Role of DNA-PK in the process of aberration formation as studied in irradiated human glioblastoma cell lines M059K and M059J

PURPOSE: The participation of various DNA double-strand break repair mechanisms in the formation of chromosome aberrations is not yet fully understood. To investigate particularly the role of non-homologous end-joining, we analysed the formation of radiation-induced aberrations in a DNA-protein kinase (PK(CS))-proficient cell line M059K and in a deficient cell line M059J. MATERIALS AND METHODS: Plateau-phase M059K and M059J cells were irradiated with low doses of X-rays. Chromosome aberrations were determined as genomic yields of dicentric chromosomes and excess acentric fragments, scored in Giemsa-stained metaphases, and as partial yields of reciprocal translocations and total visible complex exchanges (complex aberrations) for chromosomes 4, 7 and 11 using the FISH method. M059K cells were also analysed in the presence of 50 micro m wortmannin, a DNA-PK inhibitor. RESULTS: DNA-PK-deficient cells showed a higher yield of simple stable and unstable and of complex aberrations in comparison with DNA-PK-proficient cells. The largest differences were observed for excess acentric fragments and for complex aberrations. DNA-PK inhibition by wortmannin in M059-K cells resulted in increased aberration yield in the same qualitative and quantitative manner as in M059-J cells. CONCLUSIONS: The results obtained with DNA-PK-deficient M059J cells and with DNA-PK-proficient M059K cells treated with wortmannin, an inhibitor of DNA-PK and ATM, suggest that the elimination of DNA-PK-dependent non-homologous end-joining can recruit a slow, error-prone repair process, which is DNA-PK independent and favours the increased formation of chromosome aberrations. The nature of this pathway and the way of its participation in aberration formation need further elucidation.