Further evidence that ultraviolet radiation-enhanced reactivation of simian virus 40 in monkey kidney cells is not accompanied by mutagenesis

Photoprotection in human skin--a multifaceted SOS response

Human skin has developed elaborate defense mechanisms for combating a wide variety of potentially damaging environmental factors; principal among these is UV light. Despite these defenses, short-term damage may include painful sunburn and long-term UV damage results in both accelerated skin aging and skin cancers such as basal cell carcinoma, squamous cell carcinoma and even malignant melanoma. While UV radiation damages many cellular constituents, its most lasting effects involve DNA alteration. The following sections briefly review UV-inducible protective responses in bacteria and in skin, thymidine dinucleotides (pTT) as a powerful probe of DNA damage responses, and potential means of harnessing these inducible responses therapeutically to reduce the now enormous burden of cutaneous photodamage in our society.

The tale of the telomere: implications for prevention and treatment of skin cancers

Work in many laboratories over the past decade has established a central role for the telomere in maintaining genomic integrity. Available data may be interpreted to indicate that telomere disruption, whether due to acute DNA damage or progressive telomere shortening, is the initial event that triggers multiple DNA damage responses. The specific initiating event is likely exposure of the otherwise concealed single-stranded 3' overhang, tandem repeats of TTAGGG, a signal that can be provided to cells in the absence of DNA damage by exogenously provided T-oligos. The ability of T-oligo treatment to trigger SOS-like responses and/or to cause selective apoptosis of already malignantly transformed cells may provide an important new means of cancer prevention and treatment.

Do sunscreens increase or decrease melanoma risk: an epidemiologic evaluation

Ultraviolet adiation is an important cause of melanoma, so the use of sunscreen lotions has been advocated for melanoma prevention. Several arguments have been raised in opposition to this inference. Sunscreen use may interfere with cutaneous vitamin D synthesis, which some have hypothesized may lower melanoma risk. Sunscreen users may compensate for their sunscreen use by staying out much longer in the sun, or may use sunscreen lotions inconsistantly. Published melanoma case-control studies have not consistantly demonstrated a protective effect of sunscreens; however, these studies do not provide strong evidence, ultraviolet radiation is a known cause of melanoma, and ultraviolet B may be particularly potent, so on balance the evidence supports continued advocacy of sunscreen lotion use as part of an overall sun-protection regimen. Uncertainty will remain, however, until the action spectrum of melanoma is convincingly demonstrated or the methodologic limitations of existing epidemiologic evidence are overcome. The latter may require another decade or more of experience with sunscreen use.

Use of an infectious Simian virus 40-based shuttle vector to analyse UV-induced mutagenesis in monkey cells

SV40 based shuttle vectors able to be packaged as pseudovirions have been used either as naked DNA or as pseudovirus to analyse the mutation frequency and the UV-induced mutation spectra obtained after transfection or infection of COS7 monkey cells. The frequency of supF spontaneous mutants was similar whatever the state of the vector, indicating that the transfection step is not responsible for the high spontaneous mutation frequency when using shuttle vectors. Nevertheless the UV-induced mutation frequency of the supF gene was higher when transfected DNA was replicated into COS7 cells than when pseudovirus infection was performed. The UV induced mutation spectra was basically similar in both situations but a new hot-spot at nucleotide 110 was obtained after pseudovirus infection. UV-pretreated and control COS7 cells were infected with untreated or UV-damaged pi SVPC7 shuttle virus and the survival and the supF mutation frequency were analysed in the progeny. The survival of UV-damaged pseudovirus replicated in 10 J/m2 UV-pretreated cells was 2-fold higher than in untreated cells. This increase in the survival was accompanied by a slight enhancement in the number of supF mutants.

Heavy metals enhance the reactivation of nitrous acid-treated adenovirus in HeLa cells

Treatment of HeLa cells with cadmium chloride and zinc chloride increases the survival rate of nitrous acid-treated adenovirus 2 (ade2). This increase is maximal if the time interval between cell treatment and virus infection is delayed by 36 h. The induction process requires protein synthesis only during the 3-h period immediately following treatment; cycloheximide does not prevent the expression of enhanced reactivation if added to the cells after this time.

