Cellular determinants of the mutational specificity of 1-nitroso-6-nitropyrene and 1-nitroso-8-nitropyrene in the lacI gene of Escherichia coli.

We have characterized 202 lacI⁻ mutations, and 158 dominant lacI^−d mutations following treatment of Escherichia coli strains NR6112 and EE125 with 1-nitroso-6-nitropyrene (1,6-NONP), an activated metabolite of the carcinogen 1,6-dinitropyrene. In all, 91% of the induced point mutations occurred at G:C residues. The −(G:C) frameshifts were the dominant mutational class in the lacI⁻ collections of both NR6112 and EE125, and in the lacI^−d collection of NR6112. Frameshift mutations occurred preferentially in runs of guanine residues, and their frequency increased with the length of the reiterated sequence. In strain EE125, which contained the plasmid pKM101, there was a marked stimulation in the frequency of base substitution mutations that was particularly apparent in the lacI^−d collection. This study completes a comprehensive analysis of 1194 lacI⁻ and 348 lacI^−d mutations induced by either 1,6-NONP or its positional isomer 1-nitroso-8-nitropyrene (1,8-NONP) in strains of E. coli that differ with regard to their ability to carry out nucleotide excision repair and/or their ability to express the translesion synthesis DNA polymerase RI (MucAB) encoded by plasmid pKM101. Among the mutations are 763 frameshift mutations, 367 base substitutions and 47 deletions; these mutations have been characterized at more than 300 distinct sites in the lacI gene. Our studies provide detailed insight into the DNA sequence alterations and mutational mechanisms associated with dinitropyrene mutagenesis. We review the mutational spectra, and discuss cellular lesion repair or tolerance mechanisms that modulate the observed mutational specificity.     

LexA-independent expression of a mutant mucAB operon.

pKM101 is a naturally occurring plasmid that carries mucAB, an analog of the umuDC operon, the gene products of which are required for the SOS-dependent processing of damaged DNA necessary for most mutagenesis. Genetic studies have indicated that mucAB expression is controlled by the SOS regulatory circuit, with LexA acting as a direct repressor. pGW16 is a pKM101 derivative obtained by N-methyl-N'-nitro-N-nitrosoguanidine mutagenesis that was originally identified on the basis of its ability to cause a modest increase in spontaneous mutation rate. In this report, we show that pGW16 differs from pKM101 in being able to enhance methyl methanesulfonate mutagenesis and to confer substantial resistance to UV killing in a lexA3 host. The mutation carried by pGW16 is dominant and was localized to a 2.4-kb region of pGW16 that includes the mucAB coding region and approximately 0.6 kb of the 5'-flanking region. We determined the sequence of a 119-bp fragment containing the region upstream of mucAB and identified a single-base-pair change in that region, a G.C-to-A.T transition that alters a sequence homologous to known LexA-binding sites. DNA gel shift experiments indicate that LexA protein binds poorly to a 125-bp fragment containing this mutation, whereas a fragment containing the wild-type sequence is efficiently bound by LexA. This mutation also alters an overlapping sequence that is homologous to the -10 region of Escherichia coli promoters, moving it closer to the consensus sequence. The observation that the synthesis of pGW16-encoded mucAB proteins in maxicells is increased relative to that of pKM101-encoded mucAB proteins even in the absence of a lexA+ plasmid suggests that this mutation also increases the activity of the mucAB promoter.     

An alteration leading to loss of ability to support phleomycin mutagenesis in the pKM101-derived plasmid pGW16 is located in or close to the mucAB genes

The differences between the plasmid pKM101 and its derivative pGW16, which has lost the ability to support muc-dependent phleomycin mutagenesis, while retaining other muc-dependent phenotypes, have been further investigated. Deletion derivatives which retain only 10.8 kb (approximately one third) of the pKM101 genome but retain the muc genes have been constructed from both pKM101 and pGW16. The deletion derivatives confer protection and mutagenesis-enhancing properties similar to those of their respective parents, indicating that the lesion in the mutant plasmid pGW16 lies in or close to the muc genes. Differences in the muc-dependent phenotypes of strains containing pKM101 or pGW16 suggest that the pGW16 lesion results in either differential loss of function in the muc gene products, or constitutive expression of the muc gene products.     

