XERODERMA PIGMENTOSUM FIBROBLASTS INCLUDING CELLS FROM XP VARIANTS ARE ABNORMALLY SENSITIVE TO THE MUTAGENIC AND CYTOTOXIC ACTION OF BROAD SPECTRUM SIMULATED SUNLIGHT

Abstract— The cytotoxic and mutagenic effects of broad spectrum simulated sunlight, as delivered by a Westinghouse Sun Lamp FS 20 filtered to eliminate wavelengths below 290 nm, were determined in diploid human skin fibroblasts which differ in their ability to repair pyrimidine dimers, and compared with results obtained with UV 254 nm radiation. The cell strains tested included normal fibroblasts; excision repair-deficient xeroderma pigmentosum (XP) cells from patients XP12BE (complementation group A). XP7BE (group D). and XP2BI (group G): and an XP variant patient (XP4BE) whose cells excise pyrimidinc dimers at a normal rate, but exhibit abnormal replication of DNA containing unexcised lesions. Cytotoxicity was assayed from loss of colony-forming ability. The group A cells were most sensitive to the killing effect of the Sun Lamp; the group D and G cells were slightly less sensitive; the XP variant cells showed intermediate sensitivity; and normal cells were most resistant. When the Sun Lamp survival curves for the group A, group D, the XP variant and normal cells were compared with their respective UV 254 nm survival curves, the relationships between the strains were virtually identical (i. e. the curves were related by a constant fluence modification factor). suggesting a common lesion for cell killing. The marker for mutagenesis was resistance to 6-thioguanine. The group A XP cells proved most sensitive to mutations induced by the simulated sunlight: the variant cells were intermediate; and the normal cells were the most resistant. Again, when the curves for mutations induced in these cell strains by simulated sunlight were compared with their respective 254 nm UV mutation curves, these were related by a constant fluence modification factor. suggesting a common lesion for mutagenesis. These results. taken together with published data indicating that at equicytotoxic levels of UV254 nm radiation and the filtered Sun Lamp. the number of pyrimidine dimers in the DNA of XP12BE cells was equal. support the hypothesis that the dimer is the lesion principally involved in both effects. Our data also support the hypothesis that mutations are involved in the sunlight-induced skin cancer of XP patients.     

ACTION SPECTRA FOR KILLING NON-DIVIDING NORMAL HUMAN AND XERODERMA PIGMENTOSUM CELLS

Abstract— Non-dividing human cells degenerate and eventually detach from a culture vessel surface when exposed to UV light. Action spectra for this kind of cell inactivation were determined using eight monochromatic wavelengths from 240 to 313 nm and both a normal DNA excision-repair-proficient strain and a repair-deficient Xeroderma pigmentosum (XP12BE) strain. The action spectra for both strains have similar shapes with a broad peak between 254 and 280 nm followed by a steep decline at wavelengths greater than 280 nm. The relative action spectra are similar to those for inactivation of reproductive capacity and pyrimidine dimer formation in rodent cells suggesting that the critical target and critical damage for inactivation of non-dividing human cells is DNA and damage to DNA, respectively. Normal repair-proficient cells are 5–7 times more resistant at all wavelengths, based on a comparison of D_o values, than repair-deficient XP12BE cells, supporting the conclusion that the inactivating damage at all wavelengths is to DNA.     

REDUCED REPAIR OF NON-DIMER PHOTOPRODUCTS IN A GENE TRANSFECTED INTO XERODERMA PIGMENTOSUM CELLS

Abstract— 4ells from patients with the sun sensitive cancer-prone disease, xeroderma pigmentosum (XP) have defective repair of UV damaged DNA with reduced excision of the major photoproduct, the cyclobutane type pyrimidine dimer. Other (non-dimer) photoproducts, have recently been implicated in UV mutagenesis. Utilizing an expression vector host cell reactivation assay, we studied UV damaged transfecting DNA that was treated by in vitro photoreactivation to reverse pyrimidine dimers while not altering other photoproducts. We found that the reduced expression of a UV damaged transfecting plasmid in XP complementation group A cells is only partially reversed by photoreactivation. E. coli photolyase treatment of pSV2catSVgpt exposed to 100 or 200 J m⁻² of 254 nm radiation removed 99% of the T4 endonuclease V sensitive sites. Transfection of XP12BE(SV40) cells with photoreactivated pSV2catSVgpt showed residual inhibition corresponding to 25 to 37% of the lethal hits to the cat gene. This residual inhibition corresponds to the fraction of non-dimer photoproducts induced by UV. This result implies that XP12BE(SV40) cells do not repair most of the non-dimer photoproducts in DNA.     

