Further characterization of SOS system induction in recBC mutants of Escherichia coli

Expression of several SOS functions such as induction of lambda prophage, inhibition of cell division and induction of both umuC and recA genes after UV-irradiation, nalidixic acid or mitomycin C addition was studied in an RecBC- mutant. UV-irradiation and mitomycin C induced all SOS functions studied in the RecBC- cells but at a lower level and delayed with respect to the wild-type strain. On the contrary, nalidixic acid was unable to trigger any of these SOS functions. In the RecBC- mutant, adenine only had a stimulating effect on the amplification of RecA protein synthesis following UV-irradiation. Nevertheless, in the wild-type strain the stimulating effect occurred in all SOS functions studied following UV-irradiation as well as in the amplification of RecA protein synthesis by nalidixic acid but not in the other SOS functions triggered by this compound. Furthermore, adenine produced a decrease in the mitomycin C-mediated induction of all SOS functions studied in both RecBC- and wild-type strains.     

Expression of the SOS system in Escherichia coli growing under nitrate respiration conditions

Induction of several SOS functions by mitomycin C, bleomycin or thermal treatment of a recA441 mutant growing under nitrate respiration conditions was studied in Escherichia coli. Mitomycin C caused inhibition of cell division, induction of prophages and expression of umuC gene but like in aerobically growing cells, it did not trigger the cessation of cell repiration. On the contrary, both recA⁺ and recA441 cultures either treated with bleomycin or incubated at 42°C failed to induce any of the different SOS functions cited above.Furthermore, after bleomycin addition or thermal treatment both recA⁺ and recA441 cultures did not present any variation in the cellular ATP level, contrary to what happens under aerobic growth. The blocking of the expression of some SOS functions under nitrate respiration conditions is not an irreversible process because cells incubated under these anaerobic conditions were able to induce the SOS system when changed to an aerobic medium 30 min after the SOS-inducing treatment had been applied.     

Effect of L-ethionine the expression of the SOS system in Escherichia coli

The effect of L-ethionine, the ethyl analog of the essential amino acid methionine the SOS system of Escherichia coli was studied. This compound does not induce either inhibition of cell division nor cessation of cell respiration in a RecA⁺ Met⁺ RelA⁺ strain, nor in RecA⁺ Met⁻ RelA⁺ or RecA⁺ Met⁻ RelA⁻ mutants. Nevertheless, L-ethionine blocks the expression of both cited SOS functions in a recA441 mutant when it is growing at the restrictive temperature of 42°C. Furthermore, the inhibitory effect of the L-ethionine on the induction of the SOS system in this mutant is increased when the cells are preincubated for several hours in the presence of the analog, before the temperature shift. Moreover, cultures of the recA441 mutant incubated at 42°C in the presence of both L-ethionine and L-methionine present the same behaviour as the cultures of this mutant growing at the same temperature but without either amino acid. On the other hand, L-ethionine does not have any effect on the expression of the two mentioned SOS functions when these are induced by UV-irradiation in a RecA⁺ strain even if this compound is added to the cells several hours before irradiation.     

Indirect induction of SOS functions in Salmonella typhimurium

Infection of non-UV-irradiated cells of Salmonella typhimurium with UV-damaged P22 or KB1 phage induces recA-dependent inhibition of cell division, cell mutagenesis and prophage induction but not inhibition of respiration. On the contrary, respiration and ATP concentration are increased after treatment with UV-damaged phage in both RecA+ and RecA- strains, showing that this increase is not recA-dependent. Furthermore, infection with UV-damaged phage prevents both inhibition of respiration and decrease in ATP level in the UV-irradiated RecA+ strain. This indirect induction of SOS functions is related to degradation of phage DNA as well as to the multiplicity of infection used, suggesting that DNA degradation may play an important role in the mechanism of expression of the SOS system. Our results give also support to the hypothesis that there exists a differentiation in the expression of the various SOS functions.     

