Effect of suppressors of SOS-mediated filamentation on sfiA operon expression in Escherichia coli

In Escherichia coli, the cell division block observed during the SOS response requires the product of the sfiA gene, whose expression is regulated negatively by the LexA repressor and positively by the RecA protease. We have studied the effect on sfiA expression of sfiA, sfiB, infA, and infB mutations, which are known to affect SOS-associated filamentation. To measure sfiA expression in the different strains, we first constructed a lambda transducing phage carrying an sfiA::lac operon fusion. Mutations at the sfiA locus (dominant and recessive) and the sfiB locus (recessive) had no effect on sfiA expression. The mutations tif (at the recA locus) and tsl (at the lexA locus) are known to induce filamentation and a high level of sfiA expression at 42 degrees C. The infB1 mutation, which suppresses filamentation in a tif tsl strain at 42 degrees C, reduced sfiA expression at 42 degrees C in tif tsl infB1 and tsl infB1 strains but not in a tif infB1 strain. The infA3 mutation, which suppresses tif-mediated filamentation, reduced induction of sfiA expression in a tif infA3 strain at 42 degrees C or after UV irradiation. The isolation and characterization of sfiA constitutive strains revealed only lexA-linked mutations in a sfiA-background, suggesting that LexA is the only readily eliminated repressor of the sfiA gene. Nevertheless, the infA and infB mutations could define elements involved in the regulation of sfiA expression.     

Effect of alkylating agents on the expression of inducible genes of Escherichia coli

Increasing doses of alkylating agents such as N-methyl-N'-nitro-N-nitrosoguanidine, diethyl sulphate and ethylmethane sulphonate cause an inhibition of the expression of the recA and sfiA genes of wild-type Escherichia coli. This behaviour was not observed in a lexA56 mutant which has a defective LexA repressor that is unable to bind to the SOS operator. Furthermore, an ada-1 mutant showed the same behaviour as the wild-type strain indicating that the adaptive proteins are not responsible for the inhibition of recA and sfiA at high doses of alkylating agents. These results suggest that the inhibitory effect of these alkylating agents may be found in the interaction between the LexA repressor and the control regions of sfiA and recA. On the other hand, high doses of either UV light or mitomycin C produced only a slight decrease in the induction of recA and sfiA, whereas bleomycin had no effect. The fact that a repressor structurally related to LexA repressor, such as LacI protein, showed the same behaviour as the LexA repressor when a Lac+ strain was treated with alkylating agents, suggests that these compounds can modify the binding abilities of repressors to DNA, producing a limited or even abolished release of repressors, and so decreasing the expression of inducible genes.     

Constitutive expression of the SOS response in recA718 mutants of Escherichia coli requires amplification of RecA718 protein.

In recA718 lexA+ strains of Escherichia coli, induction of the SOS response requires DNA damage. This implies that RecA718 protein, like RecA+ protein, must be converted, by a process initiated by the damage, to an activated form (RecA) to promote cleavage of LexA, the cellular repressor of SOS genes. However, when LexA repressor activity was abolished by a lexA-defective mutation [lexA(Def)], strains carrying the recA718 gene (but not recA+) showed strong SOS mutator activity and were able to undergo stable DNA replication in the absence of DNA damage (two SOS functions known to require RecA activity even when cleavage of LexA is not necessary). lambda lysogens of recA718 lexA(Def) strains exhibited mass induction of prophage, indicative of constitutive ability to cleave lambda repressor. When the cloned recA718 allele was present in a lexA+ strain on a plasmid, SOS mutator activity and beta-galactosidase synthesis under LexA control were expressed in proportion to the plasmid copy number. We conclude that RecA718 is capable of becoming activated without DNA damage for cleavage of LexA and lambda repressor, but only if it is amplified above its base-line level in lexA+ strains. At amplified levels, RecA718 was also constitutively activated for its roles in SOS mutagenesis and stable DNA replication. The nucleotide sequence of recA718 reveals two base substitutions relative to the recA+ sequence. We propose that the first allows the protein to become activated constitutively, whereas the second partially suppresses this capability.     

Induction of the SOS response in Escherichia coli inhibits Tn5 and IS50 transposition.

In response to DNA damage or the inhibition of normal DNA replication in Escherichia coli, a set of some 20 unlinked operons is induced through the RecA-mediated cleavage of the LexA repressor. We examined the effect of this SOS response on the transposition of Tn5 and determined that the frequency of transposition is reduced 5- to 10-fold in cells that constitutively express SOS functions, e.g., lexA(Def) strains. Furthermore, this inhibition is independent of recA function, is fully reversed by a wild-type copy of lexA, and is not caused by an alteration in the levels of the Tn5 transposase or inhibitor proteins. We isolated insertion mutations in a lexA(Def) background that reverse this transposition defect; all of these mapped to a new locus near 23 min on the E. coli chromosome.     

