PERCHED AT THE MITO-NUCLEAR CROSSROADS: DIVERGENT MITOCHONDRIAL LINEAGES CORRELATE WITH ENVIRONMENT IN THE FACE OF ONGOING NUCLEAR GENE FLOW IN AN AUSTRALIAN BIRD

Relationships among multilocus genetic variation, geography, and environment can reveal how evolutionary processes affect genomes. We examined the evolution of an Australian bird, the eastern yellow robin Eopsaltria australis, using mitochondrial (mtDNA) and nuclear (nDNA) genetic markers, and biocl...

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Bibliographic Details
Published in:Evolution 2013-12, Vol.67 (12), p.3412-3428
Main Authors: Pavlova, Alexandra, Amos, J. Nevil, Joseph, Leo, Loynes, Kate, Austin, Jeremy J., Keogh, J. Scott, Stone, Graham N., Nicholls, James A., Sunnucks, Paul
Format: Article
Language:English
Subjects:
Animal Migration
Animals
Aves
Biological variation
Birds
dbRDA
DNA, Mitochondrial - genetics
eastern yellow robin
Environment
Eopsaltria australis
Evolution
Evolution, Molecular
Evolutionary genetics
evolutionary history
Female
female-linked selection
Gene Flow
Genetic loci
Genetic variation
Genomes
Geography
Introns
Male
Microsatellites
Mitochondrial DNA
Models, Genetic
Passeriformes - genetics
Reproductive Isolation
Selection, Genetic
Sex Factors
sPCA
SPECIAL SECTION: Evolutionary Landscape Genetics
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Summary:Relationships among multilocus genetic variation, geography, and environment can reveal how evolutionary processes affect genomes. We examined the evolution of an Australian bird, the eastern yellow robin Eopsaltria australis, using mitochondrial (mtDNA) and nuclear (nDNA) genetic markers, and bioclimatic variables. In southeastern Australia, two divergent mtDNA lineages occur east and west of the Great Dividing Range, perpendicular to latitudinal nDNA structure. We evaluated alternative scenarios to explain this striking discordance in landscape genetic patterning. Stochastic mtDNA lineage sorting can be rejected because the mtDNA lineages are essentially distinct geographically for > 1500 km. Vicariance is unlikely: the Great Dividing Range is neither a current barrier nor was it at the Last Glacial Maximum according to species distribution modeling; nuclear gene flow inferred from coalescent analysis affirms this. Female philopatry contradicts known female-biased dispersal. Contrasting mtDNA and nDNA demographies indicate their evolutionary histories are decoupled. Distance-based redundancy analysis, in which environmental temperatures explain mtDNA variance above that explained by geographic position and isolation-by-distance, favors a nonneutral explanation for mitochondrial phylogeographic patterning. Thus, observed mito-nuclear discordance accords with environmental selection on a female-linked trait, such as mtDNA, mtDNA–nDNA interactions or genes on W-chromosome, driving mitochondrial divergence in the presence of nuclear gene flow.
ISSN:0014-3820
1558-5646
DOI:10.1111/evo.12107