Abstract

The maternal inheritance of mitochondrial genomes entails a sex‐specific selective sieve, whereby mutations in mitochondrial DNA can only respond to selection acting on females. In theory, this enables male‐harming mutations to accumulate in mitochondrial genomes as long as they are neutral, beneficial, or only slightly deleterious to females. Ultimately, this bias could drive the evolution of male‐specific mitochondrial mutation loads, an idea known as mother's curse. Earlier work on this hypothesis has mainly used small Drosophila panels, in which naturally sourced mitochondrial genomes were coupled to an isogenic nuclear background. The lack of nuclear genetic variation in these designs has precluded robust generalization. Here, we test the predictions of mother's curse using a large Drosophila mitonuclear genetic panel, comprising nine isogenic nuclear genomes coupled to nine mitochondrial haplotypes, giving a total of 81 different mitonuclear genotypes. Following a predictive framework, we tested the mother's curse hypothesis by screening our panel for wing size. This trait is tightly correlated with overall body size and is sexually dimorphic in Drosophila. Moreover, growth is heavily reliant on metabolism and mitochondrial function, making wing size an ideal trait for the study of the impact of mitochondrial variation. We detect high levels of mitonuclear epistasis, and more importantly, we report that mitochondrial genetic variance is larger in male than female Drosophila for eight out of the nine nuclear genetic backgrounds used. These results demonstrate that the maternal inheritance of mitochondrial DNA does indeed modulate male life history traits in a more generalisable way than previously demonstrated.

Highlights

  • Mitochondria are essential organelles in eukaryotic cells, which originally derived from free-living bacteria and still retain their own specialized “bioenergetic” genomes

  • We created a large Drosophila mitonuclear panel comprising nine nuclear genomes, each coupled to nine mtDNA haplotypes for a total of 81 strains

  • We found mitochondria to contribute less to the overall variance in wing size observed in our data, we found it to be higher in males (2.3%) than females (0.9%)

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Summary

Introduction

Mitochondria are essential organelles in eukaryotic cells, which originally derived from free-living bacteria and still retain their own specialized “bioenergetic” genomes (mtDNA). Respiration is unusual in that the respiratory complexes within mitochondria are composed of proteins encoded by two different genomes, the nuclear and the mitochondrial. These two genomes must work harmoniously to provide cellular energy and the precursors for most macromolecule synthesis. Their interaction is vital for the maintenance of mitochondrial integrity and the viability of eukaryote life. Mitochondria are maternally inherited in most species, and so natural selection acting on the mitochondrial genome is effective only in females (Rand 2001). The process leading to sex-biased mutation accumulation has been termed “sex-specific selective sieve” (Innocenti et al 2011) or the “mother’s curse hypothesis” (Gemmell et al 2004)

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