Project description:An understanding of how genetic variants affect chromatin accessibility in unique cellular context remains poorly understood. Here, we generated single-cell chromatin accessibility profiles in nearly 200 diverse maize inbred lines, revealing for the first time variants that affect chromatin accessibility in distinct cellular contexts.

Project description:Although gene expression divergence has long been postulated to be the primary driver of human evolution, identifying the genes and genetic variants underlying uniquely human traits has proven to be quite challenging. Theory suggests that cell type-specific cis-regulatory variants may fuel evolutionary adaptation due to the specificity of their effects. These variants can precisely tune the expression of a single gene in a single cell type, avoiding the potentially deleterious consequences of trans-acting changes and non-cell type-specific changes that can impact many genes and cell types, respectively. It has recently become possible to quantify human-specific cis-acting regulatory divergence by measuring allele-specific expression in human-chimpanzee hybrid cells—the product of fusing induced pluripotent stem (iPS) cells of each species in vitro. However, these cis-regulatory changes have only been explored in a limited number of tissues and cell types. Here, we quantify human-chimpanzee cis-regulatory divergence in gene expression and chromatin accessibility across six cell types, enabling the identification of highly cell type-specific cis-regulatory changes. We find that cell type-specific genes and regulatory elements evolve faster than those shared across cell types. Furthermore, we identify several instances of lineage-specific natural selection that may have played key roles in specific cell types, such as coordinated changes in the cis-regulation of dozens of genes involved in neuronal firing in motor neurons. Finally, using novel metrics and a machine learning model, we identify genetic variants that likely alter chromatin accessibility and transcription factor binding, leading to neuron-specific changes in the expression of the neurodevelopmentally important genes FABP7 and GAD1. Overall, our results demonstrate that integrative analysis of cis-regulatory divergence in chromatin accessibility and gene expression across cell types is a promising approach to identify the specific genes and genetic variants that make us human.

Project description:Although gene expression divergence has long been postulated to be the primary driver of human evolution, identifying the genes and genetic variants underlying uniquely human traits has proven to be quite challenging. Theory suggests that cell type-specific cis-regulatory variants may fuel evolutionary adaptation due to the specificity of their effects. These variants can precisely tune the expression of a single gene in a single cell type, avoiding the potentially deleterious consequences of trans-acting changes and non-cell type-specific changes that can impact many genes and cell types, respectively. It has recently become possible to quantify human-specific cis-acting regulatory divergence by measuring allele-specific expression in human-chimpanzee hybrid cells—the product of fusing induced pluripotent stem (iPS) cells of each species in vitro. However, these cis-regulatory changes have only been explored in a limited number of tissues and cell types. Here, we quantify human-chimpanzee cis-regulatory divergence in gene expression and chromatin accessibility across six cell types, enabling the identification of highly cell type-specific cis-regulatory changes. We find that cell type-specific genes and regulatory elements evolve faster than those shared across cell types. Furthermore, we identify several instances of lineage-specific natural selection that may have played key roles in specific cell types, such as coordinated changes in the cis-regulation of dozens of genes involved in neuronal firing in motor neurons. Finally, using novel metrics and a machine learning model, we identify genetic variants that likely alter chromatin accessibility and transcription factor binding, leading to neuron-specific changes in the expression of the neurodevelopmentally important genes FABP7 and GAD1. Overall, our results demonstrate that integrative analysis of cis-regulatory divergence in chromatin accessibility and gene expression across cell types is a promising approach to identify the specific genes and genetic variants that make us human.

Project description:Accurate control of dormancy release and germination is critical for successful plantlet establishment. In this study, we characterized mutants of Arabidopsis MAP kinase 8 (MPK8) presenting altered dormancy. We identified Teosinte Branched1/Cycloidea/Proliferating cell factor 14 (TCP14), a key transcription factor for germination, as a partner of MPK8 and investigated the processes controlled by MPK8-TCP14 pathway. Kinase assay was performed using immunoprecipitated MPK8-HA protein and recombinant GST-TCP14 protein as target to find TCP14 MPK8-specific phosphorylation sites.

