The influence of dose rate on the lethal and mutagenic effects of X-rays in proliferating L5178Y cells differing in radiation sensitivity

The lethal and mutagenic effects of ionizing radiation delivered at high (53 Gy/h) and low (0.02 Gy/h) dose rates were measured in two closely related strains of mouse lymphoma L5178Y cells differing in radiation sensitivity (LY-R and LY-S). Strain LY-R was more resistant to the lethal effects of radiation than strain LY-S when exposed at either the high or low dose rate. The survival of strain LY-R was markedly enhanced by the reduction in dose rate. The dose-rate dependence of the survival of strain LY-S was less clear, because of the biphasic nature of its survival curve following low dose-rate radiation. However, if the initial slope of the low dose-rate survival curve is compared to the slope of the high dose-rate survival curve for strain LY-S, only a slight increase in survival at the low dose rate is apparent. Although more sensitive to the lethal effects of radiation, strain LY-S was less mutable at the hypoxanthine/guanine phosphoribosyl transferase locus by both low dose-rate and high dose-rate radiation than strain LY-R. Little dose-rate dependence was exhibited by either strain with regard to the mutagenic effects of radiation. Thus, for strain LY-R, which showed marked dose-rate dependence for survival but not for mutation, the ratio of mutational to lethal lesions was much greater following exposure to low dose-rate than to high dose-rate radiation.     

The cytotoxic and mutagenic effects of 5-bromodeoxyuridine-plus-black-light treatment in cultured mammalian cells

The cytotoxic and mutagenic effects of the incorporation of 5-bromodeoxyuridine (BrdU)_followed by exposure to black light were investigated with Chinese hamster ovary (CHO) cells in cell culture. Mutation induction at the hypoxanthine-guanine phosphoribosyl transferase (hgprt) locus was determined by selection for 6-thioguanine resistant (TG^r) mutants (CHO/HGPRT system). BrdU alone has been shown to be mutagenic only at concentrations of 50 μM or greater. This study was performed in an effort to determine whether BrdU is actually incorporated into the hgprt gene when lower, nonmutagenic concentrations are employed. Neither BrdU (1–20 μM) nor exposure to black light alone was mutagenic, but the combined treatment did result in the induction of TG^r mutants. The mutant frequency increased with increasing light exposure at constant BrdU and with inreasing BrdU at constant light exposure. These results show that BrdU is incorporated into the hgprt gene, but that this does not result in mutation induction in the absence of light exposure. Such a BrdU-plus-light procedure might be applied to studies of DNA repair at this locus, since mutation induction requires both BrdU incorporation and subsequent exposure to black light.     

Repeated doses of gamma rays induce resistance to N-methyl-N'-nitro-N-nitrosoguanidine in Chinese hamster cells

Chinese hamster V79 cells were preirradiated repeatedly with gamma rays and then exposed to ultraviolet (uv) light or N-methyl-N'-nitro-N-nitrosoguanidine (MNNG). The cell killing and induction of mutation at the hypoxanthine-guanine phosphoribosyltransferase locus were examined following these treatments. Cells preirradiated with multiple fractions of gamma rays exhibit the same sensitivity to uv light as the control cells with respect to cell survival and mutation induction. Following treatment with MNNG, resistance to cell killing was observed along with a decreased frequency of mutations induced. These results indicate that the progeny of cells irradiated with multiple fractions of gamma rays could display subsequent changes in sensitivity to lethal and mutagenic effects of additional treatment with DNA-damaging agents.     

Lethal and mutagenic action of solar radiation on model microbiological test systems

Lethal, mutagenic and recombonogenic action of the solar radiation on the model microorganisms--phage T4, bacteria Escherichia coli and ascomycet Aspergillus nidulans--has been studied. A considerable lethal effect of the solar radiation on phage T4 and E. coli was found. An increasing of mutation frequency in E. coli and A. nidulans by sunlight was also revealed. Recombinogenic action of solar radiation has been demonstrated in the experiments with diploid A. nidulans strains. It was shown that the excision and postreplication repair systems took part in recovery of damages induced by sunlight. An important role of ultra-violet region (280-320 nm) solar radiation in induction of lethal and mutagenic effects was demonstrated for all investigated microorganisms.     

