Project description:The Otx2 homeobox transcription factor is essential for gastrulation and early neural development. We generated Otx2 conditional knockout (cKO) mice to investigate its roles in telencephalon development after E9.0. We conducted transcriptional profiling and in situ hybridization to identify genes de-regulated in Otx2 cKO ventral forebrain. In parallel, we used ChIP-seq to identify enhancer elements, OTX2 binding motif, and which de-regulated genes are likely direct targets of Otx2 transcriptional regulation. We found that Otx2 was essential in septum specification; regulation of Fgf signaling in the rostral telencephalon; and medial ganglionic eminence (MGE) patterning, neurogenesis, and oligodendrogenesis. Within the MGE, Otx2 was required for ventral but not dorsal identity; this is the first demonstration of a transcription factor that contributes to regional patterning within the MGE. Microdissected subpallium (septum, MGE, and LGE ) from wildtype E12.5 CD-1 embryos was used in three independentanti-OTX2 ChIP-seq experiments.

Project description:Promoters initiate RNA synthesis, and enhancers stimulate promoter activity. Whether promoter and enhancer activities are encoded distinctly in DNA sequences is unknown. We measured the enhancer and promoter activities of thousands of DNA fragments transduced into mouse neurons. We focused on genomic loci bound by the neuronal activity-regulated co-activator CREBBP, and we measured enhancer and promoter activities both before and after neuronal activation. We find that the same sequences typically encode both enhancer and promoter activities. However, gene promoters generate more promoter activity than distal enhancers, despite generating similar enhancer activity. Surprisingly, the greater promoter activity of gene promoters is not due to conventional core promoter elements or splicing signals. Instead, we find that particular transcription factor binding motifs are intrinsically biased toward the generation of promoter activity, while others are not. While the specific biases we observe may be dependent on experimental or cellular context, our results suggest that gene promoters are distinguished from distal enhancers by specific complements of transcriptional activators.

Project description:Neural basic helix-loop-helix (bHLH) transcription factors are important for the differentiation and cell type specification of neurons. They are thought to share direct downstream targets in their common role as neuronal differentiation factors, but have distinct targets with respect to their cell type specific roles. Little is known about distinct cell-type specific bHLH targets as previous work did not distinguish these from common targets. Based on previous genetic evidence, we hypothesize that bHLH transcription factors have unique targets for their function in regulating neuronal sub-type specification. Atoh1 (Math1) is a bHLH transcription factor that specifies different cell types of the proprioceptive pathway in mammals such as the dorsal interneuron 1 population of the developing neural tube. Using microarray analyses of neighboring specific bHLH sorted populations from developing mouse neural tubes, we determine transcripts unique to the Atoh1-derived population and not those common to bHLH transcription factors in related neural progenitor populations. Chromatin immunoprecipitation followed by sequencing (ChIP-seq) experiments of native tissue followed by enhancer reporter analyses identified five direct cell-type specific targets of Atoh1 in vivo: Klf7, Rab15, Rassf4, Selm, and Smad7, along with their Atoh1-responsive enhancers. These Atoh1 targets were found from native tissue in the appropriate developmental context and have diverse functions that range from transcription factors to regulators of endocytosis and signaling pathways. Only Rab15 and Selm are expressed across several different Atoh1-specified cell types including external granule cells (EGL) in the developing cerebellum, hair cells of the inner ear, and Merkel cells, demonstrating that even within Atoh1 lineages, not all Atoh1 specific targets are shared. Our work establishes on a molecular level that the neuronal differentiation bHLH transcription factors also have distinct targets for their roles in neuronal sub-type specification. From this work, we can begin to address how bHLH transcription factors are able to specify unique cell types and initiate programs that organize neuronal diversity. Gene expression analysis: Two samples, Atoh1-GFP and dNeurog1-GFP, were analyzed. Two biological replicates of each. Atoh1-GFP transgenics are mice with GFP inserted into a BAC that drives GFP to the Atoh1-derived population of the developing neural tube marking the dorsal interneuron 1 population (Raft et al. Development 2007). dNeurog1-GFP transgenics are mice with a Neurog1 enhancer that drives GFP to the dorsal part of the developing neural tube marking the dorsal interneuron 2 population (Nakada et al. Dev Bio 2004). Chip-seq analysis: Series GSE22111

Project description:We used genome-wide sequencing methods to study stimulus-dependent enhancer function in neurons. We identified ~12,000 neuronal activity-regulated enhancers that are bound by the general transcriptional co-activator CBP in an activity-dependent manner. A function of CBP at enhancers may be to recruit RNA polymerase II (RNAPII), as we also observed activity-regulated RNAPII binding to thousands of enhancers. Remarkably, RNAPII at enhancers transcribes bi-directionally a novel class of enhancer RNAs (eRNAs) within enhancer domains defined by the presence of histone H3 that is mono-methylated at lysine 4 (H3K4me1). The level of eRNA expression at neuronal enhancers positively correlates with the level of mRNA synthesis at nearby genes, suggesting that eRNA synthesis occurs specifically at enhancers that are actively engaged in promoting mRNA synthesis. These findings reveal that a widespread mechanism of enhancer activation involves RNAPII binding and eRNA synthesis. Examination of genome-wide binding of three types of modified histones, four transcription factors, and RNA polymerase II (ChIP-Seq), as well as RNA expression (RNA-Seq) before and after membrane depolarization via application of extracellular potassium.

