Inactivation of the Escherichia coli chromosome during growth after ultraviolet irradiation

Loss of lambda prophage recombinogenicity in UV-irradiated Escherichia coli: the role of host genes ruvA, ruvB, ruvC, and recG

Earlier studies have revealed a radiation-induced process leading to the loss of lambda prophage recombinogenicity. The process takes place in UV-irradiated Escherichia coli cells, and renders the prophage incapable of site-specific recombination with the host chromosome, and of general recombination with an infecting homologous phage. It was found that the inhibition of prophage recombinogenicity depends on functional RecBCD enzyme of E. coli. In this work, the role of ruvABC and recG genes in the inhibitory process was assessed. The products of these genes are known to act at the last step of homologous recombination and recombinational DNA repair by catalyzing the resolution of recombination intermediates (the Holliday junctions). Irradiated prophage retained its ability to recombine in ruvA, ruvB, ruvC, and recG mutants. These results suggest that in addition to RecBCD enzyme, RuvABC and RecG proteins are also involved in the inhibition of prophage recombinogenicity. We infer that RuvABC and RecG act in this process before RecBCD, probably by processing the Holliday junctions formed upon replication arrest, and thereby providing double-stranded DNA breaks as substrate for RecBCD-mediated recombinational repair of UV-damaged bacterial chromosome.

Progressive loss of lambda prophage recombinogenicity in UV-irradiated Escherichia coli: the role of RecBCD enzyme

RecBCD enzyme is involved in the radiation-induced process known as prophage inactivation. The process leads to the inability of lambda prophage to excise itself from the Escherichia coli chromosome via site-specific recombination. In this work we sought to further characterize the role of RecBCD enzyme in this process. In addition, we examined the ability of irradiated prophage to recombine with the infecting homologous phage. We used several E. coli mutants differentially altered in RecBCD's activities. The results showed that in the mutants carrying either recB2109 or recD1903, which do not exhibit significant nuclease activities, the prophage progressively loses its capacity for both site-specific and general recombination. In the recB268 null mutant, however, prophage recombinogenicity remained fully preserved. We also showed that the prophage unable to recombine retained its ability to complement the mutant infecting phage and that the recombination frequencies in phage x phage crosses were not affected by postirradiation incubation. Our results suggest that the helicase activity of RecBCD is responsible for the progressive loss of prophage recombinogenicity. This loss is most probably a consequence of the unsuccessful RecBCD-dependent recombinational repair of double-stranded breaks in the cell chromosome, during which some structures unsuitable for further recombination reactions may be produced.

Overproduction of single-stranded DNA-binding protein increases UV-induced mutagenesis in Escherichia coli

UV-induced mutagenesis was investigated in the uvrB strain and its isogenic counterpart overproducing the single-stranded DNA-binding protein (SSB). It was demonstrated that overproduction of SSB significantly increases the frequency of mutation. Our results indicate that such an increase might be due to certain abnormalities in induction of the SOS response (untimely and prolonged activation of the RecA protein).

Kinetics of recB-dependent repair: relationship to post-UV inactivation of the prophage

By making use of the temperature-sensitive mutant recB270, we showed that the RecBCD enzyme is needed for repair between 1 and 4 h after UV exposure. recB-dependent prophage inactivation (Petranović et al. (1984), Mol. Gen. Genet., 196, 167-169) takes place in all dying cells during the same period of time. The kinetics of decrease in the yield of recombinants in phage-propage crosses resemble those of prophage inactivation in UV-irradiated bacteria. This indicates that recombination processes (including site-specific recombination required for prophage excision) are blocked in cells destined to die. On the basis of our results, we suggest that a large fraction of damaged cells is rescued by the RecA-RecBCD recombination pathway. If repair is unsuccessful, RecA-RecBCD recombination intermediates persist in the irradiated cells leading to prophage inactivation.

The relationship between survival and mutagenesis in Escherichia coli after fractionated ultraviolet irradiation

The relationship between survival and mutagenesis in Escherichia coli after fractionated ultraviolet (UV) irradiation was studied. The cells were incubated either in buffer or nutrient media. Regardless of incubation conditions, greater survival is observed after fractionated irradiation than after acute irradiation. When the cells are incubated in buffer, UV mutagenesis decreases with an increase in the number of dose fractions. However, when the cells are cultivated in nutrient media, the increased survival (i.e., the enhanced capacity for repair) is coupled with the enhanced capacity for UV mutagenesis. We, therefore, assume that during incubation in nutrient media, fractionated irradiation leads to full and prolonged expression of all UV-inducible (SOS) genes, including those required for mutagenesis.