Effect of the plasmid ColIb-P9 on cellular processes related to DNA repair

Summary The plasmid ColIb-P9 introduced into Escherichia coli K12 umuC mutant cells suppresses the deficiencies in mutagenesis and repair of mutants after UV-irradiation. These data suggest that ColIb-P9 encodes a product with a function similar to that of the chromosomal gene umuC. Tn5 insertion mutants of ColIb-P9 were isolated with an altered ability to restore UV-mutagenesis in the umuC mutant. The same plasmid mutations were shown to eliminate the effects of ColIb-P9 on UV-mutagenesis, survival after UV and mitomycin C treatment, reactivation of UV-irradiated in unirradiated cells, Weigle-reactivation, induction of colicin E1 synthesis. The ColIb-P9 genes responsible for the enhancement of UV-mutagenesis were cloned within a 14 Md SalI fragment. Their location was established by restriction analysis of the mutant plasmid ColIb 6-13::Tn5.While the action of the plasmids ColIb-P9 and pKM101 is similar, these plasmids were shown to have opposite effects on cell survival and colicin E1 synthesis after mitomycin C treatment. A study of the mutant plasmids ColIb::Tn5 and pGW12 (muc ^- mutant of pKM101) has shown the difference in the effects of ColIb-P9 and pKM101 to be associated with the plasmid genes responsible for the protective and mutagenesis-enhancing effects of these plasmids in UV-irradiated cells.Abbreviations MC mitomycin C - ICS induction of colicin synthesis     

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     

Lysogenic induction of lambdoid phages in lexA mutants of Escherichia coli

Summary UV irradiation of lexA3 mutants of E. coli caused lysogenic induction of prophage , _i21, _i434 and 80. Maximal induction in lexA3 lysogens needed less UV than in lexA ⁺ bacteria and gave 25–100% of the normal levels of infective centres induced. Assays of gene expression arising from derepression of a defective prophage showed at least 40% of the normal levels of induction by mitomycin C in lexA3 bacteria. The need for post-irradiation protein synthesis for lysogenic induction in lexA3 lysogens was reduced by increasing the basal level of recA protein with a recA ⁺ plasmid. It is concluded that in lexA E. coli some recA protein synthesis, too small to be detected by physical means, is needed for UV induced lysogenic induction.     

Uvm mutants of Escherichia coli K12 deficient in UV mutagenesis

Summary Uvm mutants of Escherichia coli K12 selected for defective UV reversion induction have previously been reported to differ considerably from the UV-reversion-less recA and lexA mutants with regard to survival or mutagenic response to UV, X-rays and alkylating agents. In the present study, the phenotypic characterization of uvm mutants was extended to investigate several cellular processes which also may be related to or involved in UV mutagenesis. Like recA and lexA mutations, the uvm mutations exhibit highly reduced Weigle reactivation and normal host cell reactivation of UV irradiated phage . But unlike recA and lexA, the uvm mutations do not impair genetic recombination, UV induction of prophage or R plasmid-mediated UV resistance and mutagenesis. These phenotypical characteristics and preliminary results of genetic mapping lend further support to the assumption that the uvm site may be a novel locus affecting, apart from the recA and lexA loci, the error-prone repair pathway in E. coli.     

Indirect and intragenic suppression of the lexA102 mutation in E. coli B/r.

Summary In Escherichia coli B/r the expression of UV inducible (SOS) functions is under the control of the recA and lexA genes. In this study we have characterized mutants which are altered in their ability to express SOS functions. These mutants were isolated as UV resistant UV nonmutable (Rnm) derivatives of the lexA102 uvrA155 mutant strain WP51. The UV resistance of these Rnm strains is a result of the suppression of lexA102 mediated UV sensitivity. Genetic mapping of rnm mutations shows that the two predominant classes, rnmA and rnmB, map in or very near the lexA and recA genes respectively. rnmA mutations differ from rnmB with respectively recA protein synthesis. rnmA mutations do not restore the ability to express high levels of recA protein after UV treatment whereas rnmB mutations result in constitutive expression of high levels of recA protein. However, both rnmA and rnmB mutant strains inhibit postirradiation DNA degradation. This shows that in rnmA strains, high levels of recA protein are not needed to inhibit postirradiation DNA degradation.The genetic map location and constitutive expression of recA protein synthesis resulting from rnmB mutations suggests that they are operator constitutive mutations of the recA gene. The result that the lexA ⁺ gene is required for the expression of UV mutagenesis in rnmB mutants shows that high levels of recA protein do not circumvent the need for the lexA ⁺ gene product in this process. Thus, while the lexA gene product is required for the induction of recA protein synthesis, lexA must have an additional role in UV induced mutagenesis.     