A new mutation inEscherichia coli K12,isfA, which is responsible for inhibition of SOS functions

A new mutation inEscherichia coli K12,isfA, is described, which causes inhibition of SOS functions. The mutation, discovered in a ΔpolA ⁺ mutant, is responsible for inhibition of several phenomena related to the SOS response inpolA ⁺ strains: UV- and methyl methanesulfonate-induced mutagenesis, resumption of DNA replication in UV-irradiated cells, cell filamentation, prophage induction and increase in UV sensitivity. TheisfA mutation also significantly reduces UV-induced expression of β-galactosidase fromrecA::lacZ andumuC′::lacZ fusions. The results suggest that theisfA gene product may affect RecA^* coprotease activity and may be involved in the regulation of the termination of the SOS response after completion of DNA repair. TheisfA mutation was localized at 85 min on theE. coli chromosome, and preliminary experiments suggest that it may be dominant to the wild-type allele.     

Constitutive expression of SOS functions and modulation of mutagenesis resulting from resolution of genetic instability at or near the recA locus of Escherichia coli

Summary Cellular activities normally inducible by DNA damage (SOS functions) are expressed, without DNA damage, in recA441 (formerly tif-1) mutants of Escherichia coli at 42° C but not at 30° C. We describe a strain (SC30) that expresses SOS functions (including mutator activity, prophage induction and copious synthesis of recA protein) constitutively at both temperatures. SC30 is one of four stable subclones (SC strains) derived from an unstable recombinant obtained in a conjugation between a recA441 K12 donor and a recA ⁺ B/r-derived recipient. SC30 does not owe its SOS-constitutive phenotype to a mutation in the lexA gene (which codes the repressor of recA and other DNA damage-inducible genes), since it is lexA ⁺. Each of the SC strains expresses SOS functions in a distinctively anomalous way. We show that the genetic basis for the differences in SOS expression among the SC strains is located at or very near the recA locus. We propose that resolution of genetic instability in this region, in the original recombinant, has altered the pattern of expression of SOS functions in the SC strains.     

Induction of lambdoid prophages by amino acid deprivation: Differential inducibility; Role of recA

Summary Lambda prophage in auxotrophic lysogens can be induced by omission of one or combinations of the required amino acids from the culture medium. Such amino acid deprivation can result in nearly as effective induction of lambda as thymine deprivation. Prophage 424 is also induced equally effectively under both conditions although to a lesser extent than lambda. By contrast prophage 21 and i²¹ are differentially induced effectively by thymine deprivation and virtually not at all during amino acid deprivation. The same differential induction of 21 and equivalent induction of and 424 occur when all three prophages are present in the same lysogen. Increasing the levels of repressor with a cI carrying-plasmid prevented amino acidless induction of as did the ind ^– mutation. A recA, but not a recB, mutation in the host prevented induction by amino acid deprivation. A recC mutant host showed increased spontaneous induction of and 21 prophages. The findings reported are used as an argument that the recA protease probably is not itself acting as the inducing protease and that a likely source of the observed specificity is an effector molecule. Different effector molecules may be produced in response to different exigent situations, to which the phage repressors may have evolved sensitivity. i⁸⁰ was inducible both by amino acid and thymine deprivation.     

A new mutation inEscherichia coli K12,isfA,which is responsible for inhibition of SOS functions

A new mutation inEscherichia coli K12,isfA, is described, which causes inhibition of SOS functions. The mutation, discovered in a ΔpolA ⁺ mutant, is responsible for inhibition of several phenomena related to the SOS response inpolA ⁺ strains: UV- and methyl methanesulfonate-induced mutagenesis, resumption of DNA replication in UV-irradiated cells, cell filamentation, prophage induction and increase in UV sensitivity. TheisfA mutation also significantly reduces UV-induced expression of β-galactosidase fromrecA::lacZ andumuC′::lacZ fusions. The results suggest that theisfA gene product may affect RecA^* coprotease activity and may be involved in the regulation of the termination of the SOS response after completion of DNA repair. TheisfA mutation was localized at 85 min on theE. coli chromosome, and preliminary experiments suggest that it may be dominant to the wild-type allele.     