Non-mutability by ultraviolet light in uvrD recB derivatives of Escherichia coli WP2 uvrA is due to inhibition of RecA protein activation

The deficiency in UV mutagenesis in uvrD3 recB21 strains of E. coli is almost completely overcome by constitutive activation of RecA protein and expression of the SOS system (by recA730 or 43 degrees C treated recA441 lexA71). When SOS was expressed but RecA protein not self-activated (recA441 lexA71 at 30 degrees C), uvrD3 recB21 still reduced UV mutagenesis at low doses. The uvrD3 recB21 combination is therefore inhibiting activation of RecA protein. It is suggested that the DNA unwinding activity of the products of the uvrD and recB genes may be involved in generating single-stranded DNA needed to activate RecA protein both for the cleavage of LexA repressor and for a further role in UV mutagenesis.     

The muc genes of pKM101 are induced by DNA damage

A gene fusion was constructed in vitro that resulted in the synthesis of a hybrid protein consisting of the amino-terminal segment of the MucB protein of the mutagenesis-enhancing plasmid pKM101 joined to an enzymatically active carboxy-terminal segment of the beta-galactosidase protein. In strains bearing this fusion, beta-galactosidase activity was induced by UV radiation and other DNA-damaging agents. A genetic analysis of the regulation of expression of the phi (mucB'-lacZ') fusion was consistent with the LexA protein acting as the direct repressor of the mucB gene. Examination of the expression of the mucA and phi (mucB'-lacZ') gene products in maxicells in the presence and absence of a high-copy-number plasmid carrying the lexA+ gene demonstrated that lexA regulated both the mucA and mucB genes, thus supporting our conclusion that the two genes are organized in an operon with the mucA gene transcribed first. An analysis of the effects of the recA430(lexB30) mutation on muc expression led to the discovery of the differential ability of the recA430 gene product to induce expression of a dinB::Mu d1(Ap lac) fusion located on the chromosome and the same phi (dinB'-lacZ+) fusion cloned into plasmid pBR322. Models to account for the role of the recA430 allele on the expression of damage-inducible genes and on mutagenesis are discussed.     

Effects of overproduction of single-stranded DNA-binding protein on RecA protein-dependent processes in Escherichia coli

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.     

SOS induction in mycobacteria: analysis of the DNA-binding activity of a LexA-like repressor and its role in DNA damage induction of the recA gene from Mycobacterium smegmatis

The protein encoded by the lexA gene from Mycobacterium leprae was overproduced in Escherichia coli . The recombinant protein bound to the promoter regions of the M. leprae lexA , M. leprae recA and M. smegmatis recA genes at sites with the sequences 5'-GAACACATGTTT and 5'-GAACAGGTGTTC, which belong to the 'Cheo box' family of binding sites recognized by the SOS repressor from Bacillus subtilis . Gel mobility shift assays were used to confirm that proteins with the same site specificity of DNA binding are also present in Mycobacterium tuberculosis and M. smegmatis . Complex formation was impaired by mutagenic disruption of the dyad symmetry of the M. smegmatis recA Cheo box. LexA binding was also inhibited by preincubation of the M. smegmatis and M. tuberculosis extracts with anti- M. leprae LexA antibodies, suggesting that the mycobacterial LexA proteins are functionally conserved at the level of DNA binding. Finally, exposure of M. smegmatis to DNA-damaging agents resulted in induction of the M. smegmatis recA promoter with concomitant loss of DNA binding of LexA to its Cheo box, confirming that this organism possesses the key regulatory elements of a functional SOS induction system.     

Effect of plasmid pKM101 on the expression of bacterial genes not related to DNa metabolism]

An experimental system ensuring fusion of bacterial genes to the lac operon of the Mu dl(Aplac) phage was used. Fusion operons in which the lac operon was under the control of promoters of the elt gene, responsible for synthesis of the LT toxin, of the tetracyclin-resistance tet gene, and sfiA gene encoding filament production, was studied. Using this experimental system, plasmid pKM101 was shown to be capable of activating the expression of the above Escherichia coli and Salmonella typhimurium genes, which is manifested as the activation of beta-galactosidase synthesis. The activation of the elt gene expression by the pKM101 plasmid was also confirmed in experiments on detecting the LT toxin synthesized by bacteria carrying this plasmid. Effect of the plasmid on the activation of elt operon expression, unlike the effect of this plasmid on mutability, does not depend on the functioning of the lexA and recA genes, i.e., this is not a SOS-regulated process. The mutant plasmid pGW12, a derivative of pKM101, deficient in the mucAB genes responsible for mutagenesis, causes a more pronounced activation of the elt gene than plasmid pKM101.     