New mutations in cloned Escherichia coli umuDC genes: novel phenotypes of strains carrying a umuC125 plasmid

The umuDC locus of Escherichia coli is required for most mutagenesis by UV and many chemicals. Mutations in E. coli umuDC genes cloned on pBR322-derived plasmids wer e isolated by two methods. First, spontaneously-arising mutant umuDC plasmids that failed to confe cold-sensitive growth on a lexA51(Def) strain were isolated by selection. Second, mutant umuDC plasmids that affected apparent mutant yield after UV-irradiation in a strain carrying umuD⁺C⁺ in the chromosome were isolated by screening hydroxylamine-mutagenized umuD⁺C⁺ plasmids. pBR322-derived umuD⁺C⁺ plasmids inhibited the induction of the SOS response of lexA⁺ strains as measured by expression of din::Mu dl(lac) Ap) fusionsbut most mutant plasmids did not. Mutant plasmids defective in complementation of chromosomal umuD44, umuC36, or both were found among those selected for failure to confer cold-sensitivity, whereas those identified by the screening procedure yielded mostly mutant plasmids with more complex phenotypes. We studied in greater detail a plasmid pLM109, carrying the umuC125 mutation. This plasmid increased the sensitivity of lexA⁺ strainsto killing by UV-irradiation but was able to complement the deficiencies of umuC mutants in UV mutagenesis. pLM109 failed to confer cold-sensitive growth on lexA(Def) strains but inhibited SOS induction in lexA⁺ strains. The effect of pLM109 on the UV sensitivity of lexA(Def)strains was similar to that of the parental umuD⁺C⁺ plasmid. The mutation responsible for the phenotypes of pLM109 was localized to a 615-bp fragment. DNA sequencing revealed that the umuC125 mutation was a G:C → A:T transition that changed codon 39 of umuC from GCC → GTC thus changing Ala39 to Val39. The implications of the umuC125 mutation for umuDC-dependent effects on UV-mutagenesis and cell survival after UV damage are discussed.     

Mutagenesis and carcinogenesis in nucleotide excision repair-deficient XPA knock out mice

Mice with a defect in the xeroderma pigmentosum group A (XPA) gene have a complete deficiency in nucleotide excision repair (NER). As such, these mice mimic the human XP phenotype in that they have a >1000-fold higher risk of developing UV-induced skin cancer. Besides being UV-sensitive, XPA^−/− mice also develop internal tumors when they are exposed to chemical carcinogens. To investigate the effect of a total NER deficiency on the induction of gene mutations and tumor development, we crossed XPA^−/− mice with transgenic lacZ/pUR288 mutation-indicator mice. The mice were treated with various agents and chemicals like UV-B, benzo[a]pyrene and 2-aceto-amino-fluorene. Gene mutation induction in several tumor target- and non-target tissues was determined in both the bacterial lacZ reporter gene and in the endogenous Hprt gene. Furthermore, alterations in the p53- and ras genes were determined in UV-induced skin tumors of XPA^−/− mice. In this work, we review these results and discuss the applicability and reliability of enhanced gene mutant frequencies as early indicators of tumorigenesis.     

