Parallel Structural Evolution of Mitochondrial Ribosomes and OXPHOS Complexes

Sluis, Eli O. van der; Bauerschmitt, Heike; Becker, Thomas; Mielke, Thorsten; Frauenfeld, Jens; Berninghausen, Otto; Neupert, Walter; Herrmann, Johannes M.; Beckmann, Roland

doi:10.1093/gbe/evv061

Cited by 76 publications

(57 citation statements)

References 81 publications

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“…2015; van der Sluis et al. 2015). mt genes can also potentially compensate for changes in deleterious changes in N‐mt genes.…”

Section: Speciation Via Mitonuclear Coevolution To Maintain Coadaptationmentioning

confidence: 99%

“…As a consequence, slightly deleterious mutations perpetually accumulate in the mitochondrial genome (Lynch and Blanchard 1998;Neiman and Taylor 2009), and because all mitochondrial genes code for OXPHOS function, an accumulation of deleterious mutations in the mitochondrial genome erodes OXPHOS function resulting in loss of fitness (Wallace 2010). Growing evidence suggests that N-mt genes can evolve so as to compensate for the deleterious effects of mutations in mt genes, thereby reversing deterioration of OXPHOS (Mishmar et al 2006;Barreto and Burton 2013;Havird et al 2015;van der Sluis et al 2015). mt genes can also potentially compensate for changes in deleterious changes in N-mt genes.…”

Section: Speciation Via Mitonuclear Coevolution To Maintain Coadaptationmentioning

confidence: 99%

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Mitonuclear coevolution as the genesis of speciation and the mitochondrial DNA barcode gap

Hill

2016

Ecology and Evolution

134

173

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Mitochondrial genes are widely used in taxonomy and systematics because high mutation rates lead to rapid sequence divergence and because such changes have long been assumed to be neutral with respect to function. In particular, the nucleotide sequence of the mitochondrial gene cytochrome c oxidase subunit 1 has been established as a highly effective DNA barcode for diagnosing the species boundaries of animals. Rarely considered in discussions of mitochondrial evolution in the context of systematics, speciation, or DNA barcodes, however, is the genomic architecture of the eukaryotes: Mitochondrial and nuclear genes must function in tight coordination to produce the complexes of the electron transport chain and enable cellular respiration. Coadaptation of these interacting gene products is essential for organism function. I extend the hypothesis that mitonuclear interactions are integral to the process of speciation. To maintain mitonuclear coadaptation, nuclear genes, which code for proteins in mitochondria that cofunction with the products of mitochondrial genes, must coevolve with rapidly changing mitochondrial genes. Mitonuclear coevolution in isolated populations leads to speciation because population‐specific mitonuclear coadaptations create between‐population mitonuclear incompatibilities and hence barriers to gene flow between populations. In addition, selection for adaptive divergence of products of mitochondrial genes, particularly in response to climate or altitude, can lead to rapid fixation of novel mitochondrial genotypes between populations and consequently to disruption in gene flow between populations as the initiating step in animal speciation. By this model, the defining characteristic of a metazoan species is a coadapted mitonuclear genotype that is incompatible with the coadapted mitochondrial and nuclear genotype of any other population.

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“…2015; van der Sluis et al. 2015). mt genes can also potentially compensate for changes in deleterious changes in N‐mt genes.…”

Section: Speciation Via Mitonuclear Coevolution To Maintain Coadaptationmentioning

confidence: 99%

Section: Speciation Via Mitonuclear Coevolution To Maintain Coadaptationmentioning

confidence: 99%

Mitonuclear coevolution as the genesis of speciation and the mitochondrial DNA barcode gap

Hill

2016

Ecology and Evolution

134

173

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“…It has also been proposed that the recruitment of novel nuclear‐encoded OXPHOS subunits in eukaryotes may have been a form of structural compensation for the unstable mitochondrial‐encoded subunits (van der Sluis et al. ).…”