THE RATE OF REMOVAL OF SUNLIGHT-INDUCED PYRIMIDINE DIMERS FROM THE DNA OF CULTURED HUMAN DIPLOID FIBROBLASTS

Abstract The rate of excision of sunlight-induced pyrimidine dimers in DNA of exposed human cells was determined. Two normal excision repair-proficient human diploid fibroblast strains (WS-1 and KD) and a repair-deficient strain (XP12BE, group A) maintained in a nondividing state were exposed to summer noon-time sunlight for times (5 and 20 min) that induced numbers of dimers equivalent to far UV (254 nm) exposures of 1 and 4 J/m². Pyrimidine dimers were quantified in extracted DNA using a U V-endonuclease-alkaline sedimentation assay. The excision rates of these dimers were similar to those observed for the excision of UV-induced pyrimidine dimers. No sunlight-induced inhibition or stimulation of DNA repair was observed in either strain at these low exposures.     

LETHALITY AND THE INDUCTION AND REPAIR OF DNA DAMAGE IN FAR, MID OR NEAR UV-IRRADIATED HUMAN FIBROBLASTS: COMPARISON OF EFFECTS IN NORMAL, XERODERMA PIGMENTOSUM AND BLOOM'S SYNDROME CELLS

Abstract Using normal human fibroblasts we have determined the ability of far (254 nm), mid (310 nm) or near (365 nm) UV radiation to: (i) induce pyrimidine dimers (detected as UV endonuclease sensitive sites) and DNA single-strand breaks (detected in alkali); (ii) elicit excision repair, monitored as unscheduled DNA synthesis (UDS); and (iii) reduce colony-forming ability. Unscheduled DNA synthesis studies were also performed on dimer excision-defective xeroderma pigmentosum (XP) cells, and the survival studies were extended to include XP and Bloom's syndrome (BS) strains. UV-induced cell killing in normal, BS and XP cells was found to relate to an equivalent dimer load per genome after 254 or 310 nm exposure, whereas at 365 nm the lethal effects of non-dimer damage appeared to predominate. Lethality could not be correlated with DNA strand breakage at any wavelength. The two XP strains examined showed the same relative UDS repair deficiency at the two shorter wavelengths in keeping with a predominant role for pyrimidine dimer repair in the expression of UDS. However, UDS was not detected in 365 nm UV-irradiated normal and XP cells despite dimer induction; this effect was due to the inhibition of DNA repair functions since 365 nm UV-irradiated normal cells showed reduced capacity to perform UDS subsequent to challenge with 254 nm UV radiation.
In short, the near UV component of sunlight apparently induces biologically important non-dimer damage in human cells and inhibits DNA repair processes, two actions which should be considered when assessing the deleterious actions of solar UV.     

DNA EXCISION REPAIR IN THE VERY UV-SENSITIVE XERODERMA PIGMENTOSUM COMPLEMENTATION GROUP A STRAIN XP4LO

Abstract— XP4L0, a xeroderma pigmentosum complementation group A strain, exhibits very limited DNA repair activity. It has extreme sensitivity to UV (254 nm) as determined by colony forming ability. The rate of loss of UV (1 J/m²)-induced pyrimidine dimers from populations of quiescent, nondividing XP4LO cells was determined and found to be slower than that observed for other group A strains (XP25R0, XP12BE, XP8LO). The extreme UV-sensitivity is also exhibited by the nondividing cells in a survival assay that employs nondividing cell populations and does not involve cell reproduction. This result suggests that the extreme sensitivity measured previously by colony-forming ability (a cell-reproduction assay) is due to the excision repair defect alone and not to an additional post-replication repair defect. The very limited excision allows for an accurate definition of target size for inactivation of nondividing cells, about 1 pyrimidine dimer per 10⁵ base pairs, and when compared to results observed for other XP-A strains, provides further evidence that even though excision repair in group A is severely limited, it has biological significance.     

Action spectra for inactivation of normal and xeroderma pigmentosum human skin fibroblasts by ultraviolet radiations

—Action spectra for UV-induced lethality as measured by colony forming ability were determined both for a normal human skin fibroblast strain (lBR) and for an excision deficient xeroderma pigmentosum strain (XP4LO) assigned to complementation group A using 7 monochromatic wavelengths in the range 254-365 nm. The relative sensitivity of the XP strain compared to the normal skin fibroblasts shows a marked decrease at wavelengths longer than 313 nm. changing from a ratio of about 20 at the shorter wavelengths to just greater than 1.0 at the longer wavelengths. The action spectra thus indicate that the influence on cell inactivation of the DNA repair defect associated with XP cells is decreased and almost reaches zero at longer UV wavelengths. This would occur, for example, if the importance of pyrimidine dimers as the lethal lesion decreased with increasing wavelength. In common with other studies both in bacterial and mammalian cells, our results are consistent with pyrimidine dimers induced in DNA being the major lethal lesion in both cell strains over the wavelength range 254-313 nm. However, it is indicated that different mechanisms of inactivation operate at wavelengths longer than 313 nm.     

