Increased mutability by oxidative stress in OxyR-deficient Escherichia coli and Salmonella typhimurium cells: clonal occurrence of the mutants during growth on nonselective media

Escherichia coli and Salmonella typhimurium strains decifient in the OxyR-regulated adaptive response to oxidative stress were used to study the mode in which spontaneous SOS-dependent mutations are generated in a distressed bacterial population. When assayed on supplemented selective medium, the E. coli strain IC3821 (trpE65), carrying the ΔoxyR30 mutation and containing the plasmid pRW144 (mucA/B), showed a frequency of spontaneous Trp⁺ revertants similar to that of the oxyR⁺ control. Instead, the IC3821 strain exhibited an enhancement in the clonal occurrence of spontaneous revertants arising at random during growth on a nonselective medium. A similar enhancement was observed for the S. typhimurium strain TA4125 (hisG428 ΔoxyR2). The mutator effect observed in oxyR⁻ cells would be induced by an increased background of reactive oxygen species; it provides a model for studying the mutability of a cell population constantly exposed to mutation-inducing agents. In the IC3821 strain, revertants were induced by f-butyl hydroperoxide with higher efficiency than in oxyR⁺. We suggest that strain IC3821 could be useful for the detection of SOS-dependent mutagenesis induced by chemical oxidants.     

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     

Mutagenicity of glyceryl trinitrate (nitroglycerin) in Salmonella typhimurium

The recent finding that the clinical nitrovasodilator, glyceryl trinitrate (GTN), is mutagenic in Salmonella typhimurium strain TA1535 has been examined in closer detail, with emphasis on its mechanism of action. GTN increased the number of His⁺ revertants to a maximum of 4 times over background at a GTN dose of 5 μmol/plate. Hamster liver S9 depressed the toxicity of high GTN doses and increased the maximum number of revertants to 5 times over background at 10 μmol/plate. GTN did not cause significant reversion in any of the six other S. typhimurium strains tested (TA1975, TA102, TA1538, TA100, TA100NR, YG1026), although signs of toxicity were observed. Therefore, the mutagenicity of GTN was manifest only in the repair-deficient (uvrB and lacking in pKM101) strain which is responsive to single base changes. Oligonucleotide probe hybridization of TA1535 revertants showed that virtually all of the GTN-induced mutants contained C → T transitions in either the first or second base of the hisG46 (CCC) target codon, with a preference for the latter. A similar mutational spectrum was seen previously with a complex of spermine and nitric oxide (NO) which releases nitric oxide. This suggests that NO, which can be derived from GTN via metabolic reduction, may be responsible for GTN's mutagenic action. The known NO scavenger oxymyoglobin did not substantially alter the dose response of GTN, indicating that extracellular NO was not mediating reversion. The data are consistent with the hypothesis that intracellular nitric oxide is responsible for the observed mutations.     

Apparent antimutagenic effect of ultraviolet irradiation

Strain SL3367 is a S. typhimurium LT2 hisG46 stock which spontaneously reverts to His⁺ at a high frequency. Plates of defined medium with 1% (v/v) nutrient broth inoculated with ca. 10⁸ washed SL3367 cells were incubated, untreated or after UV irradiation. After 2 days at 37°C, an average of 165 His⁺ colonies were obtained per control plate but significantly fewer, 105 His⁺ colonies, on plates irradiated at a fluence of 7 J/m². The dry weight of bacteria in washings from plates incubated 14 h (by which time growth of His^? cells had ceased) was the same for irradiated and non-irradiated plates but the yield of colony-forming units from irradiated plates was less than from control plates, by about the same factor as the reduction in yield of His⁺ colonies caused by the same fluence. Washings from incubated irradiated plates, but not those from control plates, contained long filaments as well as bacteria of normal size; on transfer to nutrient-agar slide cultures cells normal size grew into microcolonies but filaments did not grow. The reduced plateau yield of viable His^? cells caused by consumption of much of the growth-limiting supply of histidine by irradiated cells growing into non-viable filaments reduces the number of auxotrophic bacteria at risk for spontaneous reversion and so accounts for the apparent antimutagenic effect of UV irradiation. This effect was partly reversed by the presence of d,l-pantoyl lactone in the selection medium, and was also observed for yield of Trp⁺ colonies from trpE8 cultures with a high spontaneous reversion rate. Treatments not inducing cell filamentation did not result in the depression of spontaneous revertants and were detected as being mutagenic. The apparent antimutagenic effect may be expected for reversion of any auxotroph, unless masked by induced revertants and is particularly apparent in an auxotroph which reverts spontaneously at high frequency.     

