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Elevated temperature increases genome-wide selection on de novo mutations

Berger, David ; Stångberg, Josefine ; Baur, Julian and Walters, Richard J LU (2021) In Royal Society of London. Proceedings B. Biological Sciences 288(1944).
Abstract

Adaptation in new environments depends on the amount of genetic variation available for evolution, and the efficacy by which natural selection discriminates among this variation. However, whether some ecological factors reveal more genetic variation, or impose stronger selection pressures than others, is typically not known. Here, we apply the enzyme kinetic theory to show that rising global temperatures are predicted to intensify natural selection throughout the genome by increasing the effects of DNA sequence variation on protein stability. We test this prediction by (i) estimating temperature-dependent fitness effects of induced mutations in seed beetles adapted to ancestral or elevated temperature, and (ii) calculate 100 paired... (More)

Adaptation in new environments depends on the amount of genetic variation available for evolution, and the efficacy by which natural selection discriminates among this variation. However, whether some ecological factors reveal more genetic variation, or impose stronger selection pressures than others, is typically not known. Here, we apply the enzyme kinetic theory to show that rising global temperatures are predicted to intensify natural selection throughout the genome by increasing the effects of DNA sequence variation on protein stability. We test this prediction by (i) estimating temperature-dependent fitness effects of induced mutations in seed beetles adapted to ancestral or elevated temperature, and (ii) calculate 100 paired selection estimates on mutations in benign versus stressful environments from unicellular and multicellular organisms. Environmental stress per se did not increase mean selection on de novo mutation, suggesting that the cost of adaptation does not generally increase in new ecological settings to which the organism is maladapted. However, elevated temperature increased the mean strength of selection on genome-wide polymorphism, signified by increases in both mutation load and mutational variance in fitness. These results have important implications for genetic diversity gradients and the rate and repeatability of evolution under climate change.

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organization
publishing date
type
Contribution to journal
publication status
published
subject
in
Royal Society of London. Proceedings B. Biological Sciences
volume
288
issue
1944
article number
20203094
pages
10 pages
publisher
Royal Society Publishing
external identifiers
  • scopus:85100768936
  • pmid:33529558
ISSN
1471-2954
DOI
10.1098/rspb.2020.3094
language
English
LU publication?
yes
id
d70af5a9-25a2-4fa4-a68f-75cd748cac66
date added to LUP
2021-02-11 16:15:14
date last changed
2025-03-08 13:43:20
@article{d70af5a9-25a2-4fa4-a68f-75cd748cac66,
  abstract     = {{<p>Adaptation in new environments depends on the amount of genetic variation available for evolution, and the efficacy by which natural selection discriminates among this variation. However, whether some ecological factors reveal more genetic variation, or impose stronger selection pressures than others, is typically not known. Here, we apply the enzyme kinetic theory to show that rising global temperatures are predicted to intensify natural selection throughout the genome by increasing the effects of DNA sequence variation on protein stability. We test this prediction by (i) estimating temperature-dependent fitness effects of induced mutations in seed beetles adapted to ancestral or elevated temperature, and (ii) calculate 100 paired selection estimates on mutations in benign versus stressful environments from unicellular and multicellular organisms. Environmental stress per se did not increase mean selection on de novo mutation, suggesting that the cost of adaptation does not generally increase in new ecological settings to which the organism is maladapted. However, elevated temperature increased the mean strength of selection on genome-wide polymorphism, signified by increases in both mutation load and mutational variance in fitness. These results have important implications for genetic diversity gradients and the rate and repeatability of evolution under climate change.</p>}},
  author       = {{Berger, David and Stångberg, Josefine and Baur, Julian and Walters, Richard J}},
  issn         = {{1471-2954}},
  language     = {{eng}},
  month        = {{02}},
  number       = {{1944}},
  publisher    = {{Royal Society Publishing}},
  series       = {{Royal Society of London. Proceedings B. Biological Sciences}},
  title        = {{Elevated temperature increases genome-wide selection on de novo mutations}},
  url          = {{http://dx.doi.org/10.1098/rspb.2020.3094}},
  doi          = {{10.1098/rspb.2020.3094}},
  volume       = {{288}},
  year         = {{2021}},
}