Influence of DNA repair on mutation spectra in Salmonella

This paper reviews the influence of DNA repair on spontaneous and mutagen-induced mutation spectra at the base-substitution (hisG46) and -1 frameshift (hisD3052) alleles present in strains of the Salmonella (Ames) mutagenicity assay. At the frameshift allele (mostly a CGCGCGCG target), ΔuvrB influences the frequency of spontaneous hotspot mutations (−CG), duplications, and deletions, and it also shifts the sites of deletions and duplications. Cells with pKM101+ΔuvrB spontaneously produce complex frameshifts (frameshifts with an adjacent base substitution). The spontaneous frequency of 1-base insertions or concerted (templated) mutations is unaffected by DNA repair, and neither mutation is inducible by mutagens. Glu-P-1, 1-nitropyrene (1NP), and 2-acetylaminofluorene (2AAF) induce only hotspot mutations and are unaffected by pKM101, whereas benzo(a)pyrene and 4-aminobiphenyl induce only hotspot in pKM101⁻, and hotspot plus complex in pKM101⁺. At the base-substitution allele (mostly a CC/GG target), the ΔuvrB allele increases spontaneous transitions in the absence of pKM101 and increases transversions in its presence. The frequency of suppressor mutations is decreased 4× by ΔuvrB, but increased 7.5× by pKM101. Both repair factors cause a shift in the proportion of mutations to the second position of the CC/GG target. With UV light and γ-rays, the ΔuvrB allele increases the proportion of transitions relative to transversions. pKM101 is required for mutagenesis by Glu-P-1 and 4-AB, and the types and positions of the substitutions are not altered by the addition of the ΔuvrB allele. Changes in DNA repair appear to cause more changes in spontaneous than in mutagen-induced mutation spectra at both alleles. There is a high correlation (r²=0.8) between a mutagen's ability to induce complex frameshifts and its relative base-substitution/frameshift mutagenic potency. A mutagen induces the same primary class of base substitution in TA100 (ΔuvrB, pKM101) as it does in Escherichia coli, mammalian cells, or rodents as well as in the p53 gene of human tumors associated with exposure to that mutagen. Thus, a mutagen induces the same primary class of base substitution in most organisms, reflecting the conserved nature of DNA replication and repair processes.     

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.     

Effect of plasmid pKM101 in ultraviolet irradiated uvr+ and uvr- Escherichia coli.

The effect of plasmid pKM101 on UV irradiated excision proficient and excision deficient cells was investigated. The plasmid increased the survival of excision proficient cells while partially inhibiting thymine dimer excision. The frequency of mutations was almost unchanged. In excision deficient cells the effect of the plasmid on survival was less pronounced while cell mutability was increased. Our data indicate that the mucAB genes (carried by the plasmid) influence the two types of cells in a different way.     

Psoralen photomutagenic specificity in Salmonella typhimurium

The cytotoxic and mutagenic specificity of two therapeutically employed psoralens was examined in several Ames Salmonella typhimurium strains with near ultraviolet light (UVA, 320–400 nm) activation. Photomutagenic activity of 8-methoxypsoralen (8MOP) and 4,5′,8-trimethylpsoralen (TMP) was found to be sequence-specific, and additionally was dependent on the level of DNA-repair proficiency. Base-pair substitution photomutagenesis in hisG46 appeared to require plasmid pKM101-mediated “error-prone” repair. Frameshift photomutagenesis was observed in all hisC3076 strains but not in hisD3052 strains. Frameshift mutagenic activity in hisC3076 was enhanced in the absence of uvrB excision repair and increased further by plasmid pKM101. Phototoxicity was essentially identical in hisC3076, hisD3052 and hisG46 strains; uvrB⁻ excision-repair-deficient bacteria were considerably more susceptible to lethal effects than wild-type parental strains, while the presence of pKM101 had no apparent effect on survival. Finally, the data show that psoralens are potent frameshift photomutagens in Salmonella hisC3076 strains and demonstrate the potential utility of these strains in evaluating photomutagenic and phototoxic activity of new furocoumarin derivatives.     

An Escherichia coli plasmid-based, mutational system in which supF mutants are selectable: insertion elements dominate the spontaneous spectra.

