Project description:Integrating Single-Cell Transcriptomics with Phosphoproteomics Dissects the EGFR-Dependent Network Governing Cortical Gliogenesis

Project description:During development neural stem cells (NSCs) in the cerebral cortex, also known as radial glial cells (RGCs), generate excitatory neurons, followed by production of cortical macroglia and inhibitory neurons that migrate to the olfactory bulb (OB). Understanding the mechanisms for this lineage switch is fundamental for unraveling how proper numbers of diverse neuronal and glial cell types are controlled. We and others recently showed that Shh signaling promotes cortical RGCs to switch lineage to generate cortical oligodendrocytes and OB interneurons. During this lineage switch, cortical RGCs generate intermediate progenitor cells (IPCs) that express Ascl1, Egfr and Olig2, genes critically regulating gliogenesis. The timing of increased Ascl1 expression and the appearance of Egfr+ and Olig2+ cortical progenitors is concurrent with the switch from excitatory neurogenesis to gliogenesis and OB interneuron neurogenesis in the cortex. While Shh signaling promotes Olig2 expression in the developing spinal cord, the exact mechanism for this transcriptional regulation is not known. Further, the transcriptional regulation of Olig2 and Egfr has not been explored. Here we show that in cortical progenitor cells, multiple genetic programs, including Pax6 and Gli3, prevent precocious expression of Olig2, a gene essential for production of cortical oligodendrocytes and astrocytes. We identify multiple distal enhancers that control Olig2 expression in cortical progenitors and show that the mechanisms for regulating Olig2 expression are conserved between mouse and human. Our study reveals evolutionarily conserved regulatory logic controlling the lineage switch of cortical neural stem cells.

Project description:During development neural stem cells (NSCs) in the cerebral cortex, also known as radial glial cells (RGCs), generate excitatory neurons, followed by production of cortical macroglia and inhibitory neurons that migrate to the olfactory bulb (OB). Understanding the mechanisms for this lineage switch is fundamental for unraveling how proper numbers of diverse neuronal and glial cell types are controlled. We and others recently showed that Shh signaling promotes cortical RGCs to switch lineage to generate cortical oligodendrocytes and OB interneurons. During this lineage switch, cortical RGCs generate intermediate progenitor cells (IPCs) that express Ascl1, Egfr and Olig2, genes critically regulating gliogenesis. The timing of increased Ascl1 expression and the appearance of Egfr+ and Olig2+ cortical progenitors is concurrent with the switch from excitatory neurogenesis to gliogenesis and OB interneuron neurogenesis in the cortex. While Shh signaling promotes Olig2 expression in the developing spinal cord, the exact mechanism for this transcriptional regulation is not known. Further, the transcriptional regulation of Olig2 and Egfr has not been explored. Here we show that in cortical progenitor cells, multiple genetic programs, including Pax6 and Gli3, prevent precocious expression of Olig2, a gene essential for production of cortical oligodendrocytes and astrocytes. We identify multiple distal enhancers that control Olig2 expression in cortical progenitors and show that the mechanisms for regulating Olig2 expression are conserved between mouse and human. Our study reveals evolutionarily conserved regulatory logic controlling the lineage switch of cortical neural stem cells.

Project description:During development neural stem cells (NSCs) in the cerebral cortex, also known as radial glial cells (RGCs), generate excitatory neurons, followed by production of cortical macroglia and inhibitory neurons that migrate to the olfactory bulb (OB). Understanding the mechanisms for this lineage switch is fundamental for unraveling how proper numbers of diverse neuronal and glial cell types are controlled. We and others recently showed that Shh signaling promotes cortical RGCs to switch lineage to generate cortical oligodendrocytes and OB interneurons. During this lineage switch, cortical RGCs generate intermediate progenitor cells (IPCs) that express Ascl1, Egfr and Olig2, genes critically regulating gliogenesis. The timing of increased Ascl1 expression and the appearance of Egfr+ and Olig2+ cortical progenitors is concurrent with the switch from excitatory neurogenesis to gliogenesis and OB interneuron neurogenesis in the cortex. While Shh signaling promotes Olig2 expression in the developing spinal cord, the exact mechanism for this transcriptional regulation is not known. Further, the transcriptional regulation of Olig2 and Egfr has not been explored. Here we show that in cortical progenitor cells, multiple genetic programs, including Pax6 and Gli3, prevent precocious expression of Olig2, a gene essential for production of cortical oligodendrocytes and astrocytes. We identify multiple distal enhancers that control Olig2 expression in cortical progenitors and show that the mechanisms for regulating Olig2 expression are conserved between mouse and human. Our study reveals evolutionarily conserved regulatory logic controlling the lineage switch of cortical neural stem cells.

