Properties of Mitomycin C-sensitive Mutants of Escherichia coli K-12

Strains hypersensitive to mitomycin C (MC) were isolated from Escherichia coli K-12 after treatment with nitrosoguanidine. Of 43 MC-sensitive strains tested for their ultraviolet light (UV) sensitivity and for their ability to reactivate UV-inactivated λ phage, 38 were found to be insensitive to UV irradiation and to be able to reactivate UV-irradiated bacteriophage λ. Some properties of the MC-sensitive, uvr⁺ mutants were analyzed. Synthesis of deoxyribonucleic acid (DNA) in MC-sensitive, uvr⁺ mutants was inhibited at a lower concentration of MC than in the wild-type strain. Mutant cells, labeled with ³H-thymidine and then exposed to MC, released radioactivity as low molecular weight compounds. The amount of radioactivity released was the same as that from the wild-type strain. MC-sensitive, uvr⁺ mutants, as well as the corresponding wild-type strain, were equally susceptible to induction of prophage 80 by UV irradiation. However, MC induction of prophage was achieved in MC-sensitive, uvr⁺ mutants at a lower concentration of the antibiotic than in the wild-type strain. Genetic experiments indicated that a gene controlling MC sensitivity is located close to that determining lactose fermentation of E. coli. It is situated on episome F′13, and the wild type is dominant to the MC-sensitive allele.     

The action of nitrosoguanidine and other DNA-inactivating agents on Streptococcus pyogenes K56 strains with normal and reduced dark repair ability

Summary The response pattern for ultraviolet light, nitrogen mustard, and ethyl methane sulphonate of Hcr⁺ and Hcr^- strains ofStreptococcus pyogenes K 56 is similar to that observed for analogous strains ofE. coli, whereas repair-apt streptococcal strains are much more sensitive to nitrosoguanidine and mitomycin C thanE. coli. Theuvr gene(s) appear(s) to be without effect upon survival, prophage induction, and mutation to streptomycin resistance caused by nitrosoguanidine and only of little influence on repair of mitomycin C damage.     

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.     

Studies on radiation-sensitive mutants of E. coli. II. Breakage and repair of ultraviolet irradiated intracellular DNA of phage lambda

Summary It has been shown that linear DNA molecules of phage are converted to the twisted circular structure (species I) by covalent closure of the both strands at the cohesive ends after infection to the immune bacteria and that the twisted circular molecules are transformed to the circular form (species II) by a single-strand break in one of the strands of their DNA. This system offers a very sensitive method to study on the strand breaks or their repair. For characterization of the defects of ultraviolet sensitive strains, the structural changes of ultraviolet irradiated DNA in these strains were studied.Ultraviolet irradiation to phage greatly reduced the extent of conversion of the molecules to the species I in the uvrD mutant while the irradiation showed little effect on the conversion in the uvrA, B and C mutants. When infected bacteria carrying species I molecules were irradiated, the species I molecules in the uvrD mutant were disrupted while most of the molecules in the uvrA, B and C mutants kept the structure. These results indicate that in the irradiated DNA strand breaks are rarely introduced or, if introduced, repaired rapidly in the uvrA, B and C mutants and they are introduced in the uvrD mutant leading to the degradation of the DNA. These results provide a firm evidence that the defect of the uvrD mutant is different from other Her^- mutants and in the process of repair synthesis.Ultraviolet irradiation to the uvrD mutants promote the formation of the species I molecules from the infected irradiated -DNA.Such effect was not observed with the uvrA mutant. Since the uvrD mutant has UV reactivation capacity and the uvrA mutant has not, the above phenomenon is probably caused by UV reactivation and may provide a more direct method to study the mechanisms of UV reactivation than the plaque assay.Abbreviations used UV Ultraviolet light - UVr Ultraviolet light reactivation This work was aided in part by a research grant GM 08384 from the United States Public Health Service.     

