Inactivation of Escherichia coli, F′ Episomes at Transfer, and Bacteriophage Lambda by Psoralen Plus 360-nm Light: Significance of Deoxyribonucleic Acid Cross-Links

We have investigated some biological consequences of light-induced psoralen-deoxyribonucleic acid (DNA) adducts and find that for several Escherichia coli functions (killing of strain AB2480 recA13 uvrA6, inactivation of phage lambda plaque-forming ability in wild type and uvrA6 hosts, loss of ability to transmit intact Flac(+) episomes), a light exposure sufficient for production of a single cross-link per DNA molecule correlates well with the biological consequence. Although one cross-link per genome is apparently lethal to recA13 uvr(-) strains, mutants carrying the recA13 or uvrA6 markers survive light exposures producing 6.7 and 16 cross-links per genome, respectively, and wild-type cells recover from 65 psoralen cross-links. Evidently, the excision and recombinational repair systems complement one another in reconstructing an intact genome from cellular DNA containing psoralen photoproducts. The above bacterial and phage strains, in which DNA repair processes are minimized, are also extremely sensitive to pyrimidine dimer-forming 254-nm UV light (without psoralen), and were expected to respond similarly to formation of psoralen-pyrimidine base monoadducts in their DNA. Since the biological inactivation by psoralen correlates well with cross-link formation, we suggest that the sensitizing action of this drug primarily derives from its ability to form DNA cross-links.     

Comparative mutagenesis and interaction between near-ultraviolet (313- to 405-nm) and far-ultraviolet (254-nm) radiation in Escherichia coli strains with differing repair capabilities.

Comparative mutagenesis and possible synergistic interaction between broad-spectrum (313- to 405-nm) near-ultraviolet (black light bulb [BLB]) radiation and 254-nm radiation were studied in Escherichia coli strains WP2 (wild type), WP2s (uvrA), WP10 (recA), WP6 (polA), WP6s (polA uvrA), WP100 (uvrA recA), and WP5 (lexA). With BLB radiation, strains WP2s and WP6s demonstrated a high level of mutagenesis, whereas strains WP2, WP5, WP6, WP10, and WP100 did not demonstrate significant mutagenesis. In contrast, 254-nm radiation was mutagenic in strains WP2, WP2s, WP6, and WP6s, but strains WP5, WP10, and WP100 were not significantly mutated. The absence of mutagenesis by BLB radiation in lexA and recA strains WP10, WP5, and WP100 suggests that lex+ rec+ repair may play a major role in mutagenesis by both BLB and 254-nm radiation. The hypothesis that BLB radiation selectively inhibits rec+ lex+ repair was tested by sequential BLB-254-nm radiation. With strain WP2, a fluence of 30 J/m2 at 254 nm induced trp+ revertants at a frequency of 15 X 10(-6). However, when 10(5) J/m2 or more of BLB radiation preceded the 254-nm exposure, no trp+ revertants could be detected. A similar inhibition of 254-nm mutagenesis was observed with strain WP6 (polA). However, strains WP2s (uvrA) and wP6s (polA uvrA) showed enhanced 254-nm mutagenesis when a prior exposure to BLB radiation was given.     

Genetic control of heat resistance and thermotolerance by recA and uvrA in E. coli K12

Several recA and uvrA derivatives of E. coli K12 AB1157 develop a transient increase in heat resistance, i.e. induced thermotolerance after a brief exposure to 43.5 degrees C (less than 1 h). Thermotolerance was identified from the appearance of an inflection in the survival curve or from the loss of heat resistance in the presence of chloramphenicol (CAM) or rifampicin. Heat resistance and induced thermotolerance were enhanced by recA and uvrA gene functions and their contribution was roughly as follows: AB1157 (recA+ uvrA+) greater than AB2463 (recA- uvrA+) greater than AB1886 (recA+ uvrA-) greater than AB2480 (recA- uvrA-). In heat resistance, uvrA and recA contributed approximately equally and their effects were additive. Induced thermotolerance developed sooner and was maintained at a higher level in the presence of uvrA as compared with recA. Since uvrA-dependent excision repair is scheduled prior to recA-dependent (postreplication) repair, induction of thermotolerance may be linked to DNA repair. Although recA and uvrA play a distinct role, they are not essential, and thermotolerance can develop in the absence of either one or both of these gene functions. Furthermore, since thermotolerance can be induced in recA mutants (AB2463 and AB2480), its biochemical pathway must be different from that of the recA-dependent SOS system.     

