Mitochondrial–Nuclear Interactions: Compensatory Evolution or Variable Functional Constraint among Vertebrate Oxidative Phosphorylation Genes?

Zhang, Feifei; Broughton, Richard E.

doi:10.1093/gbe/evt129

Cited by 59 publications

(75 citation statements)

References 64 publications

(78 reference statements)

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Section: Discussionmentioning

confidence: 95%

“…Amino acid replacements putatively under selection in the Mary River cod were located in complexes I (ND1, ND5 and ND6) and, somewhat atypically, in complex IV (COI, COII and COIII) (Zhang and Broughton, 2013). Whilst amino acid replacements in complex I (ND genes) tend to have minor effects on functional properties of amino acids, amino acid replacements in complex IV (COX genes) tend to have disproportionate effects on fitness, making COX genes typically the most highly conserved in the mitogenome (Zhang and Broughton, 2013). Although sites showing signatures of episodic positive selection detected in the Mary River cod may represent false positives that are in fact deleterious but not (yet) removed by selection because of low effective population size, investigation of candidate sites and adaptive processes in Mary River cod seems warranted (Hughes, 2007).…”

Section: Discussionmentioning

confidence: 95%

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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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Section: Discussionmentioning

confidence: 95%

Section: Discussionmentioning

confidence: 95%

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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“…The Dobzhansky-Muller-type mt-n incompatibilities that sometimes exist between species may have contributed to speciation events (Trier et al 2014;Wolff et al 2014), although the dynamics of mt-n coevolution are not well enough understood to make substantial conclusions. Regardless, the trove of molecular sequence analyses repeatedly has shown evidence for coevolution of mt-n complexes (e.g., BayonaBafaluy et al 2005;Parmakelis et al 2013;Zhang and Broughton 2013), supporting the empirical data that mt-n incompatibilities generally increase with genetic distance.The yeast S. cerevisiae is potentially an excellent model system to investigate mt-n epistasis. First, yeasts undergo both meiotic and mitotic replication.…”

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confidence: 84%

Mitochondrial-Nuclear Epistasis Contributes to Phenotypic Variation and Coadaptation in Natural Isolates of Saccharomyces cerevisiae

Paliwal¹,

Fiumera²,

Fiumera

2014

Genetics

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Mitochondria are essential multifunctional organelles whose metabolic functions, biogenesis, and maintenance are controlled through genetic interactions between mitochondrial and nuclear genomes. In natural populations, mitochondrial efficiencies may be impacted by epistatic interactions between naturally segregating genome variants. The extent that mitochondrial-nuclear epistasis contributes to the phenotypic variation present in nature is unknown. We have systematically replaced mitochondrial DNAs in a collection of divergent Saccharomyces cerevisiae yeast isolates and quantified the effects on growth rates in a variety of environments. We found that mitochondrial-nuclear interactions significantly affected growth rates and explained a substantial proportion of the phenotypic variances under some environmental conditions. Naturally occurring mitochondrial-nuclear genome combinations were more likely to provide growth advantages, but genetic distance could not predict the effects of epistasis. Interruption of naturally occurring mitochondrial-nuclear genome combinations increased endogenous reactive oxygen species in several strains to levels that were not always proportional to growth rate differences. Our results demonstrate that interactions between mitochondrial and nuclear genomes generate phenotypic diversity in natural populations of yeasts and that coadaptation of intergenomic interactions likely occurs quickly within the specific niches that yeast occupy. This study reveals the importance of considering allelic interactions between mitochondrial and nuclear genomes when investigating evolutionary relationships and mapping the genetic basis underlying complex traits. M ITOCHONDRIAL energy production, which affects virtually every aspect of cellular fitness, requires the participation of two genomes. The mitochondrial genome encodes for essential components of the oxidative phosphorylation machinery and mitochondrial ribosomal RNAs and transfer RNAs. The nuclear genome encodes nearly 1000 proteins that are imported to the organelle where they compose the majority of the mitochondrial proteome. Specific interactions between components of both genomes are required at many levels, including mitochondrial DNA (mtDNA) replication, repair, and inheritance and transcription, translation, and assembly of the electron transport chain components. The respiratory complexes themselves are heterogeneous, composed of both nuclear and mitochondrially encoded proteins. Over evolutionary time, these interactions have been optimized, in part, to regulate production of the reactive oxygen species (ROS) that are the by-products of mitochondrial respiration.Allelic variation in both genomes can affect mt-n interactions and alter mitochondrial fitness. These interactions have been shown to have direct consequences on healthrelated and life-history phenotypes in several taxa. In insects such as Drosophila and Callosobruchus (seed beetle), exchanging mtDNA variants between distinct populations has led to lowered metabo...