A new system is described to determine the mutational spectra of mutagens and carcinogens in Escherichia coli; data on a limited number (142) of spontaneous mutants is presented. The mutational assay employs a method to select (rather than screen) for mutations in a supF target gene carried on a plasmid. The E. coli host cells (ES87) are lacI⁻ (am26), and carry the lacZΔM15 marker for -complementation in β-galactosidase. When these cells also carry a plasmid, such as pUB3, which contains a wild-type copy of supF and lacZ-, the lactose operon is repressed (off). Furthermore, supF suppression of lacl^um26 results in a lactose repressor that has an uninducible, lacl^S genotype, which makes the cells unable to grow on lactose minimal plates. In contrast, spontaneous or mutagen-induced supF⁻ mutations in pUB3 prevent suppresion of lacl^am26 and result in constitutive expression of the lactose operon, which permits growth on lactose minimal plates. The spontaneous mutation frequency in the supF gene is 0.7 and 1.0 × 10⁻⁶ without and with SOS induction, respectively. Spontaneous mutations are dominated by large insertions (67% in SOS-uninduced and 56% in SOS-induced cells), and their frequency of appearance is largely unaffected by SOS induction. These are identified by DNA sequencing to be Insertion Element: IS1 dominates, but IS4, IS5, gamma-delta and IS10 are also obtained. Large deletions also contribute significantly (19% and 15% for - SOS and +SOS, respectively), where a specific deletion between a 10 base pair direct repeat dominates; the frequency of appearance of these mutations also appears to be unaffected by SOS induction. In contrast, SOS induction increases base pairing mutations (13% and 27% for -SOS and +SOS, respectively), The ES87/pUB3 system has many advantages for determining mutational spectra, including the fact that mutant isolation is fast and simple, and the determination of mutational changes is rapid because of the small size of supF.     

Plasmid pKM101-dependent repair and mutagenesis in Escherichia coli cells with mutations lexB30 tif and zab-53 in the recA gene

Bacterial survival after UV irradiation was increased in E. coli K12 lexB30 and tif zab-53 mutants harboring plasmid pKM101. Mutagenesis in response to UV was observed in these bacteria which, in absence of pKM101, are not UV-mutable. The mutator effect observed in unirradiated wild-type cells containing pKM101 was higher after incubation at 30°C with adenine than at 37°C. This effect was still enhanced by tif mutation, even in the tif zab-53 strain, but it was abolished by lexB30 mutation. In the tif zab-53 (pKM101) strain, repair and mutagenesis of UV-irradiated phage λ was observed, but not in the lexB30 mutant carrying pKM101. The pKM101 mutant, pGW1, was unable to protect tif zab-53 bacteria against killing by UV, whereas the protection of lexB30 was intermediate; moreover, it did not promote the mutator effect at 30°C or enhance phage repair and mutagenesis in tif zab-53 cells. All UV-induced bacterial mutations in lexB30 (pKM101) strain were suppressors; in contrast, true revertants were found after UV irradiation of the tif zab-53 (pKM101) cells.We suggest that the constitutive activity of RecA protein is enough for the production of UV-promoted suppressor mutations, whereas true reversions require a more active form of this protein which could exert its effects directly or by acting at a regulatory level on other cellular functions.     

Plasmid pGW16, a derivative of pKM101, increases post-UV DNA synthesis, but sensitises some strains of Escherichia coli to UV

Plasmid pKM101, which carries muc genes that are analogous in function to chromosomal umu genes, protected Escherichia coli strains AB1157 uvrB+ umuC+, JC3890 uvrB umuC+, TK702 uvrB+ umuC and TK501 uvrB umuC against ultraviolet irradiation (UV). Plasmid pGW16, a derivative of pKM101 selected for its increased spontaneous mutator effect, also gave some protection to the UmuC-deficient strains, TK702 and TK501. However, it sensitised the wild-type strain AB1157 to low, but protected against high doses of UV, whilst sensitising strain JC3890 to all UV doses tested. Even though its UV-protecting effects varied, pGW16 was shown to increase both spontaneous and UV-induced mutation in all strains. Another derivative of pKM101, plasmid pGW12, was shown to have lost all spontaneous and UV-induced mutator effects and did not affect post-UV survival. Plasmids pKM101 and pGW16 increased post-UV DNA synthesis in strains AB1157 and TK702, whereas pGW12 had no effect. Similarly, the wild-type UV-protecting plasmids R46, R446b and R124 increased post-UV DNA synthesis in strain TK501, but the non-UV-protecting plasmids R1, RP4 and R6K had no effect. These results accord with the model for error-prone DNA repair that requires umu or muc gene products for chain elongation after base insertion opposite non-coding lesions. They also suggest that the UV-sensitizing effects of pGW16 on umu+ strains can be explained in terms of overactive DNA repair resulting in lethal, rather than repaired UV-induced lesions.     

