Project description:Asymmetric neuronal expansion is thought to drive evolutionary transitions from lissencephalic to gyrencephalic cerebral cortices. We report that Neurog2 and Ascl1 proneural genes interact to sustain neurogenic continuity and lissencephaly in rodents. Using transgenic reporter mice and human cerebral organoids, we found that Neurog2 and Ascl1 expression defines a continuum of four lineage-biased neural progenitor cell (NPC) pools. Double+ NPCs, at the hierarchical apex, are least lineage-restricted due to Neurog2-Ascl1 cross-repression, and display unique features of multipotency (more open chromatin, complex gene regulatory network, G2 pausing). Strikingly, selective killing of double+ NPCs using Neurog2-Ascl1 split-Cre mice and three ‘deletor’ strains breaks neurogenic symmetry by locally disrupting Notch signaling, leading to cortical folding. Consistent with proneural genes driving discontinuous neurogenesis and folding via Notch, NEUROG2, ASCL1 and HES1 transcripts are modular in gyrencephalic macaque cortices. Neurog2/Ascl1 double+ NPCs are thus Notch-ligand expressing ‘niche’ cells that control neurogenic periodicity and cortical gyrification.

Project description:The neocortex is comprised of six neuronal layers that are derived in an inside-out sequence. Neurog2, a proneural gene encoding a basic-helix-loop-helix transcription factor, is required and sufficient to specify the fate of only early-born, deep-layer neurons, despite being expressed throughout the cortical neurogenic period. To identify potential inhibitors of Neurog2 function, we used a TAP-tagging screen, identifying L3mbtl3, a histone methyl-lysine binding protein that interacts with Rnf2 in Polycomb Repressive Complex 1 (PRC1), as a novel Neurog2 interactor. We found that L3mbtl3 is co-expressed with Neurog2 and other PRC1 genes in cortical progenitors. In L3mbtl3 knock-out (KO) cortices, upper-layer neurons are generated in reduced numbers, and instead, the cortical progenitor pool is expanded. Transcriptomic analyses of L3mbtl3 KO cortices at early and mid neurogenesis revealed a striking upregulation of negative regulators of transcription, including Rest, a repressor of many neurogenic genes, and an associated downregulation of neuronal differentiation and maturation genes. Notably, transcriptomic changes occur in the absence of any changes to chromatin structure, suggesting that L3mbtl3 influences gene transcription directly and not via changes to the chromatin. Instead, L3mbtl3 represses Neurog2 transcriptional activity in vitro and blocks cortical progenitor cell maturation and neuronal migration in vivo by altering the expression of scaffold genes. L3mbtl3 is thus an essential negative regulator of cortical neurogenesis.

Project description:The neocortex is comprised of six neuronal layers that are derived in an inside-out sequence. Neurog2, a proneural gene encoding a basic-helix-loop-helix transcription factor, is required and sufficient to specify the fate of only early-born, deep-layer neurons, despite being expressed throughout the cortical neurogenic period. To identify potential inhibitors of Neurog2 function, we used a TAP-tagging screen, identifying L3mbtl3, a histone methyl-lysine binding protein that interacts with Rnf2 in Polycomb Repressive Complex 1 (PRC1), as a novel Neurog2 interactor. We found that L3mbtl3 is co-expressed with Neurog2 and other PRC1 genes in cortical progenitors. In L3mbtl3 knock-out (KO) cortices, upper-layer neurons are generated in reduced numbers, and instead, the cortical progenitor pool is expanded. Transcriptomic analyses of L3mbtl3 KO cortices at early and mid neurogenesis revealed a striking upregulation of negative regulators of transcription, including Rest, a repressor of many neurogenic genes, and an associated downregulation of neuronal differentiation and maturation genes. Notably, transcriptomic changes occur in the absence of any changes to chromatin structure, suggesting that L3mbtl3 influences gene transcription directly and not via changes to the chromatin. Instead, L3mbtl3 represses Neurog2 transcriptional activity in vitro and blocks cortical progenitor cell maturation and neuronal migration in vivo by altering the expression of scaffold genes. L3mbtl3 is thus an essential negative regulator of cortical neurogenesis.

Project description:Reprogramming offers the possibility to study cell fate acquisitions otherwise difficult to address in vivo. By monitoring the dynamics of gene expression during direct reprogramming of astrocytes into different neuronal subtypes via the activation of Neurog2 and Ascl1, we demonstrate that these proneural factors control largely different neurogenic programs. Among the cascades induced, however, we identified a common subset of transcription factors required for both Neurog2- and Ascl1-induced reprogramming, and combinations of these factors comprising NeuroD4 were sufficient to generate functional neurons. Notably, during astrocyte maturation REST prevents Neurog2 from binding to the NeuroD4 locus that becomes then enriched with histone H4 lysine 20 tri-methylation. As combinations of downstream targets are sufficient to induce reprogramming in Neurog2-resistant cultures, our data support a model of a temporal hierarchy in shutting off alternative fate in astrocyte differentiation.

