Project description:Neuronal development requires a complex choreography of transcriptional decisions to obtain specific cellular identities. Realizing the ultimate goal of identifying genome-wide signatures that define and drive specific neuronal fates has been hampered by enormous complexity in both time and space during development. Here, we have paired high-throughput purification of pyramidal neuron subclasses with deep profiling of spatiotemporal transcriptional dynamics during corticogenesis to resolve lineage choice decisions. We identified numerous features ranging from spatial and temporal usage of alternative mRNA isoforms and promoters to a host of mRNA genes modulated during fate specification. Notably, we uncovered numerous long non-coding RNAs with restricted temporal and cell type specific expression. To facilitate future exploration, we provide an interactive online database to enable multidimensional data mining and dissemination. This multi-faceted study generates a powerful resource and informs understanding of the transcriptional regulation underlying pyramidal neuron diversity in the neocortex.

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Project description:Interconnectivity between neocortical areas is critical for sensory integration and sensorimotor transformations. These functions are mediated by heterogeneous interareal cortical projection neurons (ICPN), which send axon branches to distinct cortical areas as well as to subcortical targets. Although ICPN are anatomically diverse, they are molecularly homogeneous and how the diversity of their anatomical and functional features emerge during development remains largely unknown. Here, we address this question by linking connectome and transcriptome in developing single ICPN of the mouse neocortex using a combination of MAPseq mapping (to identify single-neuron axonal projections) and single-cell RNA sequencing (to identify corresponding gene expression). Focusing on neurons of the primary somatosensory cortex (S1), we reveal a protracted unfolding of the molecular and functional differentiation of motor cortex-projecting (M) compared to secondary somatosensory cortex-projecting (S2) ICPN. We identify SOX11 as a temporally differentially expressed transcription factor in M vs. S2 ICPN. Postnatal manipulation of SOX11 expression level in S1 impaired sensorimotor connectivity and selectively disrupted exploratory behavior in freely moving mice. Together, our results reveal that within a single cortical area, different subtypes of ICPN have distinct postnatal molecular differentiation paces, which is then reflected in distinct circuit connectivities and functions. Dynamic differences in expression levels of largely generic set of genes, rather than fundamental differences in the identity of developmental genetic programs, may thus account for emergence of intra-type diversity in cortical neurons.

Project description:Interconnectivity between neocortical areas is critical for sensory integration and sensorimotor transformations. These functions are mediated by heterogeneous interareal cortical projection neurons (ICPN), which send axon branches to distinct cortical areas as well as to subcortical targets. Although ICPN are anatomically diverse, they are molecularly homogeneous and how the diversity of their anatomical and functional features emerge during development remains largely unknown. Here, we address this question by linking connectome and transcriptome in developing single ICPN of the mouse neocortex using a combination of MAPseq mapping (to identify single-neuron axonal projections) and single-cell RNA sequencing (to identify corresponding gene expression). Focusing on neurons of the primary somatosensory cortex (S1), we reveal a protracted unfolding of the molecular and functional differentiation of motor cortex-projecting (M) compared to secondary somatosensory cortex-projecting (S2) ICPN. We identify SOX11 as a temporally differentially expressed transcription factor in M vs. S2 ICPN. Postnatal manipulation of SOX11 expression level in S1 impaired sensorimotor connectivity and selectively disrupted exploratory behavior in freely moving mice. Together, our results reveal that within a single cortical area, different subtypes of ICPN have distinct postnatal molecular differentiation paces, which is then reflected in distinct circuit connectivities and functions. Dynamic differences in expression levels of largely generic set of genes, rather than fundamental differences in the identity of developmental genetic programs, may thus account for emergence of intra-type diversity in cortical neurons.