Prophage induction and cell division in E. coli. II. Linked (recA, zab) and unlinked (lex) suppressors of tif-1-mediated induction and filamentation

Summary The pleiotropy of tif-1, a mutation in E. coli K12 causing, among other effects, cellular filamentation at 42° and thermal induction of lysogenic derivatives, can be explained by the participation of the tif ⁺ gene product in more than one reaction pathway. Pathways that involve the tif ⁺ product may be analyzed by selection of secondary mutations that reverse both tif-1-mediated prophage induction and cell filamentation. Among revertants of a tif-1 lysogen among 20% are recombination deficient. These appear to carry a recA mutation. In addition to this class is a rarer (7%) phenotypically distinguishable class of revertants, called zab, first described here. Markers tif-1, recA and zab are closely linked. Mutations lex which are dominant and located near malB also appear (3%) among tif-1 revertants. The lex ⁺ function is needed for normal UV, X-ray and mitomycin C induction of prophage .The zab mutation resembles recA in causing (1) high sensitivity to UV, X-rays and mitomycin C, (2) drastic DNA degradation following UV irradiation but normal capacity to repair UV-damaged infecting phage (Hcr⁺), (3) failure to carry out UV reactivation and UV mutagenesis of UV-irradiated bacteriophage , (4) a markedly reduced level of spontaneous induction of . In contrast, other capacities, strikingly diminished by recA, are affected less, if at all by zab. Thus zab (1) permits 30–60% normal recombination proficiency, (2) shows real, although very low inducibility of by UV or mitomycin C, (3) permits 100% efficiency of plating of red gam, and (4) does not degrade DNA spontaneously.The hypothesis is proposed that the tif-1 mutation is a regulatory mutation controlling the activity, or more likely the synthesis of repair enzyme(s). The level of these repair enzyme(s), rather than DNA lesions, may govern the stability of the prophage repressor and the capacity of the bacteria to form septa.     

Identification of protein X of Escherichia coli as the recA+/tif+ gene product.

Summary Protein X, molecular weight 40,000, has been separated from the other proteins of E. coliby a two-dimensional gel electrophoretic technique which separates proteins according to isoelectric point (pI) in the firstdimension and according to molecular weight in the second. When protein X is induced in wild-type cells by mitomycin C treatmentit has a pI6.0. However, when protein X is induced in a tif-1 mutant, either by temperatureshift-up to 42° or by mitomycin C treatment at 30°, it has a pI6.2. The low level of protein X which is present inuninduced tif mutants at 30° also has a pI6.2. These results suggest thattif-1 is a mis-sense mutation in the gene coding for protein X. Since transduction andcomplementation studies indicate that tif-1 is a mutation of therecA ⁺ gene (Castellazzi, Morand, George and Buttin, 1977) it follows that protein X is the recA ⁺ gene product.A model has been formulated to account for the relationship between protein X synthesis and the recA ⁺ and lexA ⁺ genes. In this model, a repressor coded by lexA ⁺ binds to the operator of the recA ⁺ gene from whence it can normally only be removed by the combined action of an inducer and protein X, the recA ⁺ product. Thus, protein X controls its own synthesis. The tif-1 mutation leads to a temperature sensitive form of protein X which, at 42°, can spontaneously remove the repressor without the intervention of the inducer.     

Complementation pattern of lexB and recA mutations in Escherichia coli K12; mapping of tif-1, lexB and recA mutations

Summary Three lexB mutations, whose phenotypes have been previously characterized, are studied here in relation to a few recA mutations as to their complementation pattern and relative location.The restoration of resistance to UV-light and to X-rays in the hetero-allelic diploid bacteria was used as a test for dominance and complementation. The wild type allele was always dominant over the mutant allele. Only partial complementation was found between lexB and two recA alleles. There was no complementation between the recA alleles. All the data taken together strongly suggest that the complementations found are intragenic: lexB and recA mutations are in one gene.Mapping of lexB, recA and tif-1 mutations in relation to srl-1 and cysC by phage P1 transduction shows that lexB and the tif-1 mutations form a cluster proximal to srl-1 whereas recA mutations are located at the other extremity of the gene. Variability with temperature of cotransduction frequencies as well as their extended range of values prevent a meaningful calculation of the length of the recA gene.Our hypothesis is that the recA protein has two functional regions called A and B respectively defined at the genetical level by recA and lexB mutations and that it is, in vivo, an oligomeric protein forming a complex with the lexA protein. This complex is postulated to be multifunctional: recombination and control of exonuclease V are effected by the A region while the B region and lexA protein effect induced DNA repair and lysogenic induction.     

Induction of recA+-protein synthesis in Escherichia coli.

