Positive and purifying selection in mitochondrial genomes of a bird with mitonuclear discordance

Diversifying selection on metabolic pathways can reduce intraspecific gene flow and promote population divergence. An opportunity to explore this arises from mitonuclear discordance observed in an Australian bird E opsaltria australis . Across >1500 km, nuclear differentiation is low and latitudinally structured by isolation by distance, whereas two highly divergent, parapatric mitochondrial lineages (>6.6% in ND 2) show a discordant longitudinal geographic pattern and experience different climates. Vicariance, incomplete lineage sorting and sex‐biased dispersal were shown earlier to be unlikely drivers of the mitonuclear discordance; instead, natural selection on a female‐linked trait was the preferred hypothesis. Accordingly, here we tested for signals of positive, divergent selection on mitochondrial genes in E . australis . We used codon models and physicochemical profiles of amino acid replacements to analyse complete mitochondrial genomes of the two mitochondrial lineages in E . australis , its sister species E opsaltria griseogularis , and outgroups. We found evidence of positive selection on at least five amino acids, encoded by genes of two oxidative phosphorylation pathway complexes NADH dehydrogenase ( ND 4 and ND 4L) and cytochrome bc 1 (cyt‐ b ) against a background of widespread purifying selection on all mitochondrial genes. Three of these amino acid replacements were fixed in ND 4 of the geographically most widespread E . australis lineage. The other two replacements were fixed in ND 4L and cyt‐ b of the geographically more restricted E . australis lineage. We discuss whether this selection may reflect local environmental adaptation, a by‐product of other selective processes, or genetic incompatibilities, and propose how these hypotheses can be tested in future.