1 June 2000 Radiation-Induced Heat-Labile Sites that Convert into DNA Double-Strand Breaks
Björn Rydberg
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Rydberg, B. Radiation-Induced Heat-Labile Sites that Convert into DNA Double-Strand Breaks.

The yield of DNA double-strand breaks (DSBs) in SV40 DNA irradiated in aqueous solution was found to increase by more than a factor of two as a result of postirradiation incubation of the DNA at 50°C and pH 8.0 for 24 h. This is in agreement with data from studies performed at 37°C that were published previously. Importantly, similar results were also obtained from irradiation of mammalian DNA in agarose plugs. These results suggest that heat-labile sites within locally multiply damaged sites are produced by radiation and are subsequently transformed into DSBs. Since incubation at 50°C is typically employed for lysis of cells in commonly used pulsed-field gel assays for detection of DSBs in mammalian cells, the possibility that heat-labile sites are present in irradiated cells was also studied. An increase in the apparent number of DSBs as a function of lysis time at 50°C was found with kinetics that was similar to that for irradiated DNA, although the magnitude of the increase was smaller. This suggests that heat-labile sites are also formed in the cell. If this is the case, a proportion of DSBs measured by the pulsed-field gel assays may occur during the lysis step and may not be present in the cell as breaks but as heat-labile sites. It is suggested that such sites consist mainly of heat-labile sugar lesions within locally multiply damaged sites. Comparing rejoining of DSBs measured with short and long lysis procedure indicates that the heat-labile sites are repaired with fast kinetics in comparison with repair of the bulk of DSBs.

Björn Rydberg "Radiation-Induced Heat-Labile Sites that Convert into DNA Double-Strand Breaks," Radiation Research 153(6), 805-812, (1 June 2000). https://doi.org/10.1667/0033-7587(2000)153[0805:RIHLST]2.0.CO;2
Received: 31 January 2000; Accepted: 1 March 2000; Published: 1 June 2000
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