Genomics reveal the origins and current structure of a genetically depauperate freshwater species in its introduced Alaskan range

Matthew A Campbell; Matthew C Hale; Chase S Jalbert; Kristine Dunker; Adam J Sepulveda; J Andrés López; Jeffrey A Falke; Peter A H Westley

doi:10.1111/eva.13556

Genomics reveal the origins and current structure of a genetically depauperate freshwater species in its introduced Alaskan range

Evol Appl. 2023 May 12;16(6):1119-1134. doi: 10.1111/eva.13556. eCollection 2023 Jun.

Authors

Matthew A Campbell¹, Matthew C Hale², Chase S Jalbert^{3

4}, Kristine Dunker⁵, Adam J Sepulveda⁶, J Andrés López^{1

3}, Jeffrey A Falke⁷, Peter A H Westley³

Affiliations

¹ University of Alaska Museum Fairbanks Alaska USA.
² Department of Biology Texas Christian University Fort Worth Texas USA.
³ College of Fisheries and Ocean Sciences University of Alaska Fairbanks Fairbanks Alaska USA.
⁴ Present address: Division of Commercial Fisheries Alaska Department of Fish and Game Anchorage Alaska USA.
⁵ Division of Sport Fish Alaska Department of Fish and Game Anchorage Alaska USA.
⁶ Northern Rocky Mountain Science Center U.S. Geological Survey Bozeman Montana USA.
⁷ Alaska Cooperative Fish and Wildlife Research Unit, U.S. Geological Survey University of Alaska Fairbanks Fairbanks Alaska USA.

Abstract

Invasive species are a major threat to global biodiversity, yet also represent large-scale unplanned ecological and evolutionary experiments to address fundamental questions in nature. Here we analyzed both native and invasive populations of predatory northern pike (Esox lucius) to characterize landscape genetic variation, determine the most likely origins of introduced populations, and investigate a presumably postglacial population from Southeast Alaska of unclear provenance. Using a set of 4329 SNPs from 351 individual Alaskan northern pike representing the most widespread geographic sampling to date, our results confirm low levels of genetic diversity in native populations (average 𝝅 of 3.18 × 10^-4) and even less in invasive populations (average 𝝅 of 2.68 × 10^-4) consistent with bottleneck effects. Our analyses indicate that invasive northern pike likely came from multiple introductions from different native Alaskan populations and subsequently dispersed from original introduction sites. At the broadest scale, invasive populations appear to have been founded from two distinct regions of Alaska, indicative of two independent introduction events. Genetic admixture resulting from introductions from multiple source populations may have mitigated the negative effects associated with genetic bottlenecks in this species with naturally low levels of genetic diversity. Genomic signatures strongly suggest an excess of rare, population-specific alleles, pointing to a small number of founding individuals in both native and introduced populations consistent with a species' life history of limited dispersal and gene flow. Lastly, the results strongly suggest that a small isolated population of pike, located in Southeast Alaska, is native in origin rather than stemming from a contemporary introduction event. Although theory predicts that lack of genetic variation may limit colonization success of novel environments, we detected no evidence that a lack of standing variation limited the success of this genetically depauperate apex predator.

Keywords: Esox lucius; dispersal; gene flow; invasive species; northern pike; population genetics.