Project description:Sensory experience refines neural circuits during critical periods of postnatal development. Although neuronal activity is known to orchestrate the circuit wiring that underlies this process, the environmental cues that restrain developmental plasticity as animals mature are less clear. Here, we examine the experience-dependent maturation of the mouse primary visual cortex (V1) across postnatal development using paired single-cell transcriptomic and chromatin accessibility sequencing. In addition to identifying the activity-dependent gene programs that emerge within each cortical cell type, we find that light exposure drives astrocyte maturation through cell type-specific recruitment of the glucocorticoid receptor (Nr3c1/GR) to chromatin. Astrocyte GR signaling activates an extensive gene regulatory program that is partially conserved in human brain development and promotes maturation processes that may trigger critical period closure. Collectively, these findings reveal that astrocyte GR signaling restricts neuronal plasticity. ​​Glucocorticoid regulation of astrocyte maturation may also contribute to the effects of early-life stress across the brain, and the disruption of this process may increase susceptibility to neuropsychiatric disease.

Project description:Sensory experience refines neural circuits during critical periods of postnatal development. Although neuronal activity is known to orchestrate the circuit wiring that underlies this process, the environmental cues that restrain developmental plasticity as animals mature are less clear. Here, we examine the experience-dependent maturation of the mouse primary visual cortex (V1) across postnatal development using paired single-cell transcriptomic and chromatin accessibility sequencing. In addition to identifying the activity-dependent gene programs that emerge within each cortical cell type, we find that light exposure drives astrocyte maturation through cell type-specific recruitment of the glucocorticoid receptor (Nr3c1/GR) to chromatin. Astrocyte GR signaling activates an extensive gene regulatory program that is partially conserved in human brain development and promotes maturation processes that may trigger critical period closure. Collectively, these findings reveal that astrocyte GR signaling restricts neuronal plasticity. ​​Glucocorticoid regulation of astrocyte maturation may also contribute to the effects of early-life stress across the brain, and the disruption of this process may increase susceptibility to neuropsychiatric disease.

Project description:Sensory experience refines neural circuits during critical periods of postnatal development. Although neuronal activity is known to orchestrate the circuit wiring that underlies this process, the environmental cues that restrain developmental plasticity as animals mature are less clear. Here, we examine the experience-dependent maturation of the mouse primary visual cortex (V1) across postnatal development using paired single-cell transcriptomic and chromatin accessibility sequencing. In addition to identifying the activity-dependent gene programs that emerge within each cortical cell type, we find that light exposure drives astrocyte maturation through cell type-specific recruitment of the glucocorticoid receptor (Nr3c1/GR) to chromatin. Astrocyte GR signaling activates an extensive gene regulatory program that is partially conserved in human brain development and promotes maturation processes that may trigger critical period closure. Collectively, these findings reveal that astrocyte GR signaling restricts neuronal plasticity. ​​Glucocorticoid regulation of astrocyte maturation may also contribute to the effects of early-life stress across the brain, and the disruption of this process may increase susceptibility to neuropsychiatric disease.

Project description:Sensory experience refines neural circuits during critical periods of postnatal development. Although neuronal activity is known to orchestrate the circuit wiring that underlies this process, the environmental cues that restrain developmental plasticity as animals mature are less clear. Here, we examine the experience-dependent maturation of the mouse primary visual cortex (V1) across postnatal development using paired single-cell transcriptomic and chromatin accessibility sequencing. In addition to identifying the activity-dependent gene programs that emerge within each cortical cell type, we find that light exposure drives astrocyte maturation through cell type-specific recruitment of the glucocorticoid receptor (Nr3c1/GR) to chromatin. Astrocyte GR signaling activates an extensive gene regulatory program that is partially conserved in human brain development and promotes maturation processes that may trigger critical period closure. Collectively, these findings reveal that astrocyte GR signaling restricts neuronal plasticity. ​​Glucocorticoid regulation of astrocyte maturation may also contribute to the effects of early-life stress across the brain, and the disruption of this process may increase susceptibility to neuropsychiatric disease.

