Paula M. Calabro-Jones scite author profile

We have measured by gel electrophoresis the yields of single- and double-strand breaks (SSBs and DSBs) induced in aqueous solutions of SV40 DNA and the SV40 minichromosome by 137Cs gamma rays (mean LET 0.3 keV micron-1) and 4He ions (mean LETs 85, 102, and 152 keV microns-1). DNA SSBs are caused mainly by the hydroxyl radicals under these conditions and are reduced in yield as either the hydroxyl radical scavenger concentration or the LET is increased (over the range studied). The G(SSB) for 4He ion irradiation is less by a factor of up to 10 than the G(SSB) for gamma irradiation, depending upon the scavenger concentration. The difference in the yields of SSBs agrees well with the difference in the yields of hydroxyl radicals for the radiations in question. In contrast, the yields of DSBs are similar for gamma and 4He ion irradiation over much of the range of scavenging capacity studied. However, at the highest scavenger concentrations the yields of DSBs are greater for 4He ion irradiation. In addition, the yields of DSBs remain almost constant with increasing LET (over the range studied). Therefore the relative yield of DSBs per SSB increases with increasing LET, supporting the hypothesis that increasing LET leads to an increased clustering of damage in DNA.

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Effects of methylated xanthines on mammalian cells treated with bifunctional alkylating agents

Murnane

Byfield

Ward

et al. 1980

Nature

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Caffeine has been previously reported to enhance the lethal potential of many DNA-damaging agents in rodent cells1-5. This effect has most commonly been ascribed to the binding of caffeine to single-stranded DNA6, and the resulting inhibition of post-replication repair7-10, which is associated with the synthesis of abnormally small nascent DNA fragments7, 11-13. However, certain aspects of this theory remain unclear:(1) why does the addition of caffeine to damaged cells elevate the level of DNA synthesis when it supposedly blocks post-replication repair10,14, and (2) as pointed out by Cleaver15, why does caffeine continue to exert its synergistic lethal effects until completion of the S phase16, 17, even though the size of newly synthesized DNA seems normal much earlier18-20? The present studies with nitrogen mustard (HN2) fail to demonstrate any effect of non-lethal concentrations of methylated xanthines (MXs) on removal of DNA damage or post-replication repair in conditions producing synergistic lethal effects. We demonstrate an influence by MXs on initiation of DNA synthesis in damaged replicons, and propose that this effect is primarily responsible for the synergistic lethal properties of these drugs.

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Radiation vs Chemical Damage to DNA

Ward

Limoli

Calabro-Jones

et al. 1987

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