Project description:Primary somatosensory neurons are diverse neurons that report salient features of our internal and external environments. How specialized gene expression programs emerge during development to endow each somatosensory neuron subtype with unique properties is unclear. To analyze the developmental progression of transcriptional maturation of each principal somatosensory neuron subtype, we generated a transcriptomic atlas of cells traversing the somatosensory lineage. We find that somatosensory neurogenesis leads to neurons in a transcriptionally unspecialized state, characterized by trace expression of subtype-specific genes yet co-expression of transcription factors (TFs) that become restricted to select subtypes as development proceeds. Single cell transcriptomic analysis using sensory neurons from mutant mice lacking representative broad-to-restricted TFs revealed that they are essential for establishing subtype specific gene programs in subtypes where their expression is maintained, while leaving other subtypes unaffected. We also identify a role for neuronal targets by demonstrating that nerve growth factor influences subtype-restricted patterns of TFs. Our findings support a model in which extrinsic cues orchestrate somatosensory neuron diversification by influencing the expression pattern of TFs that promote transcriptional specialization of somatosensory neuron subtypes.

Project description:To characterize Jmjd3 function in motor neuron development, we isolated GFP+ cells derived from Olig2 expressing progenitor cells that included motor neuron population and then employed single cell RNAseq. We found some novel motor neuron subtypes in addition to well-known motor columns, and specific genes in each subtype by unbiased and comprehensive analysis. Moreover, by comparing control and Jmjd3cKO motor neuron lineage cells, we found many downregulated and upregulated genes affected by Jmjd3 loss of function. Single cell RNAseq provided very powerful tool to analyze different regulated genes in each subtype rather than overall motor neuron groups.

Project description:Medulloblastoma encompasses a collection of clinically and molecularly diverse tumor subtypes that together comprise the most common malignant childhood brain tumor. These tumors are thought to arise within the cerebellum, with approximately 25% originating from granule neuron precursor cells (GNPCs) following aberrant activation of the Sonic Hedgehog pathway (hereafter, SHH-subtype). The pathological processes that drive heterogeneity among the other medulloblastoma subtypes are not known, hindering the development of much needed new therapies. Here, we provide evidence that a discrete subtype of medulloblastoma that contains activating mutations in the WNT pathway effector CTNNB1 (hereafter, WNT-subtype), arises outside the cerebellum from cells of the dorsal brainstem. We found that genes marking human WNT-subtype medulloblastomas are more frequently expressed in the lower rhombic lip (LRL) and embryonic dorsal brainstem than in the upper rhombic lip (URL) and developing cerebellum. Magnetic resonance imaging (MRI) and intra-operative reports showed that human WNT-subtype tumors infiltrate the dorsal brainstem, while SHH-subtype tumors are located within the cerebellar hemispheres. Activating mutations in Ctnnb1 had little impact on progenitor cell populations in the cerebellum, but caused the abnormal accumulation of cells on the embryonic dorsal brainstem that included aberrantly proliferating Zic1+ precursor cells. These lesions persisted in all mutant adult mice and in 15% of cases in which Tp53 was concurrently deleted, progressed to form medulloblastomas that recapitulated the anatomy and gene expression profiles of human WNT-subtype medulloblastoma. We provide the first evidence that subtypes of medulloblastoma have distinct cellular origins. Our data provide an explanation for the marked molecular and clinical differences between SHH and WNT-subtype medulloblastomas and have profound implications for future research and treatment of this important childhood cancer. A total of 16 samples are analyzed, repsresenting 4 experimental groups: Ctnnb1 medulloblastoma (3 samples); Ptch1 medulloblastoma (6 samples); embryonic dorsal brainstem (4 samples); and postnatal granule neuron precursor cells (3 samples). Every sample was prepared from a different mouse.

Project description:Using Sst and parvalbumin subtype-specific fluorescence activated cell sorting (FACS) and RNA sequencing we identify distinct transcriptome profiles for these interneuron subtypes in the medial PFC. Chronic stress causes significant dysregulation of several key pathways, including sex specific differences in the SST interneuron profiles.

Project description:3 subtypes of cortical projection neurons were purified by fluorescence-activated cell sorting (FACS) at 4 different stages of development from mouse cortex. A detailed description of the data set is described in Arlotta, P et al (2005) and Molyneaux, BJ et al (2009). The hybridization cocktails used here were originally applied to the Affymetrix mouse 430A arrays and submitted as GEO accession number GSE2039. The same hybridization cocktails were then applied to the Affymetrix mouse 430 2.0 arrays, and those data are contained in this series. Experiment Overall Design: Three subtypes of cortical neurons were purified by FACS at multiple stages of mouse brain development. The neuron subtypes are: corticospinal motor neurons (CSMN), callosal projection neurons (CPN), and corticotectal projection neurons (CTPN). The stages of development included embryonic day 18 (E18), postnatal day 3 (P3), postnatal day 6 (P6), and postnatal day 14 (P14). CSMN and CPN were analyzed at all four stages, while CTPN were only analyzed at P14. The replicates included in the data set are all true biological replicates with independent sample collection for each.

