水稻4号染色体着丝粒的结构特征。

Structural features of the rice chromosome 4 centromere.

作者信息

Zhang Yu, Huang Yuchen, Zhang Lei, Li Ying, Lu Tingting, Lu Yiqi, Feng Qi, Zhao Qiang, Cheng Zhukuan, Xue Yongbiao, Wing Rod A, Han Bin

机构信息

National Center for Gene Research, Shanghai Institutes for Biological Sciences, Chinese Academy of Sciences, 500 Caobao Road, Shanghai 200233, China.

出版信息

Nucleic Acids Res. 2004 Apr 2;32(6):2023-30. doi: 10.1093/nar/gkh521. Print 2004.

DOI:10.1093/nar/gkh521

PMID:15064362

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC390372/

Abstract

A complete sequence of a chromosome centromere is necessary for fully understanding centromere function. We reported the sequence structures of the first complete rice chromosome centromere through sequencing a large insert bacterial artificial chromosome clone-based contig, which covered the rice chromosome 4 centromere. Complete sequencing of the 124-kb rice chromosome 4 centromere revealed that it consisted of 18 tracts of 379 tandemly arrayed repeats known as CentO and a total of 19 centromeric retroelements (CRs) but no unique sequences were detected. Four tracts, composed of 65 CentO repeats, were located in the opposite orientation, and 18 CentO tracts were flanked by 19 retroelements. The CRs were classified into four types, and the type I retroelements appeared to be more specific to rice centromeres. The preferential insert of the CRs among CentO repeats indicated that the centromere-specific retroelements may contribute to centromere expansion during evolution. The presence of three intact retrotransposons in the centromere suggests that they may be responsible for functional centromere initiation through a transcription-mediated mechanism.

摘要

完整的染色体着丝粒序列对于全面理解着丝粒功能是必要的。我们通过对一个基于大插入细菌人工染色体克隆的重叠群进行测序，报道了首个完整的水稻染色体着丝粒的序列结构，该重叠群覆盖了水稻第4号染色体着丝粒。对124千碱基对的水稻第4号染色体着丝粒进行全序列测定显示，它由18个包含379个串联排列的被称为CentO的重复序列的片段以及总共19个着丝粒反转录元件（CRs）组成，但未检测到独特序列。由65个CentO重复序列组成的4个片段以相反方向排列，18个CentO片段两侧各有19个反转录元件。CRs被分为四种类型，I型反转录元件似乎对水稻着丝粒更具特异性。CRs在CentO重复序列中的优先插入表明，着丝粒特异性反转录元件可能在进化过程中对着丝粒扩展起作用。着丝粒中存在三个完整的反转录转座子表明，它们可能通过转录介导机制负责功能性着丝粒的起始。

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