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.     

Role of cloned carotenoid genes expressed in Escherichia coli in protecting against inactivation by near-UV light and specific phototoxic molecules.

Genes controlling carotenoid synthesis were cloned from Erwinia herbicola and expressed in an Escherichia coli strain. Carotenoids protect against high fluences of near-UV (NUV; 320 to 400 nm) but not against far-UV (200-300 nm). Protection of E. coli cells was not observed following treatment with either psoralen or 8-methoxypsoralen plus NUV. However, significant protection of cells producing carotenoids was observed with three photosensitizing molecules activated by NUV (alpha-terthienyl, harmine, and phenylheptatriyne) which are thought to have the membrane as an important lethal target. Protection of carotenoid-producing cells against inactivation was not observed with acridine orange plus visible light but was seen with toluidine blue O plus visible light.     

Involvement of recA and exr Genes in the In Vivo Inhibition of the recBC Nuclease

When Escherichia coli cells are gamma irradiated they degrade their deoxyribonucleic acid (DNA). The DNA of previously gamma-irradiated T4 phage is also degraded in infected cells. The amount of degradation is not only dependent on the dose but also on the genotype of the cell. The amount of degradation is less in cells carrying a recB or a recC mutation, suggesting that most of the DNA degradation is due to the recB(+) and recC(+) gene product (exonuclease V). In some strains a previous dose of ultraviolet (UV) light followed by incubation renders the cells resistant to DNA degradation after gamma irradiation. We have shown this inhibition to take place for infecting T4 phage also. By using six strains of E. coli selected for mutations in the genes recA, exr (or lex), and uvrB, we have been able to show that the preliminary UV treatment produces no change in recA and exr cells for both endogenous DNA degradation and the degradation of infecting irradiated T4 phage DNA, i.e., inhibition was not detected in these strains. On the other hand, wild-type cells and strains carrying mutations of uvrB show inhibition in both types of experiments. Because the recA gene product and the exr(+) (lex(+)) gene product are necessary for the induction of prophage, it is possible that the phenomenon of inducible inhibition requires recA(+) and exr(+) presence. One interpretation of these results is that an inducible inhibitor may be controlled by the exr gene.     

Structure of the uvrB gene of Escherichia coli. Homology with other DNA repair enzymes and characterization of the uvrB5 mutation.

The complete nucleotide sequence of the Escherichia coli uvrB gene has been determined. The coding region of the uvrB gene consists of 2019 nucleotides which direct the synthesis of a 673 amino-acid long polypeptide with a calculated molecular weight of 76.614 daltons. Comparison of the UvrB protein sequence to other known DNA repair enzymes revealed that 2 domains of the UvrB protein (domain I = 6 amino acids, domain II = 14 amino acids) are also present in the protein sequence of the uvrC gene. We show that the structural homologies between UvrB and UvrC are as well reflected by the cross-reactivity of anti-uvrB and anti-uvrC antibodies with UvrC and UvrB protein respectively. In the N-terminal part of UvrB, domain III (17 amino acids) shows a strong homology with one part of the AlkA gene product. Adjacent to domain III, an ATP binding site consensus sequence is found in domain IV. The uvrB5 mutant gene from strain AB1885 has been cloned on plasmid pBL01. We show that the uvrB5 mutation is due to a point deletion of a CG basepair and results in the synthesis of an 18 kD protein composed of the 113 N-terminal amino acids of the wild type uvrB gene and a 43 amino acid long tail coded in the -1 frame.     

Photosensitivity of pigmented and nonpigmented strains ofUstilago violacea

White, pink, pumpkin, orange, and yellow strains ofUstilago violacea containing high and low levels of cytochrome c and various carotenes were subjected to high light intensities in the presence and absence of the endogenous photosensitizer toluidine blue (TB). The white strain 15.10 and the cytochrome-c-accumulating pink strain 1.C429 were completely lacking carotenes and were the most sensitive to visible light under all conditions. The phytoene-containing white strain 2.C419, the carotene-containing pink strains AB278a-1, 1.C421, and 2.C425, and pumpkin strain 2.C415 were more resistant to photodestruction in the presence and absence of TB than strains 15.10 and 1.C429. Consistently, the most light resistant strains were the high carotene, low cytochrome-c-accumulating orange, and yellow strains. The photosensitivity of strains ofU. violacea was related to the level of carotene, cytochrome c, the presence or absence of TB, and the age of the culture.     