Project description:The neocortex contains an unparalleled diversity of neuronal subtypes responsible for complex behavior. Each cortical neuron has distinct traits, which are developmentally acquired under the control of batteries of neuron subtype-specific and pan-neuronal genes. The cis-regulatory logic that orchestrates the coordinated regulation of each unique combination of genes is not known for any class of neurons of the neocortex. We report that Fezf2, a transcription factor able to induce defining features of corticospinal motor neurons (CSMN), associates with the proximal promoters and regulates expression of series of CSMN signature genes. Fezf2 targets are functionally relevant as demonstrated by the finding that Fezf2 governs expression of the axon guidance receptor EphB1 to execute the ipsilateral extension of the corticospinal tract. Our data indicate that co-regulated expression of neuron subtype-specific gene batteries by a common transcription factor is one component of the regulatory logic responsible for the establishment of CSMN identity.

Project description:Many studies have been launched to investigate cellular and molecular regulation regarding human neural system development, yet there is hardly any regional characterization on the whole developmental human cerebral cortex. We found that inhibitory neuron subtypes possibly originated from MGE and CGE. The molecular regulation of excitatory neuron maturation in vivo showed differences to that in rodent. Different regions appeared to have distinct cell type diversities with pons proceeding to show astrocyte explosion. Generally neurons of the same subtype were more uniform in gene expression inside each region except for those in parietal lobe.

Project description:To explore the molecular basis of the distinct intrinsic membrane properties and other dstinguishing features of functionally defined DRG neuron subtypes, we bulk-sequenced RNA at high depth of genetically-labeled DRG neurons to generate transcriptome profiles of eight major DRG neuron subtypes. The trancriptome profiles revealed differentially expressed and functionally relevant genes, including voltage-gated ion channels. Guided by the transcriptome pofiles, electrophysiological analyses using pharmacological and genetic manipulations as well as computational modeling of DRG neuron subtypes were undertaken to assess the functions of select voltage-gated potassium channels (Kv1, Kv2, Kv3, and Kv4) in shaping action potential (AP) waveforms and firing patterns of the DRG neuron subtypes. Our findings show that the transcriptome profiles have predictive value for defining ion channel contributions to sensory neuron subtype-specific intrinsic physiological properties.

Project description:Abnormal development of the prefrontal cortex (PFC) is associated with a number of neuropsychiatric disorders that have an onset in childhood or adolescence. Although the basic laminar structure of the PFC is established in utero, extensive remodeling continues into adolescence. To map the overall pattern of changes in cortical gene transcripts during post-natal development, we made serial measurements of mRNA levels in mouse PFC using oligonucleotide microarrays. We observed changes in mRNA transcripts consistent with known post-natal morphological and biochemical events. Overall, most transcripts that changed significantly showed a progressive decrease in abundance after birth, with the majority of change between post-natal weeks 2 and 4. Genes with cell proliferative, cytoskeletal, extracellular matrix, plasma membrane lipid / transport, protein folding, and regulatory functions had decreases in mRNA levels. Quantitative PCR verified the microarray results for six selected genes: DNA methyltransferase 3A (Dnmt3a), procollagen, type III, alpha 1 (Col3a1), solute carrier family 16 (monocarboxylic acid transporters), member 1 (Slc16a1), MARCKS-like 1 (Marcksl1), nidogen 1 (Nid1) and 3-hydroxybutyrate dehydrogenase (heart, mitochondrial) (Bdh). Keywords: time course, development, mRNA expression Single-channel affymetrix arrays were used to profile mRNA expression in the prefrontal cortex (PFC) of male mice at different time-points after birth (post-natal). Each array is an independent animal.

Project description:Microglia are the resident immune cells of the brain, and have critical roles in circuit development and plasticity. During embryonic and postnatal development, microglia exist in multiple transcriptional states. However, it is still poorly understood how these states are established, and whether they are influenced by their cellular environment. Here we show that in the juvenile neocortex, microglia exist in multiple states whose identity and laminar distribution is instructed by the neuronal class identity of local pyramidal neurons. Using single-cell RNA sequencing, we unveil molecular signatures of distinct microglia sub-states, and show that they can be divided into layer-restricted or broadly-distributed states. Strikingly, conversion of deep-layer pyramidal neurons to an alternate class identity reconfigures both the density and molecular state of local layer-restricted microglia to correspond to the new neuronal niche, thus identifying specific populations of microglia that are sensitive to pyramidal neuron subtypes. Ligand-receptor interactomes for individual neuronal subtype-microglia pairings uncovers two categories of neuron-to-microglia communication: one associated with neuronal class identity and one associated with microglial state. Our findings highlight the fundamental role that neuronal identity and neuronal niches play in locally controlling the transcriptional status of postnatal microglia.