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人类端粒酶重复序列添加持续性的DNA结合决定因素和细胞阈值

DNA-binding determinants and cellular thresholds for human telomerase repeat addition processivity.

作者信息

Wu Robert Alexander, Tam Jane, Collins Kathleen

机构信息

Department of Molecular and Cell Biology, University of California, Berkeley, Berkeley, CA, USA.

Department of Molecular and Cell Biology, University of California, Berkeley, Berkeley, CA, USA

出版信息

EMBO J. 2017 Jul 3;36(13):1908-1927. doi: 10.15252/embj.201796887. Epub 2017 May 11.

DOI:10.15252/embj.201796887
PMID:28495680
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5494469/
Abstract

The reverse transcriptase telomerase adds telomeric repeats to chromosome ends. Purified human telomerase catalyzes processive repeat synthesis, which could restore the full ~100 nucleotides of (TAG) lost from replicated chromosome ends as a single elongation event. Processivity inhibition is proposed to be a basis of human disease, but the impacts of different levels of processivity on telomere maintenance have not been examined. Here, we delineate side chains in the telomerase active-site cavity important for repeat addition processivity, determine how they contribute to duplex and single-stranded DNA handling, and test the cellular consequences of partial or complete loss of repeat addition processivity for telomere maintenance. Biochemical findings oblige a new model for DNA and RNA handling dynamics in processive repeat synthesis. Biological analyses implicate repeat addition processivity as essential for telomerase function. However, telomeres can be maintained by telomerases with lower than wild-type processivity. Furthermore, telomerases with low processivity dramatically elongate telomeres when overexpressed. These studies reveal distinct consequences of changes in telomerase repeat addition processivity and expression level on telomere elongation and length maintenance.

摘要

逆转录酶端粒酶向染色体末端添加端粒重复序列。纯化的人端粒酶催化持续性重复序列合成,这可以作为单个延伸事件,恢复从复制染色体末端丢失的约100个核苷酸的完整(TAG)。持续性抑制被认为是人类疾病的一个基础,但不同水平的持续性对端粒维持的影响尚未得到研究。在这里,我们描绘了端粒酶活性位点腔中对重复序列添加持续性很重要的侧链,确定它们如何有助于双链和单链DNA处理,并测试重复序列添加持续性部分或完全丧失对端粒维持的细胞后果。生化研究结果促使我们提出一个关于持续性重复序列合成中DNA和RNA处理动力学的新模型。生物学分析表明重复序列添加持续性是端粒酶功能所必需的。然而,端粒可以由持续性低于野生型的端粒酶维持。此外,持续性低的端粒酶在过表达时会显著延长端粒。这些研究揭示了端粒酶重复序列添加持续性和表达水平的变化对端粒延伸和长度维持的不同影响。

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