Role of post-replication and excision repair mechanism in the induction ofTrp + revenants of UV-irradiatedEscherichia coli

Both the post-replication and the excision repair mechanism participate in the induction ofTrp ⁺ revertants inEscherichia coli B/rHer ⁺ thy trp after a UV-irradiation. At low radiation doses (surviving cell fraction > 10^?) mostTrp ⁺ reversions are due to post-replication repair mechanism while at high doses (surviving cell fraction « 10^?1) theTrp ⁺ reversions arise probably as the result of an inaccurate excision repair. The absolute accuracy of repair processes decreases with increasing radiation dose.     

Frameshift mutagenesis by ultraviolet and gamma radiations in Salmonella: SOS inducibility and effects of DNA polymerase I

Ultraviolet (UV) and gamma-induced mutagenesis have been studied using a doubly auxotrophic strain of Salmonella typhimurium carrying the amber leuA150 mutation (which reverts by base-pair substitution) and the frameshift hisC3076 marker (which reverts by compensating frameshifts). In the initially constructed LT2 background, both markers were poorly revertible by UV and essentially non-revertible by gamma-radiation. A derivative of this strain carrying the mutation-enhancing plasmid pKM101 was however readily reverted by both UV and gamma, with either Leu+ (base substitution) or His+ (frameshift) revertants being observed on appropriate selective media. Photoreactivation experiments suggested that the lesions leading to formation of the two types of mutagenic event were similar if not identical. Support for this suggestion was obtained when it was found that yields of both types of UV-induced revertant were significantly increased in an excision-deficient background, while no revertants of either type were found in a recA background. Yields of gamma-induced revertants were not greatly altered in a uvrB background, but were also reduced to zero (for both markers) in the recA background. These results are consistent with what has previously been well-documented for UV and gamma-induced base-pair substitution mutagenesis, and serve to emphasize the similarities between base-pair substitution mutagenesis and frameshift mutagenesis by these agents. There are differences, however, since although UV-induced reversion of the leuA150 marker was little affected and gamma-induced reversion of leuA150 was somewhat reduced in the presence of a polA mutation (polA3), the yields of His+ frameshift revertants were significantly increased in the polA3 background following treatment with either UV or gamma. Thus while inducible DNA repair (SOS repair) appears to be involved in generating both types of mutational event following either UV- or gamma-irradiation, at some stage in the processing of premutational lesions the level (or type) of DNA polymerase I activity in the cell seems to have an important role in determining whether or not frameshifts or base-pair substitutions will be produced at a particular frequency.     

Mutational Specificity of Ultraviolet Light in ESCHERICHIA COLI with and without the R Plasmid Pkm101

Plasmid pKM101 provides UV protection and increases the frequency of spontaneous and UV-induced mutations in Escherichia coli. By analyzing reversion patterns of defined trpA alleles, we showed that pKM101 altered the mutational specificity of UV-induced mutations. Certain UV-induced base-pair substitutions were strongly enhanced, while others were decreased in frequency in the presence of pKM101. This result suggests an interaction between cellular misrepair and an error-prone repair function(s) provided by pKM101. We have also examined UV mutational specificity in the absence of pKM101 and found the following: (1) UV preferentially enhances missense, as well as nonsense, intergenic suppressor mutations; (2) UV causes all possible base-pair substitutions as well as frameshift mutations; (3) G·C base pairs are more susceptible to UV mutagenesis than A·T base pairs at the same nucleotide positions; and (4) UV-induced mutations can occur at nucleotide positions that are not part of pyrimidine-pyrimidine sequences.     

Modulation of mutagenesis involving precise excision of transposon Tn10

Precise excision of transposon Tn10 results in reversion of the Trp- phenotype to Trp+ in a trp-1014::Tn10 strain of Salmonella typhimurium, and also occurs at a markedly higher frequency in a strain carrying the temperature-sensitive polA7 allele. The frequency with which precise excision events occurs can be modified by the plating medium, results indicating that the great majority of mutants which arise on broth-supplemented or tryptophan-supplemented minimal media actually arise on the selective plating medium. Trp+ revertants (1000) arising from excision of Tn10 were purified by re-streaking for single colonies; none were found to retain the Tn10 encoded resistance to tetracycline. Yields of Trp+ revertants of the polA7 strain were consistently higher when glycerol rather than glucose was used as sole carbon source in the selective medium. Clean excision of Tn10 can also be increased by ultraviolet irradiation in (R) plasmid-free strains, and is further increased in strains carrying an N-group plasmid (R205, R46 or pKM101). Ultraviolet-induced precise excision of Tn10 also occurs at a much enhanced frequency in a strain with a deletion through the uvrB gene; in this case, however, the addition of plasmid pKM101 leads to a decrease in yields of ultraviolet-induced precise excision events.     