DNA repair in E. coli strains deficient in single-strand DNA binding protein

Summary Weigle reactivation and mutagenesis have been found to be defective in strains of E. coli deficient in single-strand DNA binding protein (SSB). These defects parallel those previously found in prophage induction and amplification of recA protein synthesis in ssb strains. Together, these results demonstrate a role for SSB in the induction of SOS responses. UV survival studies of ssb ^- recA^- and ssb ^- uvr^- strains are presented which also suggest a role for SSB in recombinational repair processes but not in excision repair. Studies of host cell reactivation support this latter conclusion.     

DNA repair properties of Escherichia coli tif-1, recAo281 and lexA1 strains deficient in single-strand DNA binding protein

Summary Mutations affecting single-strand DNA binding protein (SSB) impair induction of mutagenic (SOS) repair. To further investigate the role of SSB in SOS induction and DNA repair, isogenic strains were constructed combining the ssb ⁺, ssb-1 or ssb-113 alleles with one or more mutations known to alter regulation of damage inducible functions. As is true in ssb ⁺ strains tif-1 (recA441) was found to allow thermal induction of prophage ⁺ and Weigle reactivation in ssb-1 and ssb-113 strains. Furthermore, tif-1 decreased the UV sensitivity of the ssb-113 strain slightly and permitted UV induction of prophage ⁺ at 30°C. Strains carrying the recAo281 allele were also constructed. This mutation causes high constitutive levels of RecA protein synthesis and relieves much of the UV sensitivity conferred by lexA ^– alleles without restoring SOS (error-prone) repair. In contrast, the recAo281 allele failed to alleviate the UV sensitivity associated with either ssb ^– mutation. In a lexA1 recAo281 background the ssb-1 mutation increased the extent of postirradiation DNA degradation and concommitantly increased UV sensitivity 20-fold to the level exhibited by a recA1 strain. The ssb-113 mutation also increased UV sensitivity markedly in this background but did so without greatly increasing postirradiation DNA degradation. These results suggest a direct role for SSB in recombinational repair apart from and in addition to its role in facilitating induction of the recA-lexA regulon.     

Prophage lambda induction caused by mini-F plasmid genes

Summary When bacterial cells harboring a temperaturesensitive replication plasmid, which carries the particular ccd segment of a mini-F plasmid, are transferred to 42°C, cell division is inhibited after incubation for an appropriate time. The inhibition occurs, when the copy number of the plasmid decreases to become critically low, about one per cell (Ogura and Hiraga 1983 b). In phage lysogens carrying this type of plasmid, the prophage is induced in a small portion of the cell population under the same conditions, in addition to the inhibition of cell division in most of cells. The prophage induction, but not the inhibition of normal cell division, depends on normal recA function. Both induction of prophage and inhibition of cell division are suppressed by the simultaneous presence of a replication proficient plasmid carrying the ccdA gene. We discuss molecular mechanisms of the ccd function that couples host cell division to plasmid proliferation and induces the prophage. Additionally, we propose a hypothesis that the ccd mechanism of F plasmid contributes to indirect induction of prophage by an F plasmid damaged by UV-irradiation and then introduced into a lysogen via conjugation.Abbreviations kb kilobase pairs. m.o.i., multiplicity of infection     

Role of DNA replication in the induction and turn-off of the SOS response in Escherichia coli