W-reactivation and W-mutagenesis in lambda and T7 bacteriophages: a comparative study of the action of ultraviolet radiation (254 nm) and of the photosensitizing agents, 8-methoxypsoralen and angelicin

Monoadducts and interstrand cross-links are formed in DNA after psoralen plus light treatment of bacteriophage lambda . Survival and clear plaque mutation frequency of lambda after photosensitization with 8-methoxypsoralen (8-MOP) are increased when the wild type host is slightly UV-irradiated (W-reactivation and W-mutagenesis). The recA13, lexA1 and uvrA6 mutations block W-reactivation and W-mutagenesis of lambda treated with 8-MOP plus light. Using the technique of "repeated irradiation" we showed that the mutagenic effect of 8-MOP plus light treatment on phage is due mainly to formation of cross-links in DNA. The mutagenic activity of monoadducts had been studied by using angular furocoumarin, angelicin which forms mainly monoadducts in DNA. Upon W-mutagenesis of phage lambda treated with angelicin plus light a high mutagenic effect is observed. The results indicate that the mutagenic activity of monoadducts is 15-20 fold slower as compared to that of cross-links. W-reactivation and W-mutagenesis of UV-irradiated (254 nm) bacteriophage lambda are also observed after 8-MOP plus light treatment of Escherichia coli uvrA and wild type hosts. It is possible that the difference in mutagenic activity of psoralen adducts could depend on the repair mechanism of adducts: cross-links repair in bacterial and lambda DNA is controlled by lexA gene (error-prone SOS-repair mechanism), while monoadducts can be efficiently repaired by error-free excision and recombination.     

Mutation induction and killing of Escherichia coli by DNA adducts and crosslinks: a photobiological study with 8-methoxypsoralen.

Low doses of 350 nm radiation (NUV) in the presence of 8-methoxypsoralen (8-MOP) induce predominantly mono-adducts in bacterial DNA. Further exposure to NUV in the absence of 8-MOP converts a proportion of these mono-adducts to interstrand cross-links. Using this approach the relative effects of adducts and cross-links on bacteria with different repair capacities was studied. Escherichia coli WP100 uvrA recA, believed to be totally deficient in the ability to repair 8-MOP plus NUV damage to DNA, was inactivated on average by a single photon event occurring with a quantum efficiency of about 0.03. We conclude that the inactivating lesion is probably a single mono-adduct. E. coli WP2 uvrA, deficient in excision endonuclease activity, may be inactivated by a very small number of cross-links, probably one. These conclusions are consistent with present knowledge of the repair capabilities of these bacteria. Conversion of mono-adducts to cross-links in WP2 uvrA (which occurs with a quantum efficiency of around 0.3) greatly increases lethality but results in a reduction of the induced mutation frequency presumably because cross-links are (almost) invariably lethal. In the repair-proficient strain WP2 both adducts and cross-links can be repaired but the latter are more likely than the former to lead to either death or mutation.     

Radioadaptive enhancement of the repair of UV-induced postreplication gaps in Escherichia coli cells deficient in DNA repair

In UV-irradiated E. coli WP2 uvrA, deficient in excision repair of DNA with pyrimidine dimers, gamma-irradiation in low doses (radioadaptation) before UV-irradiation leads to the intensification of postreplication repair of DNA. This process in WP2 uvrA polA and uvrA lexA mutants is less than in WP2 uvrA cells, but in WP2 uvrA recA both postreplication repair and its radioadaptive intensification are absent. In E. coli AB1157 excising pyrimidine dimers the radioadaptive intensification of postreplication repair of DNA is expressed almost to the same extent as in WP2 uvrA. In GW2100 umuC mutant, deficient in DNA polymerase V, postreplication repair of DNA is expressed, but its radioadaptive intensification is absent, while in AB2463 recA13 both postreplication repair of DNA and radioadaptive intensification of postreplication repair of DNA are absent. The above data suggest that DNA polymerase I and LexA protein are needed for radioadaptive intensification of postreplication repair of DNA in uvrA strain, and DNA polymerase V is needed for radioadaptive intensification in E. coli AB1157, and that RecA protein is required for postreplication repair and radioadaptive intensification of postreplication repair of DNA.     

