Project description:To determine the genes regulated by Fezf2 during neocortical development, we performed RNA-seq on Fezf2 +/+; Emx1-cre (Fezf2 wildtype) and Fezf2 fl/+; Emx1-Cre (Fezf2 Knockout) neocortices isolated from the P0 mice. After RNA isolation from the dissected tissue the samples were processed for library preperation using Illumina Poly-A RNA kit. Fezf2 can reprogram the upper layer neocortical neurons to form corticospinal tract. To understand the key transcriptomic changes driven by Fezf2 that drive this reprogramming, we performed in RNA-seq on the cells over-expressing Fezf2 and Gfp or Gfp. At E15.5, in utero electroporations targeting cortical plate, were performed in pregnant mice with Fezf2 and Gfp plasmids or with Gfp plasmid alone, which was used as control. At P3, the Gfp positive cells were FAC sorted from Fezf2 and Gfp, or Gfp cortices and processed for library preparations using NUGEN Ovation® V2 system. Libraries were sequenced using Illumina 2000 platform to generate 75bp single reads. At least 10 million uniquely mapped reads were obtained for each sample. To determine the genes directly regulated by FEZF2, we performed the ChIP-Seq on N2A cells that were transfected to over express FEZF2 using pCAG- Fezf2-V5 and pCAG-V5. After 48 hr, of transfection, cells were fixed and processed for ChIP seq. Libraries were prepared using Illumina TruSeq ChIP Libary Preparation Kit.

Project description:Corticospinal motor neurons (CSMN) are one specialized class of cortical excitatory neurons, which connect layer Vb of the cortex to the spinal cord. a master transcription factor –Forebrain expressed zinc finger 2 (Fezf2) – has been identified that is necessary for the fate specification of CSMN. Fezf2 alone can cell-autonomously instruct the acquisition of CSMN-specific features when expressed in diverse, permissive cellular contexts, in vivo. In order to understand the molecular logic underlying the acquisition of CSMN traits upon Fezf2 expression, we compared the in vivo gene expression of FACS-purified cortical progenitors that ectopically expressed Fezf2 to control progenitors. We used in utero electroporation to deliver Fezf2GFP or CtrlGFP expression vectors to neocortical progenitors at E14.5, when they primarily generate CPN of the upper layers. Overexpression of Fezf2 in these progenitors is sufficient to instruct a fate-switch resulting in the generation of CSMN and other subtypes of corticofugal projection neurons. Fezf2GFP- and CtrlGFP -electroporated progenitors were FACS-purified at 24 and 48 hours after surgery and acutely profiled by microarrays.

Project description:Cortical projection neurons comprise classes of neurons connecting the cerebral cortex to distant targets in the nervous system. Each projection neuron class acquires a distinct molecular identity and develops characteristic patterns of axonal projection and dendritic arborization that determine their inputs, outputs, and distinct functions. How different aspects of neuron identity, including axonal and dendritic morphology, are coordinated appropriately in each specific neuron type is not known. A network of transcription factors, including the selector gene Fezf2, is central to specifying cortical projection neuron fates. However, regulation down-stream of these fate-determinant transcription factors to control different aspects of neuron identity is not understood, particularly as it relates to the development of distinct dendritic arbors that determine the inputs to each projection neuron class. Here we show that the miR-193b~365 microRNA cluster downstream of Fezf2 cooperatively represses the signaling molecule Mapk8 to regulate dendritic development in a neuron subtype-specific manner.

Project description:Corticospinal motor neurons (CSMN) are one specialized class of cortical excitatory neurons, which connect layer Vb of the cortex to the spinal cord. a master transcription factor –Forebrain expressed zinc finger 2 (Fezf2) – has been identified that is necessary for the fate specification of CSMN. Fezf2 alone can cell-autonomously instruct the acquisition of CSMN-specific features when expressed in diverse, permissive cellular contexts, in vivo. In order to understand the molecular logic underlying the acquisition of CSMN traits upon Fezf2 expression, we compared the in vivo gene expression of FACS-purified cortical progenitors that ectopically expressed Fezf2 to control progenitors.

