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Wirtszellreaktivierung chemisch induzierter Letalschäden im DNS-haltigen Serratia-Phagen Kappa
(1965)
After treating free phage Kappa with nitrous acid, triethylenemelamine, ethylmethanesulfonate, or hydroxylamin and using these phages for infecting Serratia H Y wildtype cells, at least 20% of the lethal damage in the phage-DNA can be reactivated by the host ( = host cell reactivation). It is known that all lethal agents tested so far attack the primary structure of the D N A in different ways. Therefore, we assume that the target for the host cell reactivation consists of some damage in the secondary structure of the DNA, because there is probably some coincidence in the action of all agents. The hypothesis that in the DNA changes of thymine are a prerequisite for host cell reactivation has been disproved by the experiments with nitrous acid and ethylmethanesulfonate because both substances do not act on thymine.
UV inactivated KAPPA can be reactivated like other temperate phages by plating on uvirradiated host cells (indicator). The capacity of the indicator Serratia HY for multiplication of unirradiated KAPPA was about 0.1% survivors (colony formers). The induction of clear plaque (c·) mutants by irradiating extracellular KAPPA and plating on untreated indicator can be increased further about 2 to 4 times by using UV irradiated indicator. The increase of the number of c mutants under the latter conditions, with increasing UV dose given to the phage, was never a firstorder reaction. The highest frequency of c mutants obtained was about 4.5 per cent. Plating of unirradiated KAPPA on irradiated indicator (lowest survival fraction was 0.01%) never increased the spontaneous mutation rate to c. Two c mutants studied in detail belong to two different cistrons as shown in a complementation test (map distance about 5.3%). Only one of both was revertible to the phenotype c+ spontaneously and with a higher rate by UV. However, as shown in crossing experiments with the wild type, the backmutants do not have the original genotype but originated from mutations in at least two different intragenic suppressor loci; the map distances between them and the original c mutation were 0.64% and 0.13 per cent. Host range (h) and virulent (v) mutants could not be induced by irradiation of the free phage and plating on untreated indicator. This indicates that the UV induced high mutability of the c loci in KAPPA represents an exceptional case of behavior (UV-hot spot). Some unstable h mutants could be isolated by plating irradiated phage on irradiated indicator.
The bactericidal effect of Mitomycin C on E. coli B and the partial reactivability of MC induced cell-inactivations depends on the genotype, the composition of the plating medium and the postincubation temperature in a way rather similar to that found in corresponding UV-experiments. This indicates that at least one type of MC-induced damage in E. coli must be identical or similar with lesions produced by UV.
The kinetics of MC-bindung to the cells is the same for the wildtype and an MC-resistant mutant. The temperature coefficient Q10 for binding of MC is between 2 and 4 in the range from 20 °C to 45 °C ; this shows that the MC-uptake is propably not limited by physical reasons.
The results have been discussed considering the hypothesis that MC acts by activating the cellular DNase.