Nuclear genetic background influences the phenotype of the Drosophila tko25t mitochondrial protein-synthesis mutant.

The Drosophila tko25t point mutation in the gene encoding mitoribosomal protein S12 produces a complex phenotype of multiple respiratory chain deficiency, developmental delay, bang-sensitivity, impaired hearing, sugar and antibiotic sensitivity, and impaired male courtship. Its phenotypic severity was previously shown to be alleviated by inbreeding and to vary with mitochondrial genetic background. Here, we show similarly profound effects conferred by nuclear genetic background. We backcrossed tko25t into each of 2 standard nuclear backgrounds, Oregon R and w1118, the latter used as recipient line in many transgenic applications requiring selection for the white minigene marker. In the w1118 background, tko25t flies showed a moderate developmental delay and modest bang-sensitivity. In the Oregon R background, males showed longer developmental delay and more severe bang-sensitivity, and we were initially unable to produce homozygous tko25t females in sufficient numbers to conduct a meaningful analysis. When maintained as a balanced stock over 2 years, tko25t flies in the Oregon R background showed clear phenotypic improvement though were still more severely affected than in the w1118 background. Phenotypic severity did not correlate with the expression level of the tko gene. Analysis of tko25t hybrids between the 2 backgrounds indicated that phenotypic severity was conferred by autosomal, X-chromosomal, and parent-of-origin-dependent determinants. Although some of these effects may be tko25t specific, we recommend that, in order to minimize genetic drift and confounding background effects, the genetic background of nonlethal mutants should be controlled by regular backcrossing, even if stocks are usually maintained over a balancer chromosome.

Lethal Interaction of Nuclear and Mitochondrial Genotypes in Drosophila melanogaster.

Drosophilamelanogaster, like most animal species, displays considerable genetic variation in both nuclear and mitochondrial DNA (mtDNA). Here we tested whether any of four natural mtDNA variants was able to modify the effect of the phenotypically mild, nuclear tko25t mutation, affecting mitochondrial protein synthesis. When combined with tko25t , the mtDNA from wild strain KSA2 produced pupal lethality, accompanied by the presence of melanotic nodules in L3 larvae. KSA2 mtDNA, which carries a substitution at a conserved residue of cytochrome b that is predicted to be involved in subunit interactions within respiratory complex III, conferred drastically decreased respiratory capacity and complex III activity in the tko25t but not a wild-type nuclear background. The complex III inhibitor antimycin A was able to phenocopy effects of the tko25t mutation in the KSA2 mtDNA background. This is the first report of a lethal, nuclear-mitochondrial interaction within a metazoan species, representing a paradigm for understanding genetic interactions between nuclear and mitochondrial genotype relevant to human health and disease.

Mitochondrial genotype modulates mtDNA copy number and organismal phenotype in Drosophila.

We evaluated the role of natural mitochondrial DNA (mtDNA) variation on mtDNA copy number, biochemical features and life history traits in Drosophila cybrid strains. We demonstrate the effects of both coding region and non-coding A+T region variation on mtDNA copy number, and demonstrate that copy number correlates with mitochondrial biochemistry and metabolically important traits such as development time. For example, high mtDNA copy number correlates with longer development times. Our findings support the hypothesis that mtDNA copy number is modulated by mtDNA genome variation and suggest that it affects OXPHOS efficiency through changes in the organization of the respiratory membrane complexes to influence organismal phenotype.