Study of the molecular mechanisms of double-strand break repair in mitochondrial DNA

DNA is constantly exposed to damaging agents from both endogenous and exogenous sources. These can cause different types of DNA lesions that include base and sugar modifications and single and double strand breaks. DNA doublestrand breaks (DSBs) are among the most cytotoxic DNA lesions, which can result in deletions and genetic instability. Deletions in the mitochondrial DNA (mtDNA) cause numerous human diseases and drive normal aging. DSBs in the nuclear DNA are repaired by non-homologous DNA end joining (NHEJ), homologous recombination (HR) or Single Strand Annealing (SSA). Yet, repair of DSBs in mammalian mitochondria has not been fully characterized. Mitochondrial extracts from rodent cells are proficient in ligating DNA ends in vitro, but little is known about which proteins are responsible for each enzymatic step and its implication in mitochondrial genome maintenance. Thus, we investigated mitochondrial localization and function of DSBR (double strand break repair) proteins ATM, Rad51, Rad52, the Ku70/86 heterodimer and DNA-PKCs.To identify DSBR proteins in mammalian mitochondria, highly purified mitochondria from HEK293T cells were isolated using differential centrifugation followed by Percoll gradient. For HR proteins, we detected similar isoforms for ATM and Rad51 proteins in all cellular compartments. Two mitochondriaspecific isoforms of Rad52 were detected, while the same antibody detected four isoforms in the nucleus. In addition, lower Rad52 protein levels, induced by specific shRNA expression, result in decreased mtDNA copy number and accumulation of deleted mitochondrial genomes. For NHEJ proteins, similar isoforms of DNA-PKcs and the Ku70 subunit were detected in all cellular compartments. On the other hand, antibodies against the Ku86 subunit detected a smaller band in mitochondrial extracts (50 KDa), lacking the N-terminal region of the canonical isoform detected in the nucleus (86 KDa). The mitochondrial Ku70/50 heterodimer interacts with mitochondrial DNA ligase III, suggesting a role in DSBR. Moreover, stability of the mtKu heterodimer is regulated by ATM. Hydrogen peroxide treatment, which induces DSBs, increases mtKu70/50 association with the mtDNA and cells with reduced Ku levels, also induced by shRNA transfection, have lower mtDNA copy number and accumulate mtDNA damage. Moreover, mitochondrial extracts from Ku knockdown cells show lower NHEJ repair activity in an in vitro assay, suggesting that damage accumulation in these cells is likely due to deficiencies in NHEJ. Together, our data suggest that both HR and NHEJ operate in mitochondria. Also, mtNHEJ requires the Ku heterodimer and is involved in mtDNA maintenance. Moreover, our results indicate that there is a significant molecular and functional conservation between NHEJ and HR repair pathways in the nucleus and in mitochondria, which reinforces their importance for maintenance of mitochondrial genomic stability and, likely mitochondrial function. (AU)