DNA sequence changes in mutations induced by ultraviolet light in the gpt gene on the chromosome of Escherichia coli uvr+ and urvA cells

Summary Sequence changes in mutations induced by ultraviolet light are reported for the chromosomal Escherichia coli gpt gene in almost isogenic E. coli uvr ⁺ and excision-deficient uvrA cells. Differences between the mutagenic spectra are ascribed to preferential removal of photoproducts in the transcribed strand by excision repair in uvr ⁺ cells. This conclusion is confirmed by analysis of published results for genes in both uvr ⁺ and uvr ^– cells, showing a similar selective removal of mutagenic products from the transcribed strand of the E. coli lacI gene and of the lambda phage cl repressor gene. Comparison of these data with published results for ultraviolet mutagenesis of gpt on a chromosome in Chinese hamster ovary cells showed that a mutagenic hot spot in mammalian cells is not present in E. coli; the possibility is suggested that the hot spot might arise from localized lack of excision repair. Otherwise, mutagenesis in hamster cells appeared similar to that in E. coli uvr ⁺ cells, except there appears to be a smaller fraction of single-base additions and deletions (frameshifts) in mammalian than in bacterial cells. Phenotypes of 6-thioguanine-resistant E. coli showed there is a gene (or genes) other than gpt involved in the utilization of thioguanine by bacteria.     

Complementation between uvr mutants of Streptococcus pyogenes

Summary From the group A streptococcal strains K 56 and 56 188, respectively 13 and 6 nitrosoguanidine-induced uvr mutants were isolated and used in complementation experiments employing strain 56 188 and its derivatives as donors in phage A 25-mediated heterologous transductions. When A 25 propagated on wild type or on 2 of the six 56 188-derived uvr mutants was used to infect 4 of the uvr recipient strains, a substantial increase in survivors of UV irradiation was found over those observed in selfing experiments or control experiments without phage. Less than 1% of the UV survivors had stably integrated the uvr ⁺ allele. The remaining 4 uvr donors failed to complement the 4 above-mentioned recipients, indicating that the strains in question fell into 2 complementation groups.Nine of the 13 K 56-derived mutants, which in contrast to the others were characterized by non-reversibility to UV resistance, did not even show an increase in UV survivors when infected with phage grown on wild type. The possibility is discussed that these strains might carry second mutations affecting UV sensitivity which, however, did not appear to be of the rec type.     

Mutagenesis in Escherichia coli. V. Attempted interconversion of ochre and amber suppressors and mutational instability due to an ochre suppressor

Summary A possible quantitative system for the interconversion of ochre and amber suppressors was studied in Escherichia coli WU36-10, a strain in which a leucine requirement is suppressed by amber suppressors and a tyrosine requirement is suppressed by ochre suppressors. The conversion of am Sup-2⁺ to oc Sup-2⁺ occurred at rates similar to those for the de novo induction of such suppressors, both spontaneously and after ultraviolet or gamma irradiation. Both induction and conversion of suppressors showed the phenomenon of mutation frequency decline after ultraviolet light. Conversions in the opposite direction from oc Sup-2⁺ to am Sup-2⁺ were, however, not detected in unmutagenised populations of oc Sup-2⁺ strains derived either by conversion from an am Sup-2⁺ strain or de novo from the parental WU36-10, nor were they detected after treatment with ultraviolet light, gamma radiation or 2-aminopurine. If the conversion of oc Sup-2⁺ to am Sup-2⁺ occurs at all, it is at a rate very considerably lower than that for the conversion of am Sup-2⁺ to oc Sup-2⁺. Some Tyr⁺ oc Sup-2⁺ mutants demonstrated mutation rates c. 100 times greater than those of WU36-10 for mutation to Leu⁺ spontaneously and after ultraviolet or gamma radiation. Possible explanations of this are discussed.     

Prophage induction in Escherichia coli K12 cells deficient in DNA polymerase I.

Summary The induction of prophage by ultraviolet light has been measured inE. coli K12 lysogenic cells deficient in DNA polymerase I. The efficiency of the induction process was greater inpolA1 polC(dnaE) double mutants incubated at the temperature that blocks DNA replication than inpolA ⁺ polC single mutants. Similarly, thepolA1 mutation sensitizedtif-promoted lysogenic induction in apolA1 tif strain at 42°. In strains bearing thepolA12 mutation, which growth normally at 30°, induction of the prophage occured after the shift to 42°. It is concluded that dissapearance of the DNA polymerase I activity leads to changes in DNA replication that are able, per se, to trigger the prophage induction process.     