Cell density dependence of ultraviolet light enhanced reactivation of Herpes simplex type I and the large plaque effect in C3H/10T1/2 mouse fibroblasts

C3H/10T1/2 mouse fibroblasts were grown to different cell densities either by plating at low density and allowing different growth periods, or by plating at a series of increasing densities and allowing the same growth period. These plates were UV irradiated at 7.5 J/m2 or mock irradiated and 24 h later infected with UV-irradiated Herpes simplex type I virus which had been UV irradiated at 50 or 125 J/m2 or mock irradiated. The numbers and sizes of plaques were measured and these data used to calculate the extent of UV-enhanced host cell reactivation, the capacity enhancement, the large plaque effect (LPE) and the small plaque effect (SME). The influence of cell density on these phenomena was similar for both series of density experiments. Ultraviolet-enhanced host cell reactivation could be demonstrated only for cultures of lower density. The capacity of the cells for Herpes simplex type I virus decreased with cell density, but UV irradiated cells showed an increase in capacity with cell density. Plaque sizes decreased in all cases with cell density but the LPE and SPE were not significantly altered. The greatest variation in the above parameters occurred just as the cells were approaching confluence, where most host cell reactivation experiments are carried out. We conclude that the reproducibility of such experiments depends critically on cell density, a dependence which may be relevant to mechanistic interpretations of the UV-dependent phenomena.

UV-enhanced reactivation of UV-damaged SV40 is due to the restoration of viral early gene function

Mammalian cells respond to UV-radiation by inducing an increased ability to support the survival of UV-damaged virus. We have tested whether the induction of enhanced viral reactivation (ER) reflects heightened UV-resistance of specific viral functions. For this, we examined the extent of ER for SV40 containing UV-damage in three functionally distinct regions of the SV40 genome: (i) the viral regulatory region, (ii) the early genes region and (iii) the late genes region. ER corresponding to a dose reduction factor of 43% was observed for damage in the early genes region. No ER was observed for damage in the regulatory or late genes regions. We conclude that ER in SV40 reverses the lethal disruption of an essential function peculiar to the viral early genes region. This function is almost certainly transcription.

Use of a simian virus 40-based shuttle vector to analyze enhanced mutagenesis in mitomycin C-treated monkey cells

When monkey cells were treated with mitomycin C 24 h before transfection with UV-irradiated pZ189 (a simian virus 40-based shuttle vector), there was a twofold increase in the frequency of mutations in the supF gene of the vector. These results suggest the existence of an enhancible mutagenesis pathway in mammalian cells. However, DNA sequence analysis of the SupF- mutants suggested no dramatic changes in the mechanisms of mutagenesis due to mitomycin C treatment of the cells.

Use of a simian virus 40-based shuttle vector to analyze enhanced mutagenesis in mitomycin C-treated monkey cells

When monkey cells were treated with mitomycin C 24 h before transfection with UV-irradiated pZ189 (a simian virus 40-based shuttle vector), there was a twofold increase in the frequency of mutations in the supF gene of the vector. These results suggest the existence of an enhancible mutagenesis pathway in mammalian cells. However, DNA sequence analysis of the SupF- mutants suggested no dramatic changes in the mechanisms of mutagenesis due to mitomycin C treatment of the cells.

Preirradiation of host cells does not alter blockage of simian virus 40 replication forks by pyrimidine dimers