DNA damage by 5-nitro-2-furylacrylic acid, a nitrofuran derivative

5-Nitro-2-furylacrylic acid (5-NFA) caused dose dependent inhibition of growth of Escherichia coli K-12 strain AB 2480 (uvr-, rec-), the 37% (D37) and 10% (D10) survival doses being 1.0 microgram/ml.h and 1.75 micrograms/ml.h, respectively. Although much higher doses of drug were required to achieve comparable inhibition of growth of E. coli strain 1157 (repair proficient), significant filamentation of these cells was produced by treatment with 1.0 microgram/ml 5-NFA for 4 hr. Ultraviolet absorption data and thermal chromatography through hydroxyapatite (HAP) column revealed that 5-NFA treatment of E. coli strain AB 2480 produced more than 80% of DNA reversibly bihelical due to the formation of interstrand cross-links and the initial part of the reaction obeyed a first order relation. 5-NFA also produced dose-dependent increase of prophage induction in E. coli strain GY 5027: envA, uvrB, ampA1, strA (lambda). The implications of the action of 5-NFA on DNA in relation to the induction of 'SOS' functions and carcinogenesis were discussed.     

A minor pathway of postreplication repair in Escherichia coli is independent of the recB, recC and recF genes

After ultraviolet (UV) irradiation, an Escherichia coli K12 uvrB5 recB21 recF143 strain (SR1203) was able to perform a limited amount of postreplication repair when incubated in minimal growth medium (MM), but not if incubated in a rich growth medium. Similarly, this strain showed a higher survival after UV irradiation if plated on MM versus rich growth medium (i.e., it showed minimal medium recovery (MMR]. In fact, its survival after UV irradiation on rich growth medium was similar to that of a uvrB5 recA56 strain, which does not show MMR or postreplication repair. The results obtained with a uvrB5 recF332::Tn3 delta recBC strain and a uvrB5 recF332::Tn3 recB21 recC22 strain were similar to those obtained for strain SR1203, suggesting that the recB21 and recF143 alleles are not leaky in strain SR1203. The treatment of UV-irradiated uvrB5 recB21 recF143 and uvrB5 recF332::Tn3 delta recBC cells with rifampicin for 2 h had no effect on survival or the repair of DNA daughter-strand gaps. Therefore, a pathway of postreplication repair has been demonstrated that is constitutive in nature, is inhibited by postirradiation incubation in rich growth medium, and does not require the recB, recC and recF gene products, which control the major pathways of postreplication repair.     

A multicopy phr-plasmid increases the ultraviolet resistance of a recA strain of Escherichia coli

It has been previously reported that the ultraviolet sensitivity of recA strains of Escherichia coli in the dark is suppressed by a plasmid pKY1 which carries the phr gene, suggesting that this is due to a novel effect of photoreactivating enzyme (PRE) of E. coli in the dark (Yamamoto et al., 1983a). In this work, we observed that an increase of UV-resistance by pKY1 in the dark is not apparent in strains with a mutation in either uvrA, uvrB, uvrC, lexA, recBC or recF. The sensitivity of recA lexA and recA recBC multiple mutants to UV is suppressed by the plasmid but that of recA uvrA, recA uvrB and recA uvrC is not. Host-cell reactivation of UV-irradiated lambda phage is slightly more efficient in the recA/pKY1 strain compared with the parental recA strain. On the other hand, the recA and recA/pKY1 strains do not differ significantly in the following properties: Hfr recombination, induction of lambda by UV, and mutagenesis. We suggest that dark repair of PRE is correlated with its capacity of excision repair.     

Isolation and Some Properties of Cell Envelope Altered Mutants of Escherichia coli

Mutants of Escherichia coli which have a defect in their permeability barrier were selected. The technique used was to employ a strain of E. coli having a deletion in the gene for lactose permease and to select for mutants which can grow on lactose at 40 C. Twenty such mutants were isolated and six of these were found to be more sensitive to actinomycin D, sodium deoxycholate, and sodium dodecyl sulfate than was the parental strain. They were also more sensitive to the antibiotics vancomycin and bacitracin, which inhibit peptidoglycan biosynthesis. These mutants were no more sensitive to several different colicins or phages than was the wild-type strain. One of the mutants selected by this technique has an abnormal morphology when grown on certain carbon sources in minimal medium, and this mutant is more extensively studied in the accompanying paper.     

