Ecology and Evolution (Nov 2024)

Gene Flow Between Populations With Highly Divergent Mitogenomes in the Australian Stingless Bee, Tetragonula hockingsi

  • Genevieve Law,
  • Carmen R. B. daSilva,
  • Inez Vlasich‐Brennan,
  • Benjamin A. Taylor,
  • Brock A. Harpur,
  • Tim Heard,
  • Scott Nacko,
  • Markus Riegler,
  • James B. Dorey,
  • Mark I. Stevens,
  • Nathan Lo,
  • Rosalyn Gloag

DOI
https://doi.org/10.1002/ece3.70475
Journal volume & issue
Vol. 14, no. 11
pp. n/a – n/a

Abstract

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ABSTRACT Coadaptation of mitochondrial and nuclear genes is essential for proper cellular function. When populations become isolated, theory predicts that they should maintain mito‐nuclear coadaptation in each population, even as they diverge in genotype. Mito‐nuclear incompatibilities may therefore arise when individuals from populations with divergent co‐evolved mito‐nuclear gene sets are re‐united and hybridise, contributing to selection against inter‐population hybrids and, potentially, to speciation. Here, we explored genetic divergence and gene flow between populations of a stingless bee (Tetragonula hockingsi) that have highly divergent mitogenomes. We identified three distinct populations across the species' 2500 km range on the east coast of Queensland (Australia): ‘Cape York’, ‘Northern’, and ‘Southern’. The mitogenomes of each population showed > 12% pairwise nucleotide divergence from each other, and > 7% pairwise amino acid divergence. Based on nuclear SNPs from reduced representation sequencing, we identified at least two zones of gene flow between populations: a narrow natural zone between Northern and Southern populations (coinciding with a biogeographic barrier, the Burdekin Gap), and an artificial zone at the southern edge of the species' distribution, where Cape York, Northern, and Southern mito‐lineages have been brought together in recent decades due to beekeeping. In the artificial hybrid zone, we also confirmed that males of all three mito‐lineages were attracted to the mating aggregations of Southern queens, consistent with inter‐population hybridisation. Populations of T. hockingsi thus appear to be in the ‘grey zone’ of the speciation continuum, having strong genetic differentiation but incomplete reproductive isolation. Among the nuclear SNPs most differentiated between Northern and Southern populations, several were associated with genes involved in mitochondrial function, consistent with populations having co‐diverged mito‐nuclear gene sets. Our observations suggest that coadapted sets of mitochondrial and nuclear genes unique to each population of T. hockingsi may play a role in maintaining population boundaries, though more study is needed to confirm the fitness costs of mito‐nuclear incompatibilities in hybrid individuals.

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