Summary Escherichia coli was infected with precA ⁺to determine the genetic and physiological factors controlling recA ⁺gene expression. When precA ⁺replication was prevented by superinfection immunity, recA ⁺protein synthesis was induced by UV radiation. The recA ⁺gene is negatively controlled by the lexA ⁺gene product because i) a dominant lexA mutation, lexA3, prevented induction of recA ⁺protein synthesis ii) a recessive lexA mutation, tsl-1, caused induction of recA ⁺protein synthesis. Conversely positive control of recA ⁺gene expression requires recA ⁺protein because i) a co-dominant tif-1 mutation (a recA mutation) caused induction of recA ⁺protein synthesis ii) a recessive mutation, recA1, prevented cis-induction of recA protein synthesis. recA ⁺protein and Protein X of UV irradiated bacteria co-migrated and were subject to the same physiological and genetic controls. It is concluded that Protein X is recA ⁺protein. lysogenic induction was prevented by TPCK, a protease inhibitor. However TPCK did not prevent induction of recA ⁺protein synthesis, indicating that induction of the two processes occurs in different ways. It is suggested that the lexA ⁺and recA ⁺proteins normally combine to repress the recA ⁺gene. Derepression might occur after DNA damaging treatments because the amount of this complex would be reduced by recA ⁺protein i) binding to single-stranded DNA and/or ii) being activated to function proteolytically towards regulatory molecules such as repressor.     

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.     

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.     

Genetic analysis of constitutive stable DNA replication in rnh mutants of Escherichia coli K12

Summary 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.     

Quantitative evaluation of recA gene expression in Escherichia coli

Summary A recA::lac operon fusion was constructed using the phage Mu d(Ap, lac) in Escherichia coli to obtain precise measurements of the level of recA gene expression in various genetic backgrounds. The RecA protein normally represents 0.02% of total protein. This value is known to increase dramatically after treatments interrupting DNA synthesis; kinetic experiments showed that the rate of recA expression increases 17-fold within 10 min after UV irradiation or thymine starvation. In mutants affected in SOS regulation or repair the following observations were made: (i) the tif-1 mutation in the recA gene does not alter the basal level of recA expression, suggesting that it improves the protease activity of RecA; (ii) the lexA3 mutation does not create a super-repressor of recA; (iii) the tsl-1 mutation in the lexA gene makes the LexA protein a poor repressor of recA at 30°C (2.5-fold derepression) and a poor substrate for RecA protease (3-fold stimulation of recA expression by UV); (iv) the spr-55 amber mutation in the lexA gene causes a 30-fold increase in recA expression, higher than all inducing treatments, and this level cannot be further increased by nalidixic acid; (v) the zab-53 mutation at the recA locus, known to abolish tsl-mediated induction of recA expression, is trans-recessive and thus probably affects a regulatory site on the DNA; (vi) uvrA, B and C, recB and recF mutations do not increase the basal level of recA expression, suggesting that there are not sufficient spontaneous lesions to cause induction even when any one of these three repair pathways is inoperative.Abbreviations Ap ampicillin - Km kanamycin - Cm chloramphenicol - Tc terracycline - Sm streptomycin - Ts thermosensitive - Tr thermoresistant - Nal nalidixic acid - X-Gal 5-bromo-4-chloro-3-indolyl--D-galactoside - mito C mitomycin C - LFT low frequency transducing - HFT high frequency transducing     

Functional domains of Escherichia coli recA protein deduced from the mutational sites in the gene

Summary The sites of recA mutations of Escherichia coli, recA441 (tif-1), recA1, recA430 (lexB30) and recA44, were determined by analyses of the nucleotide sequences. All mutations are single point missense mutations within the coding region of the recA gene. In the recA441, recA1, recA430 and recA44 proteins, the 38th, 160th, 204th, and 246th amino acids, respectively, from the amino terminal ends are altered. Based on the properties of these mutant proteins and modified forms of recA protein, the locations of various regions of the recA protein that are involved in binding with ATP, binding with single-stranded DNA, hydrolysis of ATP, interaction between the recA protein molecules and interaction with the cI or lexA repressors are mapped on the primary structure of the protein.     

Weigle reactivation of the single-stranded DNA phage f1

Summary The survival of ultraviolet light (UV) damaged single-stranded DNA bacteriophage f1 is increased when the Escherichia coli host is irradiated with UV prior to infection. This repair, called Weigle reactivation, is multiplicity independent and is absent in recA and in lexA mutants. The function of the recA-lexA repair system needed is repair and not recombination, as demonstrated by the absence of Weigle reactivation in mutants that are recombination proficient but defective in repair of double-stranded DNA. Weigle reactivation of f1 requires high levels of the recA protein, and in addition activation of recA or another protein. This activation can be produced by UV irradiation, or by the tif-1 allele of recA together with the spr allele of lexA. Mutagenesis of f1 has the same requirements as W-reactivation, and in addition requires UV irradiation of the phage.     

