Project description:The shape of the human face is largely genetically determined, but the genetic drivers of craniofacial morphology remain poorly understood. In particular, little is known about the contributions of gene regulatory sequences active in the developing face to craniofacial morphology. Here we used a combination of epigenomic profiling, in vivo characterization of more than 200 craniofacial candidate enhancer sequences in transgenic mice, and targeted deletion experiments to examine the role of distant-acting enhancers in craniofacial development. We identified complex regulatory landscapes with thousands of enhancers genome-wide that drive a remarkable spatial complexity of in vivo expression patterns. The ChIP-seq experiments in this entry was the basis for the genome-wide analysis of craniofacial enhancers and served as the source for substantialin vivo characterization via transgenic reporter mice and for enhancer knockout experiments. p300 ChIP-seq experiment on mouse embryonic tissue (e11.5)

Project description:The shape of the human face is largely genetically determined, but the genetic drivers of craniofacial morphology remain poorly understood. In particular, little is known about the contributions of gene regulatory sequences active in the developing face to craniofacial morphology. Here we used a combination of epigenomic profiling, in vivo characterization of more than 200 craniofacial candidate enhancer sequences in transgenic mice, and targeted deletion experiments to examine the role of distant-acting enhancers in craniofacial development. We identified complex regulatory landscapes with thousands of enhancers genome-wide that drive a remarkable spatial complexity of in vivo expression patterns. The ChIP-seq experiments in this entry was the basis for the genome-wide analysis of craniofacial enhancers and served as the source for substantialin vivo characterization via transgenic reporter mice and for enhancer knockout experiments.

Project description:Tissue-Specific RNA Expression Marks Distant Acting Developmental Enhancers

Project description:The genetic basis of craniofacial birth defects and general variation in human facial shape remains poorly understood. Distant-acting transcriptional enhancers are a major category of non-coding genome function and have been shown to control the fine-tuned spatiotemporal expression of genes during critical stages of craniofacial development. However, a lack of accurate maps of the genomic location and cell type-specific in vivo activities of all craniofacial enhancers prevents their systematic exploration in human genetics studies. Here, we combined transcriptome, histone modification, and chromatin accessibility profiling from different stages of human craniofacial development with single-cell analyses of the developing mouse face to create a comprehensive catalogue of the regulatory landscape of facial development at tissue- and single cell-resolution. In total, we identified approximately 14,000 enhancers across seven developmental stages from weeks 4 through 8 of human embryonic face development. To annotate the cell type specificity of human-mouse conserved enhancers, we performed single-cell RNA-seq and single-nucleus ATAC-seq of mouse craniofacial tissues from embryonic days e11.5 to e15.5. By integrating across these data sets, we identify major cell populations of the developing face and annotate over 16,000 candidate enhancers by their cell type-specific epigenomic profile. Using retrospective analysis of known craniofacial enhancers in combination with single cell-resolved transgenic reporter assays, we show the value of these data for the prediction of in vivo cell type specificity. Taken together, our data provide a critical resource for genetic and developmental studies of human craniofacial development.

Project description:The genetic basis of craniofacial birth defects and general variation in human facial shape remains poorly understood. Distant-acting transcriptional enhancers are a major category of non-coding genome function and have been shown to control the fine-tuned spatiotemporal expression of genes during critical stages of craniofacial development. However, a lack of accurate maps of the genomic location and cell type-specific in vivo activities of all craniofacial enhancers prevents their systematic exploration in human genetics studies. Here, we combined transcriptome, histone modification, and chromatin accessibility profiling from different stages of human craniofacial development with single-cell analyses of the developing mouse face to create a comprehensive catalogue of the regulatory landscape of facial development at tissue- and single cell-resolution. In total, we identified approximately 14,000 enhancers across seven developmental stages from weeks 4 through 8 of human embryonic face development. To annotate the cell type specificity of human-mouse conserved enhancers, we performed single-cell RNA-seq and single-nucleus ATAC-seq of mouse craniofacial tissues from embryonic days e11.5 to e15.5. By integrating across these data sets, we identify major cell populations of the developing face and annotate over 16,000 candidate enhancers by their cell type-specific epigenomic profile. Using retrospective analysis of known craniofacial enhancers in combination with single cell-resolved transgenic reporter assays, we show the value of these data for the prediction of in vivo cell type specificity. Taken together, our data provide a critical resource for genetic and developmental studies of human craniofacial development.

Project description:The genetic basis of craniofacial birth defects and general variation in human facial shape remains poorly understood. Distant-acting transcriptional enhancers are a major category of non-coding genome function and have been shown to control the fine-tuned spatiotemporal expression of genes during critical stages of craniofacial development. However, a lack of accurate maps of the genomic location and cell type-specific in vivo activities of all craniofacial enhancers prevents their systematic exploration in human genetics studies. Here, we combined transcriptome, histone modification, and chromatin accessibility profiling from different stages of human craniofacial development with single-cell analyses of the developing mouse face to create a comprehensive catalogue of the regulatory landscape of facial development at tissue- and single cell-resolution. In total, we identified approximately 14,000 enhancers across seven developmental stages from weeks 4 through 8 of human embryonic face development. To annotate the cell type specificity of human-mouse conserved enhancers, we performed single-cell RNA-seq and single-nucleus ATAC-seq of mouse craniofacial tissues from embryonic days e11.5 to e15.5. By integrating across these data sets, we identify major cell populations of the developing face and annotate over 16,000 candidate enhancers by their cell type-specific epigenomic profile. Using retrospective analysis of known craniofacial enhancers in combination with single cell-resolved transgenic reporter assays, we show the value of these data for the prediction of in vivo cell type specificity. Taken together, our data provide a critical resource for genetic and developmental studies of human craniofacial development.