Simultaneous production of citric acid and invertase by Yarrowia lipolytica SUC+ transformants

Simultaneous production of citric acid (CA) and invertase by Yarrowia lipolytica A-101-B56-5 (SUC⁺ clone) growing from sucrose, mixture of glucose and fructose, glucose or glycerol was investigated. Among the tested substrates the highest concentration of CA was reached from glycerol (57.15 g/L) with high yield (Y_CA/S = 0.6 g/g). When sucrose was used, comparable amount of CA was secreted (45 g/L) with slightly higher yield (Y_CA/S = 0.643 g/g). In all cultures amount of isocitrate (ICA) was below 2% of total citrates. Considering invertase production, the best carbon source appeared to be sucrose (72 380 U/L). The highest yield of CA and invertase biosynthesis calculated for 1 g of biomass was obtained for cells growing from glycerol (9.9 g/g and 4325 U/g, respectively). Concentrates of extra- and intracellular invertase of the highest activity were obtained from sucrose as substrate (0.5 and 1.8 × 10⁶ U/L, respectively).     

The effect of extracellular metabolites on the frequency of thy+ revertants in Salmonella typhimurium populations

There is convincing evidence that adaptation and survival processes in bacterial populations depend on cell-to-cell interactions. Our studies showed that the frequency of stress-induced His⁺ reversions in an amino-acid-starved Salmonella typhimurium culture is inversely proportional to cell density in this culture. The effects of cell density and of different culture liquids prepared from cultures starved for histidine on the frequency of Thy⁺ revertants were also studied. It was found that the frequency of Thy⁺ revertants is inversely proportional (r = ?0.74) to the density of the bacterial culture starved of thymine. The culture liquid prepared from the culture starved of histidine exerted an inhibitory effect on the frequency of Thy⁺ reversions, indicating that mutations induced by different types of stress have a common mechanism. The study of the effect of the culture liquid prepared from a histidine-starved culture on the frequency of ethyl-methanesulfonate-induced His⁺ revertants showed that this liquid prevented the induction of His⁺ reversions.     

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.     

Regulation of the intracellular potassium concentration in Escherichia coli B 525

The mutant Escherichia coli B 525 requires histidine, leucine and methionine and an elevated extracellular K⁺ concentration for growth, and is unable to retain K⁺ tightly inside the cells when incubated in media supplemented with glucose, arabinose, galactose or lactose as the sole energy and carbon source. The loss of K⁺ from the cells of B 525 can be prevented by adding histidine and leucine, which react specifically and only in combination. In media supplemented with glycerol as the substrate, with glucose and NH₄⁺, or with glucose under anaerobic conditions, a stationary level of K⁺ inside the cells can be obtained without the addition of histidine-leucine.On the addition of ribose to glycerol-adapted cells of B 525 preincubated in glycerol media, the intracellular K⁺ decreased immediately and markedly. This decrease can be overcome by the addition of histidine-leucine.     

The gld1 + gene encoding glycerol dehydrogenase is required for glycerol metabolism in Schizosaccharomyces pombe

