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快速进化的着丝粒特异性组蛋白在拟南芥中具有严格的功能要求。

The rapidly evolving centromere-specific histone has stringent functional requirements in Arabidopsis thaliana.

机构信息

Department of Chemistry and Biochemistry, Universityof California, Los Angeles, CA 90095, USA.

出版信息

Genetics. 2010 Oct;186(2):461-71. doi: 10.1534/genetics.110.120337. Epub 2010 Jul 13.

DOI:10.1534/genetics.110.120337
PMID:20628040
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2954480/
Abstract

Centromeres control chromosome inheritance in eukaryotes, yet their DNA structure and primary sequence are hypervariable. Most animals and plants have megabases of tandem repeats at their centromeres, unlike yeast with unique centromere sequences. Centromere function requires the centromere-specific histone CENH3 (CENP-A in human), which replaces histone H3 in centromeric nucleosomes. CENH3 evolves rapidly, particularly in its N-terminal tail domain. A portion of the CENH3 histone-fold domain, the CENP-A targeting domain (CATD), has been previously shown to confer kinetochore localization and centromere function when swapped into human H3. Furthermore, CENP-A in human cells can be functionally replaced by CENH3 from distantly related organisms including Saccharomyces cerevisiae. We have used cenh3-1 (a null mutant in Arabidopsis thaliana) to replace endogenous CENH3 with GFP-tagged variants. A H3.3 tail domain-CENH3 histone-fold domain chimera rescued viability of cenh3-1, but CENH3's lacking a tail domain were nonfunctional. In contrast to human results, H3 containing the A. thaliana CATD cannot complement cenh3-1. GFP-CENH3 from the sister species A. arenosa functionally replaces A. thaliana CENH3. GFP-CENH3 from the close relative Brassica rapa was targeted to centromeres, but did not complement cenh3-1, indicating that kinetochore localization and centromere function can be uncoupled. We conclude that CENH3 function in A. thaliana, an organism with large tandem repeat centromeres, has stringent requirements for functional complementation in mitosis.

摘要

着丝粒控制真核生物的染色体遗传,但它们的 DNA 结构和一级序列高度可变。大多数动植物的着丝粒都有兆碱基的串联重复序列,而酵母的着丝粒序列则是独特的。着丝粒的功能需要着丝粒特异性组蛋白 CENH3(人类中的 CENP-A),它取代了着丝粒核小体中的组蛋白 H3。CENH3 进化迅速,特别是在其 N 端尾部结构域。CENH3 组蛋白折叠结构域的一部分,即着丝粒靶向结构域(CATD),以前已经证明可以在交换到人类 H3 时赋予动粒定位和着丝粒功能。此外,人类细胞中的 CENP-A 可以被来自远缘生物的 CENH3 功能替代,包括酿酒酵母。我们使用 cenh3-1(拟南芥中的一个缺失突变体)用 GFP 标记的变体替换内源性 CENH3。H3.3 尾部结构域-CENH3 组蛋白折叠结构域嵌合体拯救了 cenh3-1 的活力,但缺乏尾部结构域的 CENH3 是无功能的。与人类的结果相反,含有拟南芥 CATD 的 H3 不能补充 cenh3-1。来自姐妹种拟南芥的 GFP-CENH3 功能上取代了拟南芥的 CENH3。来自近亲芸薹属的 GFP-CENH3 被靶向到着丝粒,但不能补充 cenh3-1,这表明动粒定位和着丝粒功能可以解耦。我们的结论是,在拟南芥这个拥有大型串联重复着丝粒的生物体中,CENH3 的功能在有丝分裂中具有严格的功能互补要求。

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