Independently evolved pollution resistance in four killifish populations is largely explained by few variants of large effect

Jeffrey T Miller; Bryan W Clark; Noah M Reid; Sibel I Karchner; Jennifer L Roach; Mark E Hahn; Diane Nacci; Andrew Whitehead

doi:10.1111/eva.13648

Independently evolved pollution resistance in four killifish populations is largely explained by few variants of large effect

Evol Appl. 2024 Jan 29;17(1):e13648. doi: 10.1111/eva.13648. eCollection 2024 Jan.

Authors

Jeffrey T Miller^{1

2}, Bryan W Clark³, Noah M Reid⁴, Sibel I Karchner⁵, Jennifer L Roach¹, Mark E Hahn⁵, Diane Nacci³, Andrew Whitehead¹

Affiliations

¹ Department of Environmental Toxicology, Center for Population Biology, Coastal and Marine Sciences Institute University of California, Davis Davis California USA.
² Present address: Molecular, Cellular, and Biomedical Sciences University of New Hampshire Durham New Hampshire USA.
³ Office of Research and Development, Center for Environmental Measurement and Modeling, Atlantic Coastal Environmental Sciences Division US Environmental Protection Agency Narragansett Rhode Island USA.
⁴ Department of Molecular & Cell Biology University of Connecticut Storrs Connecticut USA.
⁵ Biology Department Woods Hole Oceanographic Institution Woods Hole Massachusetts USA.

Abstract

The genetic architecture of phenotypic traits can affect the mode and tempo of trait evolution. Human-altered environments can impose strong natural selection, where successful evolutionary adaptation requires swift and large phenotypic shifts. In these scenarios, theory predicts that adaptation is due to a few adaptive variants of large effect, but empirical studies that have revealed the genetic architecture of rapidly evolved phenotypes are rare, especially for populations inhabiting polluted environments. Fundulus killifish have repeatedly evolved adaptive resistance to extreme pollution in urban estuaries. Prior studies, including genome scans for signatures of natural selection, have revealed some of the genes and pathways important for evolved pollution resistance, and provide context for the genotype-phenotype association studies reported here. We created multiple quantitative trait locus (QTL) mapping families using progenitors from four different resistant populations, and using RAD-seq genetically mapped variation in sensitivity (developmental perturbations) following embryonic exposure to a model toxicant PCB-126. We found that one to two large-effect QTL loci accounted for resistance to PCB-mediated developmental toxicity. QTLs harbored candidate genes that govern the regulation of aryl hydrocarbon receptor (AHR) signaling. One QTL locus was shared across all populations and another was shared across three populations. One QTL locus showed strong signatures of recent natural selection in the corresponding wild population but another QTL locus did not. Some candidate genes for PCB resistance inferred from genome scans in wild populations were identified as QTL, but some key candidate genes were not. We conclude that rapidly evolved resistance to the developmental defects normally caused by PCB-126 is governed by few genes of large effect. However, other aspects of resistance beyond developmental phenotypes may be governed by additional loci, such that comprehensive resistance to PCB-126, and to the mixtures of chemicals that distinguish urban estuaries more broadly, may be more genetically complex.

Keywords: adaptation; contemporary evolution; ecological genomics; genomics/proteomics; molecular evolution; quantitative genetics.

Abstract

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