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Evf2 (Dlx6as) lncRNA 调节超保守增强子甲基化和相邻基因的差异转录控制。

Evf2 (Dlx6as) lncRNA regulates ultraconserved enhancer methylation and the differential transcriptional control of adjacent genes.

机构信息

Developmental Biology and Department of Pediatrics, Lurie Children's Research Center, and Feinberg School of Medicine, Northwestern University, Box 204, 2430 N. Halsted, Chicago, IL 60614, USA.

出版信息

Development. 2013 Nov;140(21):4407-16. doi: 10.1242/dev.099390. Epub 2013 Oct 2.

DOI:10.1242/dev.099390
PMID:24089468
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4007716/
Abstract

Several lines of evidence suggest that long non-coding RNA (lncRNA)-dependent mechanisms regulate transcription and CpG DNA methylation. Whereas CpG island methylation has been studied in detail, the significance of enhancer DNA methylation and its relationship with lncRNAs is relatively unexplored. Previous experiments proposed that the ultraconserved lncRNA Evf2 represses transcription through Dlx6 antisense (Dlx6as) transcription and methyl-CpG binding protein (MECP2) recruitment to the Dlx5/6 ultraconserved DNA regulatory enhancer (Dlx5/6ei) in embryonic day 13.5 medial ganglionic eminence (E13.5 MGE). Here, genetic epistasis experiments show that MECP2 transcriptional repression of Evf2 and Dlx5, but not Dlx6, occurs through antagonism of DLX1/2 in E13.5 MGE. Analysis of E13.5 MGE from mice lacking Evf2 and of partially rescued Evf2 transgenic mice shows that Evf2 prevents site-specific CpG DNA methylation of Dlx5/6ei in trans, without altering Dlx5/6 expression. Dlx1/2 loss increases CpG DNA methylation, whereas Mecp2 loss does not affect Dlx5/6ei methylation. Based on these studies, we propose a model in which Evf2 inhibits enhancer DNA methylation, effectively modulating competition between the DLX1/2 activator and MECP2 repressor. Evf2 antisense transcription and Evf2-dependent balanced recruitment of activator and repressor proteins enables differential transcriptional control of adjacent genes with shared DNA regulatory elements.

摘要

有几条证据表明,长非编码 RNA (lncRNA) 依赖的机制调节转录和 CpG DNA 甲基化。虽然 CpG 岛甲基化已经被详细研究过,但增强子 DNA 甲基化的意义及其与 lncRNA 的关系还相对未知。以前的实验提出,超保守 lncRNA Evf2 通过 Dlx6 反义转录(Dlx6as)和甲基-CpG 结合蛋白(MECP2)募集到 Dlx5/6 超保守 DNA 调节增强子(Dlx5/6ei)来抑制转录在胚胎第 13.5 天(E13.5)中脑隆起(MGE)。在这里,遗传上位性实验表明,MECP2 对 Evf2 和 Dlx5 的转录抑制,但不是 Dlx6,是通过在 E13.5 MGE 中拮抗 DLX1/2 发生的。对缺乏 Evf2 的小鼠和部分挽救的 Evf2 转基因小鼠的 E13.5 MGE 的分析表明,Evf2 在转录水平上防止 Dlx5/6ei 的特定 CpG DNA 甲基化,而不改变 Dlx5/6 的表达。Dlx1/2 的缺失增加了 CpG DNA 甲基化,而 Mecp2 的缺失并不影响 Dlx5/6ei 的甲基化。基于这些研究,我们提出了一个模型,即 Evf2 抑制增强子 DNA 甲基化,有效地调节 DLX1/2 激活子和 MECP2 抑制剂之间的竞争。Evf2 反义转录和 Evf2 依赖性激活子和抑制剂蛋白的平衡募集使具有共享 DNA 调节元件的相邻基因能够进行差异转录控制。

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