Project description:While comparative genetic analysis has been performed between distinct regions of the embryonic forebrain, a comprehensive characterization of differential epigenomic organization has not been performed. We collected single-cell chromatin accessibility profiles from four distinct neurogenic regions of the embryonic mouse forebrain using single nuclei ATAC-Seq (snATAC-Seq). We identified thousands of differentially accessible peaks, many restricted to distinct progenitor cell types or brain regions. We integrated snATAC-Seq and single cell transcriptome data to characterize changes of chromatin accessibility at enhancers and promoters that were tightly coupled to transcript abundance. Multi-modal integration of histone modifications (CUT&Tag and CUT&RUN), promoter-enhancer interactions (Capture-C) and high-order chromatin structure (Hi-C) extended these initial observations. This dataset reveals a diverse chromatin landscape with region-specific regulatory mechanisms and genomic interactions in distinct neurogenic regions of the embryonic mouse brain and represents an extensive public resource of a ‘ground truth’ epigenomic landscape at this critical stage of neurogenesis.

Project description:While comparative genetic analysis has been performed between distinct regions of the embryonic forebrain, a comprehensive characterization of differential epigenomic organization has not been performed. We collected single-cell chromatin accessibility profiles from four distinct neurogenic regions of the embryonic mouse forebrain using single nuclei ATAC-Seq (snATAC-Seq). We identified thousands of differentially accessible peaks, many restricted to distinct progenitor cell types or brain regions. We integrated snATAC-Seq and single cell transcriptome data to characterize changes of chromatin accessibility at enhancers and promoters that were tightly coupled to transcript abundance. Multi-modal integration of histone modifications (CUT&Tag and CUT&RUN), promoter-enhancer interactions (Capture-C) and high-order chromatin structure (Hi-C) extended these initial observations. This dataset reveals a diverse chromatin landscape with region-specific regulatory mechanisms and genomic interactions in distinct neurogenic regions of the embryonic mouse brain and represents an extensive public resource of a ‘ground truth’ epigenomic landscape at this critical stage of neurogenesis.

Project description:While comparative genetic analysis has been performed between distinct regions of the embryonic forebrain, a comprehensive characterization of differential epigenomic organization has not been performed. We collected single-cell chromatin accessibility profiles from four distinct neurogenic regions of the embryonic mouse forebrain using single nuclei ATAC-Seq (snATAC-Seq). We identified thousands of differentially accessible peaks, many restricted to distinct progenitor cell types or brain regions. We integrated snATAC-Seq and single cell transcriptome data to characterize changes of chromatin accessibility at enhancers and promoters that were tightly coupled to transcript abundance. Multi-modal integration of histone modifications (CUT&Tag and CUT&RUN), promoter-enhancer interactions (Capture-C) and high-order chromatin structure (Hi-C) extended these initial observations. This dataset reveals a diverse chromatin landscape with region-specific regulatory mechanisms and genomic interactions in distinct neurogenic regions of the embryonic mouse brain and represents an extensive public resource of a ‘ground truth’ epigenomic landscape at this critical stage of neurogenesis.

Project description:While comparative genetic analysis has been performed between distinct regions of the embryonic forebrain, a comprehensive characterization of differential epigenomic organization has not been performed. We collected single-cell chromatin accessibility profiles from four distinct neurogenic regions of the embryonic mouse forebrain using single nuclei ATAC-Seq (snATAC-Seq). We identified thousands of differentially accessible peaks, many restricted to distinct progenitor cell types or brain regions. We integrated snATAC-Seq and single cell transcriptome data to characterize changes of chromatin accessibility at enhancers and promoters that were tightly coupled to transcript abundance. Multi-modal integration of histone modifications (CUT&Tag and CUT&RUN), promoter-enhancer interactions (Capture-C) and high-order chromatin structure (Hi-C) extended these initial observations. This dataset reveals a diverse chromatin landscape with region-specific regulatory mechanisms and genomic interactions in distinct neurogenic regions of the embryonic mouse brain and represents an extensive public resource of a ‘ground truth’ epigenomic landscape at this critical stage of neurogenesis.

