pages	9
Journal	Nature
Volume	611
Issue number	7936
DOIs	https://doi.org/10.1038/s41586-022-05397-3
State	Published - 17 Nov 2022

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10.1038/s41586-022-05397-3

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@article{8cc75a80a8b6403588365fe8edb803be,

title = "Parenchymal border macrophages regulate the flow dynamics of the cerebrospinal fluid",

abstract = "Macrophages are important players in the maintenance of tissue homeostasis1. Perivascular and leptomeningeal macrophages reside near the central nervous system (CNS) parenchyma2, and their role in CNS physiology has not been sufficiently well studied. Given their continuous interaction with the cerebrospinal fluid (CSF) and strategic positioning, we refer to these cells collectively as parenchymal border macrophages (PBMs). Here we demonstrate that PBMs regulate CSF flow dynamics. We identify a subpopulation of PBMs that express high levels of CD163 and LYVE1 (scavenger receptor proteins), closely associated with the brain arterial tree, and show that LYVE1+ PBMs regulate arterial motion that drives CSF flow. Pharmacological or genetic depletion of PBMs led to accumulation of extracellular matrix proteins, obstructing CSF access to perivascular spaces and impairing CNS perfusion and clearance. Ageing-associated alterations in PBMs and impairment of CSF dynamics were restored after intracisternal injection of macrophage colony-stimulating factor. Single-nucleus RNA sequencing data obtained from patients with Alzheimer{\textquoteright}s disease (AD) and from non-AD individuals point to changes in phagocytosis, endocytosis and interferon-γ signalling on PBMs, pathways that are corroborated in a mouse model of AD. Collectively, our results identify PBMs as new cellular regulators of CSF flow dynamics, which could be targeted pharmacologically to alleviate brain clearance deficits associated with ageing and AD.",

author = "{Dominantly Inherited Alzheimer Network} and Antoine Drieu and Siling Du and Storck, {Steffen E.} and Justin Rustenhoven and Zachary Papadopoulos and Taitea Dykstra and Fenghe Zhong and Kyungdeok Kim and Susan Blackburn and Tornike Mamuladze and Oscar Harari and Karch, {Celeste M.} and Bateman, {Randall J.} and Richard Perrin and Martin Farlow and Jasmeer Chhatwal and Jared Brosch and Jill Buck and Marty Farlow and Bernardino Ghetti and Sarah Adams and Nicolas Barthelemy and Tammie Benzinger and Susan Brandon and Virginia Buckles and Lisa Cash and Charlie Chen and Jasmin Chua and Carlos Cruchaga and Darcy Denner and Aylin Dincer and Tamara Donahue and Anne Fagan and Becca Feldman and Shaney Flores and Erin Franklin and Nelly Joseph-Mathurin and Alyssa Gonzalez and Brian Gordon and Julia Gray and Emily Gremminger and Alex Groves and Jason Hassenstab and Cortaiga Hellm and Elizabeth Herries and Laura Hoechst-Swisher and David Holtzman and Russ Hornbeck and Gina Jerome and Alison Goate",