W-mutagenesis in competent cells of Bacillus subtilis

Summary The relative yield (N _m/N) of fluorescent mutants Ind^- after the transformation of Bacillus subtilis cells by means of UV-irradiated DNA is much higher in an uvr ^- recipient than in an uvr ⁺ strain, when compared at equal fluence, but practically identical at equal survival. Ind^- mutations are induced by UV-irradiation of separated single strands of transforming DNA. The H-strand is much more sensitive to the mutagenic action of UV light. Preliminary irradiation of competent recipient cells by moderate UV fluences increases the survival of UV-or -irradiated transforming DNA (W-reactivation) and the frequency of Ind^- mutations (W-mutagenesis). During transfection of B. subtilis cells by UV-irradiated prophage DNA isolated from lysogenic cells B. subtilis (Ø105 c ⁺) c-mutants of the phage are obtained in high yield only in conditions of W-mutagenesis, i.e. in UV-irradiated recipient cells. These data show that there is no substantial spontaneous induction of error-prone SOS-repair system in the competent cells of B. subtilis.     

Ultraviolet sensitivity ofBacillus subtilis citD mutants

Cells ofBacillus subtilis 168 with deletions in thecitD locus were found to be sensitive to irradiation with ultraviolet light and to mitomycin C but were able to repair DNA damage induced by methyl methanesulfonate. The recombination abilities of these cells, as determined by transformation and PBS1-mediated transduction experiments, were unaffected by the deletion. These phenotypic characteristics do not result from a metabolic imbalance caused by the deficiency of a functional α-ketoglutarate dehydrogenase complex, but most likely are a consequence of a genetic locus involved in ultraviolet repair, which is deleted together with thecitK gene when the deletion is formed.     

Characteristics of DNA repair of a UV-sensitive mutant (radC) of Dictyostelium discoideum

Summary A radiation-sensitive mutant, TW8(radC), of Dictyostelium discoideum is more sensitive to ultraviolet light (UV) killing than the parental wild strain NC4(RAD ⁺), but is resistant to 4-nitroquinoline 1-oxide (4NQO) at almost the same level as NC4. In TW8 amoebae, single-strand breaks of DNA molecules were hardly detectable immediately after UV irradiation, and the removal of pyrimidine dimers was depressed during the postirradiation incubation when compared with that of NC4 amoebae. After treatment with 4NQO, however, single-strand breaks were detected in TW8 amoebae. The almost complete rejoining of these breaks was also detected after the removal of 4HAQO-adducts. The TW8 amoebae have an efficient repair capacity against DNA damage caused by 4NQO, MMS, MMC and MNNG but not UV.Abbreviations 4NQO 4-nitroquinoline 1-oxide - MMS methyl methanesulphonate - MMC mitomycin C - MNNG N-methyl-N-nitro-N-nitrosoguanidine     

Properties of a temperature sensitive plasmid in Citrobacter freundii

Summary The properties of a strain of Citrobacter freundii with a deletion of the gal, chl D, bio, uvr B, chl A region of the chromosome, harbouring a temperature sensitive plasmid F _{ts 114} ¹ aro G⁺ gal ⁺ chl D⁺ bio ⁺ uvr B⁺, originating from Escherichia coli, are described.The isolation of strains with an integrated plasmid was tried by incubation of the partial diploid strain at the restrictive temperature and selection for retained plasmid properties. However C. freundii Hfr strains were not obtained, since only fragments of the plasmid were integrated. Integration occurred at seven different sites of the chromosome and resulted in an inactivation of the gene in which the fragment was integrated. Mutants with deficiencies for arginine, isoleucine and valine, tryptophan, guanine and either tryptophan or tyrosine were obtained. In another type the deficiency, resulting from integration, could not be identified, whereas in the seventh type integration had occurred in one or more non-essential genes, because no deficiency was present. Release of the integrated fragment occurred in such a way that gene activity was restored. The released fragment was lost or was integrated again at one of the other six integration sites, resulting in another mutant type.     

Simultaneous Synthesis of Pectin Lyase and Carotovoricin Induced by Mitomycin C,Nalidixic Acid or Ultraviolet Light Irradiation in Erwinia carotovora

When Erwinia carotovora Er, a bacteriocinogenic strain, was induced after irradiation by ultraviolet (UV) light or inhibitors of DNA synthesis, such as mitomycin C or nalidixic acid, pectin lyase and bacteriocin (designated carotovoricin) activity appeared in the culture fluid. The optimal dose of each of these agents for producing the enzyme or bacteriocin was identical, and the time courses for both were essentially the same. Therefore, we assumed that the synthesis of the enzyme and bacteriocin was regulated by the same mechanism, in which a repressor inactivated by UV light, mitomycin C or nalidixic acid was involved. The other three bacteriocinogenic strains of E. carotovora also formed pectin lyase, in addition to carotovoricin in the presence of mitomycin C, indicating that simultaneous syntheses of pectin lyase and carotovoricin were widespread phenomenon in bacteriocinogenic strains of E. carotovora.     