Factors influencing survival of mammalian cells exposed to hypothermia. V. Effects of hepes, free radicals, and H2O2 under light and dark conditions

Cytotoxicity resulting from the interaction of fluorescent light from a flow hood with Hepes-buffered cell culture medium at room temperature was demonstrated. Toxicity was prevented by keeping both cells (V79 Chinese hamster) and medium shielded from direct fluorescent light ("dark conditions") or by supplementing the medium with 10 micrograms/ml catalase; this suggests that extracellular hydrogen peroxide is a major cause of the lethal effect under "lighted conditions." No sensitization resulted from the exposure of cells in a sodium bicarbonate (SBC)-buffered medium to fluorescent light, nor in a catalase supplemented SBC-buffered medium. The Hepes/light reaction during routine cell manipulations presensitized cells to hypothermia damage in the dark with the presensitization being more severe for 5 than for 10 degrees C hypothermic exposure. Presensitization was prevented by performing the complete experiment under dark conditions or by supplementing the medium with 10 micrograms/ml catalase. However, catalase did not improve the hypothermic survival when experiments were performed under dark conditions. Hence, 10 micrograms/ml catalase does not protect cells from hypothermic (5 and 10 degrees C) damage per se, but rather from Hepes/light sublethal damage which interacts with hypothermic sublethal damage to result in lethal lesions. Additionally, under dark conditions, superoxide dismutase (SOD), allopurinol, catalase plus SOD, DMSO, or mannitol did not improve survival when present during hypothermic storage, suggesting that extracellular superoxide anion, hydrogen peroxide, or hydroxyl radicals are not the cause of cell killing under conditions of pure hypothermia uncomplicated by prehypothermic ischemia or hypoxia.     

Lethal and mutagenic action of incorporated 5-3H-cytosine on extracellular phage lambda

A study was made of the lethal and mutagenic effects on extracellular phage gamma of 5-3H-cytosine incorporated into DNA. The efficiencies of inactivation by incorporated 3H were equal for 5-3H-cytosine and [3H-methyl]-thymidine, but the yield of c-mutations for the former was 14 times higher. The lethal and mutagenic effects of incorporated 5-3H-cytosine did not depend on ung mutation of host cells which caused a deficiency in uracil-DNA-glycosylase. The mutagenic effect was not enhanced when SOS-repair system was induced by UV-radiation. The mutagenic effect of 5-3H-cytosine was associated with the modified mispairing bases but not with uracil residues.     

Ecologic ultraviolet--a real mutagenic factor for vegetative cells of Bacillus subtilis]

The frequency of leu----Leu+ reversions represented mainly by suppressor mutations is increased in Bacillus subtilis uvr+ and uvr-1 cells after exposure to natural sunlight. Dependence of mutation yield on the time of exposure is linear (one hit kinetics) in case of the uvr-1 strain. In the uvr+ cells the yield of mutations is also linear, but only at short times of exposure, the curve bending and levelling off the plateau after 10-min cell illumination. It has been established in the experiments with optical filters that the mutagenic effect is related to wavelengths which correspond to the UVB zone of ecological UV. The mutagenesis caused by sunlight can be modified (weakened) by some post-irradiation treatments of bacteria, which also led to a decrease of mutations frequencies in B. subtilis uvr+ and uvr-1 cells after exposure to 254-nm UV. The data indicate that: 1) mutagenic influence of sunlight can be overcome only by the joint action of activities of the two cellular repair systems--photoreactivation and excision repair, 2) the real mutagenic effect of sunlight on such a non-photoreactivating organism as B. subtilis would not be enhanced with the increase of the UVB flow in sunlight spectrum.     

Photomutagenicity of cosmetic ingredient chemicals azulene and guaiazulene

The photomutagenicity of the popular skin conditioning agents azulene and guaiazulene were tested in Salmonella typhimurium TA98, TA100 and TA102. Following irradiation with UVA and/or visible light, both azulene and guaiazulene exhibited mutagenicity 4-5-fold higher than the spontaneous background mutation. In contrary, naphthalene, a structural isomer of azulene, was not photomutagenic under the same conditions. Azulene was photomutagenic when irradiated with UVA light alone, visible light alone, or a combination of UVA and visible light. Azulene and guaiazulene are not mutagenic when the experiment is conducted with the exclusion of light. Therefore, extreme care must be taken when using cosmetic products with azulene/guaiazulene as ingredients since after applying these products on the skin, exposure to sunlight is inevitable.     