DNA damage and prophage induction and toxicity of nitrofurantoin in Escherichia coli and Vibrio cholerae cells

Repair-deficient and repair-proficient strains of E. coli K12 were sensitive to nitrofurantoin treatment to varying degrees with the double mutant strain (uvrA 6, recA 13) being most sensitive. Ultraviolet absorption data and thermal chromatography through a hydroxyapatite column revealed that nitrofurantoin treatment of V. cholerae strain OGAWA 154 produced a maximal amount of 55% reversibly bihelical DNA at a nitrofurantoin dose of 120 micrograms/ml/h, which indicated the formation of inter-strand cross-links in DNA. Nitrofurantoin also produced prophage-lambda induction in E. coli K12 strain GY 5027: envA, uvrB, ampA 1, strA (lambda), in a dose-dependent manner, the maximum induction being highly significant (P less than 0.001). Previously published mutation data coupled with the prophage induction data presented here suggest that the genotoxic properties of nitrofurantoin are mediated through the SOS pathway.     

Relaxation of supercoiled plasmid DNA by oxidative stresses in Escherichia coli.

The relaxation of plasmid DNA was observed after the visible light irradiation of Escherichia coli AB1157 harboring plasmid pBR322 or some other plasmids in the presence of a photosensitizing dye, such as toluidine blue or acridine orange, and molecular oxygen. Treatment of the cells with hydroperoxides, such as tert-butyl hydroperoxide, cumene hydroperoxide, and hydrogen peroxide, also caused the plasmid DNA relaxation in vivo. Relaxation was not observed in these treatments of purified pBR322 DNA in vitro. Plasmid DNA relaxation was also detected after near-UV irradiation. Far-UV irradiation did not induce such relaxation.     

Cloning and expression in Escherichia coli of a xylanase gene from Bacteroides ruminicola 23.

A gene coding for xylanase activity in the ruminal bacterial strain 23, the type strain of Bacteroides ruminicola, was cloned into Escherichia coli JM83 by using plasmid pUC18. AB. ruminicola 23 genomic library was prepared in E. coli by using BamHI-digested DNA, and transformants were screened for xylanase activity on the basis of clearing areas around colonies grown on Remazol brilliant blue R-xylan plates. Six clones were identified as being xylanase positive, and all six contained the same 5.7-kilobase genomic insert. The gene was reduced to a 2.7-kilobase DNA fragment. Xylanase activity produced by the E. coli clone was found to be greater than that produced by the original B. ruminicola strain. Southern hybridization analysis of genomic DNA from the related B. ruminicola strains, D31d and H15a, by using the strain 23 xylanase gene demonstrated one hybridizing band in each DNA.     

Inactivation of Escherichia coli by Near-Ultraviolet Light and 8-Methoxypsoralen: Different Responses of Strains B/r and K-12

A series of Escherichia coli K-12 AB1157 strains with normal and defective deoxyribonucleic acid repair capacity were more resistant to treatment with 8-methoxypsoralen (8-MOP) and near-ultraviolet light (NUV) than a comparable series of strains from the B/r WP2 family although sensitivities to 254-nm ultraviolet light were closely similar. The difference was most marked with strains deficient in both excision and postreplication repair (uvrA recA). The hypothesis that the internal level of 8-MOP was lower in K-12 than B/r uvrA recA derivatives was ruled out on the basis of fluorometric determinations of 8-MOP content and the similar inactivation curves for phage T3 treated intracellularly within the two strains. The demonstration of liquid holding recovery with AB2480 but not WP100 (both recA uvrA strains) and the somewhat greater resistance of the former strain to inactivation by captan revealed the presence in the K-12 strain of a deoxyribonucleic acid repair system independent of the recA(+) and uvrA(+) genes. The presence of this repair system did not, however, affect the survival of T3 phage treated with 8-MOP plus NUV and probably has a relatively small effect on survival of AB2480 under normal conditions. Experiments in which 8-MOP monoadducts were converted to cross-links by a second NUV exposure in the absence of 8-MOP indicated that the level of potentially cross-linkable monoadducts immediately after 8-MOP + NUV is about eightfold lower in K-12-than in B/r-derived strains. It is therefore suggested that the photoproduct yield in the former is well below that in the latter. In agreement with this is the observation that, during the first 10 min after treatment, deoxyribonucleic acid synthesis was just over five times more sensitive to inhibition by 8-MOP plus NUV in WP100 than in AB2480. We assume that 8-MOP in K-12 bacteria is hindered in some way from adsorbing to cellular (though not to phage T3) deoxyribonucleic acid. Consistent with this, 8-MOP has been shown to act as an inhibitor of a component of repair of 254-nm ultraviolet light damage in WP2 but not in AB1157.     

