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Query: UNIPROT:P06889 (Mol)
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Three mutations were introduced into the cea promoter using oligonucleotide directed mutagenesis. The resulting mutant promoter has the Escherichia coli consensus sequences at its - 35 and - 10 positions, separated by the optimal spacing. In addition, a plasmid with a mutation in one of the two LexA repressor binding sites in the cea regulatory region was isolated that decreases homology with the consensus LexA binding site. The effects of these mutations on cea expression were studied in cea-lacZ protein fusions. The promoter-up mutant, when present in a multicopy plasmid, showed a shorter induction lag when compared to the wild-type cea gene, and there was less of an effect of the catabolite repression system on cea expression. However, when present in a single copy in the bacterial chromosome, catabolite repression and an induction delay were observed, despite the increased strength of the promoter. The operator mutant showed a slightly higher basal level of expression, but was still repressible. Induction occurred with a shortened lag period, but the effects were not as great as with the promoter mutant. These results support the idea that tight repression by LexA contributes to the delay in cea induction.
Mol Gen Genet 1989 Feb
PMID:Mutation of the promoter and LexA binding sites of cea, the gene encoding colicin E1. 265 93

The LexA repressor of Escherichia coli undergoes a specific cleavage reaction in vivo, an event that leads to derepression of the SOS regulon and requires an activated form of RecA protein. In vitro, cleavage requires RecA at neutral pH; at alkaline pH, a spontaneous cleavage reaction termed autodigestion takes place. Both autodigestion and RecA-mediated cleavage cut the same bond, and are observed for the same set of substrates, suggesting that RecA acts indirectly to stimulate LexA self-cleavage at neutral pH, perhaps binding to LexA and acting as an allosteric effector. We previously isolated a set of lexA(Ind-) mutants that are deficient in in vivo RecA-mediated cleavage but retain significant repressor function. Here, we describe the in vitro cleavage of purified mutant proteins. All of those tested were deficient in both cleavage reactions. Although most of them were equally deficient in both reactions, some were more deficient in one reaction than the other. Several mutant proteins appeared to have defects in binding to RecA. Autodigestion of all but one of the poorly cleavable mutant proteins reached a maximum rate at pH around 10, as does wild-type LexA. The exception was KR156, which changed Lys156, a residue previously implicated in the mechanism of cleavage, to Arg, another basic residue: for this protein, the rate of autodigestion increased with pH at values above 11. RecA-mediated cleavage of KR156 was 1% the wild-type rate at pH 7, but increased with increasing pH to a plateau at pH 9.5, where the rate was 40% the wild-type rate. In contrast, an essentially constant rate was observed for wild-type LexA over the pH range 6 to 11. We suggest, first, that deprotonation of Arg156 and, by inference, Lys156 in the wild-type protein, is required for both autodigestion and RecA-mediated cleavage: and second, that RecA acts to reduce the pKa of Lys156, allowing efficient cleavage of wild-type repressor under physiological conditions.
J Mol Biol 1989 Dec 05
PMID:Autodigestion and RecA-dependent cleavage of Ind- mutant LexA proteins. 269 34

Escherichia coli rnh mutants deficient in ribonuclease H (RNase H) are capable of DNA replication in the absence of protein synthesis. This constitutive stable DNA replication (SDR) is dependent upon the recA+ gene product. The requirement of SDR for recA+ can be suppressed by rin mutations (for recA+-independent), or by lexA(Def) mutations which inactivate the LexA repressor. Thus, there are at least three genetically distinct types of SDR in rnh mutants: recA+-dependent SDR seen in rnh- rin+ lexA+ strains, recA+-independent in rnh- rin- lexA+, and recA+-independent in rnh- rin+ lexA(Def). The expression of SDR in rin- and lexA(Def) mutants demonstrated a requirement for RNA synthesis and for the absence of RNase H. The suppression of the recA+ requirement by rin mutations was shown to depend on some new function of the recF+ gene product. In contrast, the suppression by lexA-(Def) mutations was not dependent on recF+. The lexA3 mutation inhibited recA+-dependent SDR via reducing the amount of recA+ activity available, and was suppressed by the recAo254 mutation. The SDR in rnh- rin- cells was also inhibited by the lexA3 mutation, but the inhibition was not reversed by the recAo254 mutation, indicating a requirement for some other lexA+-regulated gene product in the recA+-independent SDR process. A model is presented for the regulation of the expression of these three types of SDR by the products of the lexA+, rin+ and recF+ genes.
Mol Gen Genet 1987 Jul
PMID:Genetic analysis of constitutive stable DNA replication in rnh mutants of Escherichia coli K12. 282 60