Summary We have studied the role of DNA replication in turnon and turn-off of the SOS response in Escherichia coli using a recA::lac fusion to measure levels of recA expression.An active replication fork does not seem to be necessary for mitomycin C induced recA expression: a dnaA43 initiation defective mutant, which does not induce the SOS response at non-permissive temperature, remains mitomycin C inducible after the period of residual DNA synthesis. This induction seems to be dnaC dependent since in a dnaC325 mutant recA expression not only is not induced at 42° C but becomes mitomycin C non-inducible after the period of residual synthesis.Unscheduled halts in DNA replication, generally considered the primary inducing event, are not sufficient to induce the SOS response: no increase in recA expression was observed in dnaG(Ts) mutants cultivated at non-permissive temperature. The replication fork is nonetheless involved in induction, as seen by the increased spontaneous level of recA expression in these strains at permissive temperature.Turn-off of SOS functions can be extremely rapid: induction of recA expression by thymine starvation is reversed within 10 min after restoration of normal DNA replication. We conclude that the factors involved in induction-activated RecA (protease) and the activating molecule (effector)-do not persist in the presence of normal DNA replication.Abbreviations Ts thermosensitive - SDS sodium dodecyl sulfate - Ap ampicillin - UV ultraviolet - X-Gal 5-bromo-4-chloro-3-indolyl--D-galactoside     

Thymineless Death in Escherichia coli: Strain Specificity

Thymineless death of various ultraviolet (UV)-sensitive strains of Escherichia coli B and K-12 was investigated. It was found that E. coli B, B_s−12, K-12 rec-21, and possibly K-12 Lon⁻, all sensitive to UV, were also sensitive to thymine starvation. However, other UV-sensitive strains of E. coli were found to display the typical resistant-type kinetics of thymineless death. The correlation of these results with various other cellular processes suggested that the filament-forming ability of the bacteria might be involved in the mechanism of thymineless death. It was apparent from the present results that capacity for host-cell reactivation, recombination ability, thymine dimer excision, and probably induction of a defective prophage had little to do with determining sensitivity to thymine deprivation.     

SOS induction by thermosensitive replication mutants of miniF plasmid

Summary MiniF, a 9.3 kb fragment of the dispensable F plasmid, carries genes necessary for its replication and partition as well as for the expression of an SOS signal. The arrest of replication of a thermo-sensitive miniFts at 42°C induced SOS functions such as prophage , sfiA expression, W-reactivation of UV-irradiated phage . Two miniF ts9 and ts17 mutations were located within the KpnI fragment (43.6–46.9) in the minimal oriS replicon. Blocking miniF replication by incBC ⁺ incompatibility genes situated in trans on a second plasmid also induced SOS functions. In contrast, if miniFts17 plasmid escaped the replication block at 42°C by being inserted into pR325, there was no SOS induction. SOS induction by the arrest of miniF replication required the miniF lynA ⁺ locus in cis, the host recA ⁺ and lexA ⁺ genes. We found that SOS induction was increased greatly near the stationary phase and that cell viability declined. During host cell exponential growth, miniFts9 and miniFts17 plasmids were lost rapidly, although SOS induction persisted for several cell generations. We postulate that lynA expresses a persistent product that may lead to the unwinding of chromosomal DNA.     

Physical mapping and characterization of the mitochondrial DNA and RNA sequences from mit- mutants defective in cytochrome oxidase peptide 1 (OXI 3).

Summary The striking similarity between the treatments that induce SOS functions and those that result in stable DNA replication (continuous DNA replication in the absence of protein synthesis) prompted us to examine the possibility of stable DNA replication being a recA ⁺ lexA ⁺-dependent SOS function. In addition to the treatments previously reported, ultraviolet (UV) irradiation or treatment with mitomycin C was also found to induce stable DNA replication.The thermal treatment of tif-1 strains did not result in detectable levels of stable DNA replication, but nalidixic acid readily induced the activity in these strains. The induction of stable DNA replication with nalidixic acid was severely suppressed in tif-1 lexA mutant strains. The inhibitory activity of lexA3 was negated by the presence of the spr-51 mutation, an intragenic suppressor of lexA3.Induced stable DNA replication was found to be considerably more resistant to UV irradiation than nromal replication both in a uvrA6 strain and a uvr ⁺ strain. The UV-resistant replication occurred mostly in the semiconservative manner. The possible roles of stable DNA replication in repair of damaged DNA are discussed.     

