DNA damage induced by radiation of different linear energy transfer: initial fragmentation

Abstract

Purpose : To investigate DNA fragmentation as a function of linear energy transfer (LET) after exposure to accelerated ions in the LET range 40–225 keV/mum. Materials and methods : Fragmentation patterns of double-stranded DNA in the range 5 kilobasepairs (kbp) to 5.7 megabasepairs (Mbp) were analysed after irradiation of low-passage GM 5758 normal human fibroblast cells with 60 Co-photons, helium ions at 40 keV/mum and high-LET nitrogen ions between 80 and 225 keV/mum. Two separate pulsed-field gel electrophoresis protocols were used, optimized for separation of 1–6 Mbp and 5 kbp to 1.5 Mbp fragments. Results : An increased probability of formation of short and medium-sized DNA fragments was revealed following high-LET irradiation. The DNA double-strand break (dsb) induction yields were, respectively, 5.8 and 6.9–8.8 x 10 -9 dsb bp -1 Gy -1 for 60 Co-photons and ions. The ion yields were some 80–110% higher than those calculated according to a conventional approach, disregarding the fragment distributions. For photons, the yield was 13% higher. The corresponding relative biological effectiveness (RBE) of dsb induction was in the range 1.2–1.5. Conclusions : A significant non-random contribution to the number of dsb after irradiation with high-LET was confirmed by detailed fragment analysis using pulsed-field gel electrophoresis. The LET had a strong influence on the initial DNA fragment distribution, and hence also on the induction yields measured. However, when the LET was increased to the highest values studied for nitrogen ions, the yield decreased slightly.