Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:Evolutionary changes in gene regulation during cortical development likely contributed to the expansion and specialization of the cortex in humans. However, the lack of a regulatory map of the human embryonic cortex has hindered identification of these changes and the biological processes they influenced. We performed genome-wide epigenetic profiling to compare promoter and enhancer activity during corticogenesis in human, rhesus, and mouse. We identified 2,855 promoters and 8,996 enhancers that have gained activity in human based on increased epigenetic marking. To detect biological pathways enriched for these changes, we mapped promoters and enhancers exhibiting epigenetic gains onto modules of co-expressed genes constructed using spatio-temporally rich expression data from developing human cortex. We identified multiple modules enriched in human lineage epigenetic gains. Gains in enriched modules were associated with genes functioning in neuronal proliferation and migration, cortical patterning, and the extracellular matrix. Gain-enriched modules also showed correlated gene expression patterns and similar transcription factor binding site enrichments in promoters and enhancers, suggesting they are connected by common regulatory mechanisms. Our results reveal coordinated patterns of potential regulatory changes associated with conserved developmental processes in corticogenesis, providing insight into human cortical evolution.

Project description:Evolutionary changes in gene regulation during cortical development likely contributed to the expansion and specialization of the cortex. However, the lack of a regulatory map of the embryonic cortex has hindered identification of these changes and the biological processes they influenced. We performed genome-wide epigenetic profiling to compare promoter and enhancer activity during corticogenesis in rhesus and mouse. We identified 2,855 promoters and 8,996 enhancers that have gained activity in based on increased epigenetic marking. To detect biological pathways enriched for these changes, we mapped promoters and enhancers exhibiting epigenetic gains onto modules of co-expressed genes constructed using spatio-temporally rich expression data from developing cortex. We identified multiple modules enriched in lineage epigenetic gains. Gains in enriched modules were associated with genes functioning in neuronal proliferation and migration, cortical patterning, and the extracellular matrix. Gain-enriched modules also showed correlated gene expression patterns and similar transcription factor binding site enrichments in promoters and enhancers, suggesting they are connected by common regulatory mechanisms. Our results reveal coordinated patterns of potential regulatory changes associated with conserved developmental processes in corticogenesis, providing insight into cortical evolution.

Project description:Evolutionary changes in promoter and enhancer activity during corticogenesis (non-human)

Project description:Genetic changes that modify the function of transcriptional enhancers have been linked to the evolution of biological diversity across species. Multiple studies have focused on the role of nucleotide substitutions, transposition, and insertions and deletions in altering enhancer function. Here we show that turnover of CpG islands (CGIs), which contribute to enhancer activation, is broadly associated with changes in enhancer activity across mammals, including humans. We integrated maps of CGIs and enhancer activity-associated histone modifications obtained from multiple tissues in nine mammalian species and found that CGI content in enhancers was strongly associated with increased histone modification levels. CGIs showed widespread turnover across species and species-specific CGIs were strongly enriched for enhancers exhibiting species-specific activity across all tissues and species we examined. Genes associated with enhancers with species-specific CGIs showed concordant biases in their expression, supporting that CGI turnover contributes to gene regulatory innovation. Our results also implicate CGI turnover in the evolution of Human Gain Enhancers (HGEs), which show increased activity in human embryonic development and may have contributed to the evolution of uniquely human traits. Using a humanized mouse model, we show that a highly conserved HGE with a large CGI absent from the mouse ortholog shows increased activity at the human CGI in the humanized mouse diencephalon. Collectively, our results point to CGI turnover as a mechanism driving gene regulatory changes potentially underlying trait evolution in mammals.

Project description:BackgroundGenetic changes that modify the function of transcriptional enhancers have been linked to the evolution of biological diversity across species. Multiple studies have focused on the role of nucleotide substitutions, transposition, and insertions and deletions in altering enhancer function. CpG islands (CGIs) have recently been shown to influence enhancer activity, and here we test how their turnover across species contributes to enhancer evolution.ResultsWe integrate maps of CGIs and enhancer activity-associated histone modifications obtained from multiple tissues in nine mammalian species and find that CGI content in enhancers is strongly associated with increased histone modification levels. CGIs show widespread turnover across species and species-specific CGIs are strongly enriched for enhancers exhibiting species-specific activity across all tissues and species. Genes associated with enhancers with species-specific CGIs show concordant biases in their expression, supporting that CGI turnover contributes to gene regulatory innovation. Our results also implicate CGI turnover in the evolution of Human Gain Enhancers (HGEs), which show increased activity in human embryonic development and may have contributed to the evolution of uniquely human traits. Using a humanized mouse model, we show that a highly conserved HGE with a large CGI absent from the mouse ortholog shows increased activity at the human CGI in the humanized mouse diencephalon.ConclusionsCollectively, our results point to CGI turnover as a mechanism driving gene regulatory changes potentially underlying trait evolution in mammals.