Cloning and expression in Escherichia coli of a xylanase gene from Bacteroides ruminicola 23

A gene coding for xylanase activity in the ruminal bacterial strain 23, the type strain of Bacteroides ruminicola, was cloned into Escherichia coli JM83 by using plasmid pUC18. AB. ruminicola 23 genomic library was prepared in E. coli by using BamHI-digested DNA, and transformants were screened for xylanase activity on the basis of clearing areas around colonies grown on Remazol brilliant blue R-xylan plates. Six clones were identified as being xylanase positive, and all six contained the same 5.7-kilobase genomic insert. The gene was reduced to a 2.7-kilobase DNA fragment. Xylanase activity produced by the E. coli clone was found to be greater than that produced by the original B. ruminicola strain. Southern hybridization analysis of genomic DNA from the related B. ruminicola strains, D31d and H15a, by using the strain 23 xylanase gene demonstrated one hybridizing band in each DNA.     

Isolation and analysis of a mutant of Escherichia coli hyper-resistant to near-ultraviolet light plus 8-methoxypsoralen

A mutant of Escherichia coli K12 was isolated which shows enhanced resistance towards near-ultraviolet (NUV) light plus 8-methoxypsoralen (MPS) compared with its wild-type parent strain. The PUVA (NUV + MPS)-resistant strain remains as sensitive for far-ultraviolet (FUV) light as its parent strain. A recA- derivative of this mutant strain was as sensitive to PUVA as its reca- parental strain. A polyacrylamide gel electrophoresis study of total cell lysates from the mutant bacteria showed that a protein of approximately 55 kd was synthesised in higher concentrations compared with its synthesis in the wild-type parent strain. Furthermore, synthesis of this protein was reduced in the recA- derivative of the mutant strain suggesting that the recA gene product might be acting as a regulator of the synthesis of the 55-kd protein. It is suggested that in E. coli damage to DNA by PUVA can be repaired by a specific RecA LexA-inducible repair system and the repair efficiency is enhanced if the 55-kd protein is present in concentrations higher than that synthesised by the wild-type parent E. coli.     

Test-strains of E. coli for detection of chemical mutagens]

Two temperature-sensitive mutants--AP 16 and AP 18 were isolated after the treatment of E. coli AB2500 strain with two mutagens (acridine orange and 5-bromuracil). The mutants obtained proved to be sensitive and formed revertants when treated with the following agents: N-methyl-N'-nitro-N-nitrosoguanidine, hydroxylamine, nitrous acid, sodium metabisulfite, methylmethansulfonate, and proflavine. Introduction into the mentioned strains of additional mutation causing elevation of their sensitivity to crystal violet increased somewhat their capacity to form revertants under the effect of proflavine and methylmethansulfonate.     

Cytotoxicity and SOS-inducing ability of ethidium and photoactivable analogs on E. coli ethidium-bromide-sensitive (Ebs) strains

In a recently-characterized ethidium-bromide-sensitive E. coli strain, DNA appears to be much more accessible to DNA-binding agents. This strain therefore appears to be of interest for studying the mutagenic properties of chemicals. For this purpose, a series of ethidium-sensitive E. coli strains (Ebs) with normal and defective DNA-repair capacity was constructed and made lysogenic for lambda (sfiA::lacZ). These strains were used to study the cytotoxicity and SOS-inducing ability of ethidium and its two photoactivable analogs 8-azido- and 3,8-diazido-ethidium. When non-covalent DNA complexes are formed, these dyes elicit only a bacteriostatic effect in the Ebs strains, which is almost independent of the strain's DNA-repair capacity. The SOS system is not induced. When covalent DNA adducts are formed after photoactivation of ethidium azido analogs, the effects are quite different. The formation of about 5 DNA monoadducts per cell induces a lethal hit in the Ebs uvrB recA strain and measurable SOS induction in the Ebs uvrB (lambda (sfiA::lacZ) strain. The formation of more than 1000 DNA adducts in the Ebs strain with normal DNA-repair capacity does not induce any measurable cytotoxic effect.     

