Project description:Newborn neurons enter an extended maturation stage, during which they acquire excitability characteristics crucial for development of presynaptic and postsynaptic connectivity. In contrast to earlier specification programs, little is known aboutthe regulatory mechanisms that control neuronal maturation. The Pet-1 ETS (E26 transformation-specific) factor is continuously expressed in serotonin (5-HT) neurons and initially acts in postmitotic precursors to control acquisition of 5-HT transmitter identity. Using a combination of RNA sequencing, electrophysiology, and conditional targeting approaches, we determined gene expression patterns in maturing flow-sorted 5-HT neurons and the temporal requirements for Pet-1 in shaping these patterns for functional maturation of mouse 5-HT neurons. We report a profound disruption of postmitotic expression trajectories in Pet-1 / neurons, which prevented postnatal maturation of 5-HT neuron passive and active intrinsic membrane properties, G-protein signaling, and synaptic responses to glutamatergic, lysophosphatidic, and adrenergic agonists. Unexpectedly, conditional targeting revealed a postnatal stage-specific switch in Pet-1 targets from 5-HT synthesis genes to transmitter receptor genes required for afferent modulation of 5-HT neuron excitability. 5-HT1a autoreceptor expression depended transiently on Pet-1, thus revealing an early postnatal sensitive period for control of 5-HT excitability genes. Chromatin immunoprecipitation followed by sequencing revealed that Pet-1 regulates 5-HT neuron maturation through direct gene activation and repression. Moreover, Pet-1 directly regulates the 5-HT neuron maturation factor Engrailed 1, which suggests Pet-1 orchestrates maturationthrough secondary postmitotic regulatoryfactors. The early postnatal switch in Pet-1targets uncovers a distinct neonatal stage-specific function for Pet-1, during which it promotes maturation of 5-HT neuron excitability. 5-HT neuron mRNA profiles of E11.5, E15.5, and postnatal (P1-P3) wild type (WT) and Pet-1-/- mice were generated by deep sequencing, in triplicate, using Illumina HiSeq 2500. Myc-tagged Pet-1 ChIP-seq was performed on E12.5 to E14.5 hindbrains and sequencing using NextSeq 500.

Project description:Assembly of transcriptomes encoding unique neuronal identities requires selective accessibility of transcription factors to cis-regulatory sequences in nucleosome-embedded postmitotic chromatin. Yet, the mechanisms controlling postmitotic neuronal chromatin accessibility are poorly understood. Here, we show that unique distal enhancers define the Pet1 neuron lineage that generates serotonin (5-HT) neurons. Heterogeneous single cell chromatin landscapes are established early in postmitotic Pet1 neurons and reveal the putative regulatory programs driving Pet1 neuron subtype identities. Distal enhancer accessibility is highly dynamic as Pet1 neurons mature, suggesting the existence of regulatory factors that reorganize postmitotic neuronal chromatin. We find that Pet1 and Lmx1b control chromatin accessibility to select Pet1-lineage specific enhancers for 5-HT neurotransmission. Additionally, these factors are required to maintain chromatin accessibility during early maturation suggesting that postmitotic neuronal open chromatin is unstable and requires continuous regulatory input. Together our findings reveal postmitotic transcription factors that reorganize accessible chromatin for neuron specialization.

Project description:Pet-1 Switches Transcriptional Targets Postnatally to Regulate Maturation of Serotonin Neuron Excitability.

Project description:Electrical excitability—the ability to fire and propagate action potentials—is a signature feature of neurons. How neurons become excitable during development and whether excitability is an intrinsic property of neurons or requires signaling from glial cells remain unclear. Here, we demonstrate that Schwann cells, the most abundant glia in the peripheral nervous system, promote somatosensory neuron excitability during development. We find that Schwann cells secrete prostaglandin E2, which is necessary and sufficient to induce developing somatosensory neurons to express normal levels of genes required for neuronal function, including voltage gated sodium channels, and to fire action potential trains. In this scRNAseq study, we found that inactivating PGE2 synthesis in Schwann cells in vivo impaired somatosensory neuron maturation, with the most dramatic effects on nociceptor and proprioceptor somatosensory neuron subtypes.

