DNA maintenance following bleomycin-induced strand breaks does not require poly(ADP-ribosyl)ation activation in Drosophila S2 cells.

BACKGROUND: Poly-ADP ribosylation (PARylation) is a post translational modification, catalyzed by Poly(ADP-ribose)polymerase (PARP) family. In Drosophila, PARP-I (human PARP-1 ortholog) is considered to be the only enzymatically active isoform. PARylation is involved in various cellular processes such as DNA repair in case of base excision and strand-breaks. OBSERVATIONS: Strand-breaks (SSB and DSB) are detrimental to cell viability and, in Drosophila, that has a unique PARP family organization, little is known on PARP involvement in the control of strand-breaks repair process. In our study, strands-breaks (SSB and DSB) are chemically induced in S2 Drosophila cells using bleomycin. These breaks are efficiently repaired in S2 cells. During the bleomycin treatment, changes in PARylation levels are only detectable in a few cells, and an increase in PARP-I and PARP-II mRNAs is only observed during the recovery period. These results differ strongly from those obtained with Human cells, where PARylation is strongly activating when DNA breaks are generated. Finally, in PARP knock-down cells, DNA stability is altered but no change in strand-breaks repair can be observed. CONCLUSIONS: PARP responses in DNA strands-breaks context are functional in Drosophila model as demonstrated by PARP-I and PARP-II mRNA increases. However, no modification of the global PARylation profile is observed during strand-breaks generation, only changes at cellular levels are detectable. Taking together, these results demonstrate that PARylation process in Drosophila is tightly regulated in the context of strands-breaks repair and that PARP is essential during the maintenance of DNA integrity but dispensable in the DNA repair process.

A comprehensive approach to determining BER capacities and their change with aging in Drosophila melanogaster mitochondria by oligonucleotide microarray.

DNA repair mechanisms are key components for the maintenance of the essential mitochondrial genome. Among them, base excision repair (BER) processes, dedicated in part to oxidative DNA damage, are individually well known in mitochondria. However, no large view of these systems in differential physiological conditions is available yet. Combining the use of pure mitochondrial fractions and a multiplexed oligonucleotide cleavage assay on a microarray, we demonstrated that a large range of glycosylase activities were present in Drosophila mitochondria. Most of them were quantitatively different from their nuclear counterpart. Moreover, these activities were modified during aging.

Bleomycin-induced double-strand breaks in mitochondrial DNA of Drosophila cells are repaired.

Mitochondrial DNA lesions cause numerous human diseases, and it is therefore important to identify the mechanisms whereby the mitochondrion repairs the damage. We have studied in cultured Drosophila cells the repair of bleomycin-induced double-strand breaks (DSBs) in mitochondrial DNA. Our results show that DSBs are repaired as rapidly and effectively in the mitochondria as in the nucleus. DNA repair is complete within 2h following bleomycin treatment, showing that Drosophila mitochondria have an effective system of DSB repair. The mechanism and mitochondrial proteins involved remain to be identified.

Aging impact on biochemical activities and gene expression of Drosophila melanogaster mitochondria.

The consequences of aging are characterized by a decline in the main cellular functions, including those of the mitochondria. Although these consequences have been much studied, efforts have often focused solely on a few parameters used to assess the "state" of mitochondrial function during aging. We performed comparative measurements of several parameters in young (a few days) and old (8 and 12 weeks) adult male Drosophila melanogaster: respiratory complex activities, mitochondrial respiration, ATP synthesis, lipid composition of the inner membrane, concentrations of respiratory complex subunits, expression of genes (nuclear and mitochondrial) coding for mitochondrial proteins. Our results show that, in the mitochondria of "old" flies, the activities of three respiratory complexes (I, III, IV) are greatly diminished, ATP synthesis is decreased, and the lipid composition of the inner membrane (fatty acids, cardiolipin) is modified. However, the respiration rate and subunit concentrations measured by Western blot are unaffected. Although cellular mitochondrial DNA (mtDNA) content remains constant, there is a decrease in concentrations of nuclear and mitochondrial transcripts apparently coordinated. The expression of nuclear genes encoding the transcription factors TFAM, TFB1, TFB2, and DmTTF, which are essential for the maintenance and expression of mtDNA are also decreased. The decrease in nuclear and mitochondrial transcript concentrations may be one of the principal effects of aging on mitochondria, and could explain observed decreases in mitochondrial efficiency.