Ultraviolet-Sensitive Mutator Strain of Escherichia coli K-12

An ultraviolet (UV)-sensitive mutator gene, mutU, was identified in Escherichia coli K-12. The mutation mutU4 is very close to uvrD, between metE and ilv, on the E. coli chromosome. It was recessive as a mutator and as a UV-sensitive mutation. The frequency of reversion of trpA46 on an F episome was increased by mutU4 on the chromosome. The mutator gene did not increase mutation frequencies in virulent phages or in lytically grown phage lambda. The mutU4 mutation predominantly induced transitional base changes. Mutator strains were normal for recombination and host-cell reactivation of UV-irradiated phage T1. They were normally resistant to methyl methanesulfonate and were slightly more sensitive to gamma irradiation than Mut(+) strains. UV irradiation induced mutations in a mutU4 strain, and phage lambda was UV-inducible. Double mutants containing mutU4 and recA, B, or C were extremely sensitive to UV irradiation; a mutU4 uvrA6 double mutant was only slightly more sensitive than a uvrA6 strain. The mutU4 uvrA6 and mutU4 recA, B, or C double mutants had mutation rates similar to that of a mutU4 strain. Two UV-sensitive mutators, mut-9 and mut-10, isolated by Liberfarb and Bryson in E. coli B/UV, were found to be co-transducible with ilv in the same general region as mutU4.     

Conditional Lethality of Deletions Which Include uvrB in Strains of Escherichia coli Lacking Deoxyribonucleic Acid Polymerase I

Deletions of the uvrB gene were not obtained in polA1 strains of Escherichia coli either by selecting for spontaneous deletions or by transduction from strains carrying such deletions. A strain forming a temperature-sensitive deoxyribonucleic acid polymerase I and carrying a deletion of the uvrB gene is inviable at the nonpermissive temperature.     

Enhanced survival of gamma-irradiated Escherichia coli following pretreatment with dithiothreitol

Survival of three strains of Escherichia coli K12 was studied with respect to radiation protection by dithiothreitol (DTT). The three strains compared were AB2462 recA, AB2470 rec21 and their DNA repair-competent prototype, AB1157. The strains were incubated in 10 mmol dm-3 DTT for 60 min and allowed an expression period for SOS functions to appear which may have been induced by DTT. Following the expression period the DTT-incubated cells and incubated control cells were irradiated. When AB1157 cells were pretreated with chloramphenicol (200 micrograms cm-3) for a period of 30 min prior to addition of the induction media no increase in survival was seen. When catalase (0.1 mg cm-3) was added to the AB1157 cells prior to the induction media a decrease in the degree of induction was noted with an enhancement ratio (ER) of 0.893 (ER-1 = 1.12). Furthermore, DTT-treated AB2462 and AB2470 demonstrated no increase in survival when compared to control cells. In radiation experiments on either strain of E. coli with or without DTT present during irradiation, the following were observed: (1) survival of AB1157 was enhanced with a dose modification factor (DMF) of 1.7 with DTT present and 1.3 with pretreatment; (2) the rec mutants showed no change in survival at any dose with a DMF of approximately 1.0. Results indicate that, using our protocol, inducible repair is of more importance than free radical scavenging by DTT. Furthermore, DTT-treated AB2462 demonstrated no increase in survival when compared to control cells. In radiation experiments on either strain of E. coli with and without DTT present during irradiation, the following were observed: (1) survival of AB1157 was enhanced with a DMF of 1.7 with DTT present during irradiation and 1.3 with only pretreatment; (2) the recA and recB mutants showed no change in cell survival at any dose with a DMF of approximately 1.0. Results indicate that, using our pretreatment protocol, inducible repair is of more importance in protection than free radical scavenging by DTT.