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confidence: 99%

Conservative and compensatory evolution in oxidative phosphorylation complexes of angiosperms with highly divergent rates of mitochondrial genome evolution

et al. 2015

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Interactions between nuclear and mitochondrial gene products are critical for eukaryotic cell function. Nuclear genes encoding mitochondrial-targeted proteins (N-mt genes) experience elevated rates of evolution, which has often been interpreted as evidence of nuclear compensation in response to elevated mitochondrial mutation rates. However, N-mt genes may be under relaxed functional constraints, which could also explain observed increases in their evolutionary rate. To disentangle these hypotheses, we examined patterns of sequence and structural evolution in nuclear and mitochondrial-encoded oxidative phosphorylation proteins from species in the angiosperm genus Silene with vastly different mitochondrial mutation rates. We found correlated increases in N-mt gene evolution in species with fast-evolving mitochondrial DNA. Structural modeling revealed an overrepresentation of N-mt substitutions at positions that directly contact mutated residues in mitochondrial-encoded proteins, despite overall patterns of conservative structural evolution. These findings support the hypothesis that selection for compensatory changes in response to mitochondrial mutations contributes to the elevated rate of evolution in N-mt genes. We discuss these results in light of theories implicating mitochondrial mutation rates and mitonuclear co-evolution as drivers of speciation and suggest comparative and experimental approaches that could take advantage of heterogeneity in rates of mtDNA evolution across eukaryotes to evaluate such theories.

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“…Species‐specificity of mitonuclear coadaptation results primarily from the need to maintain coadaptation in the face of accumulation of deleterious mutations in the mitochondrial genome . Evidence suggests that N‐mt genes can evolve so as to compensate for the deleterious effects of mutations in mt genes, thereby preventing deterioration of OXPHOS . Such compensatory coevolution appears to occur not only in the protein‐protein interactions of the ETS, but also in the protein‐DNA interactions during replication of the mt genome, in protein‐RNA interactions in mitochondrial ribosomes, and between mt‐tRNAs and aminoacyl tRNA synthetase .…”

Section: Respiratory Function Requires Mitonuclear Coadaptationmentioning

confidence: 99%

“…Evidence suggests that N‐mt genes can evolve so as to compensate for the deleterious effects of mutations in mt genes, thereby preventing deterioration of OXPHOS . Such compensatory coevolution appears to occur not only in the protein‐protein interactions of the ETS, but also in the protein‐DNA interactions during replication of the mt genome, in protein‐RNA interactions in mitochondrial ribosomes, and between mt‐tRNAs and aminoacyl tRNA synthetase . Coevolution between mitochondrial and nuclear genomes – in which N‐mt genes compensate for random deleterious mutations in mt genes – can potentially lead to perpetual and unpredictable divergence in tightly coadapted complexes of mt and N‐mt genes within species .…”

Section: Respiratory Function Requires Mitonuclear Coadaptationmentioning

confidence: 99%

Mitonuclear Mate Choice: A Missing Component of Sexual Selection Theory?

Hill

2018

BioEssays

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The fitness of a eukaryote hinges on the coordinated function of the products of its nuclear and mitochondrial genomes in achieving oxidative phosphorylation (OXPHOS). I propose that sexual selection plays a key role in the maintenance of mitonuclear coadaptation across generations because it enables pre-zygotic sorting for coadapted mitonuclear genotypes. At each new generation, sexual reproduction creates new combinations of nuclear and mitochondrial genes, and the potential arises for mitonuclear incompatibilities and reduced fitness. In reviewing the literature, I hypothesize that individuals engaged in mate choice select partners with correct species-typical mitochondrial and nuclear genotypes as well as individuals with highly functional cellular respiration. The implication is that mate choice for compatible nuclear and mitochondrial genes can play a significant role in generating the patterns of ornamentation and preferences observed in animals. A number of testable predictions emerge from this mitonuclear compatibility hypothesis of sexual selection.

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Parallel Structural Evolution of Mitochondrial Ribosomes and OXPHOS Complexes

Cited by 76 publications

References 81 publications

Mitonuclear coevolution as the genesis of speciation and the mitochondrial DNA barcode gap

Mitonuclear coevolution as the genesis of speciation and the mitochondrial DNA barcode gap

Conservative and compensatory evolution in oxidative phosphorylation complexes of angiosperms with highly divergent rates of mitochondrial genome evolution

Mitonuclear Mate Choice: A Missing Component of Sexual Selection Theory?

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