Temperature-dependence of spontaneous mutation rates

  1. Markus Pfenninger2
  1. 1 University of Cologne;
  2. 2 Senckenberg Biodiversity and Climate Research Centre
  • * Corresponding author; email: a.waldvogel{at}uni-koeln.de

    • Abstract

    Mutation is the source of genetic variation and the fundament of evolution. Temperature has long been suggested to have a direct impact on realized spontaneous mutation rates. If mutation rates vary in response to environmental conditions, such as the variation of the ambient temperature through space and time, they should no longer be described as species-specific constants. By combining mutation accumulation with whole-genome sequencing in a multicellular organism, we provide empirical support to reject the null hypothesis of a constant, temperature-independent mutation rate. Instead mutation rates depended on temperature in a U-shaped manner with increasing rates towards both temperature extremes. This relation has important implications for mutation-dependent processes in molecular evolution, processes shaping the evolution of mutation rates and even the evolution of biodiversity as such.

    • Received December 21, 2020.
    • Accepted July 21, 2021.

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    This Article

    1. Published in Advance July 23, 2021, doi: 10.1101/gr.275168.120 Genome Res. gr.275168.120 Published by Cold Spring Harbor Laboratory Press

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    ORCID

    1. Profile for Waldvogel, A. M.http://orcid.org/0000-0003-2637-0766
    2. Profile for Pfenninger, M.http://orcid.org/0000-0002-1547-7245

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