Project description:The genetic basis of craniofacial birth defects and general variation in human facial shape remains poorly understood. Distant-acting transcriptional enhancers are a major category of non-coding genome function and have been shown to control the fine-tuned spatiotemporal expression of genes during critical stages of craniofacial development. However, a lack of accurate maps of the genomic location and cell type-specific in vivo activities of all craniofacial enhancers prevents their systematic exploration in human genetics studies. Here, we combined transcriptome, histone modification, and chromatin accessibility profiling from different stages of human craniofacial development with single-cell analyses of the developing mouse face to create a comprehensive catalogue of the regulatory landscape of facial development at tissue- and single cell-resolution. In total, we identified approximately 14,000 enhancers across seven developmental stages from weeks 4 through 8 of human embryonic face development. To annotate the cell type specificity of human-mouse conserved enhancers, we performed single-cell RNA-seq and single-nucleus ATAC-seq of mouse craniofacial tissues from embryonic days e11.5 to e15.5. By integrating across these data sets, we identify major cell populations of the developing face and annotate over 16,000 candidate enhancers by their cell type-specific epigenomic profile. Using retrospective analysis of known craniofacial enhancers in combination with single cell-resolved transgenic reporter assays, we show the value of these data for the prediction of in vivo cell type specificity. Taken together, our data provide a critical resource for genetic and developmental studies of human craniofacial development.

Project description:The genetic basis of craniofacial birth defects and general variation in human facial shape remains poorly understood. Distant-acting transcriptional enhancers are a major category of non-coding genome function and have been shown to control the fine-tuned spatiotemporal expression of genes during critical stages of craniofacial development. However, a lack of accurate maps of the genomic location and cell type-specific in vivo activities of all craniofacial enhancers prevents their systematic exploration in human genetics studies. Here, we combined transcriptome, histone modification, and chromatin accessibility profiling from different stages of human craniofacial development with single-cell analyses of the developing mouse face to create a comprehensive catalogue of the regulatory landscape of facial development at tissue- and single cell-resolution. In total, we identified approximately 14,000 enhancers across seven developmental stages from weeks 4 through 8 of human embryonic face development. To annotate the cell type specificity of human-mouse conserved enhancers, we performed single-cell RNA-seq and single-nucleus ATAC-seq of mouse craniofacial tissues from embryonic days e11.5 to e15.5. By integrating across these data sets, we identify major cell populations of the developing face and annotate over 16,000 candidate enhancers by their cell type-specific epigenomic profile. Using retrospective analysis of known craniofacial enhancers in combination with single cell-resolved transgenic reporter assays, we show the value of these data for the prediction of in vivo cell type specificity. Taken together, our data provide a critical resource for genetic and developmental studies of human craniofacial development.

Project description:The genetic basis of craniofacial birth defects and general variation in human facial shape remains poorly understood. Distant-acting transcriptional enhancers are a major category of non-coding genome function and have been shown to control the fine-tuned spatiotemporal expression of genes during critical stages of craniofacial development. However, a lack of accurate maps of the genomic location and cell type-specific in vivo activities of all craniofacial enhancers prevents their systematic exploration in human genetics studies. Here, we combined transcriptome, histone modification, and chromatin accessibility profiling from different stages of human craniofacial development with single-cell analyses of the developing mouse face to create a comprehensive catalogue of the regulatory landscape of facial development at tissue- and single cell-resolution. In total, we identified approximately 14,000 enhancers across seven developmental stages from weeks 4 through 8 of human embryonic face development. To annotate the cell type specificity of human-mouse conserved enhancers, we performed single-cell RNA-seq and single-nucleus ATAC-seq of mouse craniofacial tissues from embryonic days e11.5 to e15.5. By integrating across these data sets, we identify major cell populations of the developing face and annotate over 16,000 candidate enhancers by their cell type-specific epigenomic profile. Using retrospective analysis of known craniofacial enhancers in combination with single cell-resolved transgenic reporter assays, we show the value of these data for the prediction of in vivo cell type specificity. Taken together, our data provide a critical resource for genetic and developmental studies of human craniofacial development.

Project description:The genetic basis of craniofacial birth defects and general variation in human facial shape remains poorly understood. Distant-acting transcriptional enhancers are a major category of non-coding genome function and have been shown to control the fine-tuned spatiotemporal expression of genes during critical stages of craniofacial development. However, a lack of accurate maps of the genomic location and cell type-specific in vivo activities of all craniofacial enhancers prevents their systematic exploration in human genetics studies. Here, we combined transcriptome, histone modification, and chromatin accessibility profiling from different stages of human craniofacial development with single-cell analyses of the developing mouse face to create a comprehensive catalogue of the regulatory landscape of facial development at tissue- and single cell-resolution. In total, we identified approximately 14,000 enhancers across seven developmental stages from weeks 4 through 8 of human embryonic face development. To annotate the cell type specificity of human-mouse conserved enhancers, we performed single-cell RNA-seq and single-nucleus ATAC-seq of mouse craniofacial tissues from embryonic days e11.5 to e15.5. By integrating across these data sets, we identify major cell populations of the developing face and annotate over 16,000 candidate enhancers by their cell type-specific epigenomic profile. Using retrospective analysis of known craniofacial enhancers in combination with single cell-resolved transgenic reporter assays, we show the value of these data for the prediction of in vivo cell type specificity. Taken together, our data provide a critical resource for genetic and developmental studies of human craniofacial development.