Alyssa Kearly, Prontip Saelee, Jonathan Bard, Satrajit Sinha, Anne Satterthwaite, Lee Ann Garrett-Sinha
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Here we identify a topologically-associating domain (TAD) in the chromatin of B cells that includes the mouse Ets1 gene locus and describe an interaction hub that extends over 100 kb upstream and into the gene body. Additionally, we compile epigenetic datasets to find several putative regulatory elements within the interaction hub by identifying regions of high DNA accessibility and enrichment of active enhancer histone marks. Using reporter constructs, we determine that DNA sequences within this interaction hub are sufficient to direct reporter gene expression in lymphoid tissues of transgenic mice. Further analysis indicates that the reporter construct drives faithful expression of the reporter gene in mouse B cells, but variegated expression in T cells, suggesting the existence of T cell regulatory elements outside this region. To investigate how the downregulation of Ets1 transcription is associated with alterations in the epigenetic landscape of stimulated B cells, we performed ATAC-seq in resting and BCR-stimulated primary B cells and identified four regions within and upstream of the Ets1 locus that undergo changes in chromatin accessibility that correlate to Ets1 gene expression. Interestingly, functional analysis of several putative Ets1 regulatory elements using luciferase constructs suggested a high level of functional redundancy. 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引用次数: 0
摘要
静息的 B 细胞和 T 细胞中转录因子 Ets1 的水平很高,但通过抗原受体和 Toll 样受体(TLRs)发出信号时,Ets1 的水平会被下调。小鼠体内 Ets1 的缺失会导致免疫细胞过度活化和自身免疫综合症的发生,在自身免疫性疾病的情况下,也观察到人类 PBMCs 中 Ets1 的表达减少。在 B 细胞中,Ets1 的作用是防止过早活化和分化为分泌抗体的细胞。鉴于 Ets1 在免疫反应中的这些重要作用,需要对 Ets1 基因表达水平进行严格控制,以保持体内平衡。然而,控制 Ets1 基因表达的遗传调控元件仍然相对未知。在这里,我们确定了 B 细胞染色质中包括小鼠 Ets1 基因座的拓扑关联域(TAD),并描述了一个延伸至基因体上游 100 kb 以上的相互作用中心。此外,我们还汇编了表观遗传学数据集,通过识别高DNA可及性区域和活性增强子组蛋白标记的富集,在相互作用中心找到了几个推定的调控元件。利用报告基因构建体,我们确定该相互作用中枢内的 DNA 序列足以引导报告基因在转基因小鼠淋巴组织中的表达。进一步的分析表明,报告基因构建体在小鼠 B 细胞中能驱动报告基因的忠实表达,但在 T 细胞中的表达却参差不齐,这表明在该区域之外还存在 T 细胞调控元件。为了研究 Ets1 转录的下调如何与受刺激 B 细胞表观遗传景观的改变相关联,我们在静息和 BCR 刺激的原代 B 细胞中进行了 ATAC-seq 分析,发现 Ets1 基因座内和上游有四个区域的染色质可及性发生了变化,这些变化与 Ets1 基因的表达相关。有趣的是,利用荧光素酶构建物对几个假定的 Ets1 调控元件进行的功能分析表明,这些元件具有高度的功能冗余性。总之,我们的研究揭示了一个由调控元件和转录因子组成的复杂网络,它协调了 Ets1 的 B 细胞特异性表达。
Sequences within and upstream of the mouse Ets1 gene drive high level expression in B cells, but are not sufficient for consistent expression in T cells
The levels of transcription factor Ets1 are high in resting B and T cells, but are downregulated by signaling through antigen receptors and Toll-like receptors (TLRs). Loss of Ets1 in mice leads to excessive immune cell activation and development of an autoimmune syndrome and reduced Ets1 expression has been observed in human PBMCs in the context of autoimmune diseases. In B cells, Ets1 serves to prevent premature activation and differentiation to antibody-secreting cells. Given these important roles for Ets1 in the immune response, stringent control of Ets1 gene expression levels is required for homeostasis. However, the genetic regulatory elements that control expression of the Ets1 gene remain relatively unknown. Here we identify a topologically-associating domain (TAD) in the chromatin of B cells that includes the mouse Ets1 gene locus and describe an interaction hub that extends over 100 kb upstream and into the gene body. Additionally, we compile epigenetic datasets to find several putative regulatory elements within the interaction hub by identifying regions of high DNA accessibility and enrichment of active enhancer histone marks. Using reporter constructs, we determine that DNA sequences within this interaction hub are sufficient to direct reporter gene expression in lymphoid tissues of transgenic mice. Further analysis indicates that the reporter construct drives faithful expression of the reporter gene in mouse B cells, but variegated expression in T cells, suggesting the existence of T cell regulatory elements outside this region. To investigate how the downregulation of Ets1 transcription is associated with alterations in the epigenetic landscape of stimulated B cells, we performed ATAC-seq in resting and BCR-stimulated primary B cells and identified four regions within and upstream of the Ets1 locus that undergo changes in chromatin accessibility that correlate to Ets1 gene expression. Interestingly, functional analysis of several putative Ets1 regulatory elements using luciferase constructs suggested a high level of functional redundancy. Taken together our studies reveal a complex network of regulatory elements and transcription factors that coordinate the B cell-specific expression of Ets1