Epistatic interactions modulate the evolution of mammalian mitochondrial respiratory complex components

<p>Abstract</p> <p>Background</p> <p>The deleterious effect of a mutation can be reverted by a second-site interacting residue. This is an epistatic compensatory process explaining why mutations that are deleterious in some species are tolerated in phylogenetically rela...

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Main Authors: Moleirinho Ana, van Asch Barbara, Carneiro João, Azevedo Luísa, Pereira Filipe, Amorim António
Format: Article
Language:English
Published: BMC 2009-06-01
Series:BMC Genomics
Online Access:http://www.biomedcentral.com/1471-2164/10/266
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spelling doaj-90304fc446e94581a19058a909ebe2432020-11-24T21:09:26ZengBMCBMC Genomics1471-21642009-06-0110126610.1186/1471-2164-10-266Epistatic interactions modulate the evolution of mammalian mitochondrial respiratory complex componentsMoleirinho Anavan Asch BarbaraCarneiro JoãoAzevedo LuísaPereira FilipeAmorim António<p>Abstract</p> <p>Background</p> <p>The deleterious effect of a mutation can be reverted by a second-site interacting residue. This is an epistatic compensatory process explaining why mutations that are deleterious in some species are tolerated in phylogenetically related lineages, rendering evident that those mutations are, by all means, only deleterious in the species-specific context. Although an extensive and refined theoretical framework on compensatory evolution does exist, the supporting evidence remains limited, especially for protein models. In this current study, we focused on the molecular mechanism underlying the epistatic compensatory process in mammalian mitochondrial OXPHOS proteins using a combination of in-depth structural and sequence analyses.</p> <p>Results</p> <p>Modeled human structures were used in this study to predict the structural impairment and recovery of deleterious mutations alone and combined with an interacting compensatory partner, respectively. In two cases, COI and COIII, intramolecular interactions between spatially linked residues restore the folding pattern impaired by the deleterious mutation. In a third case, intermolecular contact between mitochondrial CYB and nuclear CYT1 encoded components of the cytochrome <it>bc1 </it>complex are likely to restore protein binding. Moreover, we observed different modes of compensatory evolution that have resulted in either a quasi-simultaneous occurrence of a mutation and corresponding compensatory partner, or in independent occurrences of mutations in distinct lineages that were always preceded by the compensatory site.</p> <p>Conclusion</p> <p>Epistatic interactions between individual replacements involving deleterious mutations seems to follow a parsimonious model of evolution in which genomes hold pre-compensating states that subsequently tolerate deleterious mutations. This phenomenon is likely to have been constraining the variability at coevolving sites and shaping the interaction between the mitochondrial and the nuclear genome.</p> http://www.biomedcentral.com/1471-2164/10/266
collection DOAJ
language English
format Article
sources DOAJ
author Moleirinho Ana
van Asch Barbara
Carneiro João
Azevedo Luísa
Pereira Filipe
Amorim António
spellingShingle Moleirinho Ana
van Asch Barbara
Carneiro João
Azevedo Luísa
Pereira Filipe
Amorim António
Epistatic interactions modulate the evolution of mammalian mitochondrial respiratory complex components
BMC Genomics
author_facet Moleirinho Ana
van Asch Barbara
Carneiro João
Azevedo Luísa
Pereira Filipe
Amorim António
author_sort Moleirinho Ana
title Epistatic interactions modulate the evolution of mammalian mitochondrial respiratory complex components
title_short Epistatic interactions modulate the evolution of mammalian mitochondrial respiratory complex components
title_full Epistatic interactions modulate the evolution of mammalian mitochondrial respiratory complex components
title_fullStr Epistatic interactions modulate the evolution of mammalian mitochondrial respiratory complex components
title_full_unstemmed Epistatic interactions modulate the evolution of mammalian mitochondrial respiratory complex components
title_sort epistatic interactions modulate the evolution of mammalian mitochondrial respiratory complex components
publisher BMC
series BMC Genomics
issn 1471-2164
publishDate 2009-06-01
description <p>Abstract</p> <p>Background</p> <p>The deleterious effect of a mutation can be reverted by a second-site interacting residue. This is an epistatic compensatory process explaining why mutations that are deleterious in some species are tolerated in phylogenetically related lineages, rendering evident that those mutations are, by all means, only deleterious in the species-specific context. Although an extensive and refined theoretical framework on compensatory evolution does exist, the supporting evidence remains limited, especially for protein models. In this current study, we focused on the molecular mechanism underlying the epistatic compensatory process in mammalian mitochondrial OXPHOS proteins using a combination of in-depth structural and sequence analyses.</p> <p>Results</p> <p>Modeled human structures were used in this study to predict the structural impairment and recovery of deleterious mutations alone and combined with an interacting compensatory partner, respectively. In two cases, COI and COIII, intramolecular interactions between spatially linked residues restore the folding pattern impaired by the deleterious mutation. In a third case, intermolecular contact between mitochondrial CYB and nuclear CYT1 encoded components of the cytochrome <it>bc1 </it>complex are likely to restore protein binding. Moreover, we observed different modes of compensatory evolution that have resulted in either a quasi-simultaneous occurrence of a mutation and corresponding compensatory partner, or in independent occurrences of mutations in distinct lineages that were always preceded by the compensatory site.</p> <p>Conclusion</p> <p>Epistatic interactions between individual replacements involving deleterious mutations seems to follow a parsimonious model of evolution in which genomes hold pre-compensating states that subsequently tolerate deleterious mutations. This phenomenon is likely to have been constraining the variability at coevolving sites and shaping the interaction between the mitochondrial and the nuclear genome.</p>
url http://www.biomedcentral.com/1471-2164/10/266
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