The budding yeast Saccharomyces cerevisiae is able to utilize glycerol as the sole carbon source via two pathways (glycerol 3-phosphate pathway and dihydroxyacetone [DHA] pathway). In contrast, the fission yeast Schizosaccharomyces pombe does not grow on media containing glycerol as the sole carbon source. However, in the presence of other carbon sources such as galactose and ethanol, S. pombe could assimilate glycerol and glycerol was preferentially utilized over ethanol and galactose. No equivalent of S. cerevisiae Gcy1/glycerol dehydrogenase has been identified in S. pombe. However, we identified a gene in S. pombe, SPAC13F5.03c (gld1 ⁺), that is homologous to bacterial glycerol dehydrogenase. Deletion of gld1 caused a reduction in glycerol dehydrogenase activity and prevented glycerol assimilation. The gld1Δ cells grew on 50 mM DHA as the sole carbon source, indicating that the glycerol dehydrogenase encoded by gld1 ⁺ is essential for glycerol assimilation in S. pombe. Strains of S. pombe deleted for dak1 ⁺ and dak2 ⁺ encoding DHA kinases could not grow on glycerol and showed sensitivity to a higher concentration of DHA. The dak1Δ strain showed a more severe reduction of growth on glycerol and DHA than the dak2Δ strain because the expression of dak1 ⁺ mRNA was higher than that of dak2 ⁺. In wild-type S. pombe, expression of the gld1 ⁺, dak1 ⁺, and dak2 ⁺ genes was repressed at a high concentration of glucose and was derepressed during glucose starvation. We found that gld1 ⁺ was regulated by glucose repression and that it was derepressed in scr1Δ and tup12Δ strains.     

Ethanol-inducible gene expression using gld1 + promoter in the fission yeast Schizosaccharomyces pombe

In the fission yeast Schizosaccharomyces pombe, the gld1 ⁺ gene encoding glycerol dehydrogenase is repressed by glucose and induced by ethanol and 1-propanol. The promoter region of gld1 ⁺ was cloned into a multicopy vector designated as pEG1 for evaluation as an ethanol-inducible expression vector using EGFP as a model heterologous protein. Expression of EGFP was repressed in the presence of high glucose and induced in the presence of ethanol, low-glucose, and 1-propanol in the absence of glucose. Addition of ethanol to cells harboring pEG1–EGFP was found to be the most effective means for inducing EGFP production. Protein yields were found to increase in proportion to ethanol concentration. As a further test of effectiveness, secreted recombinant human growth hormone was produced using the pEG1 expression vector in medium containing glycerol and ethanol. The pEG1 gene expression system is an effective tool for the production of heterologous proteins under glucose-limiting conditions, including medium containing glycerol as a carbon source.     

Expression of the plasmid pKM101-determined DNA repair system in recA? and lex? strains of Escherichia coli

Summary pKM101, a plasmid R factor of the N compatibility group increases methylmethane sulfonate mutagenesis and diminishes UV-killing in recA ⁺ lex ⁺ and recA ⁺ lex ^– strains, but not in recA ^– lex ⁺ strains. The induction of a reclex dependent colicin is not present in lex ^– strains carrying the pKM101 factor. These facts indicate that pKM101 acts through an error-prone DNA repair system, which is recA ⁺ dependent, but not lex ⁺ dependent.This paper is published on the occasion of Dr. C. Callerio's seventy-fifth birthday     

Elimination of plasmids pKM 101 and F'lac fromSalmonella typhimurium andEscherichia coli by bisammonium salt

Plasmid-curing activity of N,N′-bis(decyldimethyl)-1,6-hexanediammonium dibromide, BDHD, was tested on six different plasmids inE. coli and plasmid pKM 101 inS. typhimurium. BDHD eliminated theFlac plasmid fromE. coli cells only with a low efficiency. Plasmid pKM 101 was eliminated fromS. typhimurium cells significantly and this effect was dependent on an outer membrane pattern. A deep-rough mutant ofS. typhimurium is completely resistant to curing activity of BDHD, while part-rough and smooth cells are susceptible to it. In contrast to pKM 101, a cryptic plasmid being present inS. typhimurium cells was not eliminated by BDHD. The curing activity of sodium dodecyl sulfate, acridine orange, crystal violet, and promethazine was also affected by the outer membrane pattern ofS typhimurium cells.     

Spontaneous mutational specificity of drug resistance plasmid pKM101 in Escherichia coli.

Plasmid pKM101 enhances the frequency of spontaneous and ultraviolet light-induced mutations in Escherichia coli and protects the cells against the lethal effects of ultraviolet irradiation. By analyzing reversion patterns of defined trpA alleles, we showed that pKM101 caused all types of spontaneous base-pair substitution mutations with the possible exception of guanine . cytosine leads to adenine. thymine transitions. Neither insertion nor deletion frameshift mutations were enhanced. Transversions were more strongly enhanced than transitions, and adenine . thymine base pairs appeared more susceptible to pKM101 mutator activity than guanine . cytosine base pairs. In addition, there were effects from neighboring base pairs and genetic background that influenced the mutator activity of pKM101.