Project description:Radial glial cells (RGCs) are the most abundant macroglia in the teleost brain and have established roles in neurogenesis and neurosteroidogenesis; however, their transcriptome remains unstudied, limiting functional understanding of this crucial cell type. Using cultured goldfish RGCs, RNA sequencing and de novo transcriptome assembly were performed, generating the first reference transcriptome for fish RGCs with 17,620 unique genes identified. These data revealed that RGCs express a diverse repertoire of receptors and signaling molecules, suggesting that RGCs may respond to and synthesize an array of hormones, peptides, cytokines, and growth factors. Expanding on recent neuroanatomical data and possible direct neuronal regulation of RGC physiology, differential gene expression analysis identified transcriptional networks that are responsive to the conserved secretogranin II-derived neuropeptide secretoneurin A (SNa). Pathway analysis indicated that cellular processes related to the central nervous system (e.g., neurogenesis, synaptic plasticity, glial cell development) and immune functions (e.g., immune system activation, leukocyte function, macrophage response) were preferentially modulated by SNa. These data reveal an array of new functions that are proposed to be critical to neuronal-glial interactions through the mediator SNa.

Project description:Astrocytes are glial cells of the central nervous system that modulate neuronal function. Here, we present glyoxal-fixed astrocyte nuclei transcriptomics (GFAT), a protocol for the purification and transcriptomic analysis of astrocyte nuclei from the cortex and cerebellum of adult and aged fresh mouse brain. We describe steps for tissue dissection, glyoxal fixation, homogenization, nuclei isolation, antibody staining, fluorescence-activated cell sorting, and RT-qPCR or bulk RNA sequencing. GFAT does not require transgenic lines or viral injection and allows parallel astrocyte and neuron profiling.

Project description:The evolution of nervous systems hinges on cell type diversification and specialization. Neural glia, also called macroglia, make up a large percentage of the total cell numbers in the brain of several species including humans and perform critical functions related to producing, maintaining and assiting neurons. Despite their importance, glial cells have been much less studied than neurons. Here, in order to investigate the heterogeneity of adult radial glial cells in zebrafish and to study the evolution of macroglia and the adult neurogenesis process they support, we generated a single cell RNAseq dataset of the adult zebrafish telencephalon enriched for radial glial cells using a sox2:gfp transgenic line.

Project description:Chromosomes and genes are non-randomly arranged within the mammalian cell nucleus. Clustering of genes is of great significance in transcriptional regulation. However, the relevance of gene clustering in their expression during differentiation of neural precursor cells (NPCs) into astrocytes remains unclear. We performed a genome-wide enhanced circular chromosomal conformation capture (e4C) to screen genes associated with an astrocyte-specific gene, glial fibrillary acidic protein (Gfap), during astrocyte differentiation. We identified 13 genes that were specifically associated with Gfap and expressed in NPC-derived astrocytes. These results provide evidence for functional significance of gene clustering in transcriptional regulation during NPCs differentiation. comparison of NPCs vs LIF+ vs LIF- cells.

Project description:The molecular basis of astrocyte differentiation and maturation is poorly understood. As microRNAs have important roles in cell fate transitions, we set out to study their function during the glial progenitor cell (GPC) to astrocyte transition. Inducible deletion of all canonical microRNAs in GPCs in vitro led to a block in the differentiation to astrocytes. In an unbiased screen, the reintroduction of let-7 and miR-125 families of microRNAs rescued differentiation. Let-7 and miR-125 shared many targets and functioned in parallel to JAK-STAT signaling, a known regulator of astrogliogenesis. While individual knockdown of shared targets did not rescue the differentiation phenotype in microRNA-deficient GPCs, overexpression of these targets in wild-type GPCs blocked differentiation. This finding supports the idea that microRNAs simultaneously suppress multiple mRNAs that inhibit differentiation. The microRNA-regulated targets were enriched for genes downregulated during in vivo astrocyte differentiation and upregulated in glioblastomas, consistent with validity of using the in vitro model to study in vivo events. These findings provide insight into the microRNAs and the genes they regulate in this important cell fate transition. Small RNA profiling of 2 replicates of GPCs and astrocytes

