Autofluorescence is a biomarker of neural stem cell activation state

Christopher S. Morrow; Kelsey Tweed; Sabina Farhadova; Alex J. Walsh; Bo P. Lear; Avtar Roopra; Ryan D. Risgaard; Payton C. Klosa; Zachary P. Arndt; Ella R. Peterson; Michelle M. Chi; Allison G. Harris; Melissa C. Skala; Darcie L. Moore

doi:10.1016/j.stem.2024.02.011

Autofluorescence is a biomarker of neural stem cell activation state

Christopher S. Morrow, Kelsey Tweed, Sabina Farhadova, Alex J. Walsh, Bo P. Lear, Avtar Roopra, Ryan D. Risgaard, Payton C. Klosa, Zachary P. Arndt, Ella R. Peterson, Michelle M. Chi, Allison G. Harris, Melissa C. Skala, Darcie L. Moore

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

6 Scopus citations

Abstract

Neural stem cells (NSCs) must exit quiescence to produce neurons; however, our understanding of this process remains constrained by the technical limitations of current technologies. Fluorescence lifetime imaging (FLIM) of autofluorescent metabolic cofactors has been used in other cell types to study shifts in cell states driven by metabolic remodeling that change the optical properties of these endogenous fluorophores. Using this non-destructive, live-cell, and label-free strategy, we found that quiescent NSCs (qNSCs) and activated NSCs (aNSCs) have unique autofluorescence profiles. Specifically, qNSCs display an enrichment of autofluorescence localizing to a subset of lysosomes, which can be used as a graded marker of NSC quiescence to predict cell behavior at single-cell resolution. Coupling autofluorescence imaging with single-cell RNA sequencing, we provide resources revealing transcriptional features linked to deep quiescence and rapid NSC activation. Together, we describe an approach for tracking mouse NSC activation state and expand our understanding of adult neurogenesis.

Original language	English (US)
Pages (from-to)	570-581.e7
Journal	Cell Stem Cell
Volume	31
Issue number	4
DOIs	https://doi.org/10.1016/j.stem.2024.02.011
State	Published - Apr 4 2024

Keywords

FLIM
NAD(P)H
activation
adult neurogenesis
autofluorescence
fluorescence lifetime imaging
intrinsic fluorescence
lysosomes
neural stem cells
quiescence
Neurons
Biomarkers/metabolism
Animals
Neural Stem Cells/metabolism
Neurogenesis/physiology
Mice

ASJC Scopus subject areas

Molecular Medicine
Genetics
Cell Biology

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10.1016/j.stem.2024.02.011

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title = "Autofluorescence is a biomarker of neural stem cell activation state",

abstract = "Neural stem cells (NSCs) must exit quiescence to produce neurons; however, our understanding of this process remains constrained by the technical limitations of current technologies. Fluorescence lifetime imaging (FLIM) of autofluorescent metabolic cofactors has been used in other cell types to study shifts in cell states driven by metabolic remodeling that change the optical properties of these endogenous fluorophores. Using this non-destructive, live-cell, and label-free strategy, we found that quiescent NSCs (qNSCs) and activated NSCs (aNSCs) have unique autofluorescence profiles. Specifically, qNSCs display an enrichment of autofluorescence localizing to a subset of lysosomes, which can be used as a graded marker of NSC quiescence to predict cell behavior at single-cell resolution. Coupling autofluorescence imaging with single-cell RNA sequencing, we provide resources revealing transcriptional features linked to deep quiescence and rapid NSC activation. Together, we describe an approach for tracking mouse NSC activation state and expand our understanding of adult neurogenesis.",

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author = "Morrow, {Christopher S.} and Kelsey Tweed and Sabina Farhadova and Walsh, {Alex J.} and Lear, {Bo P.} and Avtar Roopra and Risgaard, {Ryan D.} and Klosa, {Payton C.} and Arndt, {Zachary P.} and Peterson, {Ella R.} and Chi, {Michelle M.} and Harris, {Allison G.} and Skala, {Melissa C.} and Moore, {Darcie L.}",

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year = "2024",

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doi = "10.1016/j.stem.2024.02.011",

language = "English (US)",

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T1 - Autofluorescence is a biomarker of neural stem cell activation state

AU - Morrow, Christopher S.

AU - Tweed, Kelsey

AU - Farhadova, Sabina

AU - Walsh, Alex J.

AU - Lear, Bo P.

AU - Roopra, Avtar

AU - Risgaard, Ryan D.

AU - Klosa, Payton C.

AU - Arndt, Zachary P.

AU - Peterson, Ella R.

AU - Chi, Michelle M.

AU - Harris, Allison G.

AU - Skala, Melissa C.

AU - Moore, Darcie L.

PY - 2024/4/4

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N2 - Neural stem cells (NSCs) must exit quiescence to produce neurons; however, our understanding of this process remains constrained by the technical limitations of current technologies. Fluorescence lifetime imaging (FLIM) of autofluorescent metabolic cofactors has been used in other cell types to study shifts in cell states driven by metabolic remodeling that change the optical properties of these endogenous fluorophores. Using this non-destructive, live-cell, and label-free strategy, we found that quiescent NSCs (qNSCs) and activated NSCs (aNSCs) have unique autofluorescence profiles. Specifically, qNSCs display an enrichment of autofluorescence localizing to a subset of lysosomes, which can be used as a graded marker of NSC quiescence to predict cell behavior at single-cell resolution. Coupling autofluorescence imaging with single-cell RNA sequencing, we provide resources revealing transcriptional features linked to deep quiescence and rapid NSC activation. Together, we describe an approach for tracking mouse NSC activation state and expand our understanding of adult neurogenesis.

AB - Neural stem cells (NSCs) must exit quiescence to produce neurons; however, our understanding of this process remains constrained by the technical limitations of current technologies. Fluorescence lifetime imaging (FLIM) of autofluorescent metabolic cofactors has been used in other cell types to study shifts in cell states driven by metabolic remodeling that change the optical properties of these endogenous fluorophores. Using this non-destructive, live-cell, and label-free strategy, we found that quiescent NSCs (qNSCs) and activated NSCs (aNSCs) have unique autofluorescence profiles. Specifically, qNSCs display an enrichment of autofluorescence localizing to a subset of lysosomes, which can be used as a graded marker of NSC quiescence to predict cell behavior at single-cell resolution. Coupling autofluorescence imaging with single-cell RNA sequencing, we provide resources revealing transcriptional features linked to deep quiescence and rapid NSC activation. Together, we describe an approach for tracking mouse NSC activation state and expand our understanding of adult neurogenesis.

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KW - quiescence

KW - Neurons

KW - Biomarkers/metabolism

KW - Animals

KW - Neural Stem Cells/metabolism

KW - Neurogenesis/physiology

KW - Mice

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JO - Cell Stem Cell

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Autofluorescence is a biomarker of neural stem cell activation state

Abstract

Keywords

ASJC Scopus subject areas

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