Do damage-inducible responses in mammalian cells alter the interaction of lesions with replication forks? We have previously demonstrated that preirradiation of the host cell mitigates UV inhibition of SV40 DNA replication; this mitigation can be detected within the first 30 min after the test irradiation. Here we test the hypotheses that this mitigation involves either (1) rapid dimer removal, (2) rapid synthesis of daughter strands past lesions (trans-dimer synthesis), or (3) continued progression of the replication fork beyond a dimer. Cells preirradiated with UV were infected with undamaged SV40, and the effects of UV upon viral DNA synthesis were measured within the first hour after a subsequent test irradiation. In preirradiated cells, as well as in non-preirradiated cells, pyrimidine dimers block elongation of daughter strands; daughter strands grow only to a size equal to the interdimer distance along the parental strands. There is, within this first hour after UV, no evidence for trans-dimer synthesis, nor for more rapid dimer removal either in the bulk of the parental DNA or in molecules in the replication pool. Progression of the replication forks was analyzed by electron microscopy of replicating SV40 molecules. Dimers block replication-fork progression in preirradiated cells to the same extent as in non-preirradiated cells. These experiments argue strongly against the hypotheses that preirradiation of host cells results in either the rapid removal of dimers, trans-dimer synthesis, or continued replication-fork progression beyond dimers.

Enhanced reactivation of UV-irradiated adenovirus 2 is not associated with enhanced mutagenesis in carcinogen-pretreated HeLa cells

Treatment of HeLa cells with low doses of the carcinogens aflatoxin B1, methyl methanesulfonate (MMS) or ethyl methanesulfonate (EMS) increases the survival rate of UV-irradiated adenovirus 2 (ade2). This increase is maximal if the time interval between cell treatment and virus infection is delayed by 36 h. No enhanced mutagenesis was found measuring the reversion frequency of a temperature-sensitive mutant of ade2 grown in HeLa cells treated with the same carcinogens. The enhanced viral reactivation observed does not, therefore, display a significant error-prone component.

Preirradiation of host (monkey) cells mitigates the effects of UV upon simian virus 40 DNA replication

We are examining the effects of preirradiation of host (monkey) cells upon the replication of UV-damaged SV40. Control cells and cells preirradiated with low fluences (5 or 10 J/m2) of UV were infected with undamaged SV40, and the immediate effects of a subsequent irradiation were determined. UV inhibited total SV 40 DNA synthesis (incorporation of thymidine into viral DNA) in both preirradiated and control cells, but the extent of inhibition was less in the preirradiated cells. A test fluence of 60 J/m2 to SV40 replicating in preirradiated cells reduced synthesis only as much as a test fluence of 25 J/m2 in control cells. The fraction of recently replicated SV40 molecules that re-entered the replication pool and subsequently completed one round of replication in the first 2 h after UV was also decreased less in the preirradiated cells. Thus preirradiation of the host cell mitigates the immediate inhibitory effects of a subsequent UV exposure upon SV40 replication.

Enhanced mutagenesis of UV-irradiated simian virus 40 occurs in mitomycin C-treated host cells only at a low multiplicity of infection

Treatment of monkey kidney cells with mitomycin C (MMC) 24 h prior to infection with UV-irradiated simian virus 40 (SV40) enhanced both virus survival and virus mutagenesis. The use of SV40 as a biological probe has been taken as an easy method to analyse SOS response of mammalian cells to the stress caused by DNA damage or inhibition of DNA replication. The mutation assay we used was based on the reversion from a temperature-sensitive phenotype (tsA58 mutant) to a wild-type phenotype. The optimal conditions for producing enhanced survival and mutagenesis in the virus progeny were determined with regard to the multiplicity of infection (MOI). Results showed that the level of enhanced mutagenesis observed for UV-irradiated virus grown in MMC-treated cells was an inverse function of the MOI, while enhanced survival was observed at nearly the same level regardless of the MOI. For the unirradiated virus, almost no increase in the mutation of virus progeny issued from MMC-treated cells was observed, while a small amount of enhanced virus survival was obtained. These results show that enhanced virus mutagenesis and enhanced virus survival can be dissociated under some experimental conditions. Enhanced virus mutagenesis, analogous to the error-prone replication of phages in SOS-induced bacteria, was observed, at least for SV40, only when DNA of both virus and host cells was damaged and when infection occurred with a small number of viral particles. We therefore hypothesize that an error-prone replication mode of UV-damaged templates is observed in induced monkey kidney cells.

