Project description:Neural functions and circuit establishment are characterized by intricate crosstalk among multiple cell types during critical periods. Impeding or delaying the crosstalk results in abnormal neural functions and neurodevelopmental disorders. However, the lack of robust mouse models to study the crosstalk between astrocytes and neurons thus renders unclear the implications of impeding such interactions. Here we found that Egfr knockout led to the absence of astrocytes during the critical period of neuronal maturation, with recovery observed in adult mice, providing an exceptional opportunity to investigate the consequences of delaying crosstalk between astrocytes and neurons. We show that, in the absence of Egfr, glial progenitor cells are unable to migrate outwardly, exhibiting a rounded and smooth morphology. This phenomenon arises as a direct consequence of the impaired Egfr-pERK-Epb41l2 signaling axis, leading to delayed communication between astrocytes and neurons. This delay results in reduced neuronal dendritic complexity and decreased neuronal excitability (due to damage to the Sema6a-Plxna2/4 receptor pair between astrocytes and neurons during the critical period), ultimately leading to the manifestation of depressive-like behaviors in adult mice.

Project description:Neural differentiation of embryonic stem cells (ESCs) requires coordinated repression of the pluripotency regulatory programme and reciprocal activation of the neurogenic regulatory programme. Upon neural induction, ESCs rapidly repress expression of pluripotency genes followed by staged activation of neural progenitor and differentiated neuronal and glial genes. The transcriptional factors that underlie pluripotency are partially characterized, whereas those underlying neural induction are much less explored, and the factors that coordinate these two developmental programs are completely unknown. One transcription factor, REST (RE1 silencing transcription factor), has been linked with terminal differentiation of neural progenitors, and more recently and controversially, with control of pluripotency. Here, we show that in the absence of REST, coordination of pluripotency and neural induction is lost and there is a resultant delay in repression of pluripotency genes and a precocious activation of both neural progenitor and differentiated neuronal and glial genes. Further, we show that REST is not required for production of radial glia-like progenitors but is required for their subsequent maintenance and differentiation into neurons, oligodendrocytes and astrocytes. We propose that REST acts as a regulatory hub that coordinates timely repression of pluripotency with neural induction and neural differentiation. We have investigated the role of REST in the coupling of pluripotency and neural induction and neurogenesis using Rest-null mouse ESCs (mESCs) in conjunction with a novel mESC neural differentiation protocol. Differential expression between Rest-null ESCs and controls was tested using Illumina Mouse Ref-8 v2 BeadArray technology. Three replicates were used for Rest-null and three for control. Data analysis was performed using Bioconductor libraries beadarray and limma.

Project description:Neural differentiation of embryonic stem cells (ESCs) requires coordinated repression of the pluripotency regulatory programme and reciprocal activation of the neurogenic regulatory programme. Upon neural induction, ESCs rapidly repress expression of pluripotency genes followed by staged activation of neural progenitor and differentiated neuronal and glial genes. The transcriptional factors that underlie pluripotency are partially characterized, whereas those underlying neural induction are much less explored, and the factors that coordinate these two developmental programs are completely unknown. One transcription factor, REST (RE1 silencing transcription factor), has been linked with terminal differentiation of neural progenitors, and more recently and controversially, with control of pluripotency. Here, we show that in the absence of REST, coordination of pluripotency and neural induction is lost and there is a resultant delay in repression of pluripotency genes and a precocious activation of both neural progenitor and differentiated neuronal and glial genes. Further, we show that REST is not required for production of radial glia-like progenitors but is required for their subsequent maintenance and differentiation into neurons, oligodendrocytes and astrocytes. We propose that REST acts as a regulatory hub that coordinates timely repression of pluripotency with neural induction and neural differentiation.

Project description:One of the key regulatory mechanisms of brain size and neuronal diversity is through control of NB identity via cell fate maintenance. Dedifferentiation is the reversion of differentiated cells to a stem cell like fate, whereby, the gene expression program of mature cells is altered and genes associated with multipotency are expressed. Beyond the fact that misexpression of these factors and pathways caused the formation of ectopic NBs, whether these dedifferentiated NBs faithfully produce the correct number and types of neurons or glial cells, or undergo timely terminal differentiation, has not been assessed. These characteristics are key determinants of overall CNS size and function, thus are important parameters when considering whether dedifferentiation leads to tumourigenesis or can be appropriately utilized for regenerative purposes. Appropriate terminal differentiation as well as neuronal diversity are key characteristics of NSCs, and are specified through temporal patterning of the NSCs driven by the successive expression of temporal transcription factors (tTFs). In this study, we found that ectopic NSCs induced via bHLH transcription factor Deadpan (Dpn) expression in the optic lobes of the developing Drosophila CNS fail to undergo appropriate temporal progression, where they express mid-tTF, Sloppy-paired 1 (Slp-1) at the expense of late-tTF Tailless (Tll); consequently generating an excess of Twin of eyeless (Toy) positive neurons and fewer Reversed polarity (Repo) positive glial cells. Dpn overexpression also resulted in stalled progression through the cell cycle, and a failure to undergo timely terminal differentiation. Mechanistically, DamID studies demonstrated that Dpn directly binds to both Dichaete (D), a Sox-box transcription factor known to repress Slp-1, as well as a number of cell cycle genes. Promoting cell cycle progression or overexpression of D were able to re-trigger the progression of the temporal series in dedifferentiated NBs, restoring both neuronal diversity and timely NB terminal differentiation.