Project description:Electrical excitability—the ability to fire and propagate action potentials—is a signature feature of neurons. How neurons become excitable during development and whether excitability is an intrinsic property of neurons or requires signaling from glial cells remain unclear. Here, we demonstrate that Schwann cells, the most abundant glia in the peripheral nervous system, promote somatosensory neuron excitability during development. We find that Schwann cells secrete prostaglandin E2, which is necessary and sufficient to induce developing somatosensory neurons to express normal levels of genes required for neuronal function, including voltage gated sodium channels, and to fire action potential trains. In this scRNAseq study, we found that inactivating PGE2 synthesis in Schwann cells, in vivo, impaired somatosensory neuron maturation, with the most dramatic effects on nociceptor and proprioceptor somatosensory neuron subtypes.

Project description:Electrical excitability—the ability to fire and propagate action potentials—is a signature feature of neurons. How neurons become excitable during development and whether excitability is an intrinsic property of neurons or requires signaling from glial cells remain unclear. Here, we demonstrate that Schwann cells, the most abundant glia in the peripheral nervous system, promote somatosensory neuron excitability during development. We find that Schwann cells secrete prostaglandin E2, which is necessary and sufficient to induce developing somatosensory neurons to express normal levels of genes required for neuronal function, including voltage gated sodium channels, and to fire action potential trains. In this RNA-Seq study, we discovered that treating cultured DRG neurons with Schwann cell-conditioned media or PGE2 increased the expression of several genes required for neuronal maturation and excitability, including voltage-gated sodium channels.

Project description:The functional and transcriptional maturation of neurons is a prolonged process that extends well beyond mitotic exit and terminal fate commitment of progenitors. The differentiation of cerebellar granule neurons (CGNs) in the postnatal mouse cerebellum provides a useful model to identify chromatin mechanisms that orchestrate temporal changes in transcription as postmitotic CGNs mature. Here we report that CGN maturation is associated with dynamic changes in the genomic distribution of histone H3 lysine 27 trimethylation (H3K27me3), a modification best known for its role in repressing alternative fates during cell specification. H3K27me3 is gained rapidly in newly postmitotic CGNs at progenitor-expressed genes that are repressed in neurons. H3K27me3 is lost more gradually at the promoters of a subset of neuronal genes that are transcriptionally induced upon CGN maturation. The loss of H3K27me3 is facilitated by the lysine demethylase KDM6B, and genes that are induced in maturing CGNs show impaired expression in the cerebellum of conditional KDM6B knockout mice. Genes that lose H3K27me3 gain H3K27 acetylation and binding of the pro-maturation ZIC1/2 transcription factors, suggesting that developmental loss of H3K27me3 may be required to permit the onset of transcriptional maturation. Interestingly, pharmacological inhibition of the H3K27 methyltransferase EZH2 in early postmitotic CGNs not only blocked the repression of progenitor genes but also impaired the induction of mature CGN genes. These data show that regulation of H3K27me3 functions in developing postmitotic neurons beyond the period of cell fate commitment to regulate the dynamics of gene expression programs that underlie functional neuronal maturation.