Project description:While comparative genetic analysis has been performed between distinct regions of the embryonic forebrain, a comprehensive characterization of differential epigenomic organization has not been performed. We collected single-cell chromatin accessibility profiles from four distinct neurogenic regions of the embryonic mouse forebrain using single nuclei ATAC-Seq (snATAC-Seq). We identified thousands of differentially accessible peaks, many restricted to distinct progenitor cell types or brain regions. We integrated snATAC-Seq and single cell transcriptome data to characterize changes of chromatin accessibility at enhancers and promoters that were tightly coupled to transcript abundance. Multi-modal integration of histone modifications (CUT&Tag and CUT&RUN), promoter-enhancer interactions (Capture-C) and high-order chromatin structure (Hi-C) extended these initial observations. This dataset reveals a diverse chromatin landscape with region-specific regulatory mechanisms and genomic interactions in distinct neurogenic regions of the embryonic mouse brain and represents an extensive public resource of a ‘ground truth’ epigenomic landscape at this critical stage of neurogenesis.

Project description:While comparative genetic analysis has been performed between distinct regions of the embryonic forebrain, a comprehensive characterization of differential epigenomic organization has not been performed. We collected single-cell chromatin accessibility profiles from four distinct neurogenic regions of the embryonic mouse forebrain using single nuclei ATAC-Seq (snATAC-Seq). We identified thousands of differentially accessible peaks, many restricted to distinct progenitor cell types or brain regions. We integrated snATAC-Seq and single cell transcriptome data to characterize changes of chromatin accessibility at enhancers and promoters that were tightly coupled to transcript abundance. Multi-modal integration of histone modifications (CUT&Tag and CUT&RUN), promoter-enhancer interactions (Capture-C) and high-order chromatin structure (Hi-C) extended these initial observations. This dataset reveals a diverse chromatin landscape with region-specific regulatory mechanisms and genomic interactions in distinct neurogenic regions of the embryonic mouse brain and represents an extensive public resource of a ‘ground truth’ epigenomic landscape at this critical stage of neurogenesis.

Project description:While epigenetic modifications are critical for cell state changes throughout development, a detailed characterization of chromatin accessibility during neurogenesis has not been explored. We collected single-cell chromatin accessibility profiles of ~40,000 cells from 4 distinct neurogenic regions of the embryonic mouse forebrain using single nuclei ATAC-Seq (snATAC-Seq). We identified thousands of differentially accessible peaks, many of which were restricted to distinct progenitor cell types or brain regions. By integrating snATAC-Seq and transcriptome data, we characterized changes of chromatin accessibility at enhancers and promoters that were tightly coupled to transcript abundance throughout neurodevelopment. Integrating our chromatin accessibility profiles from embryonic and adult interneurons with the iPSYCH2012 GWAS dataset revealed several disease-associated polymorphisms overlapped accessible regions in embryonic cells and MGE-derived mature interneurons. These findings highlight the coordination between chromatin accessibility and gene expression as neural progenitors mature during embryogenesis, and open the door for future studies to define critical enhancer-promoter interactions that direct cell fate decisions.

Project description:While epigenetic modifications are critical for cell state changes throughout development, a detailed characterization of chromatin accessibility during neurogenesis has not been explored. We collected single-cell chromatin accessibility profiles of ~40,000 cells from 4 distinct neurogenic regions of the embryonic mouse forebrain using single nuclei ATAC-Seq (snATAC-Seq). We identified thousands of differentially accessible peaks, many of which were restricted to distinct progenitor cell types or brain regions. By integrating snATAC-Seq and transcriptome data, we characterized changes of chromatin accessibility at enhancers and promoters that were tightly coupled to transcript abundance throughout neurodevelopment. Integrating our chromatin accessibility profiles from embryonic and adult interneurons with the iPSYCH2012 GWAS dataset revealed several disease-associated polymorphisms overlapped accessible regions in embryonic cells and MGE-derived mature interneurons. These findings highlight the coordination between chromatin accessibility and gene expression as neural progenitors mature during embryogenesis, and open the door for future studies to define critical enhancer-promoter interactions that direct cell fate decisions.

Project description:Hi-C in MGE, CGE, LGE and cortical regions from mouse embryonic forebrain

Project description:Capture-C in MGE, CGE, LGE and cortical regions from mouse embryonic forebrain