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“…We refer to this as the nuclear compensation hypothesis, which has been supported by the following: (1) patterns of mitonuclear evolution such as the position and relative tim Popadin et al 2013;Zhang and Broughton 2013). We refer to this argument as the selective constraints hypothesis, which is supported by two main lines of reasoning.…”

Section: Introductionmentioning

confidence: 99%

“…We refer to this argument as the selective constraints hypothesis, which is supported by two main lines of reasoning. First, N-mt genes often encode "peripheral" subunits within OXPHOS complexes, which may be able to withstand more mutations due to a less critical role in OXPHOS (note that some of these peripheral subunits are eukaryotic-specific additions to these complexes and were not ancestrally present in bacteria; van der Sluis et al 2015), whereas mt genes encode "core" subunits, which may participate in more essential functions (Zhang and Broughton 2013). Secondly, proteins that are highly abundant may be under more functional constraints because protein misfolding and misinteractions can be more costly for abundant proteins, resulting in stronger purifying selection and slower evolution (Zhang and Yang 2015).…”

Section: Introductionmentioning

confidence: 99%

The Roles of Mutation, Selection, and Expression in Determining Relative Rates of Evolution in Mitochondrial versus Nuclear Genomes

Havird

Sloan

2016

Mol Biol Evol

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Eukaryotes rely on proteins encoded by the nuclear and mitochondrial (mt) genomes, which interact within multisubunit complexes such as oxidative-phosphorylation enzymes. Although selection is thought to be less efficient on the asexual mt genome, in bilaterian animals the ratio of nonsynonymous to synonymous substitutions (x) is lower in mt-compared with nuclear-encoded OXPHOS subunits, suggesting stronger effects of purifying selection in the mt genome. Because high levels of gene expression constrain protein sequence evolution, one proposed resolution to this paradox is that mt genes are expressed more highly than nuclear genes. To test this hypothesis, we investigated expression and sequence evolution of mt and nuclear genes from 84 diverse eukaryotes that vary in mt gene content and mutation rate. We found that the relationship between mt and nuclear x values varied dramatically across eukaryotes. In contrast, transcript abundance is consistently higher for mt genes than nuclear genes, regardless of which genes happen to be in the mt genome. Consequently, expression levels cannot be responsible for the differences in x. Rather, 84% of the variance in the ratio of x values between mt and nuclear genes could be explained by differences in mutation rate between the two genomes. We relate these findings to the hypothesis that high rates of mt mutation select for compensatory changes in the nuclear genome. We also propose an explanation for why mt transcripts consistently outnumber their nuclear counterparts, with implications for mitonuclear protein imbalance and aging.

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Mitochondrial–Nuclear Interactions: Compensatory Evolution or Variable Functional Constraint among Vertebrate Oxidative Phosphorylation Genes?

Cited by 59 publications

References 64 publications

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

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

Mitochondrial-Nuclear Epistasis Contributes to Phenotypic Variation and Coadaptation in Natural Isolates of Saccharomyces cerevisiae

The Roles of Mutation, Selection, and Expression in Determining Relative Rates of Evolution in Mitochondrial versus Nuclear Genomes

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