Project description:Primed enhancers are marked by histone H3K4 mono-methylation (H3K4me1), and the conversion to active enhancers involves acetylation of histone H3K27 (H3K27Ac). However, whether active enhancers are regulated remains unclear. Here we report a biochemical complex consisting of a potential chromatin reader (RACK7) and a histone demethylase (KDM5C) that occupies many active enhancers in a breast cancer cell line. Loss of RACK7 or KDM5C results in hyperactive enhancers marked by H3K4me3 and H3K27Ac, and characterized by an increased eRNA transcription and elevated expression of nearby genes. Loss of RACK7 or KDM5C also leads to increased cell invasion and migration, and enhanced tumor growth. We propose that RACK7/KDM5C functions as an enhancer “brake” to ensure appropriate enhancer activities in the cell. Our findings provide important insight into histone H3K4 methylation dynamics at enhancers and reveal a molecular mechanism that controls the activities of active enhancers, which when compromised, can contribute to tumorigenesis. mRNA-seq of parental and RACK7-KO ZR-75-30 cells

Project description:Primed enhancers are marked by histone H3K4 mono-methylation (H3K4me1), and the conversion to active enhancers involves acetylation of histone H3K27 (H3K27Ac). However, whether active enhancers are regulated remains unclear. Here we report a biochemical complex consisting of a potential chromatin reader (RACK7) and a histone demethylase (KDM5C) that occupies many active enhancers in a breast cancer cell line. Loss of RACK7 or KDM5C results in hyperactive enhancers marked by H3K4me3 and H3K27Ac, and characterized by an increased eRNA transcription and elevated expression of nearby genes. Loss of RACK7 or KDM5C also leads to increased cell invasion and migration, and enhanced tumor growth. We propose that RACK7/KDM5C functions as an enhancer “brake” to ensure appropriate enhancer activities in the cell. Our findings provide important insight into histone H3K4 methylation dynamics at enhancers and reveal a molecular mechanism that controls the activities of active enhancers, which when compromised, can contribute to tumorigenesis. nascent RNA-seq of parental and RACK7-KO cells

Project description:Inhibitory GABAergic interneurons originate in the embryonic medial ganglionic eminence (MGE) and control network activity in the neocortex. Dysfunction of these cells is believed to lead to runaway excitation underlying seizure-based neurological disorders such as epilepsy, autism and schizophrenia. Despite their importance in heath and disease, our knowledge about the development of this diverse neuronal population remains incomplete. Here we conducted single cell RNA sequencing (scRNA-seq) of human fetal MGE from 10 to 15 weeks post conception. These MGE tissues are composed of largely cycling progenitors and immature post-mitotic interneurons with characteristic regional marker expression. Analysis of integrated human and mouse MGE data revealed species conserved transcriptomic profiles and regulatory program. Moreover, we identified novel candidate transcription regulators for human interneuron differentiation. These findings provide a framework for in vitro modelling of interneuron development and strategy for potentially enhance interneurons production from human pluripotent stem cells.

Project description:Enhancers play key roles in gene regulation. However, comprehensive enhancer discovery is challenging because most enhancers, especially those affected in complex diseases, have weak effects on gene expression. Through gene regulatory network modeling, we identified that dynamic cell state transitions, a critical missing component in prevalent enhancer discovery strategies, can be utilized to improve the cells’ sensitivity to enhancer perturbation. Guided by the modeling results, we performed a mid-transition CRISPRi-based enhancer screen utilizing human embryonic stem cell definitive endoderm differentiation as a dynamic transition system. The screen discovered a comprehensive set of enhancers (4 to 9 per locus) for each of the core lineage-specifying transcription factors (TFs), including many enhancers with weak to moderate effects. Integrating the screening results with enhancer activity measurements (ATAC-seq, H3K27ac ChIP-seq) and three-dimensional enhancer-promoter interaction information (CTCF looping, Hi-C), we were able to develop a CTCF loop-constrained Interaction Activity (CIA) model that can better predict functional enhancers compared to models that rely on Hi-C-based enhancer-promoter contact frequency. Together, our dynamic network-guided enhancer screen and the CIA enhancer prediction model provide generalizable strategies for sensitive and more comprehensive enhancer discovery in both normal and pathological cell state transitions.

Project description:The Otx2 homeobox transcription factor is essential for gastrulation and early neural development. We generated Otx2 conditional knockout (cKO) mice to investigate its roles in telencephalon development after E9.0. We conducted transcriptional profiling and in situ hybridization to identify genes de-regulated in Otx2 cKO ventral forebrain. In parallel, we used ChIP-seq to identify enhancer elements, OTX2 binding motif, and which de-regulated genes are likely direct targets of Otx2 transcriptional regulation. We found that Otx2 was essential in septum specification; regulation of Fgf signaling in the rostral telencephalon; and medial ganglionic eminence (MGE) patterning, neurogenesis, and oligodendrogenesis. Within the MGE, Otx2 was required for ventral but not dorsal identity; this is the first demonstration of a transcription factor that contributes to regional patterning within the MGE.

Project description:The Otx2 homeobox transcription factor is essential for gastrulation and early neural development. We generated Otx2 conditional knockout (cKO) mice to investigate its roles in telencephalon development after E9.0. We conducted transcriptional profiling and in situ hybridization to identify genes de-regulated in Otx2 cKO ventral forebrain. In parallel, we used ChIP-seq to identify enhancer elements, OTX2 binding motif, and which de-regulated genes are likely direct targets of Otx2 transcriptional regulation. We found that Otx2 was essential in septum specification; regulation of Fgf signaling in the rostral telencephalon; and medial ganglionic eminence (MGE) patterning, neurogenesis, and oligodendrogenesis. Within the MGE, Otx2 was required for ventral but not dorsal identity; this is the first demonstration of a transcription factor that contributes to regional patterning within the MGE.