Open access · CC-BY
via OpenAlex
High-Resolution Profiling of Stationary-Phase Survival Reveals Yeast Longevity Factors and Their Genetic Interactions
Erika Garay, Sergio E. Campos, Jorge González de la Cruz, Ana P. Gaspar, Adrián Jinich, Alexander DeLuna
PLoS Genetics · 2014 · ▲ 106 citations
Abstract
Lifespan is influenced by a large number of conserved proteins and gene-regulatory pathways. Here, we introduce a strategy for systematically finding such longevity factors in Saccharomyces cerevisiae and scoring the genetic interactions (epistasis) among these factors. Specifically, we developed an automated competition-based assay for chronological lifespan, defined as stationary-phase survival of yeast populations, and used it to phenotype over 5,600 single- or double-gene knockouts at unprecedented quantitative resolution. We found that 14% of the viable yeast mutant strains were affected in their stationary-phase survival; the extent of true-positive chronological lifespan factors was estimated by accounting for the effects of culture aeration and adaptive regrowth. We show that lifespan extension by dietary restriction depends on the Swr1 histone-exchange complex and that a functional link between autophagy(definition) and the lipid-homeostasis factor Arv1 has an impact on cellular lifespan. Importantly, we describe the first genetic interaction network based on aging phenotypes, which successfully recapitulated the core-autophagy machinery and confirmed a role of the human tumor suppressor PTEN homologue in yeast lifespan and phosphatidylinositol phosphate metabolism. Our quantitative analysis of longevity factors and their genetic interactions provides insights into the gene-network interactions of aging cells.
◌ CITATION ONLY
Full text is not openly licensed for redistribution here. Read it at the source:
Provenance
- Source
- OpenAlex
- DOI
- 10.1371/journal.pgen.1004168
- Canonical
- link ↗
- Fetched
- 2026-07-06 MST
Cite this
APA
Garay, E., Campos, S.E., Cruz, J.G.D.L., Gaspar, A.P., Jinich, A., & DeLuna, A. (2014). High-Resolution Profiling of Stationary-Phase Survival Reveals Yeast Longevity Factors and Their Genetic Interactions. <em>PLoS Genetics</em>. https://doi.org/10.1371/journal.pgen.1004168
Vancouver
Garay E, Campos SE, Cruz JGDL, Gaspar AP, Jinich A, DeLuna A. High-Resolution Profiling of Stationary-Phase Survival Reveals Yeast Longevity Factors and Their Genetic Interactions. PLoS Genetics. 2014. doi:10.1371/journal.pgen.1004168.
BibTeX
@article{erika2014HighRe,
title = {High-Resolution Profiling of Stationary-Phase Survival Reveals Yeast Longevity Factors and Their Genetic Interactions},
author = {Erika Garay and Sergio E. Campos and Jorge González de la Cruz and Ana P. Gaspar and Adrián Jinich and Alexander DeLuna},
journal = {PLoS Genetics},
year = {2014},
doi = {10.1371/journal.pgen.1004168},
}
Research neighborhood
References, citing works, and semantically nearest findings. Click a node to open it.
Related findings
Aging Cell 2018
Open access · CC-BY
Genomewide mechanisms of chronological longevity by dietary restriction in budding yeast
Cells 2022
Open access · CC-BY
Yeast Chronological Lifespan: Longevity Regulatory Genes and Mechanisms
Microbial cell (Graz, Austria) 2025
Open access · OA
The core genetic drivers of chronological aging in yeast are universal regulators of longevity.
The Journals of Gerontology Series A 2008
Open access · OA
A Method for High-Throughput Quantitative Analysis of Yeast Chronological Life Span
Current Genetic Medicine Reports 2022
Preprint · OA
Genetic, Social, and Lifestyle Drivers of Healthy Aging and Longevity
Aging Cell 2021
Open access · CC-BY