Project description:Analysis of histone modifications at single-cell resolution can provide insights into the cellular heterogeneity in activity states of regulatory elements. However, current methods are hindered by lengthy procedures and insufficient sensitivity. Here we present Droplet Paired-Tag, a microfluidic cell barcoding-based method for fast and robust joint analysis of histone modifications and gene expression from single cells. We applied Droplet Paired-Tag to mouse brain and demonstrated its utility in accurately identifying active or repressive regulatory elements, and resolving the dynamic interactions between candidate regulatory elements and putative target genes.

Project description:The limited number of in vivo germ cells poses an impediment to genome-wide studies. Here, we applied a small-scale ChIP-Seq method on purified mouse fetal germ cells to generate genome-wide maps of four histone modifications (H3K4me3, H3K27me3, H3K27ac and H2BK20ac), facilitating the identification of active and repressed cis-regulatory elements in germ cells in vivo. Comparison of active chromatin state between somatic, embryonic stem cells (ESC) and germ cells revealed promoters and enhancers needed for stem cell maintenance and germ cell development. The nuclear receptor Nr5a2 motif is enriched at a subset of cis-regulatory regions and we confirm its role in germ cell differentiation. Interestingly, germ cells have comparatively more H3K27me3-marked sites that are absent in ESC and other somatic cell types. These repressed regions are enriched for retrotransposons and MHC genes and this indicates that these loci are specifically silenced in germ cells. Together, our study provides the first genome-wide histone modification maps of in vivo germ cells and revealed the molecular chromatin signatures unique to germ cells. Germ cells were FACS-purified from gonadal single cell suspension based on Pou5f1-GFP expression. ChIP-seq of Histone modification was done for two timepoints in this study: E11.5 (male/female), E13.5 (male). For E13.5 timepoint, two biological replicates were analyzed. In order to validate small scale ChIP-seq method limited number of ES cells were used to check consistency of ChIP-seq data.

Project description:The limited number of in vivo germ cells poses an impediment to genome-wide studies. Here, we applied a small-scale ChIP-Seq method on purified mouse fetal germ cells to generate genome-wide maps of four histone modifications (H3K4me3, H3K27me3, H3K27ac and H2BK20ac), facilitating the identification of active and repressed cis-regulatory elements in germ cells in vivo. Comparison of active chromatin state between somatic, embryonic stem cells (ESC) and germ cells revealed promoters and enhancers needed for stem cell maintenance and germ cell development. The nuclear receptor Nr5a2 motif is enriched at a subset of cis-regulatory regions and we confirm its role in germ cell differentiation. Interestingly, germ cells have comparatively more H3K27me3-marked sites that are absent in ESC and other somatic cell types. These repressed regions are enriched for retrotransposons and MHC genes and this indicates that these loci are specifically silenced in germ cells. Together, our study provides the first genome-wide histone modification maps of in vivo germ cells and revealed the molecular chromatin signatures unique to germ cells.

Project description:Knowledge of the locations and activities of cis-regulatory elements (CREs) is needed to decipher basic mechanisms of gene regulation and to better understand the impact of genetic variants on complex traits. Previous studies identified candidate CREs (cCREs) using multiple epigenetic features in cell types from one species at a time, but such an approach can make it difficult to compare results across species. In contrast, we conducted a cross-species study defining epigenetic states and identifying cCREs in blood cell types to generate maps of the regulatory landscapes and cCREs that are comparable across species. This study used integrative modeling of eight epigenetic features jointly in both human and mouse in our Validated Systematic Integration (VISION) Project. The accuracy of the cCRE predictions was supported by orthogonal function-related data. The contribution of each epigenetic state in cCREs to gene regulation was estimated from a multivariate regression against gene expression across cell types, and these values were used to estimate an epigenetic state Regulatory Potential (esRP) score for each cCRE in each cell type. These esRP scores have broad utility for visualizing and categorizing the dynamic changes in cCREs during hematopoietic differentiation. After jointly clustering cCREs based on their esRP scores across human and mouse cell types, we found distinctive transcription factor binding motifs associated with each group of cCREs with similar patterns of regulatory activity; these associations are similar between human and mouse. Genetic variants associated with blood cell phenotypes (from the GWAS Catalog and the UK Biobank study) were highly and specifically enriched in the catalog of human VISION cCREs, indicating the utility of our cCRE predictions for understanding the impact of noncoding genetic variants on both physiologic and pathologic blood cell-related traits. The cross-species joint modeling enabled a comparison of cCREs that revealed both conserved and lineage-specific patterns of epigenetic evolution, even in the absence of genomic sequence alignment. The VISION project resources are accessible through a suite of tools and browsers at http://usevision.org.