Project description:Basic helix-loop-helix (bHLH) proneural transcription factors (TFs) Ascl1 and Neurog2 are integral to the development of the nervous system. Here, we investigated the molecular mechanisms by which Ascl1 and Neurog2 control the acquisition of generic neuronal fate and impose neuronal subtype identity. Using direct neuronal programming of embryonic stem cells, we found that Ascl1 and Neurog2 regulate distinct targets by binding to largely different sets of sites. Their divergent binding pattern is not determined by the previous chromatin state but distinguished by specific E-box enrichments which reflect the DNA sequence preference of the bHLH domain. The divergent Ascl1 and Neurog2 binding patterns result in distinct chromatin accessibility and enhancer activity landscapes that shape the binding and activity of downstream TFs during neuronal specification. Our findings suggest that proneural factors contribute to neuronal diversity by differentially altering the chromatin landscapes that shape the binding of neuronally expressed TFs.

Project description:Basic helix-loop-helix (bHLH) proneural transcription factors (TFs) Ascl1 and Neurog2 are integral to the development of the nervous system. Here, we investigated the molecular mechanisms by which Ascl1 and Neurog2 control the acquisition of generic neuronal fate and impose neuronal subtype identity. Using direct neuronal programming of embryonic stem cells, we found that Ascl1 and Neurog2 regulate distinct targets by binding to largely different sets of sites. Their divergent binding pattern is not determined by the previous chromatin state but distinguished by specific E-box enrichments which reflect the DNA sequence preference of the bHLH domain. The divergent Ascl1 and Neurog2 binding patterns result in distinct chromatin accessibility and enhancer activity landscapes that shape the binding and activity of downstream TFs during neuronal specification. Our findings suggest that proneural factors contribute to neuronal diversity by differentially altering the chromatin landscapes that shape the binding of neuronally expressed TFs.

Project description:Basic helix-loop-helix (bHLH) proneural transcription factors (TFs) Ascl1 and Neurog2 are integral to the development of the nervous system. Here, we investigated the molecular mechanisms by which Ascl1 and Neurog2 control the acquisition of generic neuronal fate and impose neuronal subtype identity. Using direct neuronal programming of embryonic stem cells, we found that Ascl1 and Neurog2 regulate distinct targets by binding to largely different sets of sites. Their divergent binding pattern is not determined by the previous chromatin state but distinguished by specific E-box enrichments which reflect the DNA sequence preference of the bHLH domain. The divergent Ascl1 and Neurog2 binding patterns result in distinct chromatin accessibility and enhancer activity landscapes that shape the binding and activity of downstream TFs during neuronal specification. Our findings suggest that proneural factors contribute to neuronal diversity by differentially altering the chromatin landscapes that shape the binding of neuronally expressed TFs.

Project description:Basic helix-loop-helix (bHLH) proneural transcription factors (TFs) Ascl1 and Neurog2 are integral to the development of the nervous system. Here, we investigated the molecular mechanisms by which Ascl1 and Neurog2 control the acquisition of generic neuronal fate and impose neuronal subtype identity. Using direct neuronal programming of embryonic stem cells, we found that Ascl1 and Neurog2 regulate distinct targets by binding to largely different sets of sites. Their divergent binding pattern is not determined by the previous chromatin state but distinguished by specific E-box enrichments which reflect the DNA sequence preference of the bHLH domain. The divergent Ascl1 and Neurog2 binding patterns result in distinct chromatin accessibility and enhancer activity landscapes that shape the binding and activity of downstream TFs during neuronal specification. Our findings suggest that proneural factors contribute to neuronal diversity by differentially altering the chromatin landscapes that shape the binding of neuronally expressed TFs.

Project description:In this study we examined brain gyration using the pig brain as model. Pig cortical tissue from two time points in development representing a non-folded, lissencephalic, brain (embryonic day 60) and primary-folded, gyrencephalic, brain (embryonic day 80) were examined by whole genome expression microarray studies. Experiment Overall Design: 3 samples from 3 litters mates representing the two time points E60 and E80 of the porcine gestation period

Project description:In this study we examined brain gyration using the pig brain as model. Pig cortical tissue from two time points in development representing a non-folded, lissencephalic, brain (embryonic day 60) and primary-folded, gyrencephalic, brain (embryonic day 80) were examined by whole genome expression microarray studies.