Callosal projection neurons (CPN) are a diverse population of neocortical projection neurons that connect the two hemispheres of the cerebral cortex via the corpus callosum. They play key roles in high-level associative connectivity, and have been implicated in cognitive syndromes of high-level associative dysfunction, such as autism spectrum disorders. CPN evolved relatively recently compared to other cortical neuron populations, and have undergone disproportionately large expansion from mouse to human. While much is known about the anatomical trajectory of developing CPN axons, and progress has been made in identifying cellular and molecular controls over midline crossing, only recently have molecular-genetic controls been identified that specify CPN populations, and help define CPN subpopulations. In this review, we discuss development, diversity, and evolution of CPN.
Little is known about the molecular development and heterogeneity of callosal projection neurons (CPN), cortical commissural neurons that connect homotopic regions of the two cerebral hemispheres via the corpus callosum and that are critical for bilateral integration of cortical information. Here we report on the identification of a series of genes that individually and in combination define CPN and novel CPN subpopulations during embryonic and postnatal development. We used in situ hybridization analysis, immunocytochemistry, and retrograde labeling to define the layer-specific and neuron-type-specific distribution of these newly identified CPN genes across different stages of maturation. We demonstrate that a subset of these genes (e.g., Hspb3 and Lpl) appear specific to all CPN (in layers II/III and V-VI), whereas others (e.g., Nectin-3, Plexin-D1, and Dkk3) discriminate between CPN of the deep layers and those of the upper layers. Furthermore, the data show that several genes finely subdivide CPN within individual layers and appear to label CPN subpopulations that have not been described previously using anatomical or morphological criteria. The genes identified here likely reflect the existence of distinct programs of gene expression governing the development, maturation, and function of the newly identified subpopulations of CPN. Together, these data define the first set of genes that identify and molecularly subcategorize distinct populations of callosal projection neurons, often located in distinct subdivisions of the canonical cortical laminae.
The deacetylation of histone proteins, catalyzed by histone deacetylases (HDACs), is a common epigenetic modification of chromatin, associated with gene silencing. Although HDAC inhibitors are used clinically to treat nervous system disorders, such as epilepsy, very little is known about the expression pattern of the HDACs in the central nervous system. Identifying the cell types and developmental stages that express HDAC1 and HDAC2 within the brain is important for determining the therapeutic mode of action of HDAC inhibitors, and evaluating potential side effects. Here, we examined the expression of HDAC1 and HDAC2 in the murine brain at multiple developmental ages. HDAC1 is expressed in neural stem cells/progenitors and glia. In contrast, HDAC2 is initiated in neural progenitors and is up-regulated in post-mitotic neuroblasts and neurons, but not in fully differentiated glia. These results identify key developmental stages of HDAC expression and suggest transitions of neural development that may utilize HDAC1 and/or HDAC2.
Frontotemporal lobar degeneration (FTLD) is a neurodegenerative condition characterized by focal degeneration of the frontal and temporal lobes of the brain. Autosomal dominantly inherited mutations of the progranulin gene (GRN) have been identified as the cause of a subset of cases of familial FTLD. In order to better understand the function of progranulin in the central nervous system (CNS), we have assessed the spatiotemporal expression pattern of both the murine progranulin gene (Grn) and the protein (Grn) by using transgenic knock-in mice expressing a reporter gene from the Grn locus and by immunohistochemistry, respectively. We compared Grn expression with a panel of established markers for distinct neuronal developmental stages and specific cell lineages at time points ranging from embryonic day 13.5 through to the mature adult. We find that Grn is expressed in both neurons and microglia within the CNS, but that it shows a different developmental expression pattern in each cell type. Grn expression in neurons increases as the cells mature, whereas expression in microglia varies with the cells' state of activation, being specifically upregulated in microglia in response to excitotoxic injury. Our results suggest that progranulin plays distinct roles in neurons and microglia, both of which likely contribute to overall neuronal health and function.
Mutations in the transcriptional regulator Mecp2 cause the severe X-linked neurodevelopmental disorder Rett syndrome (RTT). In this study, we investigate genes that function downstream of MeCP2 in cerebral cortex circuitry, and identify upregulation of Irak1, a central component of the NF-κB pathway. We show that overexpression of Irak1 mimics the reduced dendritic complexity of Mecp2-null cortical callosal projection neurons (CPN), and that NF-κB signalling is upregulated in the cortex with Mecp2 loss-of-function. Strikingly, we find that genetically reducing NF-κB signalling in Mecp2-null mice not only ameliorates CPN dendritic complexity but also substantially extends their normally shortened lifespan, indicating broader roles for NF-κB signalling in RTT pathogenesis. These results provide new insight into both the fundamental neurobiology of RTT, and potential therapeutic strategies via NF-κB pathway modulation.
DNA methylation-dependent gene silencing, mediated by DNA methyltransferases (DNMTs), is essential for normal mammalian development and its dysregulation has been implicated in neurodevelopmental disorders. Despite this, little is known about DNMTs in the developing or mature nervous system. Here, we show that DNMT1, 3a and 3b are expressed at discrete developmental stages in the olfactory neuron lineage, coincident with key shifts in developmental gene expression. DNMT1 is induced in cycling progenitors and is retained in post-mitotic olfactory receptor neurons (ORNs). DNMT3b is restricted to mitotic olfactory progenitors, whereas DNMT3a is expressed only in post-mitotic immature neurons prior to ORN terminal maturation, coincident with histone deacetylase 2 (HDAC2), a key downstream effector of methylation-dependent chromatin condensation. Similar stage-specific expression of DNMT3b and 3a was also found in other developing sensory and CNS neurons. This suggests that progressive lineage restriction regulated by methylation-dependent silencing could be a highly conserved mechanism shared by multiple lineages in the developing nervous system.
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