Project description:Current catalogs of regulatory sequences in the human genome are still incomplete and lack cell type resolution. To profile the activity of gene regulatory elements in diverse cell types and tissues in the human body, we applied single-cell chromatin accessibility assays to 30 adult human tissue types from multiple donors. We integrated these datasets with single-cell chromatin accessibility data from 15 fetal tissue types to reveal the status of open chromatin for approximately 1.2 million candidate cis-regulatory elements (cCREs) in 222 distinct cell types comprised of >1.3 million nuclei. We used these chromatin accessibility maps to delineate cell type-specificity of fetal and adult human cCREs and to systematically interpret the noncoding variants associated with complex human traits and diseases. This rich resource provides a foundation for the analysis of gene regulatory programs in human cell types across tissues, life stages, and organ systems.

Project description:Over 90% of genetic variants associated with complex human traits map to non-coding regions, but little is understood about how they modulate gene regulation in health and disease. One possible mechanism is that genetic variants affect the activity of one or more cis-regulatory elements leading to gene expression variation in specific cell types. To identify such cases, we analyzed Assay for Transposase-Accessible Chromatin (ATAC-seq) and RNA-seq profiles from activated primary CD4 + T cells of up to 105 healthy donors. We found that regions of chromatin accessibility (ATAC-peaks) are co-accessible at kilobase and megabase scales, in patterns consistent with the 3D organization of chromosomes measured by in situ Hi-C in T cells. Genetic variants located within ATAC-peaks often affected the accessibility of the corresponding peak and any co-accessible peaks. They also disrupt binding sites for transcription factors important for CD4 + T cell differentiation and activation, overlap and mediate expression QTLs from the same cells, and are enriched for autoimmune disease variants. Our results provide insights into how natural genetic variants modulate cis-regulatory elements, in isolation or in concert, to influence gene expression in primary immune cells that play a key role in many human diseases.

Project description:TCP (TEOSINTE BRANCHED1/CYCLOIDEA/PCF1) transcription factors control developmental processes in plants. We identified direct target genes of the Arabidopsis class I TCP20 protein in leaf development based on a glucocorticoid receptor induction assay and genome-wide expression studies. For this, we tagged TCP20 with a glucucorticoid receptor (GR) domain and transformed the resulting TCP20-GR construct into tcp20 knockout plants. Induction of these and wild type controls was done with Dexamethasone and Cycloheximide. Plants were harvested 8 h after induction, uninduced plants were taken as control. In sum, 8 samples, each pools of 30 seedlings. Wild type and TCP20-GR plants at induction times t=0 and t=8, in two biological replicates.

Project description:Deciphering cis-regulatory logic with 100 million synthetic promoters

Project description:The purpose was to show that reprogrammed TFB variants are rewired into the gene regulatory network and create global transcriptional changes. Global transcriptional changes in ?ura3, ?tfbD and ?tfbE and all synthetic TFB variants (including vector control) in the ?tfbD genetic background were determined for cultures grown at 25°C and 37°C. Each synthetic TFB variant was controlled by either PtfbD or PtfbE promoters. Two temperatures (25C) vs (37C) were tested with three OD points representing early (0.2), mid (0.4) and late (0.8) log phases. Each sample was run twice with dye flip between sample and reference RNA

Project description:Modification of cis regulatory elements to produce differences in gene expression level, localization, and timing is an important mechanism by which organisms evolve divergent adaptations. To examine gene regulatory change during the domestication of maize from its wild progenitor, teosinte, we assessed allele-specific expression in a collection of maize and teosinte inbreds and their F1 hybrids using three tissues from different developmental stages. Our use of F1 hybrids represents the first study in a domesticated crop and wild progenitor that dissects cis and trans regulatory effects to examine characteristics of genes under various cis and trans regulatory regimes. We find evidence for consistent cis regulatory divergence that differentiates maize from teosinte in approximately 4% of genes. These genes are significantly correlated with genes under selection during domestication and crop improvement, suggesting an important role for cis regulatory elements in maize evolution. We assayed genome-wide cis and trans regulatory differences between maize and its wild progenitor, teosinte, using deep RNA sequencing in F1 hybrid and parent inbred lines for three tissue types (ear, leaf and stem) followed by assessment of allele-specific gene expression.