note = "Funding Information: We thank S. Smith for editing the manuscript; S. Blackburn, N. Al-Hamadani, X. Wang and E. Griffin for animal care; S. Brophy for laboratory management; all the members of the Kipnis Laboratory for their valuable comments during numerous discussions of this work; all the members of the Washington University Center for Cellular Imaging core (WUCCI) for their valuable contribution of electron microscopy imaging; staff at the University of Virginia Flow Cytometry Core and from the Sequencing Core for their help with cell sorting and sequencing; all the members of the Washington University Small Animal MR Imaging Facility and the University of Virginia Molecular Imaging Core Facility for their help in MRI. We acknowledge the expert technical assistance of Y. Mi, P. Erdmann-Gilmore, A. Davis and R. Connors for the CSF proteomics experiment performed at the Washington University Proteomics Shared Resource (WU-PSR), and R. Reid Townsend (Director) and R. Sprung and T. Zhang (Co-directors); the staff of the Neuropathology Cores and other personnel of the Charles F. and Joanne Knight Alzheimer{\textquoteright}s Disease Research Center (ADRC); and the altruism of the participants and their families and contributions of the Knight ADRC and DIAN research and support staff at each of the participating sites for their contributions to this study. This work was supported by grants from the National Institutes of Health/National Institute on Aging (AG034113, AG057496, AG078106), the Cure Alzheimer{\textquoteright}s Fund and the Ludwig Foundation to J.K.; AG057777 and AG067764 to O.H.; and AG062734 to C.M.K. O.H. is an Archer Foundation Research Scientist. The WU-PSR is supported in part by the WU Institute of Clinical and Translational Sciences (NCATS UL1 TR000448), the Mass Spectrometry Research Resource (NIGMS P41 GM103422; R24GM136766) and a Siteman Comprehensive Cancer Center Support grant (NCI P30 CA091842). The Neuropathology Cores and the Charles F. and Joanne Knight ADRC are supported by P30 AG066444, P01AG026276 and P01AG03991. Data collection and sharing for this project was supported by the DIAN (UF1AG032438) funded by the National Institute on Aging (NIA), the German Center for Neurodegenerative Diseases (DZNE), Raul Carrea Institute for Neurological Research (FLENI), partial support by the Research and Development Grants for Dementia from Japan Agency for Medical Research and Development, AMED, and the Korea Health Technology R&D Project through the Korea Health Industry Development Institute (KHIDI). This manuscript has been reviewed by DIAN Study investigators for scientific content and consistency of data interpretation with previous DIAN Study publications. The illustrations of the mice and MRI are freely available from Servier Medical Art ( https://smart.servier.com ). The brain cartoon and the summary illustration were created by the authors. Funding Information: We thank S. Smith for editing the manuscript; S. Blackburn, N. Al-Hamadani, X. Wang and E. Griffin for animal care; S. Brophy for laboratory management; all the members of the Kipnis Laboratory for their valuable comments during numerous discussions of this work; all the members of the Washington University Center for Cellular Imaging core (WUCCI) for their valuable contribution of electron microscopy imaging; staff at the University of Virginia Flow Cytometry Core and from the Sequencing Core for their help with cell sorting and sequencing; all the members of the Washington University Small Animal MR Imaging Facility and the University of Virginia Molecular Imaging Core Facility for their help in MRI. We acknowledge the expert technical assistance of Y. Mi, P. Erdmann-Gilmore, A. Davis and R. Connors for the CSF proteomics experiment performed at the Washington University Proteomics Shared Resource (WU-PSR), and R. Reid Townsend (Director) and R. Sprung and T. Zhang (Co-directors); the staff of the Neuropathology Cores and other personnel of the Charles F. and Joanne Knight Alzheimer{\textquoteright}s Disease Research Center (ADRC); and the altruism of the participants and their families and contributions of the Knight ADRC and DIAN research and support staff at each of the participating sites for their contributions to this study. This work was supported by grants from the National Institutes of Health/National Institute on Aging (AG034113, AG057496, AG078106), the Cure Alzheimer{\textquoteright}s Fund and the Ludwig Foundation to J.K.; AG057777 and AG067764 to O.H.; and AG062734 to C.M.K. O.H. is an Archer Foundation Research Scientist. The WU-PSR is supported in part by the WU Institute of Clinical and Translational Sciences (NCATS UL1 TR000448), the Mass Spectrometry Research Resource (NIGMS P41 GM103422; R24GM136766) and a Siteman Comprehensive Cancer Center Support grant (NCI P30 CA091842). The Neuropathology Cores and the Charles F. and Joanne Knight ADRC are supported by P30 AG066444, P01AG026276 and P01AG03991. Data collection and sharing for this project was supported by the DIAN (UF1AG032438) funded by the National Institute on Aging (NIA), the German Center for Neurodegenerative Diseases (DZNE), Raul Carrea Institute for Neurological Research (FLENI), partial support by the Research and Development Grants for Dementia from Japan Agency for Medical Research and Development, AMED, and the Korea Health Technology R&D Project through the Korea Health Industry Development Institute (KHIDI). This manuscript has been reviewed by DIAN Study investigators for scientific content and consistency of data interpretation with previous DIAN Study publications. The illustrations of the mice and MRI are freely available from Servier Medical Art (https://smart.servier.com ). The brain cartoon and the summary illustration were created by the authors. Publisher Copyright: {\textcopyright} 2022, The Author(s), under exclusive licence to Springer Nature Limited.",