Physiological Modifications in the Production and Repair of Methyl Methane Sulfonate-Induced Breaks in the Deoxyribonucleic Acid of Escherichia coli K-12

The medium in which Rec(+) strains of Escherichia coli K-12 are grown affected their sensitivity to treatment with methyl methane sulfonate (MMS). Rec(+) cells grown to the stationary phase in glucose-enriched nutrient broth (GNB) were more resistant to MMS than cells grown in nutrient broth (NB). The repair of MMS-induced breaks (or alkali-labile bonds) in the deoxyribonucleic acid (DNA) from E. coli K-12 strains AB1157, AB1886 uvrA6, and SR111 recA13 recB21 grown in GNB and NB media was examined by means of alkaline sucrose gradient centrifugation. It appeared that essentially all of the repair of breaks that occurred, as evidenced by an increase in "molecular weight," took place within 10 min after treatment with MMS under our conditions. Cell survival was highest in cells for which the size of the DNA after the post-treatment incubation was the largest. The largest DNA after post-treatment incubation was found in Rec(+) cells grown in GNB medium. The results suggest that these cells may have an enhanced capacity for repairing breaks in DNA.     

UV-induced alleviation of K-specific restriction of bacteriophage lambda.

A partial release of K-specific restriction of phage lambda grown in Escherichia coli C was observed when E. coli K strains AB1157 (having wild-type repair of UV-produced DNA damage) and AB1886 (uvrA) were irradiated with UV light before infection. The effect occurred in AB1886 at lower UV fluences than it did in AB1157. Little or no release of restriction was observed when AB2463 (recA) or AB2494 (lex-1) was used. Such release of restriction appears to be another of the UV-induced phenomena associated with "SOS" repair.     

Mutagenic interaction between near-(365 nm) and far-(254 nm)ultraviolet radiation in repair-proficient and excision-deficient strains of Escherichia coli.

The mutational interaction between radiation at 365 and 254 nm was studied in various strains of E. coli by a mutant assay based on reversion to amino-acid independence in full nutrient conditions. In the two repair-proficient strains (K12 AB 1157 and B/r), pre-treatment with radiation at 365 nm strongly suppressed the induction of mutations by far-UV, a phenomenon accompanied by a strong lethal interaction. The frequency of mutations induced by far-UV progressively declined with increasing dose of near-UV. Far-UV-induced mutagenesis to T5 resistance was almost unaltered by pre-treatment with near-UV. In AB 1886 uvrA there was no lethal interaction between the two wavelengths but the mutagenic interaction was synergistic. This synergism was maximal at a 365-nm dose of 8 X 10(5) J m-2. It is proposed that in the wild-type strain, cells containing potentially mutagenic lesions are selectively eliminated from the population because of abortive excision of an error-prone repair-inducing signal. In excisionless strains, 365-nm radiation may be less damaging to the error-prone than to the error-free post-replication repair system. Alternatively, mutation may be enhanced because of the occurrence of error-prone repair of 365-nm lesions by a system that is not induced in the absence of 254-nm radiation.     

Genetic and kinetic evidence for different types of postreplication repair in Escherichia coli B.

