The respiratory chain complex thresholds in mitochondria of a Drosophila subobscura mutant strain.

Analysis of a mutant strain of Drosophila subobscura revealed that most (80%) mitochondrial genomes have undergone a large scale deletion (5 kb) in the coding region. Compared with the wild-type strain, complex I and III activities are, respectively, reduced by 50% and 30% in the mutant. However, the ATP synthesis capacities remain unchanged. In order to elucidate how the ATP synthesis is maintained at a normal level, despite a significant decrease in complex I and III activities, we progressively inhibited respiratory chain complex activities, respiration rate and ATP synthesis. Complex I, III and IV activities were inhibited by rotenone, antimycin and KCN, respectively. Threshold curves were thus determined for each complex. Our results demonstrated that in the mutant strain, both mitochondrial respiration and ATP synthesis had decreased when complex I activity was inhibited by more than 20%, whereas 70% inhibition is required to induce similar changes in the wild-type. The complex I inhibition pattern of the wild-type was restored by a backcross (mutant female/wild-type male). The complex III activity threshold is below 20% in both strains, and we observed some difference in antimycin sensitivity, suggesting a modification of the complex enzymatic properties in the mutant. In contrast, threshold values of 70% were measured for complex IV inhibition. Our data suggest that the difference in the complex I threshold curves between the wild-type and mutant strains could partially account for the absence of pathological phenotype in the mutant.

Technical knockout, a Drosophila model of mitochondrial deafness.

Mutations in mtDNA-encoded components of the mitochondrial translational apparatus are associated with diverse pathological states in humans, notably sensorineural deafness. To develop animal models of such disorders, we have manipulated the nuclear gene for mitochondrial ribosomal protein S12 in Drosophila (technical knockout, tko). The prototypic mutant tko(25t) exhibits developmental delay, bang sensitivity, impaired male courtship, and defective response to sound. On the basis of a transgenic reversion test, these phenotypes are attributable to a single substitution (L85H) at a conserved residue of the tko protein. The mutant is hypersensitive to doxycyclin, an antibiotic that selectively inhibits mitochondrial protein synthesis, and mutant larvae have greatly diminished activities of mitochondrial redox enzymes and decreased levels of mitochondrial small-subunit rRNA. A second mutation in the tko gene, Q116K, which is predicted to impair the accuracy of mitochondrial translation, results in the completely different phenotype of recessive female sterility, based on three independent transgenic insertions. We infer that the tko(25t) mutant provides a model of mitochondrial hearing impairment resulting from a quantitative deficiency of mitochondrial translational capacity.

Biochemical and molecular consequences of ethidium bromide treatment on Drosophila cells.

KC167 Drosophila cells were incubated with low concentrations of ethidium bromide (200 ng/ml), causing changes in mitochondrial DNA (mtDNA) content (2-184% of that of controls). SSCP (single strand conformational polymorphism) analysis of mtDNA indicated that the incubation with ethidium bromide also generated mutations. Compared with controls, there were marked reductions in the activities of respiratory complexes III and IV measured in these cells, and in respiration and ATP synthesis capacities measured in isolated mitochondria. These reductions matched that in mtDNA content. In contrast, no link could be demonstrated between mtDNA content and steady-state concentrations of the transcripts of genes COIII and Cyt b.

Developmental changes in heteroplasmy level and mitochondrial gene expression in a Drosophila subobscura mitochondrial deletion mutant.

Eighty percent of DNA molecules are deleted in the mitochondrial population of an adult mutant strain of D. subobscura. Both intact and deleted genomes are autonomous monomers. The heteroplasmy level, which is lower in germ tissue, increases from the oocytes (60%) to the third larval instar (83%), and is then maintained throughout the life of the fly. The mtDNA/nuclear DNA ratio is on average two-times greater in the heteroplasmic strain than in the wild-type strain, irrespective of the stage, but the cellular content of mitochondria is elevated only in the embryos and pupae of the mutant strain. The steady state concentrations (SSCs) of the transcripts affected by the deletion are greatly reduced at the larval and adult stages, and less so at the pupal stage of the mutant strain compared with the wild-type. The SSCs of these transcripts are identical in the two strains at the embryonic stage. The fusion transcript, indicating that the deleted genome is expressed, was detected at all stages. The mechanisms involved in the changes in the heteroplasmy level during the course of development and in its maintenance from the third larval instar onwards are discussed.

Biochemical and molecular consequences of massive mitochondrial gene loss in different tissues of a mutant strain of Drosophila subobscura.

In the studied mutant strain of Drosophila subobscura, 78% of the mitochondrial genomes lost >30% of the coding region by deletion. The mutations was genetically stable. Despite this massive loss of mitochondrial genes, the mutant did not seem to be affected. Distribution of the two genome types, cell levels of mitochondrial DNA, steady-state concentrations of the mitochondrial gene transcripts, mitochondrial enzymatic activities, and ATP synthesis capacities were measured in the head, thorax, and abdomen fractions of the mutant strain in comparison with a wild type strain. Results indicate that the deleted genomes are detected in all fractions but to a lesser extent in the male and female abdomen. In all fractions, there is a 50% increase in cellular mitochondrial DNA content. Although there is a decrease in steady-state concentrations of mitochondrial transcripts of genes affected by deletion, this is smaller than expected. The variations in mitochondrial biochemical activities in the different fractions of the wild strain are upheld in the mutant strain. Activity of complex I (involved in mutation) nevertheless shows a decrease in all fractions; activity of complex III (likewise involved) shows little or no change; finally, mitochondrial ATP synthesis capacity is identical to that observed in the wild strain. This latter finding possibly accounts for the lack of phenotype. This mutant is a good model for studying mitochondrial genome alterations and the role of the nuclear genome in these phenomena.