Project description:The proper function establishment of nervous system is characterized by closely crosstalk among multiple cell types during the critical periods. Impeding or delaying the crosstalk results in abnormal neural functions and neurodevelopmental disorders. However, the lack of robust mouse models to study the crosstalk between astrocytes and neurons thus renders unclear the implications of impeding such interactions. Here we found that Egfr knockout led to the absence of astrocytes during the critical period of neuronal maturation, with recovery observed in adult mice, providing an exceptional opportunity to investigate the consequences of delaying crosstalk between astrocytes and neurons. We show that glial progenitor cells exhibit a rounded and smooth morphology, displaying few or no protrusions, in the absence of Egfr, which stands in stark contrast to the multi-protrusion morphology observed in the control cells. This phenomenon arises as a direct consequence of the impaired Egfr-pERK-Epb41l2 signaling axis, leading to delayed crosstalk between astrocytes and neurons. This delay results in reduced neuronal dendritic complexity and decreased neuronal excitability (due to damage to the Sema6a-Plxna2/4 receptor pair between astrocytes and neurons during the critical period), ultimately leading to the manifestation of depressive-like behaviors in adult mice.

Project description:We examined whether a human neuronal culture system could be used to assess the transcriptional program involved in human neural differentiation and in modeling some of the molecular features of a neurodevelopmental disorder such as autism. Primary normal human neuronal progenitors differentiation for 0, 2, 4, or 8 weeks.

Project description:Neuronal synapse formation and remodeling is essential to central nervous system (CNS) development and is dysfunctional in neurodevelopmental diseases. Innate immune signals regulate tissue remodeling in the periphery, but how this impacts CNS synapses is largely unknown. Here we show that the IL-1 family cytokine Interleukin-33 (IL-33) is produced by developing astrocytes and is developmentally required for normal synapse numbers and neural circuit function in the spinal cord and thalamus. We find that IL-33 signals primarily to microglia under physiologic conditions, that it promotes microglial synapse engulfment, and that it can drive microglial-dependent synapse depletion in vivo. These data reveal a cytokine-mediated mechanism required to maintain synapse homeostasis during CNS development.

Project description:Neuronal synapse formation and remodeling is essential to central nervous system (CNS) development and is dysfunctional in neurodevelopmental diseases. Innate immune signals regulate tissue remodeling in the periphery, but how this impacts CNS synapses is largely unknown. Here we show that the IL-1 family cytokine Interleukin-33 (IL-33) is produced by developing astrocytes and is developmentally required for normal synapse numbers and neural circuit function in the spinal cord and thalamus. We find that IL-33 signals primarily to microglia under physiologic conditions, that it promotes microglial synapse engulfment, and that it can drive microglial-dependent synapse depletion in vivo. These data reveal a cytokine-mediated mechanism required to maintain synapse homeostasis during CNS development.

Project description:<p>Omega-3 fatty acids (n-3 polyunsaturated fatty acids; n-3 PUFAs) are essential for the functional maturation of the brain. Westernization of dietary habits in both developed and developing countries is accompanied by a progressive reduction in dietary intake of n-3 PUFAs. Low maternal intake of n-3 PUFAs has been linked to neurodevelopmental diseases in epidemiological studies, but the mechanisms by which a n-3 PUFA dietary imbalance affects CNS development are poorly understood. Active microglial engulfment of synaptic elements is an important process for normal brain development and altered synapse refinement is a hallmark of several neurodevelopmental disorders. Here, we identify a molecular mechanism for detrimental effects of low maternal n-3 PUFA intake on hippocampal development. Our results show that maternal dietary n-3 PUFA deficiency increases microglial phagocytosis of synaptic elements in the developing hippocampus, partly through the activation of 12/15- lipoxygenase (LOX)/12-HETE signaling, which alters neuronal morphology and affects cognition in the postnatal offspring. While women of child bearing age are at higher risk of dietary n-3 PUFA deficiency, these findings provide new insights into the mechanisms linking maternal nutrition to neurodevelopmental disorders.</p>

Project description:Gliogenesis in the Drosophila CNS occurs during embryogenesis and also during the postembryonic larval stages. Several glial subtypes are generated in the postembryonic CNS through the proliferation of differentiated glial cells. The genes and molecular pathways that regulate glial proliferation in the postembryonic CNS are poorly understood. In this study we aimed to use gene expressing profiling of CNS tissue enriched in glia to identify genes expressed in glial cells in the postembryonic CNS. We used microarrays to compare the gene expression profiles from the larval CNS of animals that had increased numbers of glial cells to identify genes that are expressed in glia. RNA was purified from the late third instar larval CNS from control larvae, or larvae expressing an activated form of the FGF receptor (Hlt[ACT]), or overexpressing the insulin receptor (InR) in glial cells using the glial specific driver repoGal4 to increase the number of glial cells and generate CNS tissue enriched in glia.