依赖MRX的对短端粒的DNA损伤反应。

MRX-dependent DNA damage response to short telomeres.

作者信息

Viscardi Valeria, Bonetti Diego, Cartagena-Lirola Hugo, Lucchini Giovanna, Longhese Maria Pia

机构信息

Dipartimento di Biotecnologie e Bioscienze, Università di Milano-Bicocca, 20126 Milan, Italy.

出版信息

Mol Biol Cell. 2007 Aug;18(8):3047-58. doi: 10.1091/mbc.e07-03-0285. Epub 2007 May 30.

DOI:10.1091/mbc.e07-03-0285

PMID:17538011

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1949382/

Abstract

Telomere structure allows cells to distinguish the natural chromosome ends from double-strand breaks (DSBs). However, DNA damage response proteins are intimately involved in telomere metabolism, suggesting that functional telomeres may be recognized as DNA damage during a time window. Here we show by two different systems that short telomeres are recognized as DSBs during the time of their replication, because they induce a transient MRX-dependent DNA damage checkpoint response during their prolonged elongation. The MRX complex, which is recruited at telomeres under these conditions, dissociates from telomeres concomitantly with checkpoint switch off when telomeres reach a new equilibrium length. We also show that MRX recruitment to telomeres is sufficient to activate the checkpoint independently of telomere elongation. We propose that MRX can signal checkpoint activation by binding to short telomeres only when they become competent for elongation. Because full-length telomeres are refractory to MRX binding and the shortest telomeres are elongated of only a few base pairs per generation, this limitation may prevent unscheduled checkpoint activation during an unperturbed S phase.

摘要

端粒结构使细胞能够区分天然染色体末端与双链断裂（DSB）。然而，DNA损伤应答蛋白密切参与端粒代谢，这表明功能性端粒在一个时间窗口内可能被识别为DNA损伤。在这里，我们通过两种不同的系统表明，短端粒在复制时被识别为DSB，因为它们在延长伸长过程中会诱导短暂的依赖MRX的DNA损伤检查点反应。在这些条件下在端粒处募集的MRX复合物，当端粒达到新的平衡长度时，会与端粒解离，同时检查点关闭。我们还表明，MRX募集到端粒足以独立于端粒伸长激活检查点。我们提出，只有当短端粒能够伸长时，MRX才能通过与它们结合来发出检查点激活信号。由于全长端粒对MRX结合具有抗性，并且最短的端粒每代仅延长几个碱基对，这种限制可能会防止在未受干扰的S期发生意外的检查点激活。

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DNA breaks are masked by multiple Rap1 binding in yeast: implications for telomere capping and telomerase regulation.酵母中多个Rap1结合掩盖DNA断裂：对端粒封端和端粒酶调控的影响

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