Mutagenicity of coolwhite fluorescent light for Salmonella

The most common fluorescent lamps in use today in homes and businesses in the United States, 'coolwhite' fluorescent lamps, emit light that is mutagenic for Salmonella. Strains that carry both a uvrB mutation and plasmid pKM101 are extremely susceptible to this light-induced mutation. Both base substitution and frameshift mutations can be induced without substantial lethal effects on the bacteria. Induced mutations accumulate essentially as a linear function of the time bacteria are exposed to illumination. Of Salmonella histidine-requiring strains with known nucleotide target sequences (Hartman et al., 1986; Cebula and Koch, 1989, 1990), strains either carrying one of the base substitution mutations, hisG428 and hisG46, or one of the frameshifts, hisC3076 and hisD6610, are most highly mutagenized whereas frameshift strains with hisD6580 and hisD3052 exhibit lower rates of mutagenesis. Mutagenicity does not appear to require the presence of oxygen. A filter blocking wavelengths below 370 nm eliminates mutagenesis. Polystyrene, cellulose acetate and, especially, mylar and glass filters reduce mutagenesis, indicating that at least some of the mutagenic effects can be attributed to leakage of radiations below 290 nm (far-ultraviolet light) from 'coolwhite' lamps. The more recently introduced fluorescent 'softwhite' lamps are roughly 10-fold less mutagenic at approximately equal light intensity. Incandescent light bulbs are much less mutagenic than are these fluorescent lamps. Our mutational data correlate closely with previous results in eukaryotic cells (Jacobson and Krell, 1982). A uvrB recA Salmonella double mutant is hypersensitive to the lethal effects of coolwhite fluorescent light, even when illuminated through the lids of glass Petri dishes. Thus, appropriate Salmonella strains would appear to be simple and useful screens for both the mutagenic and the lethal activities of fluorescent lamps. These systems are amenable to classroom laboratory use as relatively safe and effective means of demonstrating environmental mutagenesis.     

Survival and mutagenic effects of 5-azacytidine in Escherichia coli

Survival and mutagenesis caused by 5-azacytidine was studied in Escherichia coli. Survival was partially lexA- and recA-dependent and was decreased by the presence of a DNA (cytosine-5)methyltransferase. The dcm, MspI, and EcoRII methyltransferase genes all decreased survival. There was no direct relationship between amount of methylase enzyme present and cell survival, but only plasmids containing a methylase gene sensitized cells to 5-azacytidine. Survival was not affected by uvrA, uvrB or umuCD mutations. Induction of sulA::lacZ fusions by 5-azacytidine was inhibited in strains containing elevated levels of DNA methylase. Cells resistant to 5-azacytidine when they contained a plasmid specifying the EcoRII methylase were sensitive if the plasmid specified the complete EcoRII restriction-modification system. The mechanism of cell death in these situations is therefore different. Mutation of the rpoB gene by 5-azacytidine was studied. The mutation rate was decreased by the presence of recA and lexA mutations. Mutation in umuCD had little effect on the mutation rate. The recA430 mutation, which does not support SOS-dependent mutagenesis induced by UV light, does support 5-azacytidine induced mutagenesis. The presence of DNA (cytosine-5)methyltransferase had no effect on the mutation rate caused by 5-azacytidine treatment. The mutagenic and lethal lesions caused by 5-azacytidine in the absence of methylase therefore differ from the lethal lesions that occur in the presence of methylase. The former could be due to the opening of the 5-azacytosine ring in DNA. Cell death in the presence of methylase could be due to tight binding of methylase to azacytosine containing DNA as well as inhibition of induction of the SOS response.     

