Project description:3-dimensional (3D) genome conformation is central to gene expression regulation, yet our understanding of how rapid transcriptional responses, transcriptional memory, and integration of different environmental signals are orchestrated in the 3D genome is limited. Here, we study various aspects of the inflammatory response in macrophages using transcriptomic, epigenomic, and genome conformation mapping technologies, including high-resolution Micro-Capture C. We report that interleukine-4 (IL-4) stably rewires the 3D genome conformation of macrophages and juxtaposes endotoxin-, interferon-gamma-, and dexamethasone-activated enhancers to cognate gene promoters to support enhanced gene expression. IL-4-driven conformational change is indispensable for the integration of IL-4- and endotoxin-induced enhanced and synergistic transcriptional responses, provides short-term transcriptional memory, and can occur in the absence of IL-4-induced epigenetic and transcriptional changes. Our work reveals that IL-4-driven 3D genome conformation is required to shape macrophage plasticity to subsequent immunological responses, integrate distinct inflammatory signals, and provides memory.

Project description:3-dimensional (3D) genome conformation is central to gene expression regulation, yet our understanding of how rapid transcriptional responses, transcriptional memory, and integration of different environmental signals are orchestrated in the 3D genome is limited. Here, we study various aspects of the inflammatory response in macrophages using transcriptomic, epigenomic, and genome conformation mapping technologies, including high-resolution Micro-Capture C. We report that interleukine-4 (IL-4) stably rewires the 3D genome conformation of macrophages and juxtaposes endotoxin-, interferon-gamma-, and dexamethasone-activated enhancers to cognate gene promoters to support enhanced gene expression. IL-4-driven conformational change is indispensable for the integration of IL-4- and endotoxin-induced enhanced and synergistic transcriptional responses, provides short-term transcriptional memory, and can occur in the absence of IL-4-induced epigenetic and transcriptional changes. Our work reveals that IL-4-driven 3D genome conformation is required to shape macrophage plasticity to subsequent immunological responses, integrate distinct inflammatory signals, and provides memory.

Project description:3-dimensional (3D) genome conformation is central to gene expression regulation, yet our understanding of how rapid transcriptional responses, transcriptional memory, and integration of different environmental signals are orchestrated in the 3D genome is limited. Here, we study various aspects of the inflammatory response in macrophages using transcriptomic, epigenomic, and genome conformation mapping technologies, including high-resolution Micro-Capture C. We report that interleukine-4 (IL-4) stably rewires the 3D genome conformation of macrophages and juxtaposes endotoxin-, interferon-gamma-, and dexamethasone-activated enhancers to cognate gene promoters to support enhanced gene expression. IL-4-driven conformational change is indispensable for the integration of IL-4- and endotoxin-induced enhanced and synergistic transcriptional responses, provides short-term transcriptional memory, and can occur in the absence of IL-4-induced epigenetic and transcriptional changes. Our work reveals that IL-4-driven 3D genome conformation is required to shape macrophage plasticity to subsequent immunological responses, integrate distinct inflammatory signals, and provides memory.

Project description:Regulation of transcriptional signal integration and memory by inflammation-induced chromosome conformation

Project description:Regulation of transcriptional signal integration and memory by inflammation-induced chromosome conformation [MCC]

Project description:Regulation of transcriptional signal integration and memory by inflammation-induced chromosome conformation [ATAC-Seq]

Project description:Regulation of transcriptional signal integration and memory by inflammation-induced chromosome conformation [ChIP-Seq]

Project description:Regulation of transcriptional signal integration and memory by inflammation-induced chromosome conformation [Hi-C]

Project description:The 3-dimensional (3D) conformation of chromatin inside the nucleus is integral to a variety of nuclear processes including transcriptional regulation, DNA replication, and DNA damage repair. Aberrations in 3D chromatin conformation have been implicated in developmental abnormalities and cancer. Despite the importance of 3D chromatin conformation to cellular function and human health, little is known about how 3D chromatin conformation varies in the human population, or whether DNA sequence variation between individuals influences 3D chromatin conformation. To address these questions, we performed Hi-C on Lymphoblastoid Cell Lines (LCLs) from a panel of 20 individuals. We identify thousands of regions across the genome where 3D chromatin conformation varies between individuals and find that these conformational variations are often accompanied by variations in gene expression, histone modifications, and transcription factor (TF) binding. Moreover, we find that DNA sequence variation influences several features of 3D chromatin conformation including loop strength, contact insulation, contact directionality and density of local cis contacts. We map hundreds of Quantitative Trait Loci (QTLs) associated with 3D chromatin features and find evidence that some of these same variants are associated at modest levels with other molecular phenotypes as well as complex disease risk. Our results demonstrate that common DNA sequence variants can influence 3D chromatin conformation, pointing to a more pervasive role for 3D chromatin conformation in human phenotypic variation than previously recognized.

Project description:Purpose: we utilized a mouse model that permanently labels neurons activated throughout a specific experience to decipher the interplay between chromatin accessibility, 3D-chromatin architecture and transcriptional changes across different memory phases. Non activated (basal) and activated neurons during memory encoding (early), consolidation (late) and recall (reactivated) were sorted and subjected to nuclear RNA sequencing (nRNA-seq) to determine gene expression, ATAC-seq (Assay for Transposase-Accessible Chromatin using sequencing) to assess chromatin accessibility, chromosome conformation capture (Hi-C) to identify global 3D -genome architecture and promoter capture Hi-C to identify the long range promoter-enhancer interactions. Results: our data demonstrates that the initial phase of memory formation alters the chromatin accessibility landscape of activated neurons, with long lasting stable changes occurring predominantly within enhancer regions. Moreover, many of these enhancers did not return to their baseline state after stimulation ceased, but remain accessible and stable throughout all memory phases.