Project description:Knowledge of the locations and activities of cis-regulatory elements (CREs) is needed to decipher basic mechanisms of gene regulation and to better understand the impact of genetic variants on complex traits. Previous studies identified candidate CREs (cCREs) using multiple epigenetic features in cell types from one species at a time, but such an approach can make it difficult to compare results across species. In contrast, we conducted a cross-species study defining epigenetic states and identifying cCREs in blood cell types to generate maps of the regulatory landscapes and cCREs that are comparable across species. This study used integrative modeling of eight epigenetic features jointly in both human and mouse in our Validated Systematic Integration (VISION) Project. The accuracy of the cCRE predictions was supported by orthogonal function-related data. The contribution of each epigenetic state in cCREs to gene regulation was estimated from a multivariate regression against gene expression across cell types, and these values were used to estimate an epigenetic state Regulatory Potential (esRP) score for each cCRE in each cell type. These esRP scores have broad utility for visualizing and categorizing the dynamic changes in cCREs during hematopoietic differentiation. After jointly clustering cCREs based on their esRP scores across human and mouse cell types, we found distinctive transcription factor binding motifs associated with each group of cCREs with similar patterns of regulatory activity; these associations are similar between human and mouse. Genetic variants associated with blood cell phenotypes (from the GWAS Catalog and the UK Biobank study) were highly and specifically enriched in the catalog of human VISION cCREs, indicating the utility of our cCRE predictions for understanding the impact of noncoding genetic variants on both physiologic and pathologic blood cell-related traits. The cross-species joint modeling enabled a comparison of cCREs that revealed both conserved and lineage-specific patterns of epigenetic evolution, even in the absence of genomic sequence alignment. The VISION project resources are accessible through a suite of tools and browsers at http://usevision.org.

Project description:Knowledge of the locations and activities of cis-regulatory elements (CREs) is needed to decipher basic mechanisms of gene regulation and to better understand the impact of genetic variants on complex traits. Previous studies identified candidate CREs (cCREs) using multiple epigenetic features in cell types from one species at a time, but such an approach can make it difficult to compare results across species. In contrast, we conducted a cross-species study defining epigenetic states and identifying cCREs in blood cell types to generate maps of the regulatory landscapes and cCREs that are comparable across species. This study used integrative modeling of eight epigenetic features jointly in both human and mouse in our Validated Systematic Integration (VISION) Project. The accuracy of the cCRE predictions was supported by orthogonal function-related data. The contribution of each epigenetic state in cCREs to gene regulation was estimated from a multivariate regression against gene expression across cell types, and these values were used to estimate an epigenetic state Regulatory Potential (esRP) score for each cCRE in each cell type. These esRP scores have broad utility for visualizing and categorizing the dynamic changes in cCREs during hematopoietic differentiation. After jointly clustering cCREs based on their esRP scores across human and mouse cell types, we found distinctive transcription factor binding motifs associated with each group of cCREs with similar patterns of regulatory activity; these associations are similar between human and mouse. Genetic variants associated with blood cell phenotypes (from the GWAS Catalog and the UK Biobank study) were highly and specifically enriched in the catalog of human VISION cCREs, indicating the utility of our cCRE predictions for understanding the impact of noncoding genetic variants on both physiologic and pathologic blood cell-related traits. The cross-species joint modeling enabled a comparison of cCREs that revealed both conserved and lineage-specific patterns of epigenetic evolution, even in the absence of genomic sequence alignment. The VISION project resources are accessible through a suite of tools and browsers at http://usevision.org.