Solar and UVC-induced mutation in human cells and inhibition by deoxynucleosides

Optimum conditions were established for quantitating the induction of hypoxanthine guanine phosphoribosyl transferase-deficient (HGPRT-) mutants in HeLa cells and in a human amelanotic melanoma cell line (MM96L). Compared at a fluence of equal toxicity (D37, fluence required to decrease cell survival to 37% of unirradiated control), noon sunlight in summer was slightly more mutagenic in MM96L than in HeLa cells (17 and 12 HGPRT- mutants per 10(6) survivors respectively). UVC (predominantly 254 nm) exhibited similar mutagenicity as equitoxic sunlight in HeLa but was 8-fold more effective in MM96L than equitoxic sunlight. Addition of a mixture of deoxyguanosine (20 microM), deoxyadenosine (20 microM), deoxycytidine (100 microM) and thymidine (20 microM) to the culture medium during the 7-day expression period following irradiation gave a 3-fold reduction in the UVC-induced mutation frequency of MM96L but not HeLa cells. The results suggest that these melanocytic cells are highly susceptible to mutagenesis by short wavelength UV, in a mechanism sensitive to deoxynucleosides.     

Respective roles of pyrimidine dimer and pyrimidine (6-4) pyrimidone photoproducts in UV mutagenesis of simian virus 40 DNA in mammalian cells.

UV light induces DNA lesions which are mutagenic in mammalian cells. We used simian virus 40 tsB201 (unable to produce viral capsid at the restrictive temperature of 41 degrees C because of a point mutation in the VP1 gene) to analyze the mutagenic potency of the two major UV-induced lesions, pyrimidine dimers (Py-Py) and pyrimidine (6-4) pyrimidones [Py(6-4)Py], which are formed on the same nucleotide sites. The mutagenesis criterion was the reversion toward a wild-type growth phenotype. After UV irradiation (mainly at 254 nm), part of the DNA was treated with the photoreactivating enzyme of Escherichia coli, which monomerizes Py-Py but does not modify the Py(6-4)Py photoproduct. Higher survival and lower mutation frequency rates for the photoreactivated DNA indicated that the two lesions were lethal and mutagenic. The VP1 gene of some mutants was entirely sequenced. The mutation spectra showed that the two lesions did not induce the same mutation hot spots, although some sites were common to both. The induced mutation hot spots were not only correlated with lesion hot spots but seemed partially directed by local DNA structures.     

Illumination of human keratinocytes in the presence of the sunscreen ingredient Padimate-O and through an SPF-15 sunscreen reduces direct photodamage to DNA but increases strand breaks.

On illumination with simulated sunlight, the UVB-absorbing sunscreen chemical 2-ethylhexyl-4-dimethylaminobenzoate (Padimate-O) generates excited species which inflict non-ligatable strand breaks on DNA in vitro and it also becomes mutagenic to yeast in vivo. Padimate-O is known to penetrate human skin but its effects on human cells are not clear. Here, we first simulate the sunlight which penetrates human skin and use it to illuminate human keratinocytes. The DNA damage observed in terms of UV-endonuclease-sensitive sites (ESS) and direct strand breaks per kilobase (kb) of DNA per joule per square metre agrees well with that predicted from action spectra based on monochromatic light. Using plasmid DNA in vitro, we find a very similar pattern of results. Next, we simulate the spectrum that results when the incident light is first attenuated by a film of sunscreen (SPF-15; 2 mg/cm(2)) containing benzophenone-3 (a UVA absorber), octyl methoxycinnamate (a UVB absorber), and Padimate-O. If the sunscreen is not in contact with keratinocytes it reduces direct DNA damage from sunlight (ESS). However, any Padimate-O in contact with the cells substantially increases indirect damage (strand breaks) even though the film of sunscreen reduces direct photodamage. We estimate that applying an SPF-15 sunscreen which contains Padimate-O to human skin followed by exposure to only 5 minimum erythemal doses (MED) of sunlight could, while suppressing the formation of ESS, increase strand breaks in cells under the epidermis by at least 75-fold compared to exposure to 1 MED in the absence of sunscreen.     

