利用高分辨率光镊观察连续的端粒酶催化反应。

Observation of processive telomerase catalysis using high-resolution optical tweezers.

机构信息

Institute for Quantitative Health Sciences and Engineering, Michigan State University, East Lansing, MI, USA.

Department of Physics and Astronomy, Michigan State University, East Lansing, MI, USA.

出版信息

Nat Chem Biol. 2020 Jul;16(7):801-809. doi: 10.1038/s41589-020-0478-0. Epub 2020 Feb 17.

DOI:10.1038/s41589-020-0478-0

PMID:32066968

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7311264/

Abstract

Telomere maintenance by telomerase is essential for continuous proliferation of human cells and is vital for the survival of stem cells and 90% of cancer cells. To compensate for telomeric DNA lost during DNA replication, telomerase processively adds GGTTAG repeats to chromosome ends by copying the template region within its RNA subunit. Between repeat additions, the RNA template must be recycled. How telomerase remains associated with substrate DNA during this critical translocation step remains unknown. Using a single-molecule telomerase activity assay utilizing high-resolution optical tweezers, we demonstrate that stable substrate DNA binding at an anchor site within telomerase facilitates the processive synthesis of telomeric repeats. The product DNA synthesized by telomerase can be recaptured by the anchor site or fold into G-quadruplex structures. Our results provide detailed mechanistic insights into telomerase catalysis, a process of critical importance in aging and cancer.

摘要

端粒酶通过端粒维持对人类细胞的持续增殖至关重要，对干细胞和 90%的癌细胞的存活至关重要。为了补偿 DNA 复制过程中端粒 DNA 的丢失，端粒酶通过复制其 RNA 亚基内的模板区域，连续向染色体末端添加 GGTTAG 重复序列。在重复添加之间，RNA 模板必须被回收。端粒酶在这个关键的转位步骤中如何与底物 DNA 保持关联仍然未知。使用利用高分辨率光学镊子的单分子端粒酶活性测定法，我们证明了在端粒酶内的锚定位点稳定的底物 DNA 结合有利于端粒重复序列的连续合成。由端粒酶合成的产物 DNA 可以被锚定位点重新捕获或折叠成 G-四链体结构。我们的结果为端粒酶催化提供了详细的机制见解，这是衰老和癌症中至关重要的过程。

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利用高分辨率光镊观察连续的端粒酶催化反应。

Observation of processive telomerase catalysis using high-resolution optical tweezers.

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