Bettinazzi Stefano, Liang Jane, Rodriguez Enrique, Bonneau Marion, Holt Ruben, Whitehead Ben, Dowling Damian K, Lane Nick, Camus M Florencia
Department of Genetics, Evolution and Environment, University College London, London, United Kingdom.
School of Biological Sciences, Monash University, Melbourne, VIC, Australia.
Evol Lett. 2024 Aug 9;8(6):916-926. doi: 10.1093/evlett/qrae043. eCollection 2024 Dec.
Mitochondrial function depends on the effective interactions between proteins and RNA encoded by the mitochondrial and nuclear genomes. Evidence suggests that both genomes respond to thermal selection and promote adaptation. However, the contribution of their epistatic interactions to life history phenotypes in the wild remains elusive. We investigated the evolutionary implications of mitonuclear interactions in a real-world scenario that sees populations adapted to different environments, altering their geographical distribution while experiencing flow and admixture. We created a panel with replicate native populations from the ends of the Australian east-coast cline, into which we substituted the mtDNA haplotypes that were either predominant or rare at each cline-end, thus creating putatively mitonuclear matched and mismatched populations. Our results suggest that mismatching may impact phenotype, with populations harboring the rarer mtDNA haplotype suffering a trade-off between aerobic capacity and key fitness aspects such as reproduction, growth, and survival. We discuss the significance of mitonuclear interactions as modulators of life history phenotypes in the context of future adaptation and population persistence.
线粒体功能取决于线粒体基因组和核基因组编码的蛋白质与RNA之间的有效相互作用。有证据表明,这两个基因组都会对热选择做出反应并促进适应性。然而,它们的上位性相互作用对野生生物生活史表型的贡献仍然难以捉摸。我们在一个现实世界的场景中研究了线粒体-核相互作用的进化意义,在这个场景中,种群适应不同的环境,在经历种群流动和混合的同时改变其地理分布。我们创建了一个面板,其中包含来自澳大利亚东海岸渐变群两端的本地种群复制品,我们在其中替换了每个渐变群末端占主导或罕见的线粒体DNA单倍型,从而创建了假定的线粒体-核匹配和不匹配种群。我们的结果表明,不匹配可能会影响表型,携带较罕见线粒体DNA单倍型的种群在有氧能力与繁殖、生长和生存等关键适应性方面之间存在权衡。我们讨论了线粒体-核相互作用作为生活史表型调节剂在未来适应性和种群持久性背景下的重要性。
