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酵母衰老与染色体 XII 的扩增线性片段有关,而不是与核糖体 DNA 环积累有关。

Senescence in yeast is associated with amplified linear fragments of chromosome XII rather than ribosomal DNA circle accumulation.

机构信息

Epigenetics Programme, Babraham Institute, Cambridge, United Kingdom.

出版信息

PLoS Biol. 2023 Aug 29;21(8):e3002250. doi: 10.1371/journal.pbio.3002250. eCollection 2023 Aug.

DOI:10.1371/journal.pbio.3002250
PMID:37643194
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10464983/
Abstract

The massive accumulation of extrachromosomal ribosomal DNA circles (ERCs) in yeast mother cells has been long cited as the primary driver of replicative ageing. ERCs arise through ribosomal DNA (rDNA) recombination, and a wealth of genetic data connects rDNA instability events giving rise to ERCs with shortened life span and other ageing pathologies. However, we understand little about the molecular effects of ERC accumulation. Here, we studied ageing in the presence and absence of ERCs, and unexpectedly found no evidence of gene expression differences that might indicate stress responses or metabolic feedback caused by ERCs. Neither did we observe any global change in the widespread disruption of gene expression that accompanies yeast ageing, altogether suggesting that ERCs are largely inert. Much of the differential gene expression that accompanies ageing in yeast was actually associated with markers of the senescence entry point (SEP), showing that senescence, rather than age, underlies these changes. Cells passed the SEP irrespective of ERCs, but we found the SEP to be associated with copy number amplification of a region of chromosome XII between the rDNA and the telomere (ChrXIIr) forming linear fragments up to approximately 1.8 Mb size, which arise in aged cells due to rDNA instability but through a different mechanism to ERCs. Therefore, although rDNA copy number increases dramatically with age due to ERC accumulation, our findings implicate ChrXIIr, rather than ERCs, as the primary driver of senescence during budding yeast ageing.

摘要

酵母母细胞中大量额外染色体核糖体 DNA 环 (ERC) 的积累长期以来一直被认为是复制性衰老的主要驱动因素。ERC 通过核糖体 DNA (rDNA) 重组产生,大量遗传数据将导致 ERC 产生的 rDNA 不稳定性事件与寿命缩短和其他衰老病理联系起来。然而,我们对 ERC 积累的分子影响知之甚少。在这里,我们研究了有和没有 ERC 的衰老情况,出人意料的是,我们没有发现任何可能表明 ERC 引起的应激反应或代谢反馈的基因表达差异的证据。我们也没有观察到伴随酵母衰老的广泛基因表达普遍中断的任何全局变化,这一切表明 ERC 基本上是惰性的。伴随酵母衰老的大部分差异基因表达实际上与衰老进入点 (SEP) 的标志物有关,表明衰老而不是年龄是这些变化的基础。细胞无论有无 ERC 都会通过 SEP,但我们发现 SEP 与 rDNA 和端粒之间的染色体 XII 区域的拷贝数扩增有关(ChrXIIr),形成长达约 1.8Mb 大小的线性片段,这些片段是由于 rDNA 不稳定性在衰老细胞中产生的,但与 ERC 不同的机制。因此,尽管由于 ERC 积累,rDNA 拷贝数随着年龄的增长而显著增加,但我们的发现表明,在出芽酵母衰老过程中,ChrXIIr 而不是 ERC 是衰老的主要驱动因素。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/7ce2/10464983/e34edfc454bc/pbio.3002250.g008.jpg
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