SURVIVAL AND PYRIMIDINE DIMERS IN CULTURED FISH CELLS EXPOSED TO CONCURRENT SUN LAMP ULTRAVIOLET AND PHOTOREACTIVATING RADIATIONS

Abstract— Cultured fishcells(RBCF–1 line) were irradiated with filtered sun lamp ultraviolet (SL-UV; > 280 nm) together with or followed by illumination with daylight(DL) radiation (> 350 nm). The colony forming ability of the cells decreased with increasing fluence of SL-UV. Concurrent exposure of cells to SL-UV and DL, however, increased survival relative to exposure to SL-UV alone. The photoreactivable fraction reached 0.52 at22–25_‡C. By using a constant fluence modification factor of 86, the shape of dose-survival curve was found to be almost the same for 254 nm and SL-UV. In parallel with photoreactivation of cell survival, changes in the numbers of pyrimidine dimers in permeabilized cell DNA and in extracted total DNA were determined by measurements of endonuclease-sensitive sites (ESS). The yield of ESS in both DNA's increased almost linearly with increasing SL-UV fluence, although the yield in extracted DNA was about double of that in permeabilized cell DNA. The yield of ESS per unit fluence by 254 nm was about 70-fold greater than SL-UV. The fraction of cells inactivated per ESS was almost the same for 254 UV and SL-UV. In SL-UV-irradiated cells, the photoreactivable fractions in terms of ESS were _‡ 10% higher in extracted DNA than in the DNA of permeabilized cells and also were higher when DL was administered separately after SL-UV-irradiation. When irradiated cells were exposed to DL at 0_‡C, the photoreactivable fractions of both DNAs were appreciably less, indicating that the photoreactivation of ESS was enzymatic. These results support the suggestion that the mechanism for cell killing, mainly formation of pyrimidine dimers, by SL-UV is the same as that by 254 UV.     

Sunlight-induced killing of nondividing human cells in culture

Nondividing populations of human diploid fibroblasts that are DNA excision repair proficient (WS-1, KD. SSCW) and repair deficient (XP12BE) were exposed to mid-day summer sunlight for a determination of survival based on an ability of cells to remain attached to a culture vessel surface. Whereas mid- and far-UV wavelengths and radiation emitted from a sunlamp cause a gradual degeneraton and detachment of cells in a dose-dependent manner, sunlight does not promote cell killing that is evidenced by these criteria in repair proficient cells. Detachment of repair deficient cells is promoted to a limited extent but only at sunlight exposure times that are low with respect to the amount of DNA damage (pyrimidine dimers) induced. Repair proficient and deficient cells exposed to sunlight for longer times do not detach but are incapable of excuding a viable stain several days after exposure and appear as histologically fixed cells. Pyrimidine dimer levels in these sunlight irradiated cells were great enough to have promoted detachment had these levels been induced by UV (254 nm) alone. Other photodamage induced by these exposures evidently inhibits the dimer-induced cell degeneration that leads to cell detachment. We conclude that pyrimidine dimers are responsible for cell killing at short sunlight exposure times (< 40 min) but that at longer exposures (> 80 min) cells arc killed by a different mechanism that is independent of dimer-caused death.     

DNA DAMAGE and ITS REPAIR IN Dictyostelium discoideum IRRADIATED BY HEALTH LAMP LIGHT (UV- B)

Irradiation by health lamp (HL) light (280–320 nm) more efficiently induced cell killing and mutation in a radiation sensitive mutant (TW8) of Dictyostelium discoideum as compared with the parental wild-type strain (NC4). This light as well as a germicidal lamp-light (254 nm) produced pyrimidine dimers. The dimers were removed from DNA molecules by excision repair in NC4, but more slowly in TW8. It is suggested that pyrimidine dimers are the main DNA damage caused by HL light in D. discoideum , and that this results in cell killing and induced mutation.     