Construction of a fused operon consisting of the recA and kan (Kanamycin resistance) genes and regulation of its expression by the lexA gene

Summary The kanamycin resistance gene (kan) of transposon Tn5 was cloned into a derivative of plasmid pBR322. A DNA fragment containing the promoter-operator region of the recA gene was inserted into the promoter region of the cloned kan gene to produce a fused operon, recA-kan. Plasmid pMCR685 carrying recA-kan expressed a low level of activity of the kan gene product (kanamycin phosphotransferase; KPT) in the wildtype cells of Escherichia coli, while the plasmid showed an increased level of the activity in the Spr^- mutant cells which produce the inactive lexA protein. The KPT activity in the wildtype cells harboring the plasmid increased 6-to 11-fold upon treatment of the cells with mitomycin C or nalidixic acid, both of which are known to induce synthesis of recA protein.Expression of the recA-kan operon fusion was remakably repressed by the lexA gene cloned into a plasmid carrying the operon fusion. Higher concentrations of mitomycin C were required for maximal induction of KPT activity in the cells harboring the resulting plasmid pMCR687. These results strongly suggest that the lexA gene product can by itself repress the recA gene, and that pMCR687 is a useful vector to clone genes whose expression is harmful to the host cell growth.     

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.     

Damage to DNA induces expression of the ruv gene of Escherichia coli

Summary Regulation of the ruv gene of E. coli was studied using phage Mud (Ap lac) to obtain a fusion of the lac genes to the ruv promoter. -galactosidase synthesis in the ruv-lac fusion strain was induced by mitomycin C and other agents that damage DNA. The induction of -galactosidase could be altered by mutations either in lexA or recA from which it is concluded that ruv is regulated by lexA repressor. A possible function of ruv in promoting cell recovery following damage to DNA is discussed.     

Isolation of conjugation-constitutive mutants of colicin factor Ib

Summary Colicin factor ColIb-P9 is known to act as a sex factor in E. coli or Salmonella. Although ColIb-P9 confers mating ability on its host bacteria, this ability appears to be repressed since only a small proportion of cells in a culture of a colicinogenic strain are able to pair with, and transmit the factor to recipient bacteria. We have isolated mutants of ColIb-P9 which confer constitutive donor ability on their host. De-repression in these mutants is probably due to failure to produce repressor, rather than to insensitivity to repressor. As the colicin production by the mutants is still repressed, colicin synthesis and conjugation ability are subject to independent systems of regulation.     

Influence of plasmids carrying the lexA gene on DNA repair and related processes in Escherichia coli K-12

Summary Plasmid pLC44-14 from the Clarke and Carbon collection has been shown to carry the lexA gene. The presence of lexA was demonstrated by complementation of tsl mutants which lie close to lexA on the E. coli K-12 linkage map and are probably in the lexA gene, and by crossing the dominant lexA mutation on to pLC44-14 to produce a recombinant plasmid, pSEl, which gave the host cell the properties of a lexA mutant. The lexA gene has been cloned on to pBR322 (Little, 1980). pJL21, which carries the lexA ⁺ gene, rendered the host cell moderately sensitive to UV light, greatly reduced the extent of Weigle reactivation and mutagenesis of UV-irradiated phage , and inhibited induction of protein X by either UV light or nalidixic acid. A similar plasmid carrying a mutant lexA3 allele produced extreme sensitivity to UV light, reduced recombinant production 10 to 50-fold following Hfr x F^– conjugation crosses, and otherwise mimicked the effects of pJL21. Introduction of an amber mutation into the lexA gene carried by the plasmid greatly reduced the UV-sensitivity of the host, thereby indicating that the extreme sensitivity was due to the mutant lexA gene product. These properties of strains with lexA plasmids are thought to originate from high levels of the lexA protein in the cell due to a large plasmid copy number. This protein, which appears from other studies to regulate negatively the recA gene, may inhibit expression of recA or other DNA repair genes when present in excess amounts in the cell.     

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.     