year = "2022",

month = nov,

day = "17",

doi = "10.1038/s41586-022-05397-3",

language = "English",

volume = "611",

pages = "585--593",

journal = "Nature",

issn = "0028-0836",

publisher = "Nature Publishing Group",

number = "7936",

}

TY - JOUR

T1 - Parenchymal border macrophages regulate the flow dynamics of the cerebrospinal fluid

AU - Dominantly Inherited Alzheimer Network

AU - Drieu, Antoine

AU - Du, Siling

AU - Storck, Steffen E.

AU - Rustenhoven, Justin

AU - Papadopoulos, Zachary

AU - Dykstra, Taitea

AU - Zhong, Fenghe

AU - Kim, Kyungdeok

AU - Blackburn, Susan

AU - Mamuladze, Tornike

AU - Harari, Oscar

AU - Karch, Celeste M.

AU - Bateman, Randall J.

AU - Perrin, Richard

AU - Farlow, Martin

AU - Chhatwal, Jasmeer

AU - Brosch, Jared

AU - Buck, Jill

AU - Farlow, Marty

AU - Ghetti, Bernardino

AU - Adams, Sarah

AU - Barthelemy, Nicolas

AU - Benzinger, Tammie

AU - Brandon, Susan

AU - Buckles, Virginia

AU - Cash, Lisa

AU - Chen, Charlie

AU - Chua, Jasmin

AU - Cruchaga, Carlos

AU - Denner, Darcy

AU - Dincer, Aylin

AU - Donahue, Tamara

AU - Fagan, Anne

AU - Feldman, Becca

AU - Flores, Shaney

AU - Franklin, Erin

AU - Joseph-Mathurin, Nelly

AU - Gonzalez, Alyssa

AU - Gordon, Brian

AU - Gray, Julia

AU - Gremminger, Emily

AU - Groves, Alex

AU - Hassenstab, Jason

AU - Hellm, Cortaiga

AU - Herries, Elizabeth

AU - Hoechst-Swisher, Laura

AU - Holtzman, David

AU - Hornbeck, Russ

AU - Jerome, Gina

AU - Goate, Alison

N1 - Funding Information: We thank S. Smith for editing the manuscript; S. Blackburn, N. Al-Hamadani, X. Wang and E. Griffin for animal care; S. Brophy for laboratory management; all the members of the Kipnis Laboratory for their valuable comments during numerous discussions of this work; all the members of the Washington University Center for Cellular Imaging core (WUCCI) for their valuable contribution of electron microscopy imaging; staff at the University of Virginia Flow Cytometry Core and from the Sequencing Core for their help with cell sorting and sequencing; all the members of the Washington University Small Animal MR Imaging Facility and the University of Virginia Molecular Imaging Core Facility for their help in MRI. We acknowledge the expert technical assistance of Y. Mi, P. Erdmann-Gilmore, A. Davis and R. Connors for the CSF proteomics experiment performed at the Washington University Proteomics Shared Resource (WU-PSR), and R. Reid Townsend (Director) and R. Sprung and T. Zhang (Co-directors); the staff of the Neuropathology Cores and other personnel of the Charles F. and Joanne Knight Alzheimer’s Disease Research Center (ADRC); and the altruism of the participants and their families and contributions of the Knight ADRC and DIAN research and support staff at each of the participating sites for their contributions to this study. This work was supported by grants from the National Institutes of Health/National Institute on Aging (AG034113, AG057496, AG078106), the Cure Alzheimer’s Fund and the Ludwig Foundation to J.K.; AG057777 and AG067764 to O.H.; and AG062734 to C.M.K. O.H. is an Archer Foundation Research Scientist. The WU-PSR is supported in part by the WU Institute of Clinical and Translational Sciences (NCATS UL1 TR000448), the Mass Spectrometry Research Resource (NIGMS P41 GM103422; R24GM136766) and a Siteman Comprehensive Cancer Center Support grant (NCI P30 CA091842). The Neuropathology Cores and the Charles F. and Joanne Knight ADRC are supported by P30 AG066444, P01AG026276 and P01AG03991. Data collection and sharing for this project was supported by the DIAN (UF1AG032438) funded by the National Institute on Aging (NIA), the German