中心体反向元件编码的小 RNA 超表达会损害 CENP-A 的加载。

Hypermorphic expression of centromeric retroelement-encoded small RNAs impairs CENP-A loading.

机构信息

Department of Molecular and Cell Biology, University of Connecticut, Storrs, CT 06269, USA.

出版信息

Chromosome Res. 2013 Mar;21(1):49-62. doi: 10.1007/s10577-013-9337-0. Epub 2013 Feb 8.

Abstract

The proper functioning of centromeres requires a complex cascade of epigenetic events involving chromatin and kinetochore assembly; however, the precise mechanism by which this cascade proceeds is unknown. The pivotal event during kinetochore formation is the "loading," or deposition, of CENP-A. This histone H3 variant is specific to centromeres and replaces conventional H3 in centromeric chromatin. Failure to load CENP-A into mammalian centromeres in late telophase/early G1 of the cell cycle leads to malsegregation and cell division defects in subsequent cell cycles. Mounting evidence supports the hypothesis that an RNA component is involved, although how RNAs participate in centromere formation in mammals has remained unknown. Using the marsupial model, the tammar wallaby, we show that centromeric retroelements produce small RNAs and that hypermorphic expression of these centromeric small RNAs results in disruption of CENP-A localization. We propose that tight regulation of the processing of this new class of small RNAs, crasiRNAs, is an integral component of the epigenetic framework necessary for centromere establishment.

摘要

着丝粒的正常功能需要涉及染色质和动粒组装的复杂级联表观遗传事件；然而，该级联进行的确切机制尚不清楚。在动粒形成过程中的关键事件是“加载”或沉积 CENP-A。这种组蛋白 H3 变体是着丝粒特有的，取代了着丝粒染色质中的常规 H3。在细胞周期的末期/早期 G1 期，如果哺乳动物着丝粒中未能加载 CENP-A，则会导致随后的细胞周期中染色体分离错误和细胞分裂缺陷。越来越多的证据支持这样一种假设，即涉及 RNA 成分，尽管 RNA 如何参与哺乳动物着丝粒的形成仍然未知。我们使用有袋动物模型——塔马尔沙袋鼠，表明着丝粒反转录元件产生小 RNA，并且这些着丝粒小 RNA 的超量表达导致 CENP-A 定位的破坏。我们提出，这种新型小 RNA（crasiRNA）的加工的严格调控是建立着丝粒所必需的表观遗传框架的一个组成部分。

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中心体反向元件编码的小 RNA 超表达会损害 CENP-A 的加载。

Hypermorphic expression of centromeric retroelement-encoded small RNAs impairs CENP-A loading.

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