The role of DNA polymerase I and the rec system in survival of bacteria and bacteriophages damaged by the photodynamic action of acridine orange

Summary The effect of acridine orange (AO)-sensitized photodynamic treatment (PD) was studied in various repair-deficient mutants of Salmonella typhimurium and Escherichia coli. Bacteria of either species carrying mutations in the polA gene and hence deficient in the enzyme DNA polymerase I were significantly more sensitive to PD-killing than polA ⁺ parent bacteria or phenotypically POL⁺ revertants of the polA strains (selected on the basis of resistance to methyl methanesulphonate). It therefore appears that DNA polymerase I plays an important role in cellular recovery from PD treatment. E. coli carrying a mutation in the recA gene was also more sensitive to PD-treatment than its parent strain, as was S. typhimurium carrying a mutation of the recA type. In S. typhimurium the rec mutant was somewhat less sensitive to PD-killing than the pol mutant even although it is much more sensitive to ultraviolet killing. E. coli strains with mutations in the recB and recC genes were intermediate in PD sensitivity between the recA and the parent strain. S. typhimurium and E. coli bacteria with mutations in the polA and recA genes showed reduced ability to host-cell reactivate PD-damaged bacteriophages ES 18 and c1, indicating that the polA ⁺ and recA ⁺ gene products also contribute to repair of bacteriophages damaged by PD treatment. It is suggested that the recombinational repair process is less important for recovery from PD than for recovery from UV, and that the primary contribution of the rec genes to recovery from PD may be in repair of single-strand gaps by repair resynthesis.     

Nature of the SOS mutator activity: genetic characterization of untargeted mutagenesis in Escherichia coli

Summary In Escherichia coli, induction of the SOS functions by UV irradiation or by mutation in the recA gene promotes an SOS mutator activity which generates mutations in undamaged DNA. Activation of RecA protein by the recA730 mutation increases the level of spontaneous mutation in the bacterial DNA. The number of recA730-induced mutations is greatly increased in mismatch repair deficient strains in which replication errors are not corrected. This suggests that the majority of recA730-induced mutations (90%) arise through correctable, i.e. non-targeted, replication errors. This recA730 mutator effect is suppressed by a mutation in the umuC gene. We also found that dam recA730 double mutants are unstable, segregating clones that have lost the dam or the recA mutations or that have acquired a new mutation, probably in one of the genes involved in mismatch repair. We suggest that the genetic instability of the dam recA730 mutants is provoked by the high level of replication errors induced by the recA730 mutation, generating killing by coincident mismatch repair on the two unmethylated DNA strands. The recA730 mutation increases spontaneous mutagenesis of phage poorly. UV irradiation of recA730 host bacteria increases phage untargeted mutagenesis to the level observed in UV-irradiated recA ⁺ strains. This UV-induced mutator effect in recA730 mutants is not suppressed by a umuC mutation. Therefore UV and the recA730 mutation seem to induce different SOS mutator activities, both generating untargeted mutations.     

Modulation of allele leakiness and adaptive mutability inEscherichia coli

It is shown that partial phenotypic suppression of two ochre mutations (argE3 andlacZU118) and an amber mutation (inargE) by sublethal concentrations of streptomycin in anrpsL ⁺ (streptomycin-sensitive) derivative of theEscherichia coli strain AB1157 greatly enhances their adaptive mutability under selection. Streptomycin also increases adaptive mutability brought about by theppm mutation described earlier. Inactivation ofrecA affects neither phenotypic suppression by streptomycin nor replication-associated mutagenesis but abolishes adaptive mutagenesis. These results indicate a causal relationship between allele leakiness and adaptive mutability.     

Isolation and characterization of an operator-constitutive mutation in the recA gene of E. coli K-12

Summary The recA gene of E. coli is regulated by a specific repressor, the lexA protein, which binds to an operator in the recA regulatory region. We describe in this paper the isolation and characterization of a mutant thought to carry an operator-constitutive mutation in the recA gene. This mutation has the following properties: 1) It partially supresses the UV sensitivity of lexA ^– strains. 20 It maps near the recA gene. 3) It allows constitutive high-level synthesis of recA protein in both lexA ^– and lexA ⁺ backgrounds. 4) It allows constitutive synthesis of the recA messenger RNA. 5) It is cis–acting. The mutation does not restore induced cellular mutagenesis in a lexA ^– background. The expression of induced repair and mutagenesis of UV irradiated phage lambda or the regulation of the lexA gene is not affected by the presence of the mutation in either a lexA ⁺ or lexA ^– strain. These observations confirm other findings that high levels of recA protein synthesis per se is not sufficient for the expression of UV inducible functions and that the lexA protein represses other genes besides the recA gene.Abbreviations UV ultraviolet - Kd kilodalton - PAGE polyacrylamide gel electrophoresis     

Pathways for repair of DNA damaged by alkylating agent in Escherichia coli.

