Project description:We sought to find molecular signatures of the SGZ cell types, and to characterize the molecular pathways and transcription factor cascades that define the neurogenic niche. We used laser capture microdissection and DNA microarrays to profile gene expression in the inner (SGZ) and outer portions of the dentate gyrus (DG). Since the vast majority of the cells in the DG are mature granule cells, we compared the expression of the inner and outer portions to reveal molecular markers for the less numerous populations of the SGZ. This data set is part of a larger study assessing conserved molecular signatures of neurogenesis in the hippocampal subgranular zone of rodents and primates. Using a combination of selective SGZ transcriptional profiling with laser microdissection and DNA microarrays as well as in situ hybridization (ISH), we developed an extensive molecular characterization of the mouse SGZ, identifying 367 genes enriched in the SGZ compared to mature granule neurons. These genes displayed a wide range of cellular expression patterns reflecting the cellular milieu of the SGZ, including progenitor and dividing cells, immature granule cells, astrocytes, oligodendrocytes, and GABAergic interneurons. We next used a comparable microarray data set in rhesus monkey that profiled the SGZ across postnatal development to identify genes related to developmentally regulated granule cell neurogenesis. The rhesus monkey SGZ showed highly significant similarity to mouse, whereas network analysis of these data identified SGZ-enriched gene sets with different temporal profiles reflecting differential time-courses for maturation of glia and granule neurons. One neurogenesis-related gene network showed a steady decrease in expression across postnatal rhesus development from birth to adulthood. This temporal pattern is highly correlated with the number of proliferating cells in the dentate gyrus, and the neurogenic transcription factors Sox4 and Sox11 are central hub genes for this gene network. A number of the genes in this network showed a similar postnatal downregulation in mouse, suggesting a general conservation of molecular mechanisms underlying developmental and adult neurogenesis in rodents and primates. Primate data available at: http://www.blueprintnhpatlas.org/ Brains from 10- to 11-week-old C57BL/6 male mice housed in three conditions (no running, 4 days of running, 30 days of running) were sectioned and the dentate gyrus was isolated. For each brain, the inner granule cell layer (containing the subgranular zone) and outer GCL were separated using laser capture microdissection, and RNA from each region was collected and processed as described in the protocols.

Project description:Here we directly compare for the first time how the longstanding static model of mouse Dentate Gyrus (DG) development compares with a comprehensive high-resolution live-cell multiphoton (live-MPM) imaging approach. We took advantage of multiple fluorescent protein-based cell-type specific reporters to identify Neural Stem Cells (NSC), Intermediate Neurogenic Progenitors (INPs), and Granule Neurons (GNs) to generate live 4D cellular datasets across embryonic, postnatal and adult ages. Live-MPM revealed that INPs and NSCs migrated long distances along multiple routes to seed the SGZ from multiple directions, and from mosaic progenitor zones along the septo-temporal axis of the hippocampus. We found that dynamic INPs processes and interactions contributed to the architecture of both transient and permanent NSC niches during embryonic development, and that INP cellular plasticity is maintained in the adult SGZ NSC niche. We also used a Molecular Systems (MS) approach to determine the basis for maintained INP cellular plasticity that revealed an overlapping signaling network infrastructure based largely on Rho-family mediated regulation of cytoskeletal dynamics. Our combined strategies revealed that dynamic INPs are a major molecular signaling transition state in the adult SGZ, and that Tbr2 expression defines the initial stage of GN commitment. Our novel findings reveal fundamental new insight into one of the most well studied brain regions key for normal cognitive function, and the importance of analyzing the development of live stem cell niches in vivo. In concert with live-cell imaging, we used microarray analysis to identify genes that may be involved in the development of the Dentate Gyrus NSC niche.

Project description:Mutations in the JMJD3 (KDM6B) chromatin regulator are causally associated with autism spectrum disorder and syndromic intellectual disability, but the neurodevelopmental roles of this histone 3 lysine 27 (H3K27) demethylase are poorly understood. Neural stem cells (NSCs) in the hippocampal dentate gyrus (DG) generate new granule neurons throughout life, and deficits in DG neurogenesis are associated with cognitive and behavioral problems. Here we show that Jmjd3 is required for the establishment of adult neurogenesis in the mouse DG. Conditional deletion of Jmjd3 in embryonic DG precursors results in an adult hippocampus that is essentially devoid of NSCs. While early postnatal mice with Jmjd3-deletion have near normal numbers of DG NSCs, at later stages, Jmjd3-deleted NSCs fail to propagate normally. In addition to the loss of NSCs during postnatal development, neurogenesis from Jmjd3-deleted NSCs is impaired, corresponding to defective neurogenic gene expression. Without Jmjd3, NeuroD2 and Bcl11b(Ctip2) are not properly expressed and exhibit increased levels of H3K27me3, underscoring the role of Jmjd3 in the regulation of transcription for neuronal differentiation. Thus, these data indicate that Jmjd3 plays dual roles in postnatal DG neurogenesis, being critical for the establishment of the NSC pool as well as the differentiation of young DG granule neurons. More broadly, our results suggest a neurodevelopmental link between JMJD3 mutations and hippocampal dysfunction, providing new insights into how mutations in chromatin regulators may contribute to learning disorders.