The Leptospira interrogans lexA gene is not autoregulated

Footprinting and mutagenesis experiments demonstrated that Leptospira interrogans LexA binds the palindrome TTTGN(5)CAAA found in the recA promoter but not in the lexA promoter. In silico analysis revealed that none of the other canonical SOS genes is under direct control of LexA, making the leptospiral lexA gene the first described which is not autoregulated.     

Isolation and characterization of amber mutations in the lexA gene of Escherichia coli K-12.

We describe the isolation and characterization of amber mutations in the lexA gene of Escherichia coli K-12. These mutations, designated spr(Am), were isolated and characterized in a lexA tif sfi genetic background. They abolished the sensitivity of the strain to UV light and resulted in high rates of synthesis of recA protein. Phage lambda+ failed to lysogenize the strains as observed with similar strains carrying non-amber spr mutations described previously, thereby indicating a constitutive expression of the phage induction pathway. Introduction of an amber suppressor mutation into a strain bearing the spr(Am) mutation restored expression of the LexA mutant phenotype. We conclude that spr mutations either inactivate or prevent synthesis of the lexA gene product and that loss of this product results in constitutive expression of the E. coli induction system in the tif sfi genetic background.     

Inhibition of cell division in hupA hupB mutant bacteria lacking HU protein.

Escherichia coli hupA hypB double mutants that lack HU protein have severe cellular defects in cell division, DNA folding, and DNA partitioning. Here we show that the sfiA11 mutation, which alters the SfiA cell division inhibitor, reduces filamentation and production of anucleate cells in AB1157 hupA hupB strains. However, lexA3(Ind-) and sfiB(ftsZ)114 mutations, which normally counteract the effect of the SfiA inhibitor, could not restore a normal morphology to hupA hupB mutant bacteria. The LexA repressor, which controls the expression of the sfiA gene, was present in hupA hupB mutant bacteria in concentrations half of those of the parent bacteria, but this decrease was independent of the specific cleavage of the LexA repressor by activated RecA protein. One possibility to account for the filamentous morphology of hupA hupB mutant bacteria is that the lack of HU protein alters the expression of specific genes, such as lexA and fts cell division genes.     

Two Lactococcus lactis genes, including lacX, cooperate to trigger an SOS response in a recA-negative background.

A 4.3-kb EcoRI fragment from a Lactococcus lactis genomic library alleviates the methyl methanesulfonate, mitomycin C, and UV sensitivities of an Escherichia coli recA mutant (M. Novel, X. F. Huang, and G. Novel, FEMS Microbiol. Lett. 72:309-314, 1990). It complements recA1 and delta recA mutations but not recA13. Three proteins (with molecular masses of 20, 35, and 23 kDa) were produced from this fragment in a T7-directed system, and three corresponding genes were detected by DNA sequencing, namely, ISS1CH;lacX, which is the distal gene of the lac operon; and a third open reading frame, named lacN, which encodes 211 amino acids. Mutations produced in either lacX or in lacN resulted in the loss of the resistance to DNA-damaging agents. Thus, these two genes appeared to be involved in this activity. Introduction of pUCB214 carrying the 4.3-kb fragment into a lexA+ delta recA306 sfiA::lacZ strain resulted in UV-inducible synthesis of beta-galactosidase. A uvrA strain or a lexA (Ind-) strain containing pUCB214 did not support any DNA repair. However, a lexA (Def-) strain carrying pUCB214 could partly repair UV damage. We discuss possible targets for LacX and LacN products, and we speculate that LacX and LacN may constitute a two-component regulatory system that is able to respond to SOS signals, and then to act in the SOS response, bypassing the RecA-activated function.     

Regulation of the SOS response in Bacillus subtilis: evidence for a LexA repressor homolog.

