自主确定 DNA 甲基化状态的遗传元件的鉴定。

Identification of genetic elements that autonomously determine DNA methylation states.

机构信息

Friedrich Miescher Institute for Biomedical Research, Basel, Switzerland.

出版信息

Nat Genet. 2011 Oct 2;43(11):1091-7. doi: 10.1038/ng.946.

PMID:21964573

Abstract

Cytosine methylation is a repressive, epigenetically propagated DNA modification. Although patterns of DNA methylation seem tightly regulated in mammals, it is unclear how these are specified and to what extent this process entails genetic or epigenetic regulation. To dissect the role of the underlying DNA sequence, we sequentially inserted over 50 different DNA elements into the same genomic locus in mouse stem cells. Promoter sequences of approximately 1,000 bp autonomously recapitulated correct DNA methylation in pluripotent cells. Moreover, they supported proper de novo methylation during differentiation. Truncation analysis revealed that this regulatory potential is contained within small methylation-determining regions (MDRs). MDRs can mediate both hypomethylation and de novo methylation in cis, and their activity depends on developmental state, motifs for DNA-binding factors and a critical CpG density. These results demonstrate that proximal sequence elements are both necessary and sufficient for regulating DNA methylation and reveal basic constraints of this regulation.

摘要

胞嘧啶甲基化是一种抑制性的、具有表观遗传传播能力的 DNA 修饰。尽管哺乳动物中的 DNA 甲基化模式似乎受到严格调控，但目前尚不清楚这些模式是如何被指定的，以及在多大程度上需要遗传或表观遗传调控。为了剖析潜在 DNA 序列的作用，我们在小鼠干细胞中依次将 50 多个不同的 DNA 元件插入到同一个基因组位点。大约 1000 个碱基对的启动子序列在多能细胞中自主重现了正确的 DNA 甲基化。此外，它们还支持分化过程中的从头甲基化。截断分析表明，这种调控潜力包含在小的甲基化决定区域（MDR）中。MDR 可以在顺式中介导低甲基化和从头甲基化，其活性取决于发育状态、DNA 结合因子的基序和关键的 CpG 密度。这些结果表明，近端序列元件对于调节 DNA 甲基化既必要又充分，并揭示了这种调节的基本限制。

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自主确定 DNA 甲基化状态的遗传元件的鉴定。

Identification of genetic elements that autonomously determine DNA methylation states.

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