The changes in molecular weight of deoxyribonucleic acid (DNA) synthesized after ultraviolte irradiation of Escherichia coli WP28 uvrA, and strains additionally mutant at polA, exrA, recA, and exrA and polA loci, were examined by alkaline sucrose gradient centrifugation. In a repari=deficient uvrA recA strain, the frequency of breaks in newly synthesized DNA was equal to that for pyrimidine dimers in parental DNA. Measurements of the amounts and rates of postreplication repair of these breaks indicate that (i) repair is two to three times faster when DNA polymerase I is present, although (ii) almost all breaks are repaired regardless of DNA polymerase I activity. (iii) Increased ultraviolet doses lead to an increase in the proportion of breaks remaining unrepaired in uvrA recA, UVRA exrA, and uvrA exrA polA strains. The numbers of unrepaired breaks resemble the numbers expected if repair of one lesion is prevented by proximity of a second lesion.     

Spontaneous Lethal Sectoring, a Further Feature of Escherichia coli Strains Deficient in the Function of rec and uvr Genes

Eight recombination-deficient (Rec(-)) mutants of Escherichia coli were studied. Progeny lines were obtained on solid media, by means of micromanipulation, and the colony-forming ability of individual cells was analyzed. Cells of all eight strains gave rise to colony-forming as well as non-colony-forming descendants ("lethal sectoring"). Lethal sectors, i.e., groups of non-colony-forming cells which originate from a common ancestor, appeared with frequencies per generation ranging between 4 and 20% in Rec(-) strains, whereas lethal sectors were rare in Rec(+) strains (less than 1%). A strain carrying a mutation (uvrA6) in one of the genes involved in pyrimidine dimer excision from deoxyribonucleic acid (DNA) showed twice as many lethal sectors per generation as a strain with the genotype uvrA(+). Similarly, a double mutant (AB2480, uvrA6, recA13) showed twice as much spontaneous lethal sectoring as the corresponding Rec(-) strain (uvrA(+), recA13). The kinetics of growth curves obtained in nutrient broth and the frequency of non-colony-forming units in stationary-phase broth cultures indicate clearly that lethal sectors occur in liquid cultures too. The causes for spontaneous lethal sectoring are unknown at present. It seems reasonable to assume that gene uvrA and the rec genes are somehow involved in the repair of spontaneously occurring DNA lesions, since a deficiency in this type of repair may cause lethal sectors. The extent to which spontaneous lethal sectoring (observed in all Rec(-) strains of E. coli studied) may contribute indirectly to the failure to form recombinants is discussed.     

Inhibition of deoxyribonucleic acid repair in Escherichia coli by caffeine and acriflavine after ultraviolet irradiation.

The effects of caffeine and acriflavine on cell survival, single-strand deoxyribonucleic acid break formation, and postreplication repair in Escherichia coli wild-type WP2 and WP2 uvrA strains after ultraviolet irradiation was studied. Caffeine (0.5 mg/ml) added before and immediately after ultraviolet irradiation inhibited single-strand deoxyribonucleic acid breakage in wild-type WP2 cells. Single-strand breaks, once formed, were no longer subject to repair inhibition by caffeine. At 0.5 to 2 mg/ml, caffeine did not affect postreplication repair in uvrA strains. These data are consistent with the survival data of both irradiated WP2 and uvrA strains in the presence and absence of caffeine. In unirradiated WP2 and uvrA strains, however, a high caffeine concentration (greater than 2 mg/ml) resulted in gradual reduction of colony-forming units. At a concentration insufficient to alter survival of unirradiated cells, acriflavine (2 microgram/ml) inhibited both single-strand deoxyribonucleic acid breakage and postreplication repair after ultraviolet irradiation. These data suggest that although the modes of action for both caffeine and acriflavine may be similar in the inhibition of single-strand deoxyribonucleic acid break formation, they differ in their mechanisms of action on postreplication repair.     

Lethal effects of pyrimidine dimers induced at 365 nm in strains of E. coli differing in repair capability

Photoreactivation (PR) after 365-nm inactivation was measured in four strains of Escherichia coli differing in repair capability. Photoreactivation was observed in the recA strains K12 and AB2480 and K12 AB2463 indicating a significant role of pyrimide dimers in the lethal action of 365-nm radiation in these strains. Significant PR was not observed in the uvrA strain, K12 AB1886, or in the repair proficient strain, K12 AB1157, after 265-nm inactivation. Biological evidence indicated that stationary phase cells had not lost the capacity for photo-enzymatic repair after fluences of 365-nm radiation of 2 × 10⁶ J/m⁻² or less. It is proposed that pyrimidine dimers, although induced, are not significant 365-nm lethal lesions in uvrA and wild-type strains because of their efficient dark repair.     