The SOS response in UV-irradiated bacteria enhances the survival and mutagenesis of infecting damaged bacteriophage lambda. In a lexA(Def) strain, SOS bacterial genes are fully derepressed by an inactivating mutation in the LexA repressor gene. We tested several lexA(Def) derivative strains for their capacity to constitutively promote high survival and mutagenesis of irradiated lambda. We showed that UV irradiation of the lexA(Def) host bacteria is still necessary for optimal efficiency of both these SOS functions, which are dependent on the umuC gene product and an activated form of RecA protein.
Mol Gen Genet 1985
PMID:Weigle reactivation and mutagenesis of bacteriophage lambda in lexA(Def) mutants of E. coli K12. 293 11

The RecA protein of Escherichia coli is required for SOS-induced mutagenesis in addition to its recombinational and regulatory roles. We have suggested that RecA might participate directly in targeted mutagenesis by binding preferentially to the site of the DNA damage (e.g. pyrimidine dimer) because of its partially unwound nature; DNA polymerase III will then encounter RecA-coated DNA at the lesion and might replicate across the damaged site more often but with reduced fidelity. In support of this proposal, we have found that the phenotype of wild-type and mutant RecA for mutagenesis correlates with capacity to bind to double-stranded DNA. Wild-type RecA binds more efficiently to ultraviolet (u.v.)-irradiated, duplex DNA than to non-irradiated DNA. The RecA441 (Tif) protein that is constitutive for mutagenesis binds extremely well to double-stranded DNA with no lesions, whereas the RecA430 protein that is defective in mutagenesis binds poorly even to u.v.-irradiated DNA. The RecA phenotype also correlates with capacity to use duplex DNA as a cofactor for cleavage of the LexA repressor protein for SOS-controlled operons. Wild-type RecA provides efficient cleavage of LexA only with u.v.-irradiated duplex DNA; RecA441 cleaves well with non-irradiated DNA; RecA430 gives very poor cleavage even with u.v.-irradiated DNA. We conclude that the interaction of RecA with damaged double-stranded DNA is likely to be a critical component of SOS mutagenesis and to define a pathway for the LexA cleavage reaction as well.
J Mol Biol 1987 Aug 05
PMID:RecA protein and SOS. Correlation of mutagenesis phenotype with binding of mutant RecA proteins to duplex DNA and LexA cleavage. 296 Aug 17

A 2,695 bp chromosomal segment of Escherichia coli K12 containing the recQ gene was sequenced. Analysis of the sequence revealed an open reading frame thought to represent recQ, with a clockwise direction of transcription relative to the standard genetic map of E. coli K12 and having a coding capacity for a protein of Mr 68,350. The -10 region of the presumptive recQ promoter overlapped the putative terminator for the upstream gene pldA, and was immediately followed by a 15 bp stretch of DNA bearing a strong resemblance to the reported sequences of LexA repressor binding sites. This latter finding suggested the possibility of SOS regulation of recQ gene expression, which was substantiated by experiments with recQ-lacZ fusions.
Mol Gen Genet 1986 Nov
PMID:The recQ gene of Escherichia coli K12: primary structure and evidence for SOS regulation. 302 6

LexA, the repressor of the SOS system in Escherichia coli induces a substantial DNA bending upon interaction with the operator of the caa gene, which codes for the bacterial toxin colicin A. Analysis by gel electrophoresis of a family of DNA fragments of identical length, but bearing the caa operator at different positions, shows that DNA bending occurs close to or within the operator sequence upon LexA binding. In contrast, the interaction of LexA with the recA operator induces no detectable bending on 5% polyacrylamide gels. This difference between the two operators is likely to be due to an intrinsic bendability of the caa operator related to thymine tracts located on both sides of the operator. Such tracts do not exist in the recA operator. The free DNA fragments harbouring the caa operator show a slight tendency to bend even in the absence of the LexA repressor. The centre of this intrinsic bend is located close to or within the caa operator.
J Mol Biol 1988 Dec 20
PMID:LexA repressor induces operator-dependent DNA bending. 306 15