Center for Neurodegenerative Diseases (DZNE), Raul Carrea Institute for Neurological Research (FLENI), partial support by the Research and Development Grants for Dementia from Japan Agency for Medical Research and Development, AMED, and the Korea Health Technology R&D Project through the Korea Health Industry Development Institute (KHIDI). This manuscript has been reviewed by DIAN Study investigators for scientific content and consistency of data interpretation with previous DIAN Study publications. The illustrations of the mice and MRI are freely available from Servier Medical Art ( https://smart.servier.com ). The brain cartoon and the summary illustration were created by the authors. Funding Information: We thank S. Smith for editing the manuscript; S. Blackburn, N. Al-Hamadani, X. Wang and E. Griffin for animal care; S. Brophy for laboratory management; all the members of the Kipnis Laboratory for their valuable comments during numerous discussions of this work; all the members of the Washington University Center for Cellular Imaging core (WUCCI) for their valuable contribution of electron microscopy imaging; staff at the University of Virginia Flow Cytometry Core and from the Sequencing Core for their help with cell sorting and sequencing; all the members of the Washington University Small Animal MR Imaging Facility and the University of Virginia Molecular Imaging Core Facility for their help in MRI. We acknowledge the expert technical assistance of Y. Mi, P. Erdmann-Gilmore, A. Davis and R. Connors for the CSF proteomics experiment performed at the Washington University Proteomics Shared Resource (WU-PSR), and R. Reid Townsend (Director) and R. Sprung and T. Zhang (Co-directors); the staff of the Neuropathology Cores and other personnel of the Charles F. and Joanne Knight Alzheimer’s Disease Research Center (ADRC); and the altruism of the participants and their families and contributions of the Knight ADRC and DIAN research and support staff at each of the participating sites for their contributions to this study. This work was supported by grants from the National Institutes of Health/National Institute on Aging (AG034113, AG057496, AG078106), the Cure Alzheimer’s Fund and the Ludwig Foundation to J.K.; AG057777 and AG067764 to O.H.; and AG062734 to C.M.K. O.H. is an Archer Foundation Research Scientist. The WU-PSR is supported in part by the WU Institute of Clinical and Translational Sciences (NCATS UL1 TR000448), the Mass Spectrometry Research Resource (NIGMS P41 GM103422; R24GM136766) and a Siteman Comprehensive Cancer Center Support grant (NCI P30 CA091842). The Neuropathology Cores and the Charles F. and Joanne Knight ADRC are supported by P30 AG066444, P01AG026276 and P01AG03991. Data collection and sharing for this project was supported by the DIAN (UF1AG032438) funded by the National Institute on Aging (NIA), the German Center for Neurodegenerative Diseases (DZNE), Raul Carrea Institute for Neurological Research (FLENI), partial support by the Research and Development Grants for Dementia from Japan Agency for Medical Research and Development, AMED, and the Korea Health Technology R&D Project through the Korea Health Industry Development Institute (KHIDI). This manuscript has been reviewed by DIAN Study investigators for scientific content and consistency of data interpretation with previous DIAN Study publications. The illustrations of the mice and MRI are freely available from Servier Medical Art (https://smart.servier.com ). The brain cartoon and the summary illustration were created by the authors. Publisher Copyright: © 2022, The Author(s), under exclusive licence to Springer Nature Limited.