Interactions between uv radiation of different energies in the inactivation of bacteria.

A strong lethal interaction was observed between various monochromatic wavelengths (254, 334, 365, and 405 nm) in the repair-proficient E. coli K-12 strain AB 1157, except in the case of preexposure to 405-nm radiation which resulted in a protection against the inactivation resulting from subsequent exposure to 365-or 254-nm radiations. The results may be tentatively explained by assuming two classes of DNA lesions and two classes of damage to repair (reversible and inrreversible) whose proportions vary according to wavelength.     

Assessment of Escherichia coli B with enhanced permeability to fluorochromes for flow cytometric assays of bacterial cell function

BACKGROUND: Flow cytometry has become a choice methodology for microbiological research. However, functional cytometric assays in live bacteria are still limited. This is due, in part, to the cell wall impairing penetration of vital dyes in bacteria, thus imposing permeabilization procedures. These manipulations may affect cell physiology, provoke cell aggregation or lysis, and they are time-consuming. Escherichia coli B strains have been used for mutagenic assays because of an altered lipopolysaccharide that provokes increased membrane permeability. We assessed the use of these strains as possible alternatives for flow cytometric assays to avoid the permeabilization steps. METHODS: Suspensions of E. coli K-12 (strain AB1157) and E. coli B (strain WP2 uvrA/pKM101, denoted as strain IC188) were stained with several fluorochromes, including fluorescein isothiocyanate, propidium iodide, Nile Red, bis-(1,3-dibutylbarbituric acid) trimethine oxonol, hydroethidine, and dihydro-dichlorofluorescein diacetate, under basal conditions and following permeabilization, impairment of membrane potential, inhibition of dye efflux pump, and oxidative stress. Fluorescent staining of both strains was compared by epifluorescence microscopy and flow cytometry. RESULTS: The E. coli B strain IC188 exhibited more efficient staining with vital fluorochromes than the E. coli K-12 strain AB1157 and maintained a similar membrane potential. In addition, IC188 showed higher sensitivity than AB1157 to reveal oxidative stress when challenged with prooxidants. CONCLUSIONS: E. coli B strains may be useful for biochemical and toxicological studies based on flow cytometry and fluorescence microscopy.     

Cell cycle parameters of Escherichia coli K-12.

A computer simulation routine was used to calculate the DNA distributions of exponentially growing cultures of Escherichia coli K-12. Simulated distributions were compared with distributions obtained experimentally by flow cytometry. Durations of the DNA replication period (C) and the postreplication period (D) were found by minimizing the difference between theoretical and experimental DNA histograms. It was demonstrated that the K-12 strains AB1157 and CM735 had C and D periods that differed widely from each other and from those of the previously measured strain B/rA, while strain MC1000 was shown to have the same durations of the C and D periods as strain B/rA. The variation between K-12 strains may explain the divergence in the literature regarding their C and D periods. Strains W3110 and AB1157 recA1 had DNA histograms that could not be adequately simulated by the classical Cooper-Helmstetter model, which is consistent with the asymmetrically located origin and terminus for W3110 and the asynchrony of initiation for AB1157 recA1.     

