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Slowest possible replicative life at frigid temperatures for yeast

Author

Listed:
  • Diederik S. Laman Trip

    (Kavli Institute of Nanoscience
    University of Massachusetts Chan Medical School)

  • Théo Maire

    (Kavli Institute of Nanoscience
    University of Massachusetts Chan Medical School)

  • Hyun Youk

    (University of Massachusetts Chan Medical School
    CIFAR Azrieli Global Scholars Program, CIFAR)

Abstract

Determining whether life can progress arbitrarily slowly may reveal fundamental barriers to staying out of thermal equilibrium for living systems. By monitoring budding yeast’s slowed-down life at frigid temperatures and with modeling, we establish that Reactive Oxygen Species (ROS) and a global gene-expression speed quantitatively determine yeast’s pace of life and impose temperature-dependent speed limits - shortest and longest possible cell-doubling times. Increasing cells’ ROS concentration increases their doubling time by elongating the cell-growth (G1-phase) duration that precedes the cell-replication (S-G2-M) phase. Gene-expression speed constrains cells’ ROS-reducing rate and sets the shortest possible doubling-time. To replicate, cells require below-threshold concentrations of ROS. Thus, cells with sufficiently abundant ROS remain in G1, become unsustainably large and, consequently, burst. Therefore, at a given temperature, yeast’s replicative life cannot progress arbitrarily slowly and cells with the lowest ROS-levels replicate most rapidly. Fundamental barriers may constrain the thermal slowing of other organisms’ lives.

Suggested Citation

  • Diederik S. Laman Trip & Théo Maire & Hyun Youk, 2022. "Slowest possible replicative life at frigid temperatures for yeast," Nature Communications, Nature, vol. 13(1), pages 1-16, December.
    • Handle: RePEc:nat:natcom:v:13:y:2022:i:1:d:10.1038_s41467-022-35151-2
    DOI: 10.1038/s41467-022-35151-2
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    References listed on IDEAS

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    1. Kurt M. Schmoller & J. J. Turner & M. Kõivomägi & Jan M. Skotheim, 2015. "Dilution of the cell cycle inhibitor Whi5 controls budding-yeast cell size," Nature, Nature, vol. 526(7572), pages 268-272, October.
    2. Yusheng Zhao & Rea L. Antoniou-Kourounioti & Grant Calder & Caroline Dean & Martin Howard, 2020. "Temperature-dependent growth contributes to long-term cold sensing," Nature, Nature, vol. 583(7818), pages 825-829, July.
    3. Yu Tanouchi & Anand Pai & Heungwon Park & Shuqiang Huang & Rumen Stamatov & Nicolas E. Buchler & Lingchong You, 2015. "A noisy linear map underlies oscillations in cell size and gene expression in bacteria," Nature, Nature, vol. 523(7560), pages 357-360, July.
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