Project description:Here we directly compare for the first time how the longstanding static model of mouse Dentate Gyrus (DG) development compares with a comprehensive high-resolution live-cell multiphoton (live-MPM) imaging approach. We took advantage of multiple fluorescent protein-based cell-type specific reporters to identify Neural Stem Cells (NSC), Intermediate Neurogenic Progenitors (INPs), and Granule Neurons (GNs) to generate live 4D cellular datasets across embryonic, postnatal and adult ages. Live-MPM revealed that INPs and NSCs migrated long distances along multiple routes to seed the SGZ from multiple directions, and from mosaic progenitor zones along the septo-temporal axis of the hippocampus. We found that dynamic INPs processes and interactions contributed to the architecture of both transient and permanent NSC niches during embryonic development, and that INP cellular plasticity is maintained in the adult SGZ NSC niche. We also used a Molecular Systems (MS) approach to determine the basis for maintained INP cellular plasticity that revealed an overlapping signaling network infrastructure based largely on Rho-family mediated regulation of cytoskeletal dynamics. Our combined strategies revealed that dynamic INPs are a major molecular signaling transition state in the adult SGZ, and that Tbr2 expression defines the initial stage of GN commitment. Our novel findings reveal fundamental new insight into one of the most well studied brain regions key for normal cognitive function, and the importance of analyzing the development of live stem cell niches in vivo.

Project description:Low-threshold voltage gated T-type calcium channels are characterized by unique electrophysiological features with the fast inactivation and slow deactivation kinetics. Previous reports suggest that T-type calcium channels may be involved in the adult hippocampal neurogenesis, however, function of T-type calcium channels in newly generated cells is still uncertain. We demonstrated that Cav3.1 is predominantly localized in the NPCs in mouse SGZ, and that deletion of Cav3.1 attenuates proliferation and survival in 5-bromo-2'-deoxyuridine (BrdU)-labeled new born cells in the hippocampal DG. To reveal mechanism underlying impaired adult hippocampal neurogenesis in Cav3.1 KO mice, gene expression in the hippocampal DG is compared between WT and Cav3.1 KO mice. We here defined several altered genes related with cell apoptosis, proliferation and neuronal differentiation in Cav3.1 KO mice.

Project description:By precisely dissected LC-MS/MS for proteomics and phosphoproteomics, we found that deletion of NRBF2 disrupts neurogenesis-related protein network in the DG, such as neurogenesis, cell development, cell morphogenesis, cellular homeostasis, and synaptic plasticity.

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:Rhesus Monkey is one of the important primate models widely used in the fields of disease mechanism study, pre-clinical test in drug discovery and molecular evolution. However, the majority of rhesus gene annotations were putatively mapped from human genome, with only 10% supported by rhesus EST data.So, to better study the transcriptome, paired-end, strand-specific, poly(A)-positive RNA-Seq were performed in 5 rhesus monkey tissues. 5 tissue samples examined: prefrontal cortex, liver, skeletal muscle, adipose, testis

Project description:Rosette neural stem cells (R-NSCs) represent early stage of neural development and possess full neural differentiation and regionalization capacities. R-NSCs are considered as stem cells of neural lineage and have important implications in study of neurogenesis and cell replacement therapy. However, the molecules regulating their functional properties remain largely unknown. Rhesus monkey is ideal model to study human neural degenerative diseases and plays intermediate translational roles as therapeutic strategies evolve from rodent systems to human clinical applications. In this study, we derived R-NSCs from rhesus monkey embryonic stem cells (rESCs) and systematically investigated the unique expressions of mRNAs, microRNAs, and signaling pathways by genome-wide comparison of the mRNA and microRNA profilings of ESCs, R-NSCs at early (R-NSCP1) and late passages (R-NSCP6) and neural progenitor cells (NPCs). Apart from the R-NSCP1 specific protein-coding genes and microRNAs, we identified several pathways including Hedgehog and Wnt highly activated in R-NSCP1. The possible regulatory interactions among the microRNAs, protein-coding genes and signaling pathways were proposed. Besides, many genes with alternative splicing switch were identified at R-NSCP1. These data provided valuable resource to understand the regulation of early neurogenesis and to better manipulate the R-NSCs for cell replacement therapy. mRNA and miRNA profiles for four stages in rhesus embryonic stem cell neural differentiation, eight samples in all