Dark Recovery Processes in Escherichia coli Irradiated with Ultraviolet Light I. Effect of rec− Mutations on Liquid Holding Recovery

We have examined various derivatives of Escherichia coli K-12 for liquid holding recovery, a type of recovery originally observed in E. coli B irradiated with ultraviolet light. Although most of the K-12 derivatives tested showed relatively little or no recovery under our conditions, four of the six independent rec(-) mutants examined, those carrying recA1, rec-12, recA13, and rec-56, respectively, displayed marked recovery. These mutants are distinguished from rec(+) strains by their increased sensitivity to ultraviolet radiation and decreased ability to undergo genetic recombination. Two of them have also been reported to release large amounts of their deoxyribonucleic acid as acid-soluble material, especially after irradiation. None of the three uvr(-) mutants examined, containing uvrA6, uvrB5, or uvrC34, showed comparable liquid holding recovery. The one rec(-) uvr(-) derivative tested, carrying recA13 and uvrA6, did not appear to undergo liquid holding recovery, although recA13 uvr(+) strains did. Genetic analysis of one strain, a recA13 mutant, indicated that all the rec(+) derivatives obtained from it by conjugation, transduction and reversion, had lost the property of showing liquid holding recovery. From these results, we conclude that in E. coli K-12 the expression of liquid holding recovery depends upon certain rec(-) mutations.     

Lethal and mutagenic effects of 8-methoxypsoralen-induced lesions on plasmid DNA

The genotoxic effect of 8-methoxypsoralen damages (monoadducts and crosslinks) on plasmid DNA was studied. pBR322 DNA was treated with several concentrations of 8-methoxypsoralen plus fixed UVA light irradiation. After transformation into E. coli cells with different repair capacities (uvrA, recA and wild-type), plasmid survival and mutagenesis in ampicillin- and tetracycline-resistant genes were analysed. Results showed that crosslinks were extremely lethal in all 3 strains; indeed, it seemed that they were not repaired even in proficient bacteria. Monoadducts were also found to be lethal although they were removed to some extent by the excision-repair pathway (uvrA-dependent). Damaged plasmid DNA appeared to induce mutagenic repair, but only in the wild-type strain. In order to study the influence of the SOS response on plasmid recovery, preirradiation of the host cells was also performed. Preirradiation of the uvrA or wild-type strains significantly increased plasmid recovery. Consistent with the expectations of SOS repair, no effect was observed in preirradiated recA cells. Plasmid recovery in the excision-deficient strain was mainly achieved by the mutagenic repair of some fraction of the lesions, probably monoadducts. The greatest increase in plasmid recovery was found in the wild-type strain. This likely involved the repair of monoadducts and some fraction of the crosslinks. We conclude that repair in preirradiated repair-proficient cells is carried out mainly by an error-free pathway, suggesting enhancement of the excision repair promoted by the induction of SOS functions.     

Effect of tsl (thermosensitive suppressor of lex) mutation on postreplication repair in Escherichia coli K-12.

Cells of Escherichia coli K-12 carrying lexA or recA mutations are more sensitive to UV radiation than corresponding wild-type cells and are defective in postreplication repair. Supressor mutations (tsl) have been described previously which increase the UV resistance of lexA uvr+, lexA uvrA, and recAI uvr+ strains, but not the resistance of recA1 uvrA strains. We have studied the effect of the tsl-1 mutation on postreplication repair and find that the enhanced survival conferred by this mutation is correlated with an increased capacity for postreplication repair.     

SOS repair of 8-methoxypsoralene monoadducts in DNA of lambda bacteriophage and plasmids is mediated by MucA 2 ′ B, but not UmuD 2 ′ C (PolV) polymerase

The light-induced action of 8-methoxypsoralen (8-MOP) on λ phage and plasmids yields monoadducts and interstrand crosslinks. The survival and clear plaque mutation frequency in the phage photosensitized with 8-MOP and irradiated with UV at wavelength >320 nm are increased when the wild-type host (Escherichia coli uvr ⁺) is subjected to UV irradiation (wavelength = 254 nm) prior to phage inoculation. These phenomena are known as “W reactivation” and “W mutagenesis.” It is shown that 8-MOP monoadducts in λ DNA induce clear mutations in the phage inoculated to UV-irradiated excision repair mutants of E. coli only when the error-prone repair is performed by MucA ₂ ^′ B, but not PolV (UmuD ₂ ^′ C) polymerase. The efficiency of the SOS repair (W reactivation) of 8-MOP monoadducts in plasmid and λ phage DNA also only increases with the presence of pKM101 plasmid muc ⁺ in E. coli uvr ^?.