The inducible SOS response for DNA repair and mutagenesis in the bacterium Bacillus subtilis resembles the extensively characterized SOS system of Escherichia coli. In this report, we demonstrate that the cellular repressor of the E. coli SOS system, the LexA protein, is specifically cleaved in B. subtilis following exposure of the cells to DNA-damaging treatments that induce the SOS response. The in vivo cleavage of LexA is dependent upon the functions of the E. coli RecA protein homolog in B. subtilis (B. subtilis RecA) and results in the same two cleavage fragments as produced in E. coli cells following the induction of the SOS response. We also show that a mutant form of the E. coli RecA protein (RecA430) can partially substitute for the nonfunctional cellular RecA protein in the B. subtilis recA4 mutant, in a manner consistent with its known activities and deficiencies in E. coli. RecA430 protein, which has impaired repressor cleaving (LexA, UmuD, and bacteriophage lambda cI) functions in E.coli, partially restores genetic exchange to B. subtilis recA4 strains but, unlike wild-type E. coli RecA protein, is not capable of inducing SOS functions (expression of DNA damage-inducible [din::Tn917-lacZ] operons or RecA synthesis) in B. subtilis in response to DNA-damaging agents or those functions that normally accompany the development of physiological competence. Our results provide support for the existence of a cellular repressor in B. subtilis that is functionally homologous to the E. coli LexA repressor and suggest that the mechanism by which B. subtilis RecA protein (like RecA of E. coli) becomes activated to promote the induction of the SOS response is also conserved.     

UV induction of LexA independent proteins which could be involved in SOS repair

The SOS response is induced in E coli following treatments that interfere with DNA replication. The response is under the control of the recA and the lexA genes. Strains defective in LexA repressor constitutively express SOS proteins. However, SOS repair does not reach its maximum level in these strains. Instead, an activation of RecA protein and de novo protein synthesis are required for full repair. We have analyzed by 2-dimensional gel electrophoresis the induction of proteins after UV irradiation of lexA(Def) bacteria. Proteins which might participate in SOS repair are induced under these conditions.     

New recA mutations that dissociate the various RecA protein activities in Escherichia coli provide evidence for an additional role for RecA protein in UV mutagenesis.

To isolate strains with new recA mutations that differentially affect RecA protein functions, we mutagenized in vitro the recA gene carried by plasmid mini-F and then introduced the mini-F-recA plasmid into a delta recA host that was lysogenic for prophage phi 80 and carried a lac duplication. By scoring prophage induction and recombination of the lac duplication, we isolated new recA mutations. A strain carrying mutation recA1734 (Arg-243 changed to Leu) was found to be deficient in phi 80 induction but proficient in recombination. The mutation rendered the host not mutable by UV, even in a lexA(Def) background. Yet, the recA1734 host became mutable upon introduction of a plasmid encoding UmuD*, the active carboxyl-terminal fragment of UmuD. Although the recA1734 mutation permits cleavage of lambda and LexA repressors, it renders the host deficient in the cleavage of phi 80 repressor and UmuD protein. Another strain carrying mutation recA1730 (Ser-117 changed to Phe) was found to be proficient in phi 80 induction but deficient in recombination. The recombination defect conferred by the mutation was partly alleviated in a cell devoid of LexA repressor, suggesting that, when amplified, RecA1730 protein is active in recombination. Since LexA protein was poorly cleaved in the recA1730 strain while phage lambda was induced, we conclude that RecA1730 protein cannot specifically mediate LexA protein cleavage. Our results show that the recA1734 and recA1730 mutations differentially affect cleavage of various substrates. The recA1730 mutation prevented UV mutagenesis, even upon introduction into the host of a plasmid encoding UmuD* and was dominant over recA+. With respect to other RecA functions, recA1730 was recessive to recA+. This demonstrates that RecA protein has an additional role in mutagenesis beside mediating the cleavage of LexA and UmuD proteins.     

Conjugational hyperrecombination achieved by derepressing the LexA regulon,altering the properties of RecA protein and inactivating mismatch repair in Escherichia coli K-12

The frequency of recombinational exchanges (FRE) that disrupt co-inheritance of transferred donor markers in Escherichia coli Hfr by F(-) crosses differs by up to a factor of two depending on physiological factors and culture conditions. Under standard conditions we found FRE to be 5.01 +/- 0.43 exchanges per 100-min units of DNA length for wild-type strains of the AB1157 line. Using these conditions we showed a cumulative effect of various mutations on FRE. Constitutive SOS expression by lexA gene inactivation (lexA71::Tn5) and recA gene mutation (recA730) showed, respectively, approximately 4- and 7-fold increases of FRE. The double lexA71 recA730 combination gave an approximately 17-fold increase in FRE. Addition of mutS215::Tn10, inactivating the mismatch repair system, to the double lexA recA mutant increased FRE to approximately 26-fold above wild-type FRE. Finally, we showed that another recA mutation produced as much SOS expression as recA730 but increased FRE only 3-fold. We conclude that three factors contribute to normally low FRE under standard conditions: repression of the LexA regulon, the properties of wild-type RecA protein, and a functioning MutSHL mismatch repair system. We discuss mechanisms by which the lexA, recA, and mutS mutations may elevate FRE cumulatively to obtain hyperrecombination.