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OCT2 预定位促进体液免疫中的细胞命运转变和染色质构象变化。

OCT2 pre-positioning facilitates cell fate transition and chromatin architecture changes in humoral immunity.

机构信息

Caryl and Israel Englander Institute for Precision Medicine, Institute for Computational Biomedicine, Weill Cornell Medicine, New York, NY, USA.

Computational Biology and Medicine Tri-Institutional PhD Program, Weill Cornell Medicine, New York, NY, USA.

出版信息

Nat Immunol. 2021 Oct;22(10):1327-1340. doi: 10.1038/s41590-021-01025-w. Epub 2021 Sep 23.

DOI:10.1038/s41590-021-01025-w
PMID:34556886
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9829245/
Abstract

During the germinal center (GC) reaction, B cells undergo profound transcriptional, epigenetic and genomic architectural changes. How such changes are established remains unknown. Mapping chromatin accessibility during the humoral immune response, we show that OCT2 was the dominant transcription factor linked to differential accessibility of GC regulatory elements. Silent chromatin regions destined to become GC-specific super-enhancers (SEs) contained pre-positioned OCT2-binding sites in naive B cells (NBs). These preloaded SE 'seeds' featured spatial clustering of regulatory elements enriched in OCT2 DNA-binding motifs that became heavily loaded with OCT2 and its GC-specific coactivator OCAB in GC B cells (GCBs). SEs with high abundance of pre-positioned OCT2 binding preferentially formed long-range chromatin contacts in GCs, to support expression of GC-specifying factors. Gain in accessibility and architectural interactivity of these regions were dependent on recruitment of OCAB. Pre-positioning key regulators at SEs may represent a broadly used strategy for facilitating rapid cell fate transitions.

摘要

在生发中心(GC)反应期间,B 细胞经历深刻的转录、表观遗传和基因组结构变化。这些变化是如何建立的仍然未知。通过绘制体液免疫反应过程中的染色质可及性图谱,我们发现 OCT2 是与 GC 调控元件差异可及性相关的主要转录因子。注定成为 GC 特异性超级增强子(SE)的沉默染色质区域在幼稚 B 细胞(NB)中包含预先定位的 OCT2 结合位点。这些预先加载的 SE“种子”具有富含 OCT2 DNA 结合基序的调控元件的空间聚类,这些基序在 GC B 细胞(GCB)中被 OCT2 和其 GC 特异性共激活因子 OCAB 大量加载。具有高含量预先定位的 OCT2 结合的 SE 优先在 GC 中形成长距离染色质接触,以支持 GC 特异性因子的表达。这些区域的可及性和结构互作的增加依赖于 OCAB 的募集。在 SE 处预先定位关键调节剂可能代表一种广泛使用的策略,用于促进快速的细胞命运转变。

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