Project description:Surprisingly little is known about the critical metabolic changes that neural cells have to undergo during development and how even mild, temporary shifts in this program can influence brain circuitries and behavior. Inspired by the discovery that mutations in SLC7A5, a transporter of metabolically essential large neutral amino acids (LNAAs), lead to autism, we employed metabolomic profiling to study the metabolic states of the cerebral cortex across different developmental stages. We found that the forebrain undergoes significant metabolic remodeling throughout development, with certain groups of metabolites showing stage-specific changes. But what are the consequences of interfering with this metabolic program? By manipulating Slc7a5 expression in neural cells, we found that the metabolism of LNAAs and lipids are interconnected in the cortex. Deletion of Slc7a5 in neurons perturbs specifically the postnatal metabolic state leading to a shift in lipid metabolism and a stage- and cell-type-specific alteration in neuronal activity patterns, resulting in a long-term circuit dysfunction.

Project description:Surprisingly little is known about the critical metabolic changes that neural cells have to undergo during development and how even mild, temporary shifts in this program can influence brain circuitries and behavior. Inspired by the discovery that mutations in SLC7A5, a transporter of metabolically-essential large neutral amino acids (LNAAs), lead to autism, we employed metabolomic profiling to study the metabolic states of the cerebral cortex across different developmental stages. We found that the forebrain undergoes significant metabolic remodeling throughout development, with certain groups of metabolites showing stage-specific changes. But what are the consequences of interfering with this metabolic program? By manipulating Slc7a5 expression in neural cells, we found that the metabolism of LNAAs and lipids are interconnected in the cortex. Deletion of Slc7a5 in neurons perturbs specifically the postnatal metabolic state leading to a shift in lipid metabolism and a stage- and cell-type-specific alteration in neuronal activity patterns, resulting in a long-term circuit dysfunction.

Project description:During development of the human cerebral cortex, multipotent neural progenitors generate excitatory neurons and glial cells. This process is faithfully recapitulated in brain organoids. By using telencephalic brain organoids grown using a dual reporter cell line to isolate neural progenitors and neurons we generated a cell type and developmental stage-specific transcriptome dataset..

Project description:During development of the human cerebral cortex, multipotent neural progenitors generate excitatory neurons and glial cells. This process is faithfully recapitulated in brain organoids. By using telencephalic brain organoids grown using a dual reporter cell line to isolate neural progenitors and neurons we generated a cell type and developmental stage-specific ATAC-seq dataset.

Project description:During development of the human cerebral cortex, multipotent neural progenitors generate excitatory neurons and glial cells. Investigations of the transcriptome and epigenome have revealed important gene regulatory networks underlying this crucial developmental event. However, the post-transcriptional control of gene expression and protein abundance during human corticogenesis remains poorly understood. We addressed this issue by using a dual reporter cell line to isolate neural progenitors and neurons from the telencephalic brain organoid tissue and performed cell type and developmental stage-specific transcriptome and proteome analysis. Integrating the two datasets revealed temporal modules of gene expression during human corticogenesis, both at RNA and protein level. Our multiomics approach reveals novel posttranscriptional regulatory mechanisms crucial for fidelity of cortical development.

Project description:The developing mammalian brain generates a variety of Neural Progenitor Cells (NPCs). Primary NPCs throughout the neuraxis are derived from the ventricular zone. Intermediate progenitor cells (IPCs) are produced uniquely in the telencephalon and contribute extensively to the neurons that comprise the cerebral cortex and basal ganglia. It is known that the fate of the diverse NPC populations is determined by the interplay of transcription factors and regulation by regional humoral cues. However, despite our recent appreciation that nutrient-regulated intracellular metabolic milieu (pO2, energy, and redox state) significantly influence cell fate, an unexplored area is whether NPCs have intrinsic metabolic identity, and if so, the mechanism by which molecular metabolism contributes to brain development.Little is known however, if intrinsic differences in cellular metabolism of regional NPCs make certain NPCs susceptible while others resistant to genetic and environmental insults. We conjectured that regional (fore-and hindbrain) NPCs are metabolically distinct.