The use of recombinant DNA techniques to study radiation-induced damage, repair and genetic change in mammalian cells

A brief Introduction is given to appropriate elements of recombinant DNA techniques and applications to problems in radiobiology are reviewed with illustrative detail. Examples are included of studies with both 254 nm ultraviolet light (u.v.) and ionizing radiation (i.r.) and the review progresses from the molecular analysis of DNA damage in vitro through to the nature of consequent cellular responses. The section on the Molecular distribution of DNA damage (section 2) focuses on the use of defined DNA molecules to assess the nature, sites and frequency of radiation damage. Recombinant DNA techniques have also been used in the study of enzyme-DNA interactions, to comment upon the rôle of specific types and sites of damage in producing cellular responses. The use of DNA-mediated gene transfer to assess damage and repair (section 3) indicates that recombinant DNA molecules can be used to implicate (or reject) specific types of DNA damage in gene inactivation. Some gene-transfer assays may also be able to confirm the presence of specific repair functions in mammalian cells. Restriction endonucleases are essential for the construction of recombinant DNA molecules, but their ability to cut DNA at specific sequences is also being exploited to implicate the double-strand break as an important type of damage leading to the well-characterized responses of irradiated cells. The DNA double strand break: use of restriction endonucleases to model radiation damage (section 4) documents experiments showing that blunt-ended cuts introduced into cellular DNA are able to produce chromosome aberrations and cell death. Assays based upon the introduction of restriction endonuclease-cut plasmids into radiosensitive and normal cells suggest that sensitivity is in some instances, e.g. the radiosensitive disorder ataxia-telangiectasia, a result of excessive degradation of DNA around broken ends. Identification and cloning of DNA repair genes (section 5) reviews the successful cloning of one human repair gene and the putative identification of others, as well as the lack of success in identifying genes complementing radiosensitive human disorders. Analysis of radiation-induced genetic change (section 6) links the types of DNA damage observed in defined DNA molecules with the types of mutations occurring in irradiated prokaryotes. In mammalian cells recombinant DNA techniques have allowed the nature of mutational changes to be determined for the first time: to date it seems that u.v. produces mainly small (point) mutations while i.r. produces mainly large changes (deletions/rearrangements).(ABSTRACT TRUNCATED AT 400 WORDS)

Effects of carcinogen treatment on rat liver DNA synthesis in vivo and on nascent DNA synthesis and elongation in cultured hepatocytes

One objective of this study was to determine the effects of N-hydroxy-2-acetylaminofluorene (N-OH-AAF) treatment on DNA synthesis in regenerating rat liver. Rats were subjected to a two-thirds hepatectomy followed 20 h later by i.p. injection of N-OH-AAF. 4 h after carcinogen injection, it was found that N-OH-AAF caused a dose-dependent inhibition of [3H]thymidine incorporation into liver DNA. This inhibition was followed by a gradual, but incomplete recovery beginning 28 h after carcinogen treatment. Radioimmunoassay of deoxyguanine-C8 adducts remaining in liver DNA indicated that the recovery began prior to detection of adduct removal. The second objective of the study was to determine the effects of DNA damage on the size distribution and elongation of nascent hepatocyte DNA. Hepatocytes, which have been shown to demonstrate a pattern of inhibition and subsequent recovery of DNA synthesis following UV irradiation similar to that seen in vivo upon treatment with N-OH-AAF (Zurlo and Yager, 1984), were cultured under conditions that promote replicative DNA synthesis. The size distribution of nascent DNA after UV irradiation was determined by pH step gradient alkaline elution analysis. [3H]Thymidine pulse times and subsequent chase times were adjusted to equalize amounts of DNA synthesis in control and UV-irradiated cells. The results show that UV irradiation caused a dose-dependent decrease in the size distribution of nascent DNA suggesting an inhibition of elongation. Pulse-chase studies revealed that subsequent joining of nascent chains in UV-irradiated hepatocytes occurred at a rate comparable to or faster than controls and that this could be inhibited by caffeine. The results obtained from both the in vivo and in vitro studies show that resumption of DNA synthesis and nascent strand elongation occur on damaged templates. These observations along with our previous studies demonstrating the ability of UV-irradiated hepatocytes to carry out enhanced reactivation of UV-irradiated herpes virus lend support to the idea that DNA damage leading to inhibition of DNA synthesis may induce SOS-type processes which if mutagenic may play a role in the initiation of carcinogenesis.