PY - 2022/11/17

Y1 - 2022/11/17

N2 - Macrophages are important players in the maintenance of tissue homeostasis1. Perivascular and leptomeningeal macrophages reside near the central nervous system (CNS) parenchyma2, and their role in CNS physiology has not been sufficiently well studied. Given their continuous interaction with the cerebrospinal fluid (CSF) and strategic positioning, we refer to these cells collectively as parenchymal border macrophages (PBMs). Here we demonstrate that PBMs regulate CSF flow dynamics. We identify a subpopulation of PBMs that express high levels of CD163 and LYVE1 (scavenger receptor proteins), closely associated with the brain arterial tree, and show that LYVE1+ PBMs regulate arterial motion that drives CSF flow. Pharmacological or genetic depletion of PBMs led to accumulation of extracellular matrix proteins, obstructing CSF access to perivascular spaces and impairing CNS perfusion and clearance. Ageing-associated alterations in PBMs and impairment of CSF dynamics were restored after intracisternal injection of macrophage colony-stimulating factor. Single-nucleus RNA sequencing data obtained from patients with Alzheimer’s disease (AD) and from non-AD individuals point to changes in phagocytosis, endocytosis and interferon-γ signalling on PBMs, pathways that are corroborated in a mouse model of AD. Collectively, our results identify PBMs as new cellular regulators of CSF flow dynamics, which could be targeted pharmacologically to alleviate brain clearance deficits associated with ageing and AD.

AB - Macrophages are important players in the maintenance of tissue homeostasis1. Perivascular and leptomeningeal macrophages reside near the central nervous system (CNS) parenchyma2, and their role in CNS physiology has not been sufficiently well studied. Given their continuous interaction with the cerebrospinal fluid (CSF) and strategic positioning, we refer to these cells collectively as parenchymal border macrophages (PBMs). Here we demonstrate that PBMs regulate CSF flow dynamics. We identify a subpopulation of PBMs that express high levels of CD163 and LYVE1 (scavenger receptor proteins), closely associated with the brain arterial tree, and show that LYVE1+ PBMs regulate arterial motion that drives CSF flow. Pharmacological or genetic depletion of PBMs led to accumulation of extracellular matrix proteins, obstructing CSF access to perivascular spaces and impairing CNS perfusion and clearance. Ageing-associated alterations in PBMs and impairment of CSF dynamics were restored after intracisternal injection of macrophage colony-stimulating factor. Single-nucleus RNA sequencing data obtained from patients with Alzheimer’s disease (AD) and from non-AD individuals point to changes in phagocytosis, endocytosis and interferon-γ signalling on PBMs, pathways that are corroborated in a mouse model of AD. Collectively, our results identify PBMs as new cellular regulators of CSF flow dynamics, which could be targeted pharmacologically to alleviate brain clearance deficits associated with ageing and AD.

UR - http://www.scopus.com/inward/record.url?scp=85141714808&partnerID=8YFLogxK

U2 - 10.1038/s41586-022-05397-3

DO - 10.1038/s41586-022-05397-3

M3 - Article

C2 - 36352225

AN - SCOPUS:85141714808

SN - 0028-0836

VL - 611

SP - 585

EP - 593

JO - Nature

JF - Nature

IS - 7936

ER -

Parenchymal border macrophages regulate the flow dynamics of the cerebrospinal fluid

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