Semipermeable species boundaries create opportunities for gene flow and adaptive potential
No Thumbnail Available
Restricted Availability
Date
2023-05-24, 2023-05-24
Persistent identifier of the Data Catalogue metadata
Creator/contributor
Editor
Journal title
Journal volume
Publisher
Publication Type
dataset
Peer Review Status
Repositories
Access rights
ISBN
ISSN
Description
Hybridisation and gene flow can have both deleterious and adaptive consequences for natural populations and species. To better understand the extent of hybridisation in nature and the balance between its beneficial and deleterious outcomes in a changing environment, information on naturally hybridising non-model organisms is needed. This requires the characterisation of the structure and extent of natural hybrid zones. Here we study natural populations of five keystone mound-building wood ant species in the Formica rufa group across Finland. No genomic studies across the species group exist, and the extent of hybridisation and genomic differentiation in sympatry is unknown. Combining genome-wide and morphological data, we demonstrate more extensive hybridisation than was previously detected between all five species in Finland. Specifically, we reveal a mosaic hybrid zone between F. aquilonia, F. rufa and F. polyctena, comprising further generation hybrid populations. Despite this, we find that Formica rufa, F. aquilonia, F. lugubris, and F. pratensis form distinct gene pools in Finland. We also find that hybrids occupy warmer microhabitats than the non-admixed populations of cold-adapted F. aquilonia, and suggest that warm winters and springs, in particular, may benefit hybrids over F. aquilonia, the most abundant F. rufa group species in Finland. In summary, our results indicate that extensive hybridisation may create adaptive potential that could promote wood ant persistence in a changing climate. Additionally, they highlight the potentially significant ecological and evolutionary consequences of extensive mosaic hybrid zones, within which independent hybrid populations face an array of ecological and intrinsic selection pressures.