Restriction in vivo

Summary Degradation products of restricted T4 DNA induced filamentation, mutagenesis, and to a lesser extent, synthesis of recA protein in wild type cells but not in recA, lexA or recBC mutants of Escherichia coli. We conclude that the structural damage to the DNA caused by restriction cleavage and exonuclease V degradation can induce SOS functions. Degradation of restricted nonglucosylated T4 DNA by exonuclease V delayed cell division and induced filament formation and mutagenesis in lexA ⁺ but not in lexA ^- cells. Delay of cell division was also dependent upon recA and recBC funtions. Such degradation of DNA also dramatically increased mutagenesis in tif ^- Sfi^- cells at 42°C. The synthesis of recA protein continued in the restricting host after infection by the nonglucosylated T4 phage, but enhanced synthesis is not induced to the extent seen in SOS induced tif ^- cells grown at 42°. We also found that restriction of nonglucosylated T4 was alleviated in UV irradiated cells. The UV induced alleviation of rgl and r _K restriction depended upon post irradiation protein synthesis and was not observed in recA, lexA or recBC mutants.     

Expression of the dnaN and dnaQ genes of Escherichia coli is inducible by mitomycin C

Summary The dnaN and dnaQ genes encode the subunit and the subunit of the DNA polymerase III holoenzyme. Using translational fusions to lacZ we found that DNA damage caused by mitomycin C induces expression of the dnaA and dnaQ genes. This induction was not observed in lexA and recA mutants which block the induction of the SOS response, suggesting a relationship between the mechanism(s) of genetic control of DNA polymerase III holoenzyme and the SOS regulatory network. Nevertheless, there is evidence that the mitomycin C induction of dnaN and dnaQ is not a simple lexA-regulated process, because nalidixic acid (an excellent SOS inducer) does not increase dnaN and dnaQ gene expression, and the time course of induction is abnormally slow.     

Induction of phr gene expression by irradiation of ultraviolet light in Escherichia coli

Summary To measure the degree of phr gene induction by DNA-damaging agents, the promoter region was fused to the coding region of the lacZ gene in plasmid pMC1403. The new plasmids were introduced into Escherichia coli cells having different repair capabilities. More efficient induction of phr gene expression was detected in a uvrA ^– strain as compared with the wild-type strain. In addition, obvious induction was detected in uvrA ^– cells treated by 4-nitroquinoline 1-oxide and mitomycin C. Nalidixic acid, an inhibitor of DNA gyrase, also induced phr gene expression. In contrast, little induced gene expression was noted in UV-irradiated lexA ^– and recA ^– strains. It is suggested from these results that induction of the phr gene is one of the SOS responses. Possible nucleotide sequences which could be considered to constitute an SOS box were found at the regulator region of the phr gene.Abbreviations phr photoreactivation - UV ultraviolet light - 4NQO 4-nitroquinoline 1-oxide - MMC mitomycin C - PRE photoreactivating enzyme - E. coli Escherichia coli     

Induced radioresistance: An aspect of induced repair

Summary Irradiation of Escherichia coli cells with UV or X-rays followed by incubation under conditions in which protein synthesis can occur results in a population of cells that is resistant to X-rays; however, this resistance develops only if the cells are recA ⁺ and lexA ⁺, a fact that associates the phenomenon with induced (S.O.S.) repair. By observing separately the component of a culture that is resistant and the component that retains its normal growth, the fraction of induced and uninduced cells for a dose of UV or X-rays can be estimated. Such estimates show that the dose-response for UV induction of resistant cells agrees with that of the recA gene product. Thus induced radioresistance is considered to be due to the changes in the cell occasioned by the derepression of recA and lexA. These changes are expected to be involved with the synapsis of homologous genomes that is necessary for the use of a second genome to repair damage occurring in both strands of a duplex at the same base, as exemplified by a double-strand break or an interstrand crosslink. This consideration is additionally supported by the increased resistance of cells grown to contain multiple genomes in the same envelope, an increased resistance not found in recA ^- or lexA ^- cells. The condition of a completed chromosome is also resistant, again not in recA ^- or lexA ^- cells. We suggest that cell killing by X-rays is due to the double-strand breaks which are not repaired by molecular synapsis before the arrival of the replication polymerase at the break.     

