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: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.

Project description:Pancreatic beta cells (β-cells) differentiate during fetal life, but only postnatally acquire the capacity for glucose-stimulated insulin secretion (GSIS). The molecular mechanisms driving this maturation of β-cell function remain incompletely understood. Here, we show that the control of cellular signaling in β-cells fundamentally switches from the nutrient sensor target of rapamycin (mTORC1) to the energy sensor 5'-adenosine monophosphate-activated protein kinase (AMPK), and that this is critical for functional maturation. Moreover, AMPK is activated by the dietary transition taking place during weaning, and this in turn inhibits mTORC1 activity to drive the adult β-cell phenotype. While forcing constitutive mTORC1 signaling in adult β-cells relegates them to a functionally immature phenotype with characteristic transcriptional and metabolic profiles, engineering the switch from mTORC1 to AMPK signaling is sufficient to promote β-cell mitochondrial biogenesis, a shift to oxidative metabolism, and functional maturation. We also show that type 2 diabetes, a condition marked by both mitochondrial degeneration and dysregulated GSIS, is associated with a remarkable reversion of the normal AMPK-dependent adult β-cell signature to a more neonatal one characterized by mTORC1 activation. Manipulating the way in which cellular nutrient signaling pathways regulate β-cell metabolism may thus offer new targets to improve β-cell function in diabetes.

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:DNA methylation is a major epigenetic factor regulating genome reprogramming, cell differentiation, developmental gene expression. To understand the role DNA methylation in CNS neurons, we generated conditional Dnmt1 mutant mice that possess ~90% hypomethylated cortical and hippocampal cells in the dorsal forebrain from E13.5 on. The mutant mice were viable with a normal lifespan, but displayed severe neuronal cell death between E14.5 to 3-weeks postnatally. Accompanied with the striking cortical and hippocampal degeneration, adult mutant mice exhibited neurobehavioral defects in learning and memory in adulthood. Unexpectedly, a fraction of Dnmt1-/- cortical neurons survived through postnatal development, so that the residual cortex in mutant mice contained 20-30% of hypomethylated neurons throughout the life. Hypomethylated excitatory neurons exhibited multiple defects in postnatal maturation including abnormal dendritic arborization and impaired neuronal excitability. The mutant phenotypes are coupled with deregulation of those genes involved in neuronal layer-specification, cell death, and the function of ion channels. Our results suggest that DNA methylation, through its role in modulating neuronal gene expression, plays multiple roles in regulating cell survival, neuronal migration and maturation in the CNS. Experiment Overall Design: We compared gene expression patterns in Wildtype and DNA methylation deficient (Emx1-cre; Dnmt1 mutant) mouse dorsal cortex. We performed 3 replicates using different each individual mouse strain. The Sample GSM350992 table is the average log ratio for the 3 replicatesArrays were performed in triplicate.

Project description:Disease causal mechanism remains largely unknown for most Alzheimer’s disease (AD) genome-wide association studies (GWAS) risk loci, including the Clusterin (CLU) locus. Here, leveraging our approach to identify functional GWAS risk variants that show allele-specific open chromatin (ASoC), we nominated a putative AD causal SNP rs1532278 (T/C) of CLU that showed strong ASoC specifically in iPSC-derived excitatory neurons (iGlut). We found the AD protective allele T of rs1532278 elevated neuronal CLU and promoted neuron excitability. Transcriptomic analysis of iGlut (T/T vs. C/C) co-cultured with mouse astrocytes surprisingly showed allele T upregulated lipid synthesis and astrocytic lipid metabolism pathways. Further corroborative functional studies mechanistically tied allele T to CLU-facilitated neuron-glia lipid transfer and astrocytic lipid droplet (LD) formation. Interestingly, astrocytes with more LD were found to uptake less glutamate likely due to reactive oxygen species (ROS), which may contribute to CLU-promoted neuron excitability. Our study uncovered a previously unappreciated protective role of neuronal CLU in maintaining proper neuronal excitability through lipid-mediated neuron-glia communication.

Project description:Astrocytes regulate the functional maturation of neurons by providing trophic support, regulating membrane properties and coordinating synapse formation. However, it is unclear to what degree astrocytes use activity-dependent mechanisms in these intercellular signalling processes. Using an induced pluripotent stem cell system and long-term optogenetic stimulation of human astrocytes, we reveal that activity-dependent astrocytic signals enhance the functional maturation of human cortical neurons, through increases in synaptic connectivity and excitability. Transcriptomic analyses determine that this involves the activity-dependent up-regulation of cholesterol synthesis – a process ascribed to astrocytes, which regulates neuronal maturation. Up-regulated astrocyte genes encode enzymes and transcription factors that control the levels of cholesterol synthesis. Biochemical assays confirm an activity-dependent upregulation of cholesterol synthesis in astrocytes, which is required for the maturational effects upon neurons. Thus, we reveal a novel mechanism that may dynamically match astrocyte function to neuronal needs, and identify targets for modulating cholesterol synthesis in the CNS.

Project description:Human neurons engineered from induced pluripotent stem cells (iPSCs) through Neurogenin 2 (Ngn2) overexpression are widely used to study neuronal differentiation mechanisms and to model neurological diseases. However, the differentiation paths and heterogeneity of emerged neurons have not been fully explored. Here we used single-cell transcriptomics to dissect the cell states that emerge during Ngn2 overexpression across a time course from pluripotency to neuron functional maturation. We find a substantial molecular heterogeneity in the neuron types generated, with at least two populations that express genes associated with neurons of the peripheral nervous system. Neuron heterogeneity is observed across multiple iPSC clones and lines from different individuals. We find that neuron fate acquisition is sensitive to Ngn2 expression level and the duration of Ngn2 forced expression. Our data reveals that Ngn2 dosage can regulate neuron fate acquisition, and that Ngn2-iN heterogeneity can confound results that are sensitive to neuron type.