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

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. Gutierrez and Tyler investigate the limits of replicative lifespan in yeast. The authors show that nucleolar expansion during aging is a mortality timer. Enlargement of nucleoli beyond a defined size alters their biophysical properties; normally excluded DNA repair protein enter, causing aberrant rDNA recombination, genome instability and death.