Complementation of Bacteriophage Induction and Recombination Defects in <Emphasis Type="Italic">Escherichia coli</Emphasis> RecA<Superscript>−</Superscript> Mutants by Expression of the Cloned T4 Bacteriophage <Emphasis Type="Italic">uvsX</Emphasis> Gene

Previous workers reported that the T4 bacteriophage UvsX protein could promote neither RecA-LexA-mediated DNA repair nor induction of lysogenized bacteriophage, only recombination. Reexamination of these phenotypes demonstrated that, in contrast to these prior studies, when this gene was cloned into a medium but not a low-copy-number vector, it stimulated both a high frequency of spontaneous induction and mitomycin C-stimulated bacteriophage induction in a strain containing a recA13 mutation, but not a recA1 defect. The gene when cloned into a low- or medium- copy-number vector also promoted a low frequency of recombination of two duplicated genes in Escherichia coli in a strain with a complete recA gene deletion. These results suggest that a narrow concentration range of T4 UvsX protein is required to promote both high-frequency spontaneous and mitomycin C-stimulated bacteriophage induction in a recA13 gene mutant, but it facilitates recombination of duplicated genes at only a very low frequency in E. coli RecA⁻ mutants with a complete recA deletion. These results also suggest that the different UvsX phenotypes are affected differentially by the concentration of UvsX protein present. Received: 11 February 2002 / Accepted: 12 April 2002     

Induction of protein synthesis in Escherichia coli following UV- or gamma-irradiation, mitomycin C treatment or tif Expression.

Summary The rate of synthesis of total cellular proteins has been studied by pulse labelling cells at various periods after irradiation with UV or -rays, after treatment with mitomycin C (MMC) or after expression of the temperature sensitive mutation tif. Subsequent gel electrophoresis and autoradiography reveals changes in the rate of synthesis of several proteins. The most striking change is in a protein of molecular weight 40,000, protein X, which has been previously most extensively studied in cells treated with nalidixic acid (Gudas, 1976). Synthesis of large quantities of protein X is induced by UV, -rays, MMC treatment or tif expression in rec ⁺ but not recA cells. A feature of recA cells is that they break down their DNA excessively after irradiation or MMC treatment. However, if protein synthesis following irradiation is prohibited by chloramphenicol, post-irradiation degradation becomes excessive in recA ⁺ cells. This inverse relationship between DNA degradation and new protein synthesis is consistent with the hypothesis that an induced protein such as X is responsible for controlling DNA degradation following irradiation. Protein X is not induced in a lexB mutant following MMC treatment. In this respect the lexB mutant behaves like lexA and recA mutants in that the ability to induce protein X can be correlated with excessive DNA degradation.Studies on the induction of proteins in inf, tif and tif sfi mutants fail to reveal any correlation between induction of protein X and either the induction of prophage or septation.     

Damage and mutagenesis of E. coli and bacteriophage λ induced by oxathiolane and aziridinyl steroids

λ-Escherichia coli complexes exhibited remarkable sensitivity to the treatment with test steroidal derivatives in the presence of Cu(II). The decline in plaque-forming units after steroid treatment was more pronounced in complexes with some of the irradiation repair-defective mutants of E. coli K-12, i.e., recA, lexA and polA, as compared to uvrA and wild-type strains. The red gene of λ phage and recA gene of E. coli seem to have a complementary effect on the steroid-induced lesions. An enhanced level of mutagenesis was observed when steroid-treated E. coli cells were transformed with steroid-treated pBR322 plasmid DNA. A remarkable degree of c mutation was also observed when steroid I-treated phage particles were allowed to adsorb on steroid-treated wild-type bacteria. Moreover, the oxathione steroid treatment of λcI857-E. coli lysogen resulted in prophage induction in nutrient broth even at 32°C. Thus on the basis of these results, the role of SOS repair system in steroid-induced mutagenesis and repair of DNA lesions in E. coli and bacteriophage λ has been suggested.     

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 Colicin Production by High Temperature or Inhibition of Protein Synthesis

Escherichia coli K-12 colicinogenic for ColE1 yielded mutants that appeared to produce colicin at 43 C but not at 30 or 37. These mutants proved to have the mutation recA⁻ Further study revealed that both recA⁻ and recA⁺ bacteria, when carrying ColE1 or ColE2, produce more colicin during growth at higher temperatures or after brief exposure to temperatures beyond the growth range. Counts of lacunae demonstrated that the increase of colicin production is due to an increase in the number of cells that yield colicin. Heat treatment causes lacunae to increase by the same factor in recA⁺ and recA⁻ cells, although recA⁻ bacteria produce 500 times fewer lacunae than recA⁺. Inhibition of protein synthesis, notably by chloramphenicol, also induces colicin production in as much as 90% of the cells after removal of inhibition (to permit colicin synthesis). Induction of colicin production by chloramphenicol requires that ribonucleic acid synthesis continue during the period of inhibition. These results are discussed in relation to the regulation of colicin production.