Project description:Stem cell dysfunction drives many age-related disorders. Identifying mechanisms that initially compromise stem cell behavior represent early targets to enhance stem cell function later in life. Here, we pinpoint multiple factors that disrupt neural stem cell (NSC) behavior in the adult hippocampus. Clonal tracing showed that NSCs exhibit asynchronous depletion by identifying short-term (ST-NSC) and long-term NSCs (LT-NSCs). ST-NSC divide rapidly to generate neurons and deplete in the young brain. Meanwhile, multipotent LT-NSCs are maintained for months, but are pushed out of homeostasis by lengthening quiescence. Single cell transcriptome analysis of deep NSC quiescence revealed several hallmarks of molecular aging in the mature brain and identified tyrosine-protein kinase Abl1 as an NSC pro-aging factor. Treatment with the Abl-inhibitor Imatinib increased NSC proliferation without impairing NSC maintenance in the middle-aged brain. Our study indicates that hippocampal NSCs are particularly vulnerable to cellular aging, yet NSC function can be partially restored.

Project description:Quiescence, a hallmark of adult neural stem cells (NSCs), is required for maintaining the NSC pool to support life-long continuous neurogenesis in the adult dentate gyrus (DG). Whether epigenetic mechanisms can maintain NSC quiescence over long term in the adult brain is not well-understood. Here we showed that adult mice with haploinsufficiency of Setd1a, a schizophrenia risk gene encoding a histone H3K4 methyltransferase, exhibited substantially enlarged DG with increased number of dentate granule cells. Deletion of Setd1a specifically in quiescent NSCs in the adult DG promoted their activation and neurogenesis, which was countered by inhibition of histone demethylase LSD1. Mechanistically, RNA sequencing and CUT & RUN analyses of cultured quiescent adult NSCs revealed Setd1a deletion-induced transcriptional changes and Setd1a targets, among which down-regulation of Bhlhe40 promoted quiescent NSC activation in the adult DG. Together, our study revealed a Setd1a-dependent epigenetic mechanism that sustains NSC quiescence in the adult DG.

Project description:Quiescence, a hallmark of adult neural stem cells (NSCs), is required for maintaining the NSC pool to support life-long continuous neurogenesis in the adult dentate gyrus (DG). Whether epigenetic mechanisms can maintain NSC quiescence over long term in the adult brain is not well-understood. Here we showed that adult mice with haploinsufficiency of Setd1a, a schizophrenia risk gene encoding a histone H3K4 methyltransferase, exhibited substantially enlarged DG with increased number of dentate granule cells. Deletion of Setd1a specifically in quiescent NSCs in the adult DG promoted their activation and neurogenesis, which was countered by inhibition of histone demethylase LSD1. Mechanistically, RNA sequencing and CUT & RUN analyses of cultured quiescent adult NSCs revealed Setd1a deletion-induced transcriptional changes and Setd1a targets, among which down-regulation of Bhlhe40 promoted quiescent NSC activation in the adult DG. Together, our study revealed a Setd1a-dependent epigenetic mechanism that sustains NSC quiescence in the adult DG.

Project description:Heterogeneous pools of adult neural stem cells (NSCs) contribute to brain maintenance and regeneration after injury. The balance of NSC activation and quiescence, as well as the induction of lineage-specific transcription factors, may contribute to diversity of neuronal and glial fates. To identify molecular hallmarks governing these characteristics, we performed single-cell sequencing of an unbiased pool of adult subventricular zone NSCs. This analysis identified a discrete, dormant NSC subpopulation that already expresses distinct combinations of lineage-specific transcription factors during homeostasis. Dormant NSCs enter a primed-quiescent state before activation, which is accompanied by downregulation of glycolytic metabolism, Notch, and BMP signaling and a concomitant upregulation of lineage-specific transcription factors and protein synthesis. In response to brain ischemia, interferon gamma signaling induces dormant NSC subpopulations to enter the primed-quiescent state. This study unveils general principles underlying NSC activation and lineage priming and opens potential avenues for regenerative medicine in the brain. Single cell RNAseq of cells isolated from their in vivo niche in the subventricular zone, Striatum and Cortex during homeostasis as well as following ischemic injury. In total 272 single cells. (<WT>: homeostasis samples; <Ischemic_injured> and <Ischemic_injured_and_Interferon_gamma_knockout>: samples following ischemic injuried).

Project description:Neural stem cells (NSCs) in the adult brain are primarily quiescent but can activate and enter the cell cycle to produce newborn neurons. NSC quiescence can be regulated by disease, injury, and age, however our understanding of NSC quiescence is limited by technical limitations imposed by the bias of markers used to isolate each population of NSCs and the lack of live-cell labeling strategies. Fluorescence lifetime imaging (FLIM) of autofluorescent metabolic cofactors has previously 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. Here we asked whether autofluorescence could be used to discriminate NSC activation state. We found that quiescent NSCs (qNSCs) and activated NSCs (aNSCs) each have unique autofluorescence intensity and fluorescence lifetime profiles. Additionally, qNSCs specifically display an enrichment of a specific autofluorescent signal localizing to lysosomes that is highly predictive of cell state. These signals can be used as a graded marker of NSC quiescence to predict cell behavior and track the dynamics of quiescence exit at single cell resolution in vitro and in vivo. Through coupling autofluorescence imaging with single-cell RNA sequencing in vitro and in vivo, we provide a high-resolution resource revealing transcriptional features linked to rapid NSC activation and deep quiescence. Taken together, we describe a single-cell resolution, non-destructive, live-cell, label-free strategy for measuring NSC activation state in vitro and in vivo and use this tool to expand our understanding of adult neurogenesis.