Coordinated decrease of the expression of the mitochondrial and nuclear complex I genes in a mitochondrial mutant of Drosophila.

We have studied a mutant strain of Drosophila in which 80% of the mitochondrial DNA molecules have lost over 30% of their coding region through deletion. This deletion affects genes encoding five subunits of complex I of the respiratory chain (NADH:ubiquinone oxidoreductase). The enzymatic activity of complex I in the mutant strain is half that in the wild strain, but ATP synthesis is unaffected. The drop in enzymatic activity of complex I in the mutant strain is associated with a 50% decrease in the quantity of constitutive proteins of the complex. Moreover, in the mutant strain there is a 50% decrease in the steady-state concentration of the transcripts of the mitochondrial genes affected by the deletion. This decrease is also observed for the transcripts of the nuclear genes coding for the subunits of complex I. These results suggest a coordination of the expression of the mitochondrial and nuclear genes coding for mitochondrial proteins.

Gene dosage and selective expression modify phenotype in a Drosophila model of human mitochondrial disease.

Human mitochondrial disease manifests with a wide range of clinical phenotypes of varying severity. To create a model for these disorders, we have manipulated the Drosophila gene technical knockout, encoding mitoribosomal protein S12. Various permutations of endogenous and transgenic alleles create a range of phenotypes, varying from larval developmental arrest through to mild neurological defects in the adult, and also mimic threshold effects associated with human mtDNA disease. Nuclear genetic background influences mutant phenotype by a compensatory mechanism affecting mitochondrial RNA levels. Selective expression of the wild-type allele indicates critical times and cell-types in development, in which mitochondrial protein synthesis deficiency leads to specific phenotypic outcomes.

The nuclear genome of a Drosophila mutant strain increases the frequency of rearranged mitochondrial DNA molecules.

We studied a mutant strain of Drosophila subobscura, in which 80% of the mitochondrial genomes (mtDNA) have lost over 30% of the coding region. The mutation is stable and is transmitted identically to offspring. The putative role of the mutant nuclear genome in the production of rearranged mtDNA was investigated using reciprocal crosses, to place the mitochondria of the wild strain in a mutant nuclear context. Nested PCR was used to screen for rearrangements in different regions of mtDNA; and rearrangements were detected in some individuals from the F6 generation. The frequency of these deleted mtDNAs then increased progressively in the population; and they were present in nearly all individuals in the F11 generation. They were not transmissible. Direct repeats were present at the deletion boundaries. These mutated genomes disappeared on reversion to a wild-type nuclear genome. Deletions were detected in a very small fraction of the wild population (0.7% of individuals). The mutant nuclear genome therefore does not promote a particular deletion but increases the frequency of different mtDNA rearrangements. The potential involvement of different candidate nuclear genes is discussed.

The nuclear genome is involved in heteroplasmy control in a mitochondrial mutant strain of Drosophila subobscura.

Most (78%) mitochondrial genomes in the studied mutant strain of Drosophila subobscura have undergone a large-scale deletion (5 kb) in the coding region. This mutation is stable, and is transmitted intact to the offspring. This animal model of major rearrangements of mitochondrial genomes can be used to analyse the involvement of the nuclear genome in the production and maintenance of these rearrangements. Successive backcrosses between mutant strain females and wild-type males yield a biphasic change in heteroplasmy level: (a) a 5% decrease in mutated genomes per generation (from 78 to 55%), until the nuclear genome is virtually replaced by the wild-type genome (seven to eight crosses); and (b) a continuous decrease of 0.5% per generation when the nuclear context is completely wild-type. In parallel with these changes, NADH dehydrogenase activity, which is halved in the mutant strain (five subunits of this complex are affected by the mutation), gradually increases and stabilizes near the wild-type activity. A return to a nuclear context is accompanied by the opposite phenomena: progressive increase in heteroplasmy level and stabilization at the value seen in the wild-type strain and a decrease in the activity of complex I. These results indicate that the nuclear genome plays an important role in the control of heteroplasmy level and probably in the production of rearranged genomes.