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Proceedings. Biological sciences
Jun, 2024;291 (2024): 20240876.

Selection on the joint actions of pairs leads to divergent adaptation and coadaptation of care-giving parents during pre-hatching care.

Benjamin J M Jarrett, Rahia Mashoodh, Swastika Issar, Sonia Pascoal, Darren Rebar, Syuan-Jyun Sun, Matthew Schrader, Rebecca M Kilner
Author Information
  1. Benjamin J M Jarrett: School of Environmental and Natural Sciences, Bangor University , Bangor, UK. ORCID
  2. Rahia Mashoodh: Department of Zoology, University of Cambridge , Cambridge, UK.
  3. Swastika Issar: Department of Zoology, University of Cambridge , Cambridge, UK.
  4. Sonia Pascoal: Department of Zoology, University of Cambridge , Cambridge, UK.
  5. Darren Rebar: Department of Biological Sciences, Emporia State University , Emporia, KS, USA. ORCID
  6. Syuan-Jyun Sun: International Degree Program in Climate Change and Sustainable Development, National Taiwan University , Taipei, Taiwan. ORCID
  7. Matthew Schrader: Department of Biology, University of the South , Sewanee, TN, USA. ORCID
  8. Rebecca M Kilner: Department of Zoology, University of Cambridge , Cambridge, UK. ORCID
PMID: 38864319 DOI: 10.1098/rspb.2024.0876

Abstract

The joint actions of animals in partnerships or social groups evolve under both natural selection from the wider environment and social selection imposed by other members of the pair or group. We used experimental evolution to investigate how jointly expressed actions evolve upon exposure to a new environmental challenge. Our work focused on the evolution of carrion nest preparation by pairs of burying beetles , a joint activity undertaken by the pair but typically led by the male. In previous work, we found that carrion nest preparation evolved to be faster in experimental populations without post-hatching care (No Care: NC lines) than with post-hatching care (Full Care: FC lines). Here, we investigate how this joint activity evolved. After 15 generations of experimental evolution, we created heterotypic pairs (NC females with FC males and NC males with FC females) and compared their carrion nest making with homotypic NC and FC pairs. We found that pairs with NC males prepared the nest more rapidly than pairs with FC males, regardless of the female's line of origin. We discuss how social coadaptations within pairs or groups could act as a post-mating barrier to gene flow.

Keywords

division of labour nest-building reproductive isolation

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Grants

  1. /European Research Council
  2. /Royal Society
  3. /Human Frontiers Science Program

MeSH Term

Animals
Male
Female
Coleoptera
Nesting Behavior
Selection, Genetic
Social Behavior
Biological Evolution
Maternal Behavior
Paternal Behavior
Journal Article
Article has an altmetric score of 7

Word Cloud

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