Effect of L-ethionine on the expression of the SOS system in Escherichia coli

The effect of L-ethionine, the ethyl analog of the essential amino acid methionine, on the SOS system of Escherichia coli was studied. This compound does not induce either inhibition of cell division nor cessation of cell respiration in a RecA+ Met+ RelA+ strain, nor in RecA+ Met- RelA+ or RecA+ Met- RelA- mutants. Nevertheless, L-ethionine blocks the expression of both cited SOS functions in a recA441 mutant when it is growing at the restrictive temperature of 42 degrees C. Furthermore, the inhibitory effect of the L-ethionine on the induction of the SOS system in this mutant is increased when the cells are preincubated for several hours in the presence of the analog, before the temperature shift. Moreover, cultures of the recA441 mutant incubated at 42 degrees C in the presence of both L-ethionine and L-methionine present the same behaviour as the cultures of this mutant growing at the same temperature but without either amino acid. On the other hand, L-ethionine does not have any effect on the expression of the two mentioned SOS functions when these are induced by UV-irradiation in a RecA+ strain even if this compound is added to the cells several hours before irradiation.     

Indirect SOS induction is promoted by ultraviolet light-damaged miniF and requires the miniF lynA locus

Indirect prophage induction is produced by transfer to recipients of u.v.-damaged F plasmid (95 kb). We tested whether the SOS signal can be produced by miniF, a 9.3 kb restriction fragment, coding for the replication and segregation functions of plasmid F. We used λminiF, a hybrid phage-plasmid. u.v.-irradiated λminiF induced prophages φ80 or λ and sfiA, a chromosomal SOS gene, in more than 50% of the infected cells. The maximal inducing dose produced about 0.5 pyrimidine dimers per kb and left 1% of λminiF survivors. Thus, the SOS signal produced by u.v.-damaged λminiF was almost as potent as that resulting from direct u.v.-irradiation of the lysogens. The u.v.-damaged vector λ, devoid of miniF, failed to promote SOS induction. In contrast, efficient induction was observed when u.v.-damaged λminiF infected a λ immune host, in which replication and expression of the phage genome were repressed. When replication and expression of the miniF genome was repressed by Hfr incompatibility, SOS induction was largely prevented. All these facts indicate that, in the hybrid λ-miniF, it is the u.v.-damaged miniF that generates an SOS signal.To locate on the miniF genome the loci that are involved in the production of the SOS signal, we isolated deletions spanning all the miniF restriction fragments. We characterized six mutant phenotypes (Par⁺, Rep^?, Fid^?, Par-2, Par-1 and SOS^?) related to four functions; partition, copy number, replication and SOS induction. A locus, we call lynA, 800bp long, located by deletion mapping between the two origins of replication oriP and oriS is required for the production of an inducing signal.We postulate that indirect SOS induction by u.v.-damaged miniF results from the disturbance of the lynA function that may be involved in the co-segregation of F plasmid with the host chromosome.     

5-Azacytidine: survival and induction of the SOS response in Escherichia coli K-12

Survival and induction of the SOS system by 5-azacytidine, an analog of cytidine, were studied in Escherichia coli K-12. This compound did not produce any effect on the viability of dcm and dam dcm mutants. Furthermore, recA430 and lexA1 strains (both mutations interfere with LexA repressor cleavage but not recombination proficiency) were more resistant than the wild-type strain of E. coli K-12. In contrast, recBC and recA13 mutants were more sensitive to 5-azacytidine than the wild type. Transient exposure of E. coli to 5-azacytidine for 60 min induced both recA-dependent inhibition of cell division and induction of lambda prophage in Dcm+ strains but not in Dcm- mutants. Expression of both functions was dependent on recBC exonuclease. On the other hand, 5-azacytidine was unable to trigger the induction of umuCD and mucB genes and no amplification of RecA protein synthesis in either Dcm+ or Dcm- strains was observed. These last results are in agreement with previously reported data suggesting that there is a discrimination in the expression of the several SOS functions and that some SOS genes may be induced without amplification of RecA protein synthesis.