The DNA concentration effect on DNA radiation damage induced by <Superscript>7</Superscript>Li ions and γ rays

To evaluate the influence of the DNA concentration in the aqueous solution on DNA radiation damage, the plasmid DNA in the presence or absence of Mannitol （scavenger of free radical OH.） was irradiated by ^7Li ions and γ rays at various DNA concentrations. Gel electrophoresis analysis revealed that the DNA damage of single and double strand breaks induced by irradiation became more severe at lower DNA concentration. In the condition of γ-ray irradiation, most of double strand breaks （DSB） damage was neutralized and less associated with DNA concentration in the presence of mannitol. However, under ^7Li irradiation, DSB damage could not be cleared by mannitol but was gradually aggravated with decreasing DNA concentrations. These findings imply that under low-LET irradiation, most of the DSB damage is generated by free radical OH·diffusion, and thus may be counteracted by scavengers, while at higher-LET irradiation, quite a fraction of DSB induction is caused by direct ionizing energy deposition of heavy ions, which cannot be eliminated. This work also indicates that the proportion between free radical damage and direct ionizing damage is s constant which is independent of DNA concentration when the DNA concentration is under a certain value （50ng/μL）. Our study sheds light on the un- derlying mechanisms in the DNA radiation damage process.     

Improving DNA damage repair ability ofE. coli to UV-radiosensitivity by DNA-mediated gene transfer of low energy ion beam

Using calcium chloride method of transfer gene as control, a new technique of transferring gene by low energy ion beam has been applied to the study of improving DNA damage repair ability ofE. coli to UV-radiosensitivity. The genome DNA pieces ofDeinococcus radiodurans, as “foreign” genetic materials, were introduced into the UV-radiosensitive strains ofE. coli by implantation of 20 keV Ar⁺ at doses ranging from 1 × 10¹⁵ to 2 × 10¹⁵ ions/cm². Results show that the transfected strains present higher UV-radioresistance than that of un-transfected ones and start ones. The survival rate of transfected strains and their unscheduled DNA synthesis (UDS) ability is increased, indicating that the transfer gene is a success.