Project description:Knowledge of the locations and activities of cis-regulatory elements (CREs) is needed to decipher basic mechanisms of gene regulation and to better understand the impact of genetic variants on complex traits. Previous studies identified candidate CREs (cCREs) using multiple epigenetic features in cell types from one species at a time, but such an approach can make it difficult to compare results across species. In contrast, we conducted a cross-species study defining epigenetic states and identifying cCREs in blood cell types to generate maps of the regulatory landscapes and cCREs that are comparable across species. This study used integrative modeling of eight epigenetic features jointly in both human and mouse in our Validated Systematic Integration (VISION) Project. The accuracy of the cCRE predictions was supported by orthogonal function-related data. The contribution of each epigenetic state in cCREs to gene regulation was estimated from a multivariate regression against gene expression across cell types, and these values were used to estimate an epigenetic state Regulatory Potential (esRP) score for each cCRE in each cell type. These esRP scores have broad utility for visualizing and categorizing the dynamic changes in cCREs during hematopoietic differentiation. After jointly clustering cCREs based on their esRP scores across human and mouse cell types, we found distinctive transcription factor binding motifs associated with each group of cCREs with similar patterns of regulatory activity; these associations are similar between human and mouse. Genetic variants associated with blood cell phenotypes (from the GWAS Catalog and the UK Biobank study) were highly and specifically enriched in the catalog of human VISION cCREs, indicating the utility of our cCRE predictions for understanding the impact of noncoding genetic variants on both physiologic and pathologic blood cell-related traits. The cross-species joint modeling enabled a comparison of cCREs that revealed both conserved and lineage-specific patterns of epigenetic evolution, even in the absence of genomic sequence alignment. The VISION project resources are accessible through a suite of tools and browsers at http://usevision.org.

Project description:Wnt signal usually functions as a spatial gradient. A localized Wnt3a can induce asymmetric division of mouse embryonic stem cells, whereas proximal daughter cells maintain self-renew and distal daughter cells acquire hallmarks of differentiation. Here, we develop an approach, SET-seq (same cell epigenome and transcriptome sequencing), to jointly profile epigenome and transcriptome in the same single cell. By utilizing SET-seq, we profile H3K27me3 and H3K4me3 with gene expression in Wnt3a induced asymmetric cell division. H3K27me3, but not H3K4me3, is correlatedly changed with gene expression. Single cells clustered by H3K27me3 recapitulate the clusters defined by gene expression. Furthermore, Aebp2, which is the regulator of H3K27me3, is important for the cell-fate decision with localized Wnt signal. Our results provide a convenient way to jointly profile epigenome and transcriptome in the same cell, and uncover the mechanistic insights into the gene regulatory programs for maintaining and resetting stem cell fate during differentiation.

Project description:We report the application of single-molecule-based sequencing technology for high-throughput profiling of histone modifications in NSC. By obtaining sequences from chromatin immunoprecipitated DNA, we generated genome-wide chromatin-state maps of NSC. We compared histone modifications between wild type and Sox2-deleted NSC.

Project description:Droplet-based single cell transcriptome sequencing (scRNA-seq) technology is able to measure the gene expression from tens of thousands of single cells simultaneously. More recently, coupled with the cutting-edge Cellular Indexing of Transcriptomes and Epitopes by Sequencing (CITE-seq), the droplet-based system has allowed for immunophenotyping of single cells based on cell surface expression of specific proteins together with simultaneous transcriptome profiling in the same cell. In this study, we developed BREM-SC, a novel Bayesian Random Effects Mixture model that jointly clusters paired single cell transcriptomic and proteomic data, which will greatly facilitate researchers to jointly study transcriptome and surface proteins at the single cell level to make new biological discoveries.