Enhanced mutagenesis of UV-irradiated simian virus 40 occurs in mitomycin C-treated host cells only at a low multiplicity of infection

Treatment of monkey kidney cells with mitomycin C (MMC) 24 h prior to infection with UV-irradiated simian virus 40 (SV40) enhanced both virus survival and virus mutagenesis. The use of SV40 as a biological probe has been taken as an easy method to analyse SOS response of mammalian cells to the stress caused by DNA damage or inhibition of DNA replication. The mutation assay we used was based on the reversion from a temperature-sensitive phenotype (tsA58 mutant) to a wild-type phenotype. The optimal conditions for producing enhanced survival and mutagenesis in the virus progeny were determined with regard to the multiplicity of infection (MOI). Results showed that the level of enhanced mutagenesis observed for UV-irradiated virus grown in MMC-treated cells was an inverse function of the MOI, while enhanced survival was observed at nearly the same level regardless of the MOI. For the unirradiated virus, almost no increase in the mutation of virus progeny issued from MMC-treated cells was observed, while a small amount of enhanced virus survival was obtained. These results show that enhanced virus mutagenesis and enhanced virus survival can be dissociated under some experimental conditions. Enhanced virus mutagenesis, analogous to the error-prone replication of phages in SOS-induced bacteria, was observed, at least for SV40, only when DNA of both virus and host cells was damaged and when infection occurred with a small number of viral particles. We therefore hypothesize that an error-prone replication mode of UV-damaged templates is observed in induced monkey kidney cells.

Heat-shock-induced enhanced reactivation of UV-irradiated Herpesvirus

The objective of this study was to compare the ability of heat shock (HS) with that of another type of cellular stress, UV irradiation, to cause the induction of enhanced viral reactivation, a process that may represent an SOS-type repair process in mammalian cells. Studies performed to evaluate the effect of HS on growth of Vero cells revealed that HS at 45 degrees C for 45 min caused inhibition of cell growth similar to that caused by UV irradiation at 12 J/m2, but this inhibition was not observed at HS treatment for 5-15 min, or at a UV fluence of 2 J/m2. Enhanced reactivation of UV-irradiated Herpesvirus was observed in cells which had been pretreated by HS for greater than 30 min or UV at 12 J/m2. The synthesis of new proteins following HS for 15 and 45 min and UV at 12 J/m2 was examined by [35S]methionine-labeling experiments. The new synthesis of two HS proteins with molecular weights of 46 000 and 78 000 was induced by both levels of HS, but to a much greater extent at the high dose. These proteins were not detected in response to UV irradiation. These results indicate that, like UV irradiation, HS at levels inhibitory to cell growth induced enhanced viral reactivation in Vero cells. The results also suggest that at least two proteins in the HS protein family are not necessary for this response to occur.

Reactivation and mutagenesis of herpes virus in 5-azacytidine-treated monkey kidney cells

Enhanced survival of UV-damaged herpes simplex virus and Simian virus 40 was investigated in CV-1 monkey cells treated with inhibitors of DNA methylation such as 5-azacytidine and ethionine. Survival of UV-irradiated virus was higher in treated cells than in untreated cells. Survival of herpes virus irradiated with 60Co gamma-ray was not enhanced in the treated cells. The frequency of forward mutation of herpes virus increased in 5-azacytidine-treated cells. Relative content of methylcytosine was reduced in the cells treated with 5-azacytidine. Therefore a mechanism similar to UV-enhanced reactivation of virus was operating in the cells with hypomethylated DNA.

Enhanced reactivation of UV-irradiated adenovirus 2 in HeLa cells treated with non-mutagenic chemical agents

Treatment of HeLa cells with ethanol and sodium arsenite, compounds which are known to elicit the heat-shock response, before infection with UV-irradiated adenovirus 2 has been found to result in the enhanced reactivation of the damaged virus in a manner similar to that obtained by pre-irradiation or heating of the cells. Enhanced reactivation may be the result of the inhibition of DNA synthesis caused by these agents since hydroxyurea also produced a significant enhancement.

