The effect of radioprotection of indolylalkylamines (5-methoxytryptamine) and aminothiols (cysteamine) on E. coli cells is practically absent if the cells have genetic defects in the repair systems. This means that the explanation of radioprotection by scavenging of free radicals is invalid and that specific repair mechanisms may be involved. In order to explain the radioprotective mechanism it was suggested that the radioprotectors interact with the damaged sites in DNA so that they become partly screened from repairing endonucleases. Under these conditions the reduction of incision rate results in diminished enzymatic induction of lethal double-strand breaks in DNA, this being important only in wild type cells. To prove this hypothesis an experimental procedure was developed using bacterial cells carrying plasmids (ColE1). This procedure enabled to determine the in vivo rate of enzymatic incision of gamma-sites. It was found that the protectors did not change the total amount of gamma-damages in DNA but reduced the rate of enzymatic incision.
Quantitative studies of the number of gamma-induced single-strand breaks (SSBs) and enzyme-labile sites (ELSs) were performed using the model of Col E1 plasmids, which undergo transition from the covalently closed form (CCF) into the open circular form (OCF) during gamma-irradiation of the plasmid-bearing strain E. coli JC 411. By adding 0.5 MEDTA the repair endonucleases of the cell, which effect the transition of ELSs into SSBs during and after gamma-irradiation, were totally inhibited. It was found thless than 15 per cent of the number of gamma-induced lesions are primarily induced SSBs. About the saditions of direct radiation damage. The conclusions are that (1) the contribution of the direct radiation effect in the cell is greater than that of the indirect effect; (2) the main type of gamma-induced lesions are the ELSs (most of which--more than 75 per cent--are alkali-stable; (3) the enzymatic incision of gamma-induced ELSs into SSBs is effected very quickly, mainly during irradiation; and (4) 0.5 MEDTA is a universal inhibitor of repair processes in cell, including the action of N-glycosidases and endonucleases.
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