PHOTOREACTIVATION OF ICR 2A FROG CELLS EXPOSED TO SOLAR UV WAVELENGTHS

Abstract Exposure of ICR 2A frog cells to photoreactivating light (PRL) following irradiation with a fluorescent sun lamp (FSL) resulted in an enhancement in survival compared with FSL-irradiated cells incubated in the dark. Hence, pyrimidine dimers played a role in the killing of cells exposed to the UV produced by this source. However, when the light was passed through a series of filters to remove increasing segments of the wavelength region shorter than 320 nm, the effect of the PRL progressively decreased, demonstrating that non-dimer photoproducts play an increasingly important role in the killing of cells exposed to wavelengths approaching 320 nm. Cells were also exposed to 313 nm UV produced by a monochromator and it was found, once again, that the effectiveness of the PRL treatment depended on the filter the beam was passed through. These results indicate that for both FSL-produced UV and 313 nm UV emitted by a monochromator, that the critical photoproducts induced within the cell depend on the filter used in conjunction with the UV source.     

INDUCTION OF DNA-PROTEIN CROSSLINKS IN HUMAN CELLS BY ULTRAVIOLET and VISIBLE RADIATIONS: ACTION SPECTRUM

Abstract— DNA-protein crosslinking was induced in cultured human P3 teratocarcinoma cells by irradiation with monochromatic radiation with wavelengths in the range254–434 nm (far-UV, near-UV, and blue light). Wavelength 545 nm green light did not induce these crosslinks, using the method of alkaline elution of the DNA from membrane filters. The action spectrum for the formation of DNA-protein crosslinks revealed two maxima, one in the far-UV spectrum that closely coincided with the relative spectrum of DNA at 254 and 290 nm, and one in the visible light spectrum at 405 nm, which has no counterpart in the DNA spectrum. The primary events for the formation of DNA-protein crosslinks by such long-wavelength radiation probably involve photosensitizers. This dual mechanism for DNA-protein crosslink formation is in strong contrast to the single mechanism for pyrimidine dimer formation in DNA, which apparently has no component in the visible light spectrum.     

INCREASED LEVELS OF UNSCHEDULED DNA SYNTHESIS IN UV-IRRADIATED HUMAN FIBROBLASTS PRETREATED WITH SODIUM BUTYRATE

Pretreatment of growing normal and xeroderma pigmentosum (XP) human fibroblasts with sodium butyrate at concentrations of 5-20 m M results in increased levels of DNA repair synthesis measured by autoradiography after exposure of the cells to 254 nm UV radiation in the fluence range 0-25 J/m². The phenomenon manifests as an increased extent and an increased initial rate of unscheduled DNA synthesis (UDS). This experimental result is not due to an artifact of autoradiography related to cell size. Xeroderma pigmentosum cells from complementation groups A, C, D and E and XP variant cells all exhibit increases in the levels of UV-induced UDS in response to sodium butyrate proportional to those observed with normal cells. These UDS increases associated with butyrate pretreatment correlate with demonstrable changes in intracellular thymidine pool size and suggest that sodium butyrate enhances uptake of exogenous radiolabeled thymidine during UV-induced repair synthesis by reducing endogenous levels of thymidine.     

RELATIVE REPAIR OF ADENOVIRUS DAMAGED BY SUNLAMP, UV AND γ-IRRADIATION IN COCKAYNE SYNDROME FIBROBLASTS IS DIFFERENT FROM THAT IN XERODERMA PIGMENTOSUM FIBROBLASTS

The DNA repair capacities of three unrelated Cockayne syndrome (CS) fibroblast strains were compared to that of three unrelated xeroderma pigmentosum (XP) strains for three different DNA damaging agents using a sensitive host cell reactivation (HCR) technique. Adenovirus type 2 (Ad 2) was treated with either UV light, gamma-rays or sunlamp-irradiation and subsequently assayed for its ability to form viral structural antigens (Vag) in the CS and XP strains using immunofluorescent straining. D37 values for the survival of Ad 2 Vag synthesis in the CS and XP strains, expressed as a percentage of those obtained in normal strains, were used as a measure of DNA repair capacity. Percent HCR values in the XP strains XP25RO, XP2BE and XP5BE respectively were lowest for UV (6, 14 and 6%), intermediate for sunlamp-irradiation (18, 32 and 10%) and highest for gamma-irradiation (65, 61 and 60%), whereas for the CS strains CS1BE, CS3BE and CS278CTO respectively, percent HCR values were lowest for UV (26, 30 and 34%), intermediate for gamma-irradiation (61, 64 and 69%) and near normal for sunlamp-irradiation (82, 73 and 89%). These results suggest that the 'spectrum of lesions' which is defectively repaired in CS is not the same as that which is defectively repaired in XP.     

Absence of photoreactivation of pyrimidine dimers in the epidermis of hairless mice following exposures to ