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:Sequence divergence of cis-regulatory elements drives species-specific traits, but how this manifests in the evolution of neocortex at the molecular and cellular level remains to be elucidated. We investigated the gene regulatory programs in the primary motor cortex of human, macaque, marmoset, and mouse with single cell multiomics assays, generating gene expression, chromatin accessibility, DNA methylome and chromosomal conformation profiles from a total of over 180,000 cells. For each modality, we determined species-specific, divergent, and conserved gene expression and epigenetic features at multiple levels. We find that cell type-specific gene expression evolves more rapidly than broadly expressed genes, and that epigenetic status at distal candidate cis-regulatory elements (cCREs) evolves faster than promoters. Strikingly, transposable elements (TEs) contribute to nearly 80% of the human-specific cCREs in cortical cells. Through machine learning, we develop sequence-based predictors of cCREs in different species, and demonstrate that the genomic regulatory syntax is highly preserved from rodents to primates. Lastly, we show that epigenetic conservation combined with sequence similarity help uncover functional cis-regulatory elements and enhance our ability to interpret genetic variants contributing to neurological disease and traits.

Project description:Sequence divergence of cis-regulatory elements drives species-specific traits, but how this manifests in the evolution of the neocortex at the molecular and cellular level remains to be elucidated. We investigated the gene regulatory programs in the primary motor cortex of human, macaque, marmoset, and mouse with single-cell multiomics assays, generating gene expression, chromatin accessibility, DNA methylome, and chromosomal conformation profiles from a total of over 180,000 cells. For each modality, we determined species-specific, divergent, and conserved gene expression and epigenetic features at multiple levels. We find that cell type-specific gene expression evolves more rapidly than broadly expressed genes and that epigenetic status at distal candidate cis-regulatory elements (cCREs) evolves faster than promoters. Strikingly, transposable elements (TEs) contribute to nearly 80% of the human-specific cCREs in cortical cells. Through machine learning, we develop sequence-based predictors of cCREs in different species and demonstrate that the genomic regulatory syntax is highly preserved from rodents to primates. Lastly, we show that epigenetic conservation combined with sequence similarity helps uncover functional cis-regulatory elements and enhances our ability to interpret genetic variants contributing to neurological disease and traits.

Project description:Sequence divergence of cis-regulatory elements drives species-specific traits, but how this manifests in the evolution of neocortex at the molecular and cellular level remains to be elucidated. We investigated the gene regulatory programs in the primary motor cortex of human, macaque, marmoset, and mouse with single cell multiomics assays, generating gene expression, chromatin accessibility, DNA methylome and chromosomal conformation profiles from a total of over 180,000 cells. For each modality, we determined species-specific, divergent, and conserved gene expression and epigenetic features at multiple levels. We find that cell type-specific gene expression evolves more rapidly than broadly expressed genes, and that epigenetic status at distal candidate cis-regulatory elements (cCREs) evolves faster than promoters. Strikingly, transposable elements (TEs) contribute to nearly 80% of the human-specific cCREs in cortical cells. Through machine learning, we develop sequence-based predictors of cCREs in different species, and demonstrate that the genomic regulatory syntax is highly preserved from rodents to primates. Lastly, we show that epigenetic conservation combined with sequence similarity help uncover functional cis-regulatory elements and enhance our ability to interpret genetic variants contributing to neurological disease and traits.

Project description:Sequence divergence of cis-regulatory elements drives species-specific traits, but how this manifests in the evolution of the neocortex at the molecular and cellular level remains to be elucidated. We investigated the gene regulatory programs in the primary motor cortex of human, macaque, marmoset, and mouse with single-cell multiomics assays, generating gene expression, chromatin accessibility, DNA methylome, and chromosomal conformation profiles from a total of over 180,000 cells. For each modality, we determined species-specific, divergent, and conserved gene expression and epigenetic features at multiple levels. We find that cell type-specific gene expression evolves more rapidly than broadly expressed genes and that epigenetic status at distal candidate cis-regulatory elements (cCREs) evolves faster than promoters. Strikingly, transposable elements (TEs) contribute to nearly 80% of the human-specific cCREs in cortical cells. Through machine learning, we develop sequence-based predictors of cCREs in different species and demonstrate that the genomic regulatory syntax is highly preserved from rodents to primates. Lastly, we show that epigenetic conservation combined with sequence similarity helps uncover functional cis-regulatory elements and enhances our ability to interpret genetic variants contributing to neurological disease and traits.

Project description:Cis-regulatory elements (CREs) precisely control the spatiotemporal gene expression in cells. Using a spatially resolved single-cell atlas of gene expression and chromatin accessibility across ten soybean tissues, we identified 103 distinct cell types and 303,199 accessible chromatin regions (ACRs). Nearly 40% of ACRs showed cell-type-specific patterns and were enriched for transcription factor (TF) binding motifs controlling cell-type specification and maintenance. We identified non-cell autonomous activity of NIN-LIKE PROTEIN 7 (NLP7), the Nodule Inception (NIN) gene regulatory network and de novo enriched TF motifs in the nodule infected cells. With comprehensive developmental trajectories for endosperm and embryo, we found that 13 sucrose transporters, sharing the DOF11 binding motif, were co-up-regulated in late peripheral endosperm and identified the key embryo cell-type specification regulators during embryogenesis, including a homeobox TF that promotes cotyledon parenchyma identity. This resource provides a valuable foundation for analyzing gene regulatory programs in soybean cell types across tissues and life stages.

Project description:Cis-regulatory elements (CREs) encode the genomic blueprints for coordinating the spatiotemporal regulation of gene transcription programs necessary for highly specialized cellular functions. To identify cis-regulatory elements underlying cell-type specification and developmental transitions, we implemented single-cell sequencing of Assay for Transposase Accessible Chromatin (scATAC-seq) in an atlas of Zea mays tissues and organs. We describe 92 distinct patterns of chromatin accessibility across more than 165,913 putative CREs, greater than 56,575 cells, and 52 known cell-types using a novel regularized quasibinomial logistic model for estimating single cell accessibility. Cell-type specification could be largely explained by combinatorial accessibility of transcription factors (TFs) and their associated binding. Analysis of cell type-specific co-accessible chromatin recapitulated higher-order chromatin interactions, providing novel insight into cell type-specific regulatory dynamics. Integration of genetic diversity data revealed cell-type specific CREs contributed to specific morphological and molecular phenotypic traits indicative of their cellular functions, expanding our understanding of the molecular influence of complex traits in a eukaryotic species.