Multigenerational silencing dynamics control cell aging

Cellular aging plays an important role in many diseases, such as cancers, metabolic syndromes, and neurodegenerative disorders. There has been steady progress in identifying aging-related factors such as reactive oxygen species and genomic instability, yet an emerging challenge is to reconcile the c...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS 2017-10, Vol.114 (42), p.11253-11258
Main Authors: Li, Yang, Jin, Meng, O’Laughlin, Richard, Bittihn, Philip, Tsimring, Lev S., Pillus, Lorraine, Hasty, Jeff, Hao, Nan
Format: Article
Language:English
Subjects:
Acetylation
Active control
Biological Sciences
Cellular Senescence
Coronatine
Cullin
DNA-directed RNA polymerase
F-box protein
Genes
Genetics
Genomes
Helix-loop-helix proteins (basic)
Heterochromatin - physiology
Isoleucine
Jasmonic acid
Lysine
Microfluidics
Models, Biological
Plant hormones
Promoters
Proteins
Regulators
Repressors
Ribonucleic acid
RNA
RNA polymerase
RNA polymerase II
Saccharomyces cerevisiae
Signaling
Single-Cell Analysis
Transcription factors
Ubiquitin
Ubiquitin-protein ligase
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Summary:Cellular aging plays an important role in many diseases, such as cancers, metabolic syndromes, and neurodegenerative disorders. There has been steady progress in identifying aging-related factors such as reactive oxygen species and genomic instability, yet an emerging challenge is to reconcile the contributions of these factors with the fact that genetically identical cells can age at significantly different rates. Such complexity requires single-cell analyses designed to unravel the interplay of aging dynamics and cell-to-cell variability. Here we use microfluidic technologies to track the replicative aging of single yeast cells and reveal that the temporal patterns of heterochromatin silencing loss regulate cellular life span. We found that cells show sporadic waves of silencing loss in the heterochromatic ribosomal DNA during the early phases of aging, followed by sustained loss of silencing preceding cell death. Isogenic cells have different lengths of the early intermittent silencing phase that largely determine their final life spans. Combining computational modeling and experimental approaches, we found that the intermittent silencing dynamics is important for longevity and is dependent on the conserved Sir2 deacetylase, whereas either sustained silencing or sustained loss of silencing shortens life span. These findings reveal that the temporal patterns of a key molecular process can directly influence cellular aging, and thus could provide guidance for the design of temporally controlled strategies to extend life span.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1703379114