Synergistic effects of ethanol and temperature on yeast mitochondria

At temperatures lower than 37°C, the ethanol inhibition constant (Ki) for growth or fermentation inrho ⁺ cells of theSaccharomyces cerevisiae strain S288C was always higher (1.1M) than inrho ^– mutants (0.7M). At 37°C these differences disappeared, and both strains were equally inhibited by ethanol (Ki=0.7m). Mitochondrial activity can be inhibited by high ethanol concentration and temperature. In fact, the stronger inhibition by ethanol of therho ⁺ strain at 37°C was due to the fact that, under these conditions, this strain loses the advantage conferred by mitochondrial activity since the induction ofrho ^– cells in the population is very high. This does not result in an increase in the frequency ofrho ^– mutants because of the poor viability of these mutants in conditions of high temperature and ethanol. In consequence, S288C strain becomes as strongly inhibited by ethanol as therho ^– mutant strains. Differences in viability were not related to the fatty acids and ergosterol composition of the strain. In the presence of ethanol, bothrho ⁺ andrho ^– strains modified their lipids in the same way, but these changes did not improve their ethanol tolerance. They were not due to differences in adaptation to ethanol either, since after successive transfers in ethanol, growth () and fermentation () rates in therho ^– mutants were increasingly inhibited with time, whereas in the S288C strain inhibition of and by ethanol remained unaltered. Rather,rho ^– mutants are less viable thanrho ⁺ cells because of the inability of the former to respire. At 37°C the Ki increased to 0.9M ethanol either when mitochondrial from highly ethanol-tolerant wine yeasts were transferred torho ^– mutants of the strain S288C or when the mitochondria of strain S288C were preadapted by growing the strain in glycerol instead of glucose before it was cultivated in ethanol.     

Some Properties of Excision-defective Recombination-deficient Mutants of Escherichia coli K-12

Strains of Escherichia coli that carry the mutation uvrA6 show no measurable excision of pyrimidine dimers and are easily killed by ultraviolet (UV) light, whereas strains that carry recA13 are defective in genetic recombination and are also UV-sensitive. An Hfr strain carrying uvrA6 was crossed with an F⁻ strain carrying recA13. Among the recombinants identified, one carrying uvrA recA proved to be of exceptional sensitivity to UV light. It is estimated from the UV dose (0.2 erg/mm² at 253.7 nm) required to reduce the number of colony-forming cells by one natural logarithm that about 1.3 pyrimidine dimers were formed in a genome of 5 × 10⁶ base pairs for each lethal event. This double mutant is 40 times more UV-sensitive than the excision-defective strain carrying uvrA6. The replication of one pyrimidine dimer is generally a lethal event in strains carrying recA13. Spontaneous breakdown and UV-induced breakdown of the deoxyribonucleic acid (DNA) of cells of the various genotypes were estimated by growing the cells in medium containing ³H-thymidine and measuring both acid-precipitable and acid-soluble radioactivity. The UV-induced degradation in strains with recA13 did not require the uvr⁺ genes and hence appears to depend upon a mechanism other than dimer excision. The greater level of survival after irradiation in Rec⁺ as compared to Rec⁻ bacteria may be due to a recovery mechanism involving the reconstruction of the bacterial chromosome through genetic exchanges which occur between the newly replicated sister duplexes and which effectively circumvent the damaged bases remaining in the DNA.     

Cloning and characterization of a DNA repair gene inHaemophilus influenzae

Using a high-efficiency DNA cloning vector pJ1–8, a DNA repair geneuvr1 has been self-cloned in bacteriumHaemophilus influenzae. Chimeric plasmid pKuvrl, carrying wild type allele ofuvr1 gene and flanking DNA sequences, specifically complements auvr1 gene mutation in the bacterial chromosome. Auvr1_} mutation could be transferred from chromosome byin vivo recombination to pKuvr1 and isolated and designated as plasmid pKuvrl₋. Plasmid pKuvrl carries a 11.3 kb chromosomal DNA insert which was scanned for the presence of any other DNA repair genes by a novel method of directed mutagenesis. Preliminary analysis of the 3 new mutants isolated by this method supports the notion that the insert contains more than one gene concerned with ultraviolet radiation-sensitivity.     