Project description:Alternative splicing (AS) generates vast transcriptomic complexity in the vertebrate nervous system. However, the extent to which trans-acting splicing regulators and their target AS regulatory networks contribute to nervous system development is not completely understood. To address these questions, we have generated mice lacking the vertebrate- and neural-specific Ser/Arg-repeat related protein of 100 kDa (nSR100/SRRM4). Loss of nSR100 impairs development of the central and peripheral nervous systems, in part by disrupting neurite outgrowth, cortical layering in the forebrain, and axon guidance in the corpus callosum. Accompanying these developmental defects are widespread changes in AS that primarily result in shifts to non-neural patterns for different classes of splicing events. The main component of the altered AS program comprises 3-27 nucleotide neural microexons, an emerging class of highly conserved alternative splicing event associated with the regulation of protein interaction networks in developing neurons and neurological disorders. Remarkably, inclusion of a 6-nucleotide nSR100-activated microexon in Unc13b transcripts is sufficient to rescue a neuritogenesis defect in nSR100 mutant primary neurons. These results thus reveal critical in vivo neurodevelopmental functions of nSR100, and they further link these functions to a conserved program of neural microexon splicing. mRNA profiles of mouse control or nSR100/Srrm4 KO cortex or hippocampus using high-throughput sequencing data.

Project description:Neurons utilize glucose to generate adenosine triphosphate (ATP) essential for their survival, excitability and synaptic signaling, as well as initiating changes in neuronal structure and function. Defects in oxidative metabolism and mitochondria functions are also associated with aging and diverse human neurological diseases1-4. While neurons are known to adapt their metabolism to meet the increased energy demands of complex behaviors such as learning and memory, the molecular underpinnings regulating this process remain poorly understood4-6. Here we show that the orphan nuclear receptor estrogen related receptor gamma (ERRγ) becomes highly expressed during retinoic-acid induced neurogenesis and is widely expressed in neuronal nuclei throughout the brain. Mechanistically, we show that ERRγ directly orchestrates the expression of networks of genes involved in mitochondrial oxidative phosphorylation and energy generation in neurons. The importance of this regulation is evidenced by decreased adaptive metabolic capacity in cultured neurons lacking ERRγ, and reduced long-term potentiation (LTP) in ERRγ-/- hippocampal slices. Notably, the defect in LTP was rescued by the metabolic intermediate pyruvate, functionally linking the ERRγ knockout metabolic phenotype and memory formation. Consistent with this notion, mice lacking neuronal ERRγ exhibit defects in spatial learning and memory. These findings implicate ERRγ in the metabolic adaptations required for long-term memory formation. We used microarray analysis to compare the genome-wide gene expression changes between wild type (WT) and ERRγ-/- P0 cerebral cortex as it contains mainly neuronal lineage at this stage compared to adult cortex.

Project description:Parvalbumin neurons, as an important subtype of inhibitory neurons, play a crucial role in the brain. The dysfunctions of those cells are associated with multiple neural system disorders. We carried out whole gene expression studies for the induction process of parvalbumin neurons. We used microarrays to detail the global program of gene expression underlying cellularization and identified distinct classes of up-regulated genes during this process. Induced parvalbumin neuron cells were selected at successive stages of induction process for RNA extraction and hybridization on Affymetrix microarrays. We sought to obtain homogeneous populations of induced parvalbumin neurons at each developmental stage in order to increase the temporal resolution of expression profiles.

Project description:Tissue-specific deletion of the gene encoding the histone acetyltransferase Kat7 (Hbo1) in the developing mouse central nervous system using cre-recombinase expression driven by regulatory sequences of the nestin locus (NesCre transgene) resulted in defective cerebral cortex development, a complete failure of neural stem cells to give rise to neurons and oligodendrocytes during in vitro differentiation, and a failure to express the neuronal differentiation program. Proliferating neural stem and progenitor cells (NPSCs) were isolated from Kat7-deleted and Kat7-intact 14.5 day embryonic mouse fetuses.