UV irradiation of competent cells of Escherichia coli K12 produced an increase in the efficiency of transformation with plasmid DNA. This phenomenon has been called IPTE (increase in plasmid transformation efficiency) and is dependent on the activated state of the RecA protein. IPTE is independent of the lexA, recB recC, and recF genes. It is not related to the size or the replicon type of the plasmid. Furthermore, it is also induced in cells which have been previously treated with other SOS system-inducing agents such as bleomycin, mitomycin C, or nalidixic acid. IPTE is therefore similar to other repair (SOS) functions inducible by DNA damage since all of them are dependent upon activation of the RecA protein. IPTE differs from other SOS functions in the absence of a direct control by the LexA repressor.
Mol Gen Genet 1988 Mar
PMID:Increase in plasmid transformation efficiency in SOS-induced Escherichia coli cells. 328 40

A comparative study of the interaction of the LexA repressor of Escherichia coli and of its amino-terminal DNA binding domain to the uvrA operator has been undertaken. Most of the binding constants are determined from competition experiments with RNA polymerase by measuring the time-course of the abortive initiation transcriptional activity. The presence of repressor increases the lag time, tau, without affecting the final maximum activity. The inhibition of transcription by LexA, at least in the case of the uvrA gene, is thus a transient, time-dependent phenomenon, because once the RNA polymerase is engaged in a stable "open" complex, it is quasi-irreversibly trapped in this state. A study of the binding constants as a function of ionic strength suggests the formation of 5.5(+/- 1) salt bridges between the uvrA operator and a LexA dimer. Surprisingly, the binding affinity of the amino-terminal domain was only about one order of magnitude smaller than that of the entire LexA repressor. The determination of the binding constant of the RNA polymerase to the "closed" uvrA promoter (KB approximately 1 X 10(7) to 2 X 10(7) M-1) allowed us to determine theoretical repression curves for the two repressor species. These calculations show that the binding constant found for LexA is sufficiently high to account for substantial or complete repression, and that of the amino-terminal domain is sufficiently low to account for partial or nearly full induction. Under solvent conditions used by others for the determination of binding constants to other SOS operators by DNAase I footprinting, the uvrA operator turns out to be a rather weak one (K approximately 3 X 10(7) M-1), being comparable with that of the uvrB gene. The uvrA promoter is "association-limited" with a KB X k2 product fitting very nicely the homology score for the promoter of 55.
J Mol Biol 1987 Jan 20
PMID:Promoter properties and negative regulation of the uvrA gene by the LexA repressor and its amino-terminal DNA binding domain. 329 58

Overproduction of single-stranded DNA-binding protein (SSB) in Escherichia coli led to a decrease in the basal level of repressor LexA. Expression of the LexA-controlled genes was increased differentially, depending on the affinity of the LexA repressor for each promoter: expression of the recA and sfiA genes was increased 5-fold and 1.5-fold, respectively. Despite only a slight effect on expression of sfiA, which codes for an inhibitor of cell division, bacteria overproducing SSB produced elongated cells. In fact, the effect on cell shape appeared to be essentially independent of the expression of the sfiA and recA genes. Bacteria overproducing SSB were therefore phenotypically similar to bacteria partially starved of thymine, in which filamentation results from both sfiA-dependent and sfiA-recA-independent pathways. These data indicate that excess SSB acts primarily by perturbing DNA replication, thereby favoring gratuitous activation of RecA protein to promote cleavage of LexA protein. When bacteria overproducing SSB were exposed to a DNA-damaging agent such as ultraviolet light or mitomycin C, the recA and sfiA genes were fully induced. Induction of the sfiA gene occurred, however, at higher doses in bacteria overproducing SSB protein than in bacteria with normal levels of SSB. Whereas the efficiency of excision repair was apparently increased by excess SSB, the efficiency of post-replication recombinational repair was reduced as judged by a decrease in the recombination proficiency between a prophage and ultraviolet-irradiated heteroimmune infecting phage. Following induction of ssb+ bacteria with mitomycin C, the cellular content of SSB was slightly increased. These results provide evidence that SSB modulates RecA protein-dependent activities in vivo. It is proposed that SSB favors the formation of short complexes of RecA protein and single-stranded DNA that mediate cleavage of the LexA and lambda repressors, while it delays the formation of long nucleoprotein filaments, thereby slowing down RecA-promoted recombinational events in uninduced as well as in induced bacteria.
J Mol Biol 1987 Apr 20
PMID:Effects of overproduction of single-stranded DNA-binding protein on RecA protein-dependent processes in Escherichia coli. 330 27


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