The two-step model of bacterial UV mutagenesis

Recent results are discussed which have led to a two-step model for UV mutagenesis in excision-deficient Escherichia coli. After exposure to UV, the replication fork is assumed to continue until immediately before certain photoproducts where it stops and leaves a gap which cannot be dealt with by recombination repair. In the first (misincorporation) step, bases (a proportion of which are ‘wrong’) are postulated to be inserted opposite the photoproduct under the direct influence of the recA gene product. These misincorporated bases can be revealed as mutations by delayed photoreversal in umuD, C and lexA (ind⁻) bacteria. Their level is determined by the particular allele of recA that is present (recA441 > recA⁺ > recA430) and their rate of formation by the amount of recA protein in the cell and the degree of enrichment of the medium. No other protein needs to be synthesized for this step to occur. The second (bypass) step requires induced levels of the products of the umuD and C genes which are postulated to facilitate continued DNA synthesis on the priming end opposite the photoproduct. In principle, further errors could be made at this stage which might appear as ‘hitch-hiking’ rather than ‘targeted’ mutations.     

The muc+ gene of plasmid pKM101 prevents respiration shutoff in far ultraviolet-irradiated Salmonella typhimurium

Summary The plasmid pKM101 is known to protect Escherichia coli and Salmonella typhimurium against killing by far UV irradiation and to enhance UV-induced mutagenesis. The muc ⁺ gene of the plasmid is responsible for both of these effects. This paper shows that respiration of S. typhimurium shuts off about an hour after UV irradiation and that pKM101 prevents the shutoff. Plasmids which contained Tn5 translocatable elements, either in (and having produced a muc mutation) or flanking the muc ⁺ gene, have been introduced into S. typhimurium. The muc mutant plasmid, which does not protect its host against UV killing and does not enhance UV induced mutagenesis, also does not protect against UV induced respiration shutoff. Like-wise, plasmids in which the Tn5 translocatable elements flank the nuc ⁺ gene protect against shutoff of respiration. Thus the muc ⁺ gene of pKM101 is responsible for protection against UV induced shutoff of respiration in S. typhimurium.Research sponsored by the Office of Health and Environmental Research, U.S. Department of Energy, under contract W-7405-eng-26 with the Union Carbide Corporation and by the National Science Foundation under grant No. PCM 7908647 with the University of Tennessee, Knoxville     

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     

Effect of phenylacetic acid on the growth and production of penicillin G acylase of recombinant and host strains derived from Escherichia coli W

The industrial production strain Escherichia coli RE3(pKA18) for penicillin G acylase (PGA) bears simultaneously the pga gene on the chromosome as an inducible gene pgaⁱ, (the inductor is phenylacetic acid, PAA) and on the recombinant plasmid pKA18 as a constitutively expressed gene pga^c. Under non-selective conditions, plasmid-less strains (P⁻) appeared in 17th successive batch culture. However, the population was over taken by P⁻ cells already in fourth culture if the medium was supplemented with PAA. The rate of plasmid loss from the culture depends on the PAA concentration and on the expression of pgaⁱ, not on PGA overproduction from pga^c. PAA at inducing concentration has a negative effect on PGA expression and plasmid stability in the high-expression self-cloning system RE3(pKA18) which results in the reduction of: (1) the specific growth rate of a culture and biomass concentration, (2) the synthesis of PGA (e.g. the specific activity of the strain) and (3) the copy number of the recombinant plasmid and promotion of the plasmid loss from the culture. Segregational stability of pKA18 increases in P⁺ persisting clones and in re-transformed P⁻ clones segregated during the selection in the presence of PAA.     

Isolation and characterization of mutants of the plasmid pKM101 deficient in their ability to enhance mutagenesis and repair.

