Epigenetic priming of embryonic enhancer elements coordinates developmental gene networks

Christopher D Todd, Jannat Ijaz, Fereshteh Torabi, Oleksandr Dovgusha, Stephen Bevan, Olivia Cracknell, Tim Lohoff, Stephen Clark, Ricard Argelaguet, Juliette Pearce, Ioannis Kafetzopoulos, Alice Santambrogio, Jennifer Nichols, Ferdinand von Meyenn, Ufuk Guenesdogan, Stefan Schoenfelder, Wolf Reik
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Abstract

Embryonic development requires the accurate spatiotemporal execution of cell lineage-specific gene expression programs, which are controlled by transcriptional enhancers. Developmental enhancers adopt a primed chromatin state prior to their activation; however, how this primed enhancer state is established, maintained, and how it affects the regulation of developmental gene networks remains poorly understood. Here, we use comparative multi-omic analyses of human and mouse early embryonic development to identify subsets of post-gastrulation lineage-specific enhancers which are epigenetically primed ahead of their activation, marked by the histone modification H3K4me1 within the epiblast. We show that epigenetic priming occurs at lineage-specific enhancers for all three germ layers, and that epigenetic priming of enhancers confers lineage-specific regulation of key developmental gene networks. Surprisingly in some cases, lineage-specific enhancers are epigenetically marked already in the zygote, weeks before their activation during lineage specification. Moreover, we outline a generalisable strategy to use naturally occurring human genetic variation to delineate important sequence determinants of primed enhancer function. Our findings identify an evolutionarily conserved program of enhancer priming and begin to dissect the temporal dynamics and mechanisms of its establishment and maintenance during early mammalian development.
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胚胎增强子元件的表观遗传引物协调发育基因网络
胚胎发育需要细胞系特异性基因表达程序的准确时空执行,而这些程序是由转录增强子控制的。发育增强子在被激活之前会呈现一种引物染色质状态;然而,人们对这种引物增强子状态是如何建立、维持以及如何影响发育基因网络的调控仍然知之甚少。在这里,我们通过对人类和小鼠早期胚胎发育的多组学比较分析,确定了在上胚层内以组蛋白修饰 H3K4me1 为标志的、在激活前具有表观遗传学引物的后母系特异性增强子子集。我们的研究表明,表观遗传启动发生在所有三个胚层的世系特异性增强子上,增强子的表观遗传启动赋予了关键发育基因网络的世系特异性调控。令人惊奇的是,在某些情况下,特异性增强子在胎儿时期就已被表观遗传标记,这比它们在发育过程中被激活早了数周。此外,我们还概述了一种可推广的策略,即利用自然发生的人类遗传变异来划定启动增强子功能的重要序列决定因素。我们的研究结果确定了增强子引物的进化保守程序,并开始剖析其在哺乳动物早期发育过程中建立和维持的时间动态和机制。
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