Efficient repair of hydrogen peroxide-induced DNA damage by Escherichia coli requires SOS induction of RecA and RuvA proteins.

The survival of Escherichia coli following treatment with a low dose (1-3 mM) of hydrogen peroxide (H(2)O(2)) that causes extensive mode-one killing of DNA repair mutants is stimulated by the induction of the SOS regulon. Results for various mutants indicate that induction of recA and RecA protein-mediated recombination are critical factors contributing to the repair of H(2)O(2)-induced oxidative DNA damage. However, because DNA damage activates RecA protein's coprotease activity essential to cleavage of LexA repressor protein and derepression of all SOS genes, it is unclear to what extent induction of RecA protein stimulates this repair. To make this determination, we examined mode-one killing of DeltarecA cells carrying plasmid-borne recA (P(tac)-recA(+)) and constitutively expressing a fully induced level of wild-type RecA protein when SOS genes other than recA are non-inducible in a lexA3 (Ind(-)) genetic background or inducible in a lexA(+) background. At a H(2)O(2) dose resulting in maximal killing, DeltarecA lexA3 (Ind(-)) cells with P(tac)-recA(+) show 40-fold greater survival than lexA3 (Ind(-)) cells with chromosomal recA having a low, non-induced level of RecA protein. However, they still show 10- to 15-fold lower survival than wild-type cells and DeltarecA lexA(+) cells with P(tac)-recA(+). To determine if the inducible RuvA protein stimulates survival, we examined a ruvA60 mutant that is defective for the repair of UV-induced DNA damage. This mutant also shows 10- to 15-fold lower survival than wild-type cells. We conclude that while induction of RecA protein has a pronounced stimulatory effect on the recombinational repair of H(2)O(2)-induced oxidative DNA damage, the induction of other SOS proteins such as RuvA is essential for wild-type repair.

Differential cleavage of LexA and UmuD mediated by recA Pro67 mutants: implications for common LexA and UmuD binding sites on RecA.

In Escherichia coli, RecA-mediated cleavage of LexA repressor is a key regulatory event required for expression of SOS genes involved in the repair of DNA damage. RecA also mediates the cleavage of UmuD protein to UmuD, a form active in SOS mutagenesis. To determine whether LexA and UmuD have common binding determinants on RecA, we have compared the ability of several recA mutants to function in the cleavage of LexA versus UmuD in vivo. The data reveal that while some recA mutations at Pro67 have a similar effect on LexA and UmuD cleavage, others have striking differential effects. For example, a Pro67-->Trp mutation results in a high level of constitutive cleavage of both proteins. However, Pro67-->Asp and Glu mutations promote constitutive cleavage of LexA and reduce induction of UmuD cleavage to just 5 to 10% of wild-type activity. In contrast, Pro67-->Arg prevents LexA cleavage while allowing nearly 50% of wild-type induction of UmuD cleavage. These results are consistent with the idea that Pro67 is located at a site in the nucleoprotein filament where both LexA and UmuD contact RecA.

Cellular expression of the beige mouse mutation and its correction in hybrids with control human fibroblasts.

Fibroblasts from a beige mouse (C57BL/6J; bgJ bgJ) have been established and maintained in culture for more than 3 yr. At early passages, the mutant cells were distinguishable from C57BL/6J control mouse fibroblasts at the ultrastructural level by the presence of enlarged cytoplasmic granules. After continuous passaging, this distinguishing feature was lost from the mutant cells, correlated with their increased growth rate. Clustered, perinuclear distribution of lysosomes was retained, however, and was quantitatively different at any passage number of the beige cell line from the dispersed distribution of these organelles in control mouse fibroblasts, as analyzed by computer-aided, video-enhanced light microscopy. In somatic cell hybrids between the established beige cell line and a control human diploid fibroblast cell strain, seven uncorrected hybrid lines retained a lysosomal dispersion pattern statistically indistinguishable from that of the beige mouse cell lines. Three corrected hybrid lines had lysosomal dispersion patterns that were significantly different from the beige parent line and indistinguishable from that of the control mouse fibroblast line. Thus, lysosomal dispersion can be used objectively and quantitatively to distinguish mutant beige and control mouse fibroblasts and corrected vs. uncorrected cell hybrids made from the beige/control human somatic cell crosses.