Development of a novel purification protocol to isolate and identify brain microglia

Deanna Doughty; Surendra K. Rajpurohit; Amy Trang; Ahmet Alptekin; Ahmet K. Korkaya; Bhagelu R. Achyut; Ali S. Arbab; Jennifer W. Bradford

doi:10.1177/15353702221096060

Development of a novel purification protocol to isolate and identify brain microglia

Deanna Doughty, Surendra K. Rajpurohit, Amy Trang, Ahmet Alptekin, Ahmet K. Korkaya, Bhagelu R. Achyut, Ali S. Arbab, Jennifer W. Bradford

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

Abstract

Microglia, the tissue-resident macrophage of the central nervous system (CNS), play a paramount role in brain health and disease status. Here, we describe a novel method for enriching and isolating primary microglia from mouse brain tissue. This isolation method yields a high number of cells from either young or adult mice, and importantly, maintains the health and function of the cells for subsequent cell culture. We also describe flow cytometry methods using novel cell surface markers, including CX3CR1 and Siglec-H, to specifically label microglia while avoiding other bone marrow and/or non-CNS derived macrophages and monocytes, which has been historically difficult to achieve. As microglia are crucial in multiple aspects of biology, such as in normal brain development/function, immune response, neurodegeneration, and cancer, this isolation technique could greatly benefit a wide range of studies in human CNS biology, health, and disease mechanisms. Being able to isolate a largely pure population of microglia could also allow for a more comprehensive understanding of their functional dynamics and role in disease mechanisms, advancement of potential biomarkers, and development of novel therapeutic targets to improve prognosis and quality of life in multiple diseases.

Original language	English (US)
Pages (from-to)	1433-1446
Number of pages	14
Journal	Experimental Biology and Medicine
Volume	247
Issue number	16
DOIs	https://doi.org/10.1177/15353702221096060
State	Published - Aug 2022

Keywords

Microglia
flow cytometry
primary cell culture
primary cell isolation

ASJC Scopus subject areas

Biochemistry, Genetics and Molecular Biology(all)

Access to Document

10.1177/15353702221096060

Cite this

@article{b21940a43940466cac02ebb3b402331b,

title = "Development of a novel purification protocol to isolate and identify brain microglia",

abstract = "Microglia, the tissue-resident macrophage of the central nervous system (CNS), play a paramount role in brain health and disease status. Here, we describe a novel method for enriching and isolating primary microglia from mouse brain tissue. This isolation method yields a high number of cells from either young or adult mice, and importantly, maintains the health and function of the cells for subsequent cell culture. We also describe flow cytometry methods using novel cell surface markers, including CX3CR1 and Siglec-H, to specifically label microglia while avoiding other bone marrow and/or non-CNS derived macrophages and monocytes, which has been historically difficult to achieve. As microglia are crucial in multiple aspects of biology, such as in normal brain development/function, immune response, neurodegeneration, and cancer, this isolation technique could greatly benefit a wide range of studies in human CNS biology, health, and disease mechanisms. Being able to isolate a largely pure population of microglia could also allow for a more comprehensive understanding of their functional dynamics and role in disease mechanisms, advancement of potential biomarkers, and development of novel therapeutic targets to improve prognosis and quality of life in multiple diseases.",

keywords = "Microglia, flow cytometry, primary cell culture, primary cell isolation",

author = "Deanna Doughty and Rajpurohit, {Surendra K.} and Amy Trang and Ahmet Alptekin and Korkaya, {Ahmet K.} and Achyut, {Bhagelu R.} and Arbab, {Ali S.} and Bradford, {Jennifer W.}",

note = "Funding Information: The authors thank Dr Joshua Morganti from the University of Kentucky College of Medicine for assistance in developing the Percoll gradient technique; members of the Department of Biological Sciences for technical assistance, including Dr Jeffrey Fischer for IHC staining and microscopy assistance, Dr Joanna Appel for assistance with microglial cell culture, and Dr Richard Griner, Department Chair, for his constant support; Jeanene Pihkala at the Georgia Cancer Center{\textquoteright}s Flow Cytometry Core at Augusta University for flow cytometry assistance. They also thank all involved with the Augusta University Honors Program, especially Dr Tim Sadenwasser for guidance during Deanna Doughty{\textquoteright}s honors thesis, and Scott Bradford for graphic design and illustration assistance. The author(s) disclosed receipt of the following financial support for the research, authorship, and/or publication of this article: This work was supported by the National Institutes of Health NINDS (1R15NS111401-01), the American Cancer Society (IRG-14-193-01), the Augusta University Intramural Grants Program (PSRP Award), and the Augusta University Center for Undergraduate Research and Scholarship. Funding Information: The author(s) disclosed receipt of the following financial support for the research, authorship, and/or publication of this article: This work was supported by the National Institutes of Health NINDS (1R15NS111401-01), the American Cancer Society (IRG-14-193-01), the Augusta University Intramural Grants Program (PSRP Award), and the Augusta University Center for Undergraduate Research and Scholarship. Publisher Copyright: {\textcopyright} 2022 by the Society for Experimental Biology and Medicine.",