Project description:To date, most epigenetic datasets have been generated on DNA samples isolated from bulk tissues. As the proportion of individual cell types within a sample can vary across individuals, systematic differences in cellular proportions that correlate with the phenotype of interest may manifest as differences in the overall epigenetic profile. Deconvolution algorithms calculate a series of continuous variables reflecting the underlying cellular heterogeneity of each sample from the bulk tissue profile that can be used to adjust for confounding in epigenome-wide association analyses. Here we provide novel reference profiles for brain cell types for use with reference based deconvolution algorithms. We used a FANS protocol recently described by our group to purify nuclei populations from prefrontal cortex tissue from 43 adult donors. Our initial gating strategy used an antibody against NeuN to isolate neuronal nuclei in combination with an antibody against SOX10 to separate oligodendrocyte nuclei from other glial nuclei. Subsequently, in a second gating strategy we additionally included an antibody against IRF8 to enrich microglia from the NeuNNeg/SOX10Neg fraction. Our third gating strategy used an antibody against SATB2 in place of NeuN to isolate excitatory neurons. We generated DNA methylation profiles using the Illumina EPIC array for NeuNPos (neuron-enriched; n = 28), NeuNNeg/SOX10Pos (oligodendrocyte-enriched; n = 24), NeuNNeg/SOX10Neg (microglia- and astrocyte-enriched; n = 21), NeuNNeg/SOX10Neg/IRF8Pos (microglia-enriched; n = 17), NeuNNeg/SOX10Neg/IRF8Neg, (astrocyte-enriched; n = 7), SATB2Pos (excitatory neuron-enriched; n = 9), and SATB2Neg (inhibitory neuron- and glial- enriched; n = 6) nuclei populations. We have demonstrated that these are applicable for use with established deconvolution algorithms to quantify the cellular heterogeneity of the cortex and other regions of the human brain from bulk DNAm data. These variables will be critical covariates to include in future epigenetic studies of brain disorders to minimise the risk of false positive associations and improve our understanding of the changes in the brain that underpin the development of psychiatric disorders and neurodegenerative diseases.

Project description:we have evaluated the effects of APP overexpression in hNSCs at a global 16 level by a transcriptomic analysis using the massive RNA sequencing (RNA-seq) technology. Spe-17 cifically, we have focused on differentially expressed genes that are related to neuronal and glial 18 differentiation processes, as well as on groups of differentially expressed genes associated with dif-19 ferent signaling pathways, in order to find a possible interaction between them and APP

Project description:Astrocytes are increasingly recognized as crucial contributors to neuronal function at synapses, axons, and somas. Reliable methods that can provide insight into the astrocyte proteins at the neuron-astrocyte functional interface are highly desirable. Here we conducted a mass spectrometry analysis of Percoll® gradient isolated gliosomes, a viable preparation of glial subcellular particles often used to study mechanisms of astrocytic transmitter uptake and release and their regulation. Gliosomes were compared with synaptosomes, a preparation containing the neurotransmitter release machinery, and accordingly synaptosomes were enriched for proteins involved in synaptic vesicle mediated transport. Interestingly, gliosome preparations were found to be enriched for different classes of known astrocyte proteins, such as VAMP3 (involved in astrocyte exocytosis), Ezrin (perisynaptic astrocyte cytoskeletal protein), and Basigin (astrocyte membrane glycoprotein), as well as for G-protein mediated signaling proteins. Together, these data provide the first detailed description of the gliosome proteome and show that gliosomes can be a useful preparation to study glial membrane proteins and associated processes.

Project description:This study generates a census of cell signatures using single-nucleus RNA-sequencing data from dissociated lumbar human spinal cord. Nuclei were isolated using a triton-based dissociation protocol, processed using the 10x Genomic Chromium 3' platform (v3), and clustered into major cell classes as well as subtypes within each neuronal and glial class.

Project description:Astrocytes, the predominant glial cells in the central nervous system, play essential roles in maintaining brain function. Reprogramming induced pluripotent stem cells (iPSCs) to become astrocytes through overexpression of the transcription factors, NFIB and SOX9, is a rapid and efficient approach for studying human neurological diseases and identifying therapeutic targets. However, the precise differentiation path and molecular signatures of induced astrocytes remain incompletely understood. Accordingly, we performed single-cell RNA sequencing analysis on 64,736 cells to establish a comprehensive atlas of NFIB/SOX9-directed astrocyte differentiation from human iPSCs. Our dataset provides detailed information about the path of astrocyte differentiation, highlighting the stepwise molecular changes that occur throughout the differentiation process. This dataset serves as a valuable reference for dissecting uncharacterized transcriptomic features of NFIB/SOX9-induced astrocytes and investigating lineage progression during astrocyte differentiation. Moreover, these findings pave the way for future studies on neurological diseases using the NFIB/SOX9-induced astrocyte model.