A screening procedure was developed for identifying mutants of the plasmid pKM101 no longer capable of enhancing mutagenesis. The test was based on the large pKM101-mediated increase in the number of Gal+ papillae observed on colonies of Salmonella typhimurium gal mutants plated on tetrazolium-galactose plates in the presence of a mutagen. The pKM101 mutant plasmids transferred normally, were stably maintained in cells, caused normal levels of ampicillin resistance, and still imparted sensitivity to phage Ike to their hosts. However, the pKM101 mutants had lost the ability to (i) enhance the reversion of both point and frameshift mutations, (ii) protect the cells against killing by UV irradiation, (iii) increase the spontaneous reversion rates of point mutations, (iv) enhance plasmid-mediated reactivation of UV-irradiated phage P22, (v) enhance Weigle reactivation. One pKM101 mutant with different properties from the others was identified by its increased spontaneous mutator effect. It is suggested that pKM101 amplifies the activity of the inducible error-prone repair systems in bacteria and that this is the function of pKM101 in the Ames Salmonella tester strains used for detection of carcinogens as mutagens.     

Physical mapping of the plasmid R205 and identification of a site responsible for increased UV-induced mutability of the bacterial host

A physical map of the conjugative IncN plasmid R205 (56.1 kb) was constructed. The distribution of cleavage sites for investigated restriction enzymes is asymmetric. It was found that R205 suppresses the mutant phenotype of E. coli K12 umuC or umuD strains deficient in UV-induced mutagenesis. A mini-derivative of R205, designated pMU4 (15.1 kb) preserves the ability of the parent plasmid to increase the survival and induced mutagenesis of UV-irradiated host cells. A region of R205 located between 0 and 2.0 kb-on the plasmid map seems to contain information necessary for complementation of mutation in the host genes umuD/C, Hybridization between this region of pMU4 and plasmid pGW1700 bearing mucAB genes of pKM101 was observed.     

Isolation of plasmid pKM101 in the Stocker laboratory

pKM101 is a mutagenesis-enhancing resistance transfer plasmid (R plasmid) that was introduced into several tester strains used in the Salmonella/microsome mutation assay (Ames test). Plasmid pKM101 has contributed substantially to the effectiveness of the Ames assay, which is used on a world-wide basis to detect mutagens and is required by many government regulatory agencies for approval to market new drugs and other chemical agents. Widely used since 1975, the Ames test is still regarded as one of the most sensitive genetic toxicity assays and a useful short-term test for predicting carcinogenicity in animals. Plasmid pKM101, which is a deletion derivative of plasmid R46 (also referred to as R-Brighton after its origin of isolation in Brighton, England), has also been used to elucidate molecular mechanisms of mutagenesis. It was isolated in the laboratory of Professor Bruce A.D. Stocker at Stanford University as part of my doctoral research with 20 R plasmids. Professor Stocker's phenomenal insight into the genetics of Salmonella typhimurium and plasmid behavior was a major factor that led to the isolation of pKM101. This paper includes a tribute to Bruce Stocker, together with a summary of my research with mutagenesis-enhancing R plasmids and a brief discussion of the molecular mechanisms involved in pKM101 plasmid-mediated bacterial mutagenesis.     

Repair promoted by plasmid pKM101 is different from SOS repair.

In E. coli K12 bacteria carrying plasmid pKM101, prophage lambda was induced at UV doses higher than in plasmid-less parental bacteria. UV-induced reactivation per se was less effective. Bacteria with pKM101 showed no alteration in their division cycle. Plasmid pKM101 coded for a constitutive error-prone repair different from the inducible error-prone repair called SOS repair. Plasmid pKM101 protected E. coli bacteria from UV damage but slightly sensitized them to X-ray lesions. Protection against UV damage was effective in mutant bacteria deficient in DNA excision-repair provided that the recA, lexA and uvrE genes were functional. Survival of phages lambda and S13 after UV irradiation was enhanced in bacteria carrying plasmid pKM101; phage lambda mutagenesis was also increased. Plasmid pKM101 repaired potentially lethal DNA lesions, although wild-type DNA sequences may not necessarily be restored; hence the mutations observed are the traces of the original DNA lesions.