Recovery from lethal and mutagenic damage during postirradiation holding and low-dose-rate irradiations of cultured hamster cells

Survival and mutation to thioguanine resistance were measured in V79-4 hamster cells grown to plateau phase without refeeding and irradiated with 60Co gamma rays. The effects of low-dose-rate irradiation and of postirradiation holding on recovery from gamma-ray damage leading to these two responses were also studied. The responses of these plateau (extended G1)-phase cells to acute irradiation were similar to those we previously found for exponentially growing cells, including the linear relationship between induced mutant frequency and (log) surviving fraction. Irradiation at low dose rate (0.34 rad/min) considerably reduced both the lethal and mutagenic effects of given doses of gamma rays, but the linear mutation-survival relationship was approximately the same as for acute irradiation. In contrast, cells given a 5-hr holding period after acute irradiation showed the anticipated recovery from potentially lethal damage but no recovery from damage leading to mutation. These results are discussed in terms of previously proposed cellular repair processes (sublethal damage repair and potentially lethal damage repair) and the possibility that the radiation damage leading to lethality is different from mutagenic damage.     

Photosensitizing effect of 8-methoxypsoralen on bacteriophage cd

Mutagenesis in extracellular phage sd by 8-metoxypsoralen (8-MOP) and longwave (lambda greater than 310 nm) UV-irradiation has been established. The kinetics of lethal and mutagenic effects of 8-MOP+light was studied. The efficiency of mutagenesis on the first linear part of mutation curve was 0.3% per the lethal hit which is 2 times lower than that of shortwave (lambda=254 nm) UV-irradiation. The maximum yield of mutants makes up 1%, after which the mutation curve is maintained. It has been established that the main (may be the only) contribution into mutagenesis is made by monoadducts, whereas the lethal effect is conditioned by diadducts (cross-links). The comparison of the efficiency of mutagenic effects of 8-MOP+light with mutagenic effects of other kinds of irradiations was carried out. The possibility of repair of damaged 8-MOP+light phage sd DNA by transfection of Escherichia coli C (uvr+) and Cs (uvr-) lysozyme spheroplasts has been established. The repair mechanism of photodamage in intact phage sd induced with 8-MOP+light was also investigated using the method of two-step irradiation. It has been shown that 65% of photodamages are repaired in E. coli SK cells in the M9 medium, i. e. under cellular metabolism. The recovery of phage sd is completely inhibited in phosphate buffer. Unlike chloramphenicol (150 microgram/ml), 1% caffeine blocks the phage recovery only by 30%. The participation of phage sd determining enzymes in its intracellular recovery from 8-MOP+light damages is assumed.     

Multiple, small exposures of far-ultraviolet or mid-ultraviolet light change the sensitivity to acute ultraviolet exposures measured by cell lethality and mutagenesis in V79 Chinese hamster cells

Chinese hamster V79 cells (subline MI2G) were exposed repeatedly to fractionated doses of germicidal 254 nm light (far-uv) at 6 J.m-2/fraction/day or sunlight-simulating 290-330 nm (mid-uv) at 150 J.m-2/fraction/day and sensitivities to cell killing action and mutation of far-uv and mid-uv were examined. As the number of exposure fractions increased, the cell cultures became resistant to cell killing induced by both far-uv and mid-uv. Increases in both Do and Dq were observed. Treatment with exposures of 6 J.m-2 far-uv is more efficient in yielding cell cultures that are resistant than exposures of 150 J.m-2 mid-uv. In contrast to the cells exposed to repeated far-uv, the cells exposed to repeated mid-uv were relatively more resistant to cell killing effects of mid-uv than far-uv, suggesting a possible role of photolesions other than pyrimidine dimers. When mutants resistant to 6-thioguanine were assayed during repeated exposure to far- or mid-uv light, the yield was initially linear with accumulating dose. At high total accumulated doses, the frequency decreased gradually (6 J.m-2 mid-uv) or reached a plateau (150 J.m-2 mid-uv). The sensitivity of N80 cells (exposed to 80 fractions of mid-uv) to mutation induction by uv light is higher than that of the original MI2G cells, whereas U81 cells (exposed to 81 fractions of far-uv) have a sensitivity similar to that of the original cells. Although an initial decrease in resistance to cell killing was observed, resistant cells retained their characteristics after 100 days in culture without further exposure. Cross-resistance to X rays was not shown. The data in this paper suggest that the capacity for repair of photolesions in DNA by repair processes was enhanced in cell cultures by repeated exposure to far-uv or mid-uv and that this altered the cells' ability to cope with lethal and mutagenic lesions. It remains to be seen if these changes in cell sensitivity were brought about by selective or inductive processes or a combination of both.     