Project description:Astrocyte glucocorticoid receptor signaling restricts neuronal plasticity

Project description:Mouse whisker somatosensory cortex (wS1) is a major model system to study the experience-dependent plasticity of cortical neuron physiology, morphology, and sensory coding. However, the role of sensory experience in regulating neuronal cell type development and gene expression in wS1 remains poorly understood. We assembled and annotated a transcriptomic atlas of wS1 during postnatal development comprising 45 molecularly distinct neuronal types that can be grouped into eight subclasses of excitatory neurons and four subclasses of inhibitory neurons. Using this atlas, we examined the influence of whisker experience between postnatal day (P) 12, the onset of active whisking, to P22, on the maturation of molecularly distinct cell types. During this developmental period, when whisker experience was normal, ~250 genes were regulated in a neuronal subclass-specific fashion. At the resolution of neuronal types, we found that only the composition of layer (L) 2/3 glutamatergic neuronal types, but not other neuronal types, changed substantially between P12 and P22. These compositional changes resemble those observed previously in the primary visual cortex (V1), and the temporal gene expression changes were also highly conserved between the two regions. In contrast to V1, however, cell type maturation in wS1 is likely independent of sensory experience, as 10-day full-face whisker deprivation had no influence on the transcriptomic identity and composition of L2/3 neuronal types. A one-day competitive whisker deprivation protocol also did not affect cell type identity but induced moderate changes in plasticity-related gene expression. Thus, developmental maturation of cell types is similar in V1 and wS1, but sensory deprivation has a minimal effect on cell type development in wS1.

Project description:ARGLU1 is a Transcriptional Coactivator and Splicing Regulator Important for Stress Hormone Signaling and Development Stress hormones bind and activate the glucocorticoid receptor (GR) in many tissues including the brain. We identified arginine and glutamate rich 1 (ARGLU1) in a screen for new modulators of glucocorticoid signaling in the CNS. Biochemical studies show that the glutamate rich C-terminus of ARGLU1 coactivates multiple nuclear receptors including the glucocorticoid receptor (GR) and the arginine rich N-terminus interacts with splicing factors and binds to RNA. RNA-seq of neuronal cells depleted of ARGLU1 revealed significant changes in the expression and alternative splicing of distinct genes involved in neurogenesis. Loss of ARGLU1 is embryonic lethal in mice, and knockdown in zebrafish causes neurodevelopmental and heart defects. Treatment with dexamethasone, a GR activator, also induces changes in the pattern of alternatively spliced genes, many of which were lost when ARGLU1 was absent. Importantly, the genes found to be alternatively spliced in response to glucocorticoid treatment were distinct from those under transcriptional control by GR, suggesting an additional mechanism of glucocorticoid action is present in neuronal cells. Our results thus show that ARGLU1 is a novel factor for embryonic development that modulates basal transcription and alternative splicing in neuronal cells with consequences for glucocorticoid signaling.

Project description:ARGLU1 is a Transcriptional Coactivator and Splicing Regulator Important for Stress Hormone Signaling and Development Stress hormones bind and activate the glucocorticoid receptor (GR) in many tissues including the brain. We identified arginine and glutamate rich 1 (ARGLU1) in a screen for new modulators of glucocorticoid signaling in the CNS. Biochemical studies show that the glutamate rich C-terminus of ARGLU1 coactivates multiple nuclear receptors including the glucocorticoid receptor (GR) and the arginine rich N-terminus interacts with splicing factors and binds to RNA. RNA-seq of neuronal cells depleted of ARGLU1 revealed significant changes in the expression and alternative splicing of distinct genes involved in neurogenesis. Loss of ARGLU1 is embryonic lethal in mice, and knockdown in zebrafish causes neurodevelopmental and heart defects. Treatment with dexamethasone, a GR activator, also induces changes in the pattern of alternatively spliced genes, many of which were lost when ARGLU1 was absent. Importantly, the genes found to be alternatively spliced in response to glucocorticoid treatment were distinct from those under transcriptional control by GR, suggesting an additional mechanism of glucocorticoid action is present in neuronal cells. Our results thus show that ARGLU1 is a novel factor for embryonic development that modulates basal transcription and alternative splicing in neuronal cells with consequences for glucocorticoid signaling.

Project description:To investigate the role of the glucocorticoid receptor (GR) in the regulation of cardiomyocyte maturation and proliferation, we established a cardiomyocyte-specific GR knock-out (GR-cKO) mouse model by Cre-Lox technology. We thus performed gene expression profiling analysis using data obtained from RNA-seq of the cardiac tissue of GR-cKO and control mouse models extracted during the early postnatal development. Our analyses unveiled a role for GR in regulating gene networks related to the energetic metabolism, which in turn may impact on cardiomyocyte proliferative and regenerative ability.

Project description:Astrocyte glucocorticoid receptor signaling restricts neuronal plasticity [ATAC-seq]