Project description:Neural stem cells (NSCs) in the adult brain are primarily quiescent but can activate and enter the cell cycle to produce newborn neurons. NSC quiescence can be regulated by disease, injury, and age, however our understanding of NSC quiescence is limited by technical limitations imposed by the bias of markers used to isolate each population of NSCs and the lack of live-cell labeling strategies. Fluorescence lifetime imaging (FLIM) of autofluorescent metabolic cofactors has previously 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. Here we asked whether autofluorescence could be used to discriminate NSC activation state. We found that quiescent NSCs (qNSCs) and activated NSCs (aNSCs) each have unique autofluorescence intensity and fluorescence lifetime profiles. Additionally, qNSCs specifically display an enrichment of a specific autofluorescent signal localizing to lysosomes that is highly predictive of cell state. These signals can be used as a graded marker of NSC quiescence to predict cell behavior and track the dynamics of quiescence exit at single cell resolution in vitro and in vivo. Through coupling autofluorescence imaging with single-cell RNA sequencing in vitro and in vivo, we provide a high-resolution resource revealing transcriptional features linked to rapid NSC activation and deep quiescence. Taken together, we describe a single-cell resolution, non-destructive, live-cell, label-free strategy for measuring NSC activation state in vitro and in vivo and use this tool to expand our understanding of adult neurogenesis.

Project description:To identify pathways regulating NSC quiescence, with a possible link to quiescence depth, we used double transgenic Tg(her4:drfp);Tg(mcm5:gfp) fish and paradigms predicted to highlight deep vs shallower quiescence. In adult fish (3 month-post-fertilization -mpf-), we performed bulk RNA sequencing on FACS sorted RFPhigh,GFPneg qNSCs (expressing strongly her4, signing NSCs transcriptionally remote from activation), and activated NSCs.

Project description:Heterogeneous pools of adult neural stem cells (NSCs) contribute to brain maintenance and regeneration after injury. The balance of NSC activation and quiescence, as well as the induction of lineage-specific transcription factors, may contribute to diversity of neuronal and glial fates. To identify molecular hallmarks governing these characteristics, we performed single-cell sequencing of an unbiased pool of adult subventricular zone NSCs. This analysis identified a discrete, dormant NSC subpopulation that already expresses distinct combinations of lineage-specific transcription factors during homeostasis. Dormant NSCs enter a primed-quiescent state before activation, which is accompanied by downregulation of glycolytic metabolism, Notch, and BMP signaling and a concomitant upregulation of lineage-specific transcription factors and protein synthesis. In response to brain ischemia, interferon gamma signaling induces dormant NSC subpopulations to enter the primed-quiescent state. This study unveils general principles underlying NSC activation and lineage priming and opens potential avenues for regenerative medicine in the brain.

Project description:The long-term maintenance of the adult neurogenic niche and neurogenesis is dependent on the proper regulation of entry and exit from quiescence. The dynamic transition from quiescence to activation is a complex process requiring not only precise cell cycle control, but also a co-ordinated phenotypic transition involving transcriptional and morphological changes. Presently, the mechanisms by which such a complex repertoire of factors interact and co-ordinate with the core cell cycle machinery to mediate these critical NSC fate transitions remains unknown. Here we show that the Rb/E2F axis functions as an on-off switch for NSC quiescence and activation, by linking the cell cycle machinery to pivotal regulators of NSC fate. Compound deletion of Rb family proteins results in massive activation and expansion of NSCs, and induces a global transcriptomic transition towards NSC activation followed by niche depletion. Deletion of their target activator E2Fs1/3 results in the failure of NSCs to become activated and the acquisition of a global transcriptome associated with intractable NSC quiescence and the cessation of adult neurogenesis. We further show that the Rb/E2F axis orchestrates these fate transitions through the direct regulation of factors essential to NSC function, including REST and ASCL1. This places the Rb/E2F axis as a master regulator of NSC fate, coordinating cell cycle control with NSC activation and quiescence fate transitions.

Project description:The long-term maintenance of the adult neurogenic niche and neurogenesis is dependent on the proper regulation of entry and exit from quiescence. The dynamic transition from quiescence to activation is a complex process requiring not only precise cell cycle control, but also a co-ordinated phenotypic transition involving transcriptional and morphological changes. Presently, the mechanisms by which such a complex repertoire of factors interact and co-ordinate with the core cell cycle machinery to mediate these critical NSC fate transitions remains unknown. Here we show that the Rb/E2F axis functions as an on-off switch for NSC quiescence and activation, by linking the cell cycle machinery to pivotal regulators of NSC fate. Compound deletion of Rb family proteins results in massive activation and expansion of NSCs, and induces a global transcriptomic transition towards NSC activation followed by niche depletion. Deletion of their target activator E2Fs1/3 results in the failure of NSCs to become activated and the acquisition of a global transcriptome associated with intractable NSC quiescence and the cessation of adult neurogenesis. We further show that the Rb/E2F axis orchestrates these fate transitions through the direct regulation of factors essential to NSC function, including REST and ASCL1. This places the Rb/E2F axis as a master regulator of NSC fate, coordinating cell cycle control with NSC activation and quiescence fate transitions.