Changes in the respiratory chain complexes activities and in the mitochondrial DNA content during ageing in D. subobscura.

The time course (age 0-8 weeks) of the enzyme activities of respiratory chain complexes I, III and IV and of citrate synthase, and the cell mitochondrial/nuclear DNA content ratio were studied in Drosophila subobscura. The activities of the three respiratory complexes decreased with age, but with different kinetics. The activities of complexes I and III remained nearly stable between weeks 0 and 3 (falling by 6% and 15%, respectively), and then gradually decreased; after 8 weeks residual activities were about 50% of the initial value for complexes I and III. The activity of complex IV fell in the first week, decreasing continually to week 8, where residual activity was 30% of the initial value. No significant age-related change in citrate synthase activity was observed. Mitochondrial DNA (measured by mitDNA/nucDNA) increased linearly up to week 5 (2.6-fold) and then dropped by 40% in week 6 though it remained higher than initial values.

Biochemical consequences of a large deletion in the mitochondrial genome of a Drosophila subobscura strain.

A mutant strain of D. Subobscura possesses two populations of mitochondrial genomes: a population identical to that of the wild strain (20%) and a dominant population (80%) which has lost more than 30% of its coding zone by deletion. Spectrophotometric determination of respiratory complex activities shows that: complex I (5 genes implicated in deletion) presents maximal activity reduced by 40%, whereas that of complex III (concerned by cytochrome b) is lowered by 30%. Nevertheless, polarographic determinations of substrate oxidation show activity of complex I to be reduced by 30%. In contrast, complex III activity is similar to that measured in the wild strain. The predominant use of one part of the respiratory chain may account for the fact that the mutant strain is apparently unaffected by mutation.

Translation of polyuridylic acid in lysed mitochondria.

After osmotic shock with 50 mM Tricine buffer (pH 7.9), isolated mitochondria from D. Melanogaster embryos are treated with a low concentration of Triton X-100 (25 micrograms/mg of protein). The lysed mitochondria are still capable of RNA and protein synthesis. While incorporation of labeled precursor is often higher in lysed than in intact mitochondria, neosynthesized proteins exhibit similar electrophoretic patterns. Studies of labeled precursor incorporation in the presence of various effectors indicate a better accessibility to the translation machinery in lysed mitochondria than in intact mitochondria. Such a system has proven capable of translating an exogenous synthetic mRNA, i.e., poly (U).

Mitochondrial DNA expression in Drosophila melanogaster: neosynthesized polypeptides in isolated mitochondria.

The expression of mitochondrial genome of D. melanogaster in isolated mitochondria was followed by incorporation of 35S methionine in neosynthesized polypeptides. A high level of protein synthesis was obtained after optimization of all the incubation parameters. Two kinds of energy-generating systems were used: an endogenous system where an oxidizable substrate were added for ATP synthesis; an exogenous system with an energy-rich compound for ATP regeneration, the latter proved to be the most effective. The effect of the oxidative phosphorylation uncoupler (Clccp), and an ATPase inhibitor (oligomycine) allow us to postulate the role of the electrochemical potential in the expression of the mitochondrial genome. Electrophoresis and autoradiography of neosynthesized mitochondrial proteins exhibits 18 to 24 protein bands, ranging from 6.5 to 65 Kd; incubation of KC 0% drosophila cells with 35S methionine and cycloheximide gave similar results. Both our results and those published elsewhere suggest that the expression of mitochondrial genome in higher organisms could be more complex than simple translation of the 13 genes presents on these genomes.

Phosphate transport and proteins with SH groups in rat liver mitochondria.

Phosphate transport in rat liver mitochondria was studied by following [32P] phosphate uptake within physiological concentrations. Transport inhibition due to mersalyl and protection by mersalyl against N-ethylmaleimide measured in those conditions corresponded to earlier results obtained by the swelling technique. When mitochondria were incubated with [3H] N-ethylmaleimide in the presence of mersalyl, the radioactive labeling in proteins of particles obtained after sonication was decreased in all fractions, but three proteins were both highly alkylated and also highly protected by mersalyl (M.W. 48,000 - 36,000 - 31,000). Two of these (M.W. 36,000 and 31,000) were partially purified by ultrogel chromatography in the presence of sodium dodecyl sulfate. Furthermore, it was shown that both phosphate and nigericin diminished labeling by N-ethylmaleimide in the final supernatant fraction. Two proteins (M.W. 98,000 and 31,000) were significantly alkylated by [3H] N-ethylmaleimide and protected by phosphate and nigericin.

Proteins dealing with N-ethylmaleimide inhibition of pig heart mitochondrial phosphate transport system.

Our data clearly demonstrate that protective effect of phosphate and protective effect of mersalyl against NEM-inhibition of phosphate transport act at the level of two kinds of proteins. (1)Two major components are phosphate and nigericin NEM sensitive. According to our previous data [13] it has been also demonstrated that these two proteins components are valinomycin NEM sensitive (results not shown here) suggesting a relationship between these proteins and the energy linked proton translocation process. Relationships between these proteins and the phosphate translocation process are not evident and are under further investigations. (2) Two other insoluble major components localised at the level of the subparticular fraction are mersalyl NEM sensitive. We can suggest that these proteins are implicated in the translocation of phosphate in pig heart mitochondria.