year = "2022",

month = aug,

doi = "10.1177/15353702221096060",

language = "English (US)",

volume = "247",

pages = "1433--1446",

journal = "Proceedings of the Society for Experimental Biology and Medicine. Society for Experimental Biology and Medicine (New York, N. Y.)",

issn = "1535-3702",

publisher = "Society for Experimental Biology and Medicine",

number = "16",

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T1 - Development of a novel purification protocol to isolate and identify brain microglia

AU - Doughty, Deanna

AU - Rajpurohit, Surendra K.

AU - Trang, Amy

AU - Alptekin, Ahmet

AU - Korkaya, Ahmet K.

AU - Achyut, Bhagelu R.

AU - Arbab, Ali S.

AU - Bradford, Jennifer W.

N1 - Funding Information: The authors thank Dr Joshua Morganti from the University of Kentucky College of Medicine for assistance in developing the Percoll gradient technique; members of the Department of Biological Sciences for technical assistance, including Dr Jeffrey Fischer for IHC staining and microscopy assistance, Dr Joanna Appel for assistance with microglial cell culture, and Dr Richard Griner, Department Chair, for his constant support; Jeanene Pihkala at the Georgia Cancer Center’s Flow Cytometry Core at Augusta University for flow cytometry assistance. They also thank all involved with the Augusta University Honors Program, especially Dr Tim Sadenwasser for guidance during Deanna Doughty’s honors thesis, and Scott Bradford for graphic design and illustration assistance. The author(s) disclosed receipt of the following financial support for the research, authorship, and/or publication of this article: This work was supported by the National Institutes of Health NINDS (1R15NS111401-01), the American Cancer Society (IRG-14-193-01), the Augusta University Intramural Grants Program (PSRP Award), and the Augusta University Center for Undergraduate Research and Scholarship. Funding Information: The author(s) disclosed receipt of the following financial support for the research, authorship, and/or publication of this article: This work was supported by the National Institutes of Health NINDS (1R15NS111401-01), the American Cancer Society (IRG-14-193-01), the Augusta University Intramural Grants Program (PSRP Award), and the Augusta University Center for Undergraduate Research and Scholarship. Publisher Copyright: © 2022 by the Society for Experimental Biology and Medicine.

PY - 2022/8

Y1 - 2022/8

N2 - Microglia, the tissue-resident macrophage of the central nervous system (CNS), play a paramount role in brain health and disease status. Here, we describe a novel method for enriching and isolating primary microglia from mouse brain tissue. This isolation method yields a high number of cells from either young or adult mice, and importantly, maintains the health and function of the cells for subsequent cell culture. We also describe flow cytometry methods using novel cell surface markers, including CX3CR1 and Siglec-H, to specifically label microglia while avoiding other bone marrow and/or non-CNS derived macrophages and monocytes, which has been historically difficult to achieve. As microglia are crucial in multiple aspects of biology, such as in normal brain development/function, immune response, neurodegeneration, and cancer, this isolation technique could greatly benefit a wide range of studies in human CNS biology, health, and disease mechanisms. Being able to isolate a largely pure population of microglia could also allow for a more comprehensive understanding of their functional dynamics and role in disease mechanisms, advancement of potential biomarkers, and development of novel therapeutic targets to improve prognosis and quality of life in multiple diseases.

AB - Microglia, the tissue-resident macrophage of the central nervous system (CNS), play a paramount role in brain health and disease status. Here, we describe a novel method for enriching and isolating primary microglia from mouse brain tissue. This isolation method yields a high number of cells from either young or adult mice, and importantly, maintains the health and function of the cells for subsequent cell culture. We also describe flow cytometry methods using novel cell surface markers, including CX3CR1 and Siglec-H, to specifically label microglia while avoiding other bone marrow and/or non-CNS derived macrophages and monocytes, which has been historically difficult to achieve. As microglia are crucial in multiple aspects of biology, such as in normal brain development/function, immune response, neurodegeneration, and cancer, this isolation technique could greatly benefit a wide range of studies in human CNS biology, health, and disease mechanisms. Being able to isolate a largely pure population of microglia could also allow for a more comprehensive understanding of their functional dynamics and role in disease mechanisms, advancement of potential biomarkers, and development of novel therapeutic targets to improve prognosis and quality of life in multiple diseases.

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Development of a novel purification protocol to isolate and identify brain microglia

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