Project description:Sequence variation within enhancers plays a major role in both evolution and disease, yet its functional impact on transcription factor (TF) occupancy and enhancer activity remains poorly understood. Here, we assayed the binding of five essential TFs over multiple stages of embryogenesis in two distant Drosophila species (with 1.4 substitutions per neutral site), identifying thousands of orthologous enhancers with conserved or diverged combinatorial occupancy. We used these binding signatures to dissect two properties of developmental enhancers: (1) potential TF cooperativity, using signatures of co-associations and co-divergence in TF occupancy. This revealed conserved combinatorial binding despite sequence divergence, suggesting protein-protein interactions sustain conserved collective occupancy. (2) Enhancer in-vivo activity, revealing orthologous enhancers with conserved activity despite divergence in TF occupancy. Taken together, we identify enhancers with diverged motifs yet conserved occupancy and others with diverged occupancy yet conserved activity, emphasising the need to functionally measure the effect of divergence on enhancer activity.

Project description:Changes in the activity of transcriptional enhancers have been shown to influence phenotypic variation across species. However, it remains challenging to identify the sequence features associated with species differences in enhancer activity. Here we assessed the contribution of orphan CpG islands (oCGIs), which are regions enriched in CpG dinucleotides that are known to recruit chromatin modifiers and components of the transcriptional machinery. We integrated oCGIs in nine mammals with previously ascertained maps of chromatin modifications across multiple tissues, and found that species-specific oCGIs significantly co-localize with species-specific histone modification peaks. We focused on one enhancer of interest (hs754) which contains an oCGI in human but not in mouse, and overlaps an H3K27ac peak in the developing human brain, but not in mouse. We generated a humanized mouse model and profiled the locus using ChIP-seq, finding increased deposition of the histone modifications H3K27ac and H3K4me3 and gained CTCF binding sites in the humanized enhancer. ChIP-seq data for H3K27me3 was also generated and was not included in the final study, but is deposited here. We also measured gene expression in the humanized mouse and did not find any changes associated with the humanized enhancer, although using the datasets described above we found that genes near enhancers with species-specific oCGIs and species-specific activity show a species bias in expression. This work identifies oCGI turnover as a mechanism affecting mammalian enhancer evolution.

Project description:A long-standing question in gene regulation is how remote enhancers communicate with their target promoters, and specifically how chromatin topology dynamically relates to gene activation. Here, we combine genome editing and multi-color live imaging to simultaneously visualize physical enhancer-promoter interaction and transcription at the single-cell level in Drosophila embryos. By examining transcriptional activation of a reporter by the endogenous even-skipped enhancers, which are located 150 kb away, we identify three distinct topological conformation states and measure their transition kinetics. We show that sustained proximity of the enhancer to its target is required for activation. Transcription in turn affects the three-dimensional topology as it enhances the temporal stability of the proximal conformation and is associated with further spatial compaction. Furthermore, the facilitated long-range activation results in transcriptional competition at the locus, causing corresponding developmental defects. Our approach offers quantitative insight into the spatial and temporal determinants of long-range gene regulation and their implications for cellular fates.

Project description:Elucidating the regulatory mechanisms of human brain evolution is essential to understanding human cognition and mental disorders. We generated multi-omics profiles and constructed a high-resolution map of 3D genome architecture of rhesus macaque during corticogenesis. By comparing the 3D genomes of human, macaque and mouse brains, we identified many human-specific chromatin structure changes, including 499 topologically associating domains (TADs) and 1,266 chromatin loops. The human-specific loops are significantly enriched in enhancer-enhancer interactions and the regulated genes show human-specific expression changes in the subplate, a transient zone of the developing brain critical for neural circuit formation and plasticity. Notably, many human-specific sequence changes are located in the human-specific TAD boundaries and loop anchors, which may lead to the formation of new transcription factor binding sites and chromatin structures in human. Collectively, the presented data highlight the value of comparative 3D genome analyses in dissecting the regulatory mechanisms of brain development and evolution.