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

Morales, Hernán E.; Pavlova, Alexandra; Joseph, Leo; Sunnucks, Paul

doi:10.1111/mec.13203

Cited by 132 publications

(174 citation statements)

References 112 publications

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“…Thousands of studies have been based solely on mtDNA and the question has arisen as to whether the results of such studies can be accepted or whether they must be tested by corresponding analyses of nuclear loci. In our opinion, a relatively few instances of discordance between mitochondrial and nuclear genes has been emphasized [41][42][43], despite more frequent cases of congruence between the two types of markers [2,8,44 -46]. Our systematic examinations suggest that mtDNA can be an efficient estimator of population divergence, but not effective population size, which requires multiple loci for accurate estimate [2,8].…”

Section: Discussionmentioning

confidence: 76%

Matching loci surveyed to questions asked in phylogeography

2016

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Although mitochondrial DNA (mtDNA) has long been used for assessing genetic variation within and between populations, its workhorse role in phylogeography has been criticized owing to its single-locus nature. The only choice for testing mtDNA results is to survey nuclear loci, which brings into contrast the difference in locus effective size and coalescence times. Thus, it remains unclear how erroneous mtDNA-based estimates of species history might be, especially for evolutionary events in the recent past. To test the robustness of mtDNA and nuclear sequences in phylogeography, we provide one of the largest paired comparisons of summary statistics and demographic parameters estimated from mitochondrial, five Z-linked and 10 autosomal genes of 30 avian species co-distributed in the Caucasus and Europe. The results suggest that mtDNA is robust in estimating inter-population divergence but not in intra-population diversity, which is sensitive to population size change. Here, we provide empirical evidence showing that mtDNA was more likely to detect population divergence than any other single locus owing to its smaller N e and thus faster coalescent time. Therefore, at least in birds, numerous studies that have based their inferences of phylogeographic patterns solely on mtDNA should not be readily dismissed.

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Section: Discussionmentioning

confidence: 76%

Matching loci surveyed to questions asked in phylogeography

2016

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“…Additional support for the hypothesis has been provided from studies of other metazoans, some of which have reported signatures of positive selection on mtDNA genes sampled from populations inhabiting particular thermal environments (Foote, et al 2011;Silva, et al 2014;80 Ma, et al 2015;Morales, et al 2015), and others which have documented variation in mitochondrial gene or haplotype frequencies along clinal gradients associated with climate, such as latitude (Silva, et al 2014;Consuegra, et al 2015), altitude (Fontanillas, et al 2005; Cheviron and Brumfield 2009), or with temperature itself (Quintela, et al 2014). Such clinal patterns are, however, based on correlations between haplotype frequencies and 85 environmental gradients.…”

Section: Introductionmentioning

confidence: 97%

Experimental Support That Natural Selection Has Shaped the Latitudinal Distribution of Mitochondrial Haplotypes in Australian Drosophila melanogaster

Camus

Wolff

Sgrò

et al. 2017

Molecular Biology and Evolution

106

138

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Cellular metabolism is regulated by enzyme complexes within the mitochondrion, the function of which are sensitive to the prevailing temperature. Such thermal sensitivity, coupled with the observation that population frequencies of mitochondrial haplotypes tend to 25 associate with latitude, altitude or climatic regions across species distributions, led to the hypothesis that thermal selection has played a role in shaping standing variation in the mitochondrial DNA (mtDNA) sequence. This hypothesis, however, remains controversial, and requires evidence that the distribution of haplotypes observed in nature corresponds with the capacity of these haplotypes to confer differences in thermal tolerance. Specifically, 30 haplotypes predominating in tropical climates are predicted to encode increased tolerance to heat stress, but decreased tolerance to cold stress. We present direct evidence for these predictions, using mtDNA haplotypes sampled from the Australian distribution of Drosophila melanogaster. We show that the ability of flies to tolerate extreme thermal challenges is affected by sequence variation across mtDNA haplotypes, and that the thermal performance 35 associated with each haplotype corresponds with its latitudinal prevalence. The haplotype that predominates at low (subtropical) latitudes confers greater resilience to heat stress, but lower resilience to cold stress, than haplotypes predominating at higher (temperate) latitudes. We explore molecular mechanisms that might underlie these responses, presenting evidence that the effects are in part regulated by SNPs that do not change the protein sequence. Our 40 findings suggest that standing variation in the mitochondrial genome can be shaped by thermal selection, and could therefore contribute to evolutionary adaptation under climatic stress.

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“…However, despite a background of strong purifying selection, particular sites in the mitochondrial genome can experience positive selection in response to environmental pressures. Many studies have reported positive selection acting on mitochondrial protein-coding genes in vertebrates in response to environmental factors, including in mammals (da Fonseca et al, 2008), birds (Stager et al, 2014;Morales et al, 2015) and fish (Silva et al, 2014). Many of these studies find that candidate sites for positive selection are disproportionately concentrated in the NADH complex genes (OXPHOS complex I), which produces~40% of the proton flux required for ATP synthesis (Garvin et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

Pleistocene divergence across a mountain range and the influence of selection on mitogenome evolution in threatened Australian freshwater cod species

et al. 2016

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Climatic differences across a taxon's range may be associated with specific bioenergetic demands and may result in geneticsbased metabolic adaptation, particularly in aquatic ectothermic organisms that rely on heat exchange with the environment to regulate key physiological processes. Extending down the east coast of Australia, the Great Dividing Range (GDR) has a strong influence on climate and the evolutionary history of freshwater fish species. Despite the GDR acting as a strong contemporary barrier to fish movement, many species, and species with shared ancestries, are found on both sides of the GDR, indicative of historical dispersal events. We sequenced complete mitogenomes from the four extant species of the freshwater cod genus Maccullochella, two of which occur on the semi-arid, inland side of the GDR, and two on the mesic coastal side. We constructed a dated phylogeny and explored the relative influences of purifying and positive selection in the evolution of mitogenome divergence among species. Results supported mid-to late-Pleistocene divergence of Maccullochella across the GDR (220-710 thousand years ago), bringing forward previously reported dates. Against a background of pervasive purifying selection, we detected potentially functionally relevant fixed amino acid differences across the GDR. Although many amino acid differences between inland and coastal species may have become fixed under relaxed purifying selection in coastal environments rather than positive selection, there was evidence of episodic positive selection acting on specific codons in the Mary River coastal lineage, which has consistently experienced the warmest and least extreme climate in the genus.

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

Cited by 132 publications

References 112 publications

Matching loci surveyed to questions asked in phylogeography

Matching loci surveyed to questions asked in phylogeography

Experimental Support That Natural Selection Has Shaped the Latitudinal Distribution of Mitochondrial Haplotypes in Australian Drosophila melanogaster

Pleistocene divergence across a mountain range and the influence of selection on mitogenome evolution in threatened Australian freshwater cod species

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