Summary A strain with both the polA12 and the alk-1 mutation is only slightly more sensitive to methyl methane sulfonate (MMS) than isogenic strains with only one of the mutations. On the other hand, alk-1 recA1 double mutant is much more sensitive to MMS than are strains carrying either one of alk or recA mutation. It was suggested that the alk and the polA gene products are involved in the same DNA repair process whereas the recA function is independent from the process. The yield of MMS-induced mutation (Arg^- (argE) to Arg⁺ reversion) in alk mutant is considerably higher than that in wild type strain. Thus, the repair process in which the alk gene product is involved is relatively accurate. When MMS-treated phages were plated on MMS-treated bacteria, there were considerable increases in survival of treated phage even in recA alk double mutant. It seems that a new repair pathway, which is specific for alkylating agent-induced damages and is not dependent on the RecA function, may be induced on exposure of bacteria to the alkylating agent.     

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.     

Influence of single-stranded DNA-binding protein on recA induction in Escherichia coli

Two ssb mutants of Escherichia coli, whic carry a lesion in the single-strand DNA-binding protein (SSB), are sensitive to UV-irradiation. We have investigated the influence of SSB on the “SOS” repair pathway by examining the levels of recA protein synthesis. These strains fail to induced normal levels of recA protein after treatment with nalidixic acid or ultraviolet light. The level of recA protein synthesis in wild-type cells is about three times greater than ssb cells. This deficiency in ssb mutants occurs in all strains and at all temperatures tested (30–41.5°). In contrast, the ssb-1 mutant has no effect on temperature-induced recA induction in a recA441 (tif-1) strain. Cells carrying ssb⁺ plasmids and overproducing normal DNA-binding protein surprisingly are moderated UV-sensitive and have reduced levels of recA protein synthesis. Together these results establish that single-strand DNA-binding protein is involved in the induction of recA, and accounts, at least in part, for the UV sensivitiy of ssb mutant. Three possible mechanisms to explain the role of SSB are discussed.     

Involvement of DNA polymerase III in UV-induced mutagenesis of bacteriophage lambda

Summary It has been proposed that the mutation fixation processes stimulated by SOS induction result from an induced infidelity of DNA replication (Radman 1974). The aim of this study was to determine if mutator mutations in the E. coli DNA polymerase III might affect UV-induced mutagenesis.Using a phage mutation assay which can discriminate between targeted and untargeted mutations, we show that the polC74 mutator mutation (Sevastopoulos and Glaser 1977) primarily affects untargeted mutagenesis, which occurs in a recA1 genetic background and is amplified in the recA ⁺ genetic background. The polC74 mutation also increases the UV-induced mutagenesis of the bacterial chromosome. These results suggest that DNA polymerase III is involved in the process of UV-induced mutagenesis in E. coli.     

Mutagenic DNA repair in Escherichia coli. VI. Gamma radiation mutagenesis in a tif-1 strain.

Summary In the non-filamenting tif-1 strain WP44_s NF trp a dramatic enhancement of both UV and gamma ray mutability to Trp⁺ was observed when irradiated bacteria were incubated on plates at 43°. This enhanced mutability was progressively suppressed when the initial plating density exceeded 10⁸ bacteria per plate and was not demonstrable in liquid media. Under optimal conditions more mutants were induced by gamma radiation than could reasonably be accounted for by the initial number of radiation-induced lesions in the DNA, implying the existence of some mechanism for amplifying the radiation effect. Moreover, the tif-enhanced mutation frequency could be obtained if incubation at restrictive temperature was delayed for up to 60 min in nutrient broth after irradiation, at a time when all known reparable DNA damage had been repaired and the number of viable bacteria had more than doubled. On plates the effect of high temperature was still fully demonstrable 120 min after irradiation. The results are hard to reconcile with the hypothesis that incubation of tif-1 bacteria at restrictive temperature causes the induction of a repair system acting on DNA damaged by gamma radiation. A more compatible interpretation would be that radiation causes a persisting physiological disturbance in the cell and that this enhances the spontaneous mutator effect occurring in tif-1 bacteria subjected to subsequent thermal shock.