Project description:During development neural stem cells (NSCs) in the cerebral cortex, also known as radial glial cells (RGCs), generate excitatory neurons, followed by production of cortical macroglia and inhibitory neurons that migrate to the olfactory bulb (OB). Understanding the mechanisms for this lineage switch is fundamental for unraveling how proper numbers of diverse neuronal and glial cell types are controlled. We and others recently showed that Shh signaling promotes cortical RGCs to switch lineage to generate cortical oligodendrocytes and OB interneurons. During this lineage switch, cortical RGCs generate intermediate progenitor cells (IPCs) that express Ascl1, Egfr and Olig2, genes critically regulating gliogenesis. The timing of increased Ascl1 expression and the appearance of Egfr+ and Olig2+ cortical progenitors is concurrent with the switch from excitatory neurogenesis to gliogenesis and OB interneuron neurogenesis in the cortex. While Shh signaling promotes Olig2 expression in the developing spinal cord, the exact mechanism for this transcriptional regulation is not known. Further, the transcriptional regulation of Olig2 and Egfr has not been explored. Here we show that in cortical progenitor cells, multiple genetic programs, including Pax6 and Gli3, prevent precocious expression of Olig2, a gene essential for production of cortical oligodendrocytes and astrocytes. We identify multiple distal enhancers that control Olig2 expression in cortical progenitors and show that the mechanisms for regulating Olig2 expression are conserved between mouse and human. Our study reveals evolutionarily conserved regulatory logic controlling the lineage switch of cortical neural stem cells.

Project description:During mammalian brain development, neural stem cells (NSCs) initially produce only neurons and subsequently shift to glial production, while it is still unknown what regulates this drastic fate change. Here we discovered RNA-binding protein (RBP) of quaking (Qk) is selectively expressed in NSCs and is essential for switching from neurogenesis to gliogenesis. Using CNS-specific KO mice for Qk, we found that gliogenesis, but not neurogenesis, was specifically disrupted in Qk-/- brains. In glial differentiating condition, Qk-/- NSCs failed to enter gliogenesis but caused ectopic neurogenic gene expression. Pathway analysis of Qk-/- NSCs identified endocytosis as the regulatory functional cluster of Qk which has been shown to facilitate extra-cellular signaling receptors replacement and promote NSC differentiation. Mechanistically, Qk regulates endocytosis pathway genes through stabilizing their mRNAs via Qk binding sequences in 3’UTR. These results uncovered the cell fate determination mechanism of NSCs through mRNA regulation.

Project description:During mammalian brain development, neural stem cells (NSCs) initially produce only neurons and subsequently shift to glial production, while it is still unknown what regulates this drastic fate change. Here we discovered RNA-binding protein (RBP) of quaking (Qk) is selectively expressed in NSCs and is essential for switching from neurogenesis to gliogenesis. Using CNS-specific KO mice for Qk, we found that gliogenesis, but not neurogenesis, was specifically disrupted in Qk-/- brains. In glial differentiating condition, Qk-/- NSCs failed to enter gliogenesis but caused ectopic neurogenic gene expression. Pathway analysis of Qk-/- NSCs identified endocytosis as the regulatory functional cluster of Qk which has been shown to facilitate extra-cellular signaling receptors replacement and promote NSC differentiation. Mechanistically, Qk regulates endocytosis pathway genes through stabilizing their mRNAs via Qk binding sequences in 3’UTR. These results uncovered the cell fate determination mechanism of NSCs through mRNA regulation.

Project description:Glial cells distribute extensively in the brain and execute important functions. However, their developmental process and molecular features are still not fully explored in human, especially for fetal astrocytes. It is known that EGFR is involved in glial development and we found that the emergence of EGFR+ cells are near the start of gliogenesis and majority of those co-expressed SOX2 during human cerebral cortex development at midgestation. We performed single-cell RNA sequencing of thousands of EGFR+ cells in the human fetal brain cortex from GW21 to GW26. Compared with other published brain sequencing data, our dataset highly enriched the progenitor cells and glial cells. Multiple molecularly specific populations were identified.

Project description:In Drosophila, the glial cells missing (gcm) gene encodes a transcription factor that controls the determination of glial versus neuronal fate. In gcm mutants, presumptive glial cells are transformed into neurons and, conversely, when gcm is ectopically misexpressed, presumptive neurons become glia. Although gcm is thought to initiate glial cell development through its action on downstream genes that execute the glial differentiation program, little is known about the identity of these genes. To identify gcm downstream genes in a comprehensive manner, genome-wide oligonucleotide arrays were used to analyze differential gene expression in wild-type embryos versus embryos in which gcm is misexpressed throughout the neuroectoderm. Transcripts were analyzed at two defined temporal windows during embryogenesis. This first genome-wide analysis of gene expression events downstream of a key developmental transcription factor presents a novel level of insight into the repertoire of genes that initiate and maintain cell fate choices in CNS development. Keywords: other

Project description:The African turquoise killifish combines a short lifespan with age-dependent loss of neuroregenerative capacity, making it a well-suited model for studying brain repair mechanisms in the context of aging. To investigate the extent of cellular diversity that shapes neuro- and gliogenesis, we performed single cell sequencing of the adult telencephalon. Our analysis identifies seventeen cell types including neuronal cells, and progenitors of glial and non-glial nature. Further subclustering unveils four radial glia (RG) types, one atypical non-glial progenitor (NGP) and two intermediate subtypes. Validation of our data in situ reveals a distinct spatial setting for defined RG subtypes, reflecting the distribution of morphologically and physiologically distinct populations. Lineage inference analysis suggests neuroepithelial-like radial glia and NGP to be the start point and intercessor of neural development, respectively. Neuronal sub-clustering uncovers immature and mature excitatory or inhibitory sub-clusters. This complete catalogue of killifish telencephalon cell types is accessible via an online tool, providing a resource to understand neurogenesis in healthy brains and upon injury or disease.