The nfo (endonuclease IV) gene of Escherichia coli is induced by superoxide generators such as paraquat (methyl viologen). An nfo'-lacZ operon fusion was used to isolate extragenic mutations affecting its expression. The mutations also affected the expression of glucose 6-phosphate dehydrogenase, Mn2+-superoxide dismutase (sodA), and three lacZ fusions to soi (superoxide-inducible) genes of unknown function. The mutations were located 2 kilobases clockwise of ssb at 92 min on the current linkage map. One set of mutations, in a new gene designated soxR, caused constitutive overexpression of nfo and the other genes. It included insertions or deletions affecting the carboxyl end of a 17-kilodalton polypeptide. In a soxR mutant, the expression of sodA, unlike that of nfo, was also regulated independently by oxygen tension. Two other mutants were isolated in which the target genes were noninducible; they had an increased sensitivity to killing by superoxide-generating compounds. One had a TnlO insertion in or near soxR; the other had a multigene deletion encompassing soxR. Therefore, the region functions as a positive regulator because it encodes one or more products needed for the induction of nfo. Regulation is likely to be at the level of transcription because the mutations were able to affect the expression of an nfo'-lac operon fusion that contained the ribosome-binding site for lacZ. Some mutant plasmids that failed to suppress (or complement) constitutivity in trans had insertion mutations several hundred nucleotides upstream of soxR in the general region of a gene for a 13-kilodalton protein encoded by the opposite strand, raising the possibility of a second regulatory gene in this region. The results define a new regulon, controlled by soxR, mediating at least part of the global response to superoxide in E. coli.When Escherichia coli is exposed to redox reagents that generate superoxide radical anions through oxidative recycling, it responds with an increased synthesis of a specific set of proteins. Typical inducers are paraquat (methyl viologen), phenazine methosulfate, plumbagin, and menadione. The global response to superoxide involves genes for at least 33 proteins, most of which are of unknown function and which were detected by two-dimensional gel electrophoresis (16,51). The known enzymes that are induced by superoxide include Mn2+-superoxide dismutase (21), glucose 6-
The RuvA, RuvB, and RuvC proteins of Eseherichia coli are required for the recombinational repair of ultraviolet light-or chemical-induced DNA damage. In vitro, RuvC protein interacts with Holliday junctions in DNA and promotes their resolution by endonucleolytic cleavage. In this paper, we investigate the interaction of RuvA and RuvB proteins with model Holliday junctions. Using band-shift assays, we show that RuvA binds synthetic Holliday structures to form specific protein-DNA complexes. Moreover, in the presence of ATP, the RuvA and RuvB proteins act in concert to promote dissociation of the synthetic Holliday structures. The dissociation reaction requires both RuvA and RuvB and a nucleotide cofactor (ATP or dATP) and is rapid (40% of DNA molecules dissociate within 1 min). The reaction does not occur when ATP is replaced by either ADP or the nonhydrolyzable analog of ATP, adenosine 5'-[v-thioltriphosphate. We suggest that the RuvA and RuvB proteins play a specific role in the branch migration of Holliday junctions during postreplication repair of DNA damage in E. coil.Mutations in the ruvA, ruvB, or ruvC genes of Escherichia coli give rise to mutants that are phenotypically very similar.
Holliday junctions occur as intermediates in homologous recombination and DNA repair. In bacteria, resolution of Holliday junctions is accomplished by the RuvABC system, consisting of a junction-specific helicase complex RuvAB, which promotes branch migration, and a junction-specific endonuclease RuvC, which nicks two strands. The crystal structure of a complex between the RuvA protein of M. leprae and a synthetic four-way junction has now been determined. Rather than binding on the open surface of a RuvA tetramer as previously suggested, the DNA is sandwiched between two RuvA tetramers, which form a closed octameric shell, stabilized by a conserved tetramer-tetramer interface. Interactions between the DNA backbone and helix-hairpin-helix motifs from both tetramers suggest a mechanism for strand separation promoted by RuvA.
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