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基于核仁大小的死亡率计时器会引发核仁完整性丧失和灾难性的基因组不稳定。

A mortality timer based on nucleolar size triggers nucleolar integrity loss and catastrophic genomic instability.

作者信息

Gutierrez J Ignacio, Tyler Jessica K

机构信息

Weill Cornell Medicine, Department of Pathology and Laboratory Medicine, New York, NY, USA.

出版信息

Nat Aging. 2024 Dec;4(12):1782-1793. doi: 10.1038/s43587-024-00754-5. Epub 2024 Nov 25.

DOI:10.1038/s43587-024-00754-5
PMID:39587368
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11964297/
Abstract

Genome instability is a hallmark of aging, with the highly repetitive ribosomal DNA (rDNA) within the nucleolus being particularly prone to genome instability. Nucleolar enlargement accompanies aging in organisms ranging from yeast to mammals, and treatment with many antiaging interventions results in small nucleoli. Here, we report that an engineered system to reduce nucleolar size robustly extends budding yeast replicative lifespan in a manner independent of protein synthesis rate or rDNA silencing. Instead, when nucleoli expand beyond a size threshold, their biophysical properties change, allowing entry of proteins normally excluded from the nucleolus, including the homologous recombinational repair protein Rad52. This triggers rDNA instability due to aberrant recombination, catastrophic genome instability and imminent death. These results establish that nucleolar expansion is sufficient to drive aging. Moreover, nucleolar expansion beyond a specific size threshold is a mortality timer, as the accompanying disruption of the nucleolar condensate boundary results in catastrophic genome instability that ends replicative lifespan.

摘要

基因组不稳定是衰老的一个标志,核仁内高度重复的核糖体DNA(rDNA)尤其容易发生基因组不稳定。从酵母到哺乳动物,生物体衰老过程中都会伴随核仁增大,而许多抗衰老干预措施会使核仁变小。在此,我们报告一种用于减小核仁大小的工程系统,它能以一种独立于蛋白质合成速率或rDNA沉默的方式显著延长出芽酵母的复制寿命。相反,当核仁扩展超过一个大小阈值时,它们的生物物理特性会发生变化,使得通常被排除在核仁之外的蛋白质进入,包括同源重组修复蛋白Rad52。这会由于异常重组引发rDNA不稳定、灾难性的基因组不稳定并导致细胞即将死亡。这些结果表明核仁扩展足以驱动衰老。此外,核仁扩展超过特定大小阈值是一个死亡计时器,因为随之而来的核仁凝聚物边界的破坏会导致灾难性的基因组不稳定,从而结束复制寿命。

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