Project description:The functional and transcriptional maturation of neurons is a prolonged process that extends well beyond mitotic exit and terminal fate commitment of progenitors. The differentiation of cerebellar granule neurons (CGNs) in the postnatal mouse cerebellum provides a useful model to identify chromatin mechanisms that orchestrate temporal changes in transcription as postmitotic CGNs mature. Here we report that CGN maturation is associated with dynamic changes in the genomic distribution of histone H3 lysine 27 trimethylation (H3K27me3), a modification best known for its role in repressing alternative fates during cell specification. H3K27me3 is gained rapidly in newly postmitotic CGNs at progenitor-expressed genes that are repressed in neurons. H3K27me3 is lost more gradually at the promoters of a subset of neuronal genes that are transcriptionally induced upon CGN maturation. The loss of H3K27me3 is facilitated by the lysine demethylase KDM6B, and genes that are induced in maturing CGNs show impaired expression in the cerebellum of conditional KDM6B knockout mice. Genes that lose H3K27me3 gain H3K27 acetylation and binding of the pro-maturation ZIC1/2 transcription factors, suggesting that developmental loss of H3K27me3 may be required to permit the onset of transcriptional maturation. Interestingly, pharmacological inhibition of the H3K27 methyltransferase EZH2 in early postmitotic CGNs not only blocked the repression of progenitor genes but also impaired the induction of mature CGN genes. These data show that regulation of H3K27me3 functions in developing postmitotic neurons beyond the period of cell fate commitment to regulate the dynamics of gene expression programs that underlie functional neuronal maturation.

Project description:The functional and transcriptional maturation of neurons is a prolonged process that extends well beyond mitotic exit and terminal fate commitment of progenitors. The differentiation of cerebellar granule neurons (CGNs) in the postnatal mouse cerebellum provides a useful model to identify chromatin mechanisms that orchestrate temporal changes in transcription as postmitotic CGNs mature. Here we report that CGN maturation is associated with dynamic changes in the genomic distribution of histone H3 lysine 27 trimethylation (H3K27me3), a modification best known for its role in repressing alternative fates during cell specification. H3K27me3 is gained rapidly in newly postmitotic CGNs at progenitor-expressed genes that are repressed in neurons. H3K27me3 is lost more gradually at the promoters of a subset of neuronal genes that are transcriptionally induced upon CGN maturation. The loss of H3K27me3 is facilitated by the lysine demethylase KDM6B, and genes that are induced in maturing CGNs show impaired expression in the cerebellum of conditional KDM6B knockout mice. Genes that lose H3K27me3 gain H3K27 acetylation and binding of the pro-maturation ZIC1/2 transcription factors, suggesting that developmental loss of H3K27me3 may be required to permit the onset of transcriptional maturation. Interestingly, pharmacological inhibition of the H3K27 methyltransferase EZH2 in early postmitotic CGNs not only blocked the repression of progenitor genes but also impaired the induction of mature CGN genes. These data show that regulation of H3K27me3 functions in developing postmitotic neurons beyond the period of cell fate commitment to regulate the dynamics of gene expression programs that underlie functional neuronal maturation.

Project description:The functional and transcriptional maturation of neurons is a prolonged process that extends well beyond mitotic exit and terminal fate commitment of progenitors. The differentiation of cerebellar granule neurons (CGNs) in the postnatal mouse cerebellum provides a useful model to identify chromatin mechanisms that orchestrate temporal changes in transcription as postmitotic CGNs mature. Here we report that CGN maturation is associated with dynamic changes in the genomic distribution of histone H3 lysine 27 trimethylation (H3K27me3), a modification best known for its role in repressing alternative fates during cell specification. H3K27me3 is gained rapidly in newly postmitotic CGNs at progenitor-expressed genes that are repressed in neurons. H3K27me3 is lost more gradually at the promoters of a subset of neuronal genes that are transcriptionally induced upon CGN maturation. The loss of H3K27me3 is facilitated by the lysine demethylase KDM6B, and genes that are induced in maturing CGNs show impaired expression in the cerebellum of conditional KDM6B knockout mice. Genes that lose H3K27me3 gain H3K27 acetylation and binding of the pro-maturation ZIC1/2 transcription factors, suggesting that developmental loss of H3K27me3 may be required to permit the onset of transcriptional maturation. Interestingly, pharmacological inhibition of the H3K27 methyltransferase EZH2 in early postmitotic CGNs not only blocked the repression of progenitor genes but also impaired the induction of mature CGN genes. These data show that regulation of H3K27me3 functions in developing postmitotic neurons beyond the period of cell fate commitment to regulate the dynamics of gene expression programs that underlie functional neuronal maturation.