The induction of mutants of Acinetobacter calcoaceticus NCIB8250 and their selection by Vancomycin.

The mutagenic and lethal effects of N-methyl-N-nitro-N-nitrosoguanidine (NTG), ethyl methanesulphonate (EMS), ultraviolet light iffadiation and near-ultraviolet light irradiation with 8-methoxypsoralen on the bacterium Acinetobacter calcoaceticus NCIB8250 were examined. The production of auxotrophic mutants was used as a measure of mutagenic efficiency. Under appropriate conditions all four agents were mutagenic. EMS and NTG although more effective than irradiation, did not cause such a high frequency of mutation as has been observed with other bacteria. A combination of vancomycin and penicillin V gave enrichment of non-metabolizing bacteria and optimum conditions were found for the use of these compounds in a selection technique.     

Effect of sunlight on the survival of Salmonella on surfaces

AIMS: To investigate the effect of simulated full-spectrum tropical sunlight on the survival of Salmonella in droplets on surfaces. MATERIALS AND RESULTS: The survival on surfaces of three Zambian strains of Salmonella enterica serovars Enteritidis and Heidelberg was compared with that of a strain of S. enterica serovar Enteritidis phage type (PT) 4 with known characteristics which had been isolated from poultry in the UK. Samples were taken from surfaces every hour for 3 h and after 24 h exposure in either dark or 12 h light/12 h dark cycle conditions. Differences were analysed for significance using a one-way analysis of variance (anova). Results show that there were a significantly higher number of cells surviving on surfaces after 24 h in the dark when compared with populations exposed to a 12 h light/12 h dark cycle. Significantly more cells also survived exposure to sunlight under dirty than clean conditions. CONCLUSIONS: Exposure to sunlight results in a significant decrease in numbers of Salmonella on surfaces. SIGNIFICANCE AND IMPACT OF THE STUDY: Under field conditions exposure of contaminated surfaces to sunlight could be used in place of chemical methods of control as a cheaper way to reduce Salmonella contamination of surfaces.     

Mutation induction with UV- and X-radiations in spores and vegetative cells of Bacillus subtilis.

Spores and vegetative cells of Bacillus subtilis strains with various defects in DNA-repair capacities (hcr-, ssp-, hcr-ssp-) were irradiated with UV radiation or X-rays. Induced mutation frequency was determined from the observed frequency of prototrophic reversion of a suppressible auxotrophic mutation. At equal physical dose, after either UV- or X-irradiation, spores were more resistant to mutations as well as to killing than were vegetative cells. However, quantitative comparison revealed that, at equally lethal doses, spores and vegetative cells were almost equally mutable by X-rays whereas spores were considerably less mutable by UV than were vegetative cells. Thus, as judged from their mutagenic efficiency relative to the lethality, X-ray-induced damage in the spore DNA and the vegetative DNA were equally mutagenic, while UV-induced DNA photoproducts in the spore were less mutagenic than those in vegetative cells. Post-treatment of UV-irradiated cells with caffeine decreased the survival and the induced mutation frequency for either spores or vegetative cells for all the strains. In X-irradiated spores, however, a similar suppressing effect of caffeine was observed only for mutability of a strain lacking DNA polymerase I activity.     

Effects of ultraviolet radiation and sunlight on the entomogenous nematode,Neoaplectana carpocapsae

Infective-stage juveniles of Neoaplectana carpocapsae were acutely sensitive to short uv radiation (254 nm) and natural sunlight. High nematode mortality, although delayed, accompanied uv exposure. Irradiation rapidly reduced nematode pathogenicity, so that nematodes exposed for 7 min were unable to cause lethal infections in Galleria mellonelia larvae. Moreover, the median survival time of Galleria larvae increased progressively as nematode exposure to uv was lengthened. Inhibition of nematode reproduction and development was noted at exposure periods longer than 2.45 and 5 min, respectively. However, irradiation did not appear to affect juvenile motility. Exposure to direct sunlight also reduced pathogenicity, in a range from 6.9 to 94.9% at 30 and 60 min of exposure, respectively. Long uv (366 nm) did not affect juveniles at the exposures tested.