loading page

One substance to rule them all and in the darkness bind them: whole-genome sequencing illuminates multifaceted targets of humic adaptation in Eurasian perch
  • +8
  • Mikhail Ozerov,
  • Kristina Noreikiene,
  • Siim Kahar,
  • Magnus Huss,
  • Ari Huusko,
  • Toomas Kõiv,
  • Margot Sepp,
  • María López,
  • Anna Gårdmark,
  • Riho Gross,
  • Anti Vasemägi
Mikhail Ozerov
Swedish University of Agricultural Sciences Department of Aquatic Resources

Corresponding Author:mikoze@utu.fi

Author Profile
Kristina Noreikiene
Estonian University of Life Sciences
Author Profile
Siim Kahar
Estonian University of Life Sciences
Author Profile
Magnus Huss
Swedish University of Agricultural Sciences Department of Aquatic Resources
Author Profile
Ari Huusko
Natural Resources Institute Finland
Author Profile
Toomas Kõiv
Estonian University of Life Sciences Institute of Agricultural and Environmental Sciences
Author Profile
Margot Sepp
Estonian University of Life Sciences Institute of Agricultural and Environmental Sciences
Author Profile
María López
Swedish University of Agricultural Sciences Department of Aquatic Resources
Author Profile
Anna Gårdmark
Swedish University of Agricultural Sciences Department of Aquatic Resources
Author Profile
Riho Gross
Estonian University of Life Sciences
Author Profile
Anti Vasemägi
Swedish University of Agricultural Sciences Department of Aquatic Resources
Author Profile

Abstract

Extreme environments are inhospitable to the majority of species, but some organisms are able to survive in such hostile conditions due to evolutionary adaptations. For example, modern bony fishes have colonized various aquatic environments, including perpetually dark, hypoxic, hypersaline and toxic habitats. Eurasian perch (Perca fluviatilis) is among the few fish species of northern latitudes that is able to live in extremely acidic humic lakes. Such lakes represent almost “nocturnal” environments; they contain high levels of dissolved organic matter, which in addition to creating a challenging visual environment, also affects a large number of other habitat parameters and biotic interactions. To reveal the genomic targets of humic-associated selection, we performed whole-genome sequencing of perch originating from 16 humic and 16 clear-water lakes in northern Europe. We identified over 800,000 SNPs, of which >10,000 were identified as potential candidates under selection (associated with >3,000 genes) using multiple outlier approaches. Our findings suggest that adaptation to the humic environment involves hundreds of regions scattered across the genome. Putative signals of adaptation were detected in genes and gene families with diverse functions, including organism development and ion transportation. The observed excess of variants under selection in regulatory regions highlights the importance of adaptive evolution via regulatory elements, rather than via protein sequence modification. Our study demonstrates the power of whole-genome analysis to illuminate multifaceted nature of humic adaptation and highlights the next challenge moving from high-throughput outlier identification towards functional validation of causal mutations underlying phenotypic traits of ecological and evolutionary importance.
06 Oct 2021Submitted to Molecular Ecology
07 Oct 2021Submission Checks Completed
07 Oct 2021Assigned to Editor
18 Oct 2021Reviewer(s) Assigned
26 Nov 2021Review(s) Completed, Editorial Evaluation Pending
01 Dec 2021Editorial Decision: Revise Minor
30 Dec 2021Review(s) Completed, Editorial Evaluation Pending
30 Dec 20211st Revision Received
10 Jan 2022Reviewer(s) Assigned
03 Feb 2022Editorial Decision: Revise Minor
10 Feb 2022Review(s) Completed, Editorial Evaluation Pending
10 Feb 20222nd Revision Received
17 Feb 2022Editorial Decision: Accept