Survival and mutagenesis of ultraviolet irradiated simian virus 40 in foetal human fibroblasts

Survival and mutagenesis of UV-irradiated, temperature-sensitive simian virus 40 mutants (SV40) have been studied after infection of human fibroblasts. Survival of the viral progeny obtained after 6,8 or 10 days at permissive temperature decrease as a function of the UV-dose delivered to the virus. In cels which have been pretreated with 10 Jm-2 of UV 24 hours before infection, progeny survival was increased as compared to survival in control cells. The reactivation factor varies from one to ten, depending on the number of lytic cycles carried out at permissive temperature. The level of mutation frequency, as measured by the reversion from a temperature sensitive growth phenotype towards a wild type phenotype, increases with the dose of UV-irradiation given to the virus. Moreover, the mutation frequency is increased in the viral progeny produced in UV-irradiated human cells. Similar experiments carried out with SV40-transformed human fibroblasts, which constitutively express SV40 T antigen, gave comparable results. These experiments show that, as in monkey cells, a new error-prone recovery pathway can be induced by pretreating human cells with UV-light before infection.

Heat-enhanced reactivation of UV-irradiated adenovirus 2 is not associated with enhanced mutagenesis in HeLa cells

The reversion frequency of an adenovirus 2 temperature-sensitive growth mutant irradiated with different doses of UV light was determined after infection of control, UV-irradiated and heat-shocked HeLa cells. No enhancement of mutagenesis by treatment of the cells was observed. Heat-enhanced viral reactivation does not therefore display a significant error-prone component.

Hyperthermia enhances the reactivation of irradiated adenovirus in HeLa cells

The reactivation of U.V.-irradiated adenovirus 2 in HeLa cells is enhanced 8-9 fold if the cells are given a brief hyperthermic shock before infection. Maximum reactivation is achieved by heating for 10 min at 45.5 degrees C and with a delay of 36 h between heating and infection. The induction process requires protein synthesis only during the 3 h period immediately following heating; cycloheximide does not prevent the expression of enhanced reactivation if added to the cells after this time. Heat-enhanced reactivation exhibits properties similar in some respects to radiation-enhanced reactivation and indicates an increased capacity of the heated cells to tolerate DNA damage.

Exposure of nondividing populations of primary human fibroblasts to UV (254 nm) radiation induces a transient enhancement in capacity to repair potentially lethal cellular damage

Nondividing (arrested) populations of primary human fibroblasts from normal individuals exposed to an initial dose (1.5 or 3 J X m-2) of far-UV (254 nm) radiation and then incubated in medium containing low (0.5%) serum develop enhanced resistance to inactivation of cloning efficiency by a second (challenge) dose of UV. The resistance develops within 2-4 days, after which there is a decline. Resistance develops to a higher degree and more rapidly (1-2 days) in cells derived from patients with the variant form of xeroderma pigmentosum. Excision-deficient cells from xeroderma pigmentosum complementation group A individuals also develop UV resistance after a lower (0.2 J X m-2) exposure to UV. Enhanced UV resistance does not develop in UV-irradiated cell populations incubated with the protein synthesis inhibitor cycloheximide (5 microM). These observations are consistent with the interpretation that exposure of human fibroblasts to low doses of UV induces synthesis of a protein involved in a metabolic pathway that transiently enhances the capacity of cells to repair potentially lethal damage resulting from a subsequent dose of UV.

UV-induced imbalance of the deoxyribonucleoside triphosphate pool in E. coli

The effect of UV irradiation on the intracellular DNA precursor pool in E. coli was investigated. UV irradiation of E. coli, followed by post-incubation for 1-1.5 h, altered the relative sizes of the deoxyribonucleoside triphosphate (dNTP) pool. The total amount of dNTPs increased: both dATP and dTTP increased several-fold, dCTP about twofold, while dGTP remained almost unchanged. In recA- and umuC- strains, which are defective in UV-induced mutagenesis, the pattern of nucleotide pool alterations was similar to that of wild-type strains.