Overexpression of Escherichia coli nucleotide excision repair genes after cisplatin-induced damage

Cisplatin is currently used in tumor chemotherapy to induce the death of malignant cells through blockage of DNA replication. It is a commonly used chemotherapeutic agent binding mono- or bifunctionally to guanines in DNA. Escherichia coli K12 mutant strains deficient in nucleotide excision repair (NER) were submitted to increasing concentrations of cisplatin, and the results revealed that uvrA and uvrB mutants are sensitive to this agent, while uvrC and cho mutants remain as the wild type strain. The time required for both gene expression turn-off and return to normal weight DNA in wild-type E. coli was not accomplished even after 4 h post-treatment with cisplatin, while the same process takes place within 1.5 h after ultraviolet radiation (UV). Besides, a heavily damaging action of cisplatin can be seen not only by persistent nicks on genomic DNA, but also by NER gene expression exceeding manifold that seen after equivalent lethal doses of UV. Moreover, cisplatin caused an increase in uvrB gene expression from its putative upstream promoter P3 in an SOS-independent manner.     

Slow milk coagulating variants ofLactobacillus helveticus

Curing experiments were performed onLactobacillus helveticus strain ATCC 15009 in order to find a correlation between the presence of three extrachromosomal elements and specific phenotypic traits. Mitomycin C treatment of the strain was found to result in an appearance of slow-coagulation variants unable to coagulate milk in 24 h at 42 °C. The effect of mitomycin C on phenotypic and genotypic characteristics ofL. helveticus was therefore further examined. The presence of mitomycin C appeared to act on the proteolytic system of the strain: slow variants exhibited a poor casein breakdown (50 % less) compared with the parental strain. Aminopeptidase activity and lactose utilization were unaffected. The phenotypic variation is possibly due to a point mutation of genetic patrimony. No loss of plasmid DNA was detected after mitomycin C treatment and the restriction pattern of plasmid and chromosomal DNA of the variants, after digestion with several restriction endonucleases, was identical to that obtained for the parental strain.     

Effect of ruv mutations on recombination and DNA repair in Escherichia coli K12

Summary Mutation of the ruv gene of E. coli is associated with sensitivity to radiation, and filamentous growth after transient inhibition of DNA synthesis. The filamentation of ruv strains is abolished by mutations in sfiA or sfiB that prevent SOS induced inhibition of cell division, but this does not restore resistance to UV radiation. Double mutants carrying both ruv and uvr mutations are considerably more sensitive to UV radiation than the single mutants, but there is no additive effect of ruv with recA, recF, recB, or recC mutations. ruv mutations have little effect on conjugal recombination in wild-type strains but confer recombination deficiency and extreme sensitivity to ionizing radiation in recBC sbcB strain. These results, together with the fact that ruv strains are excision proficient and mutable by UV light, are interpreted to suggest that the ruv ⁺ product is involved in recombinational repair of damaged DNA rather than in cell division as suggested by Otsuji et al. (1974).     

Isolation and initial characterization of a Schizosaccharomyces pombe mutant exhibiting temperature-dependent radiation sensitivity due to a mutation in a previously unidentified rad locus

Summary We have isolated a mutant of the yeast Schizosaccharomyces pombe which exhibits sensitivity to UV light when grown at either 30° or 37°C, as compared to the parental wild-type strain. This increased sensitivity is more pronounced when cells are grown at 37°C. The mutant is also sensitive to 18 MeV electrons at the high temperature. Tetrad analysis of spores generated by crossing the mutant and a Rad⁺ strain revealed that sensitivity to both types of radiation cosegregate 2:2, relative to wild-type resistance, indicating that a single altered chromosomal locus is responsible for the radiation sensitivities observed. In addition, analysis of spores resulting from crosses between the mutant and all other known S. pombe rad mutants indicates that the temperature-dependent sensitivity described in this report is mediated by a mutation in a previously unidentified rad locus.