Project description:RNA Sequencing of E14.5 mouse cortical neurospheres in response to Fezf2 over-expression 2 replicates each of GFP-transfected or Fezf2/GFP-transfected E14.5 mouse cortical neurospheres. Paired-end sequencing 101bp.

Project description:Cas9/gRNA and TALEN Targeting in hiPSCs

Project description:A microRNA cluster downstream of Fezf2 coordinates projection identity and dendritic morphology in cortical projection neurons

Project description:Molecular mechanisms controlling specification and differentiation of distinct neuron subtypes in the cerebral cortex are not well understood. Corticothalamic projection neurons (CThPN) are a diverse set of neurons, critical for function of the neocortex, but little is known about the molecular mechansims controlling their development. We used microarrays to detail CThPN gene expression at 3 developmental time points. We then compared CThPN gene expression, with the gene expression of other neuron subtypes in the cerebral cortex at the same stages (previously described in Arlotta et a., 2005) CThPN were retrogradely label with fluorescent microespheres injected into the thalamus, and were FACS purified at 3 developmental stages for RNA extraction and hybridization on Affymetrix microarrays.

Project description:During development, the human brain orchestrates the generation of hundreds of diverse cell types, and recent transcriptomic atlases of the developing human cortex provide new opportunities to identify novel regulators of cell fate specification. We have conducted an integrated meta-analysis of seven recently published single-cell transcriptomic profiles of the developing human cortex, generating a meta-atlas of 225 meta-modules. By tracking the activity of these meta-modules throughout development and comparing this to datasets from the adult human as well as the developing and adult mouse, we identified modules with potential roles in the transition from neurogenesis to gliogenesis and neuronal subtype maturation. The cell type and developmental state at which these modules exist was validated in primary samples from the developing human brain. Of particular interest, we identified and validated a module associated with both developing human deep layer neurons and human adult deep layer neuronal subtypes expressing the terminal differentiation marker FEZF2. Though FEZF2 is neither a member of nor co-expressed with our deep layer-associated gene module, almost half of module genes are putative FEZF2 targets, including TSHZ3, a transcription factor associated with neurodevelopmental disorders such as autism. Knockdown experiments in human cortical organoid models confirm that both FEZF2 and TSHZ3 are necessary for deep layer neuron specification. Importantly, we observe that subtle manipulations of these transcription factors result in slight changes in module activity, but together yield strong differences in cell fate. Our analyses therefore reveal a gene network that required to generate deep layer neuronal subtypes, demonstrating the ability of our meta-atlas to engender further mechanistic analyses of cortical fate specification. We anticipate this resource being useful for the study of co-expression programs across diverse biological questions related to the developing neocortex.

Project description:During development, the human brain orchestrates the generation of hundreds of diverse cell types, and recent transcriptomic atlases of the developing human cortex provide new opportunities to identify novel regulators of cell fate specification. We have conducted an integrated meta-analysis of seven recently published single-cell transcriptomic profiles of the developing human cortex, generating a meta-atlas of 225 meta-modules. By tracking the activity of these meta-modules throughout development and comparing this to datasets from the adult human as well as the developing and adult mouse, we identified modules with potential roles in the transition from neurogenesis to gliogenesis and neuronal subtype maturation. The cell type and developmental state at which these modules exist was validated in primary samples from the developing human brain. Of particular interest, we identified and validated a module associated with both developing human deep layer neurons and human adult deep layer neuronal subtypes expressing the terminal differentiation marker FEZF2. Though FEZF2 is neither a member of nor co-expressed with our deep layer-associated gene module, almost half of module genes are putative FEZF2 targets, including TSHZ3, a transcription factor associated with neurodevelopmental disorders such as autism. Knockdown experiments in human cortical organoid models confirm that both FEZF2 and TSHZ3 are necessary for deep layer neuron specification. Importantly, we observe that subtle manipulations of these transcription factors result in slight changes in module activity, but together yield strong differences in cell fate. Our analyses therefore reveal a gene network that required to generate deep layer neuronal subtypes, demonstrating the ability of our meta-atlas to engender further mechanistic analyses of cortical fate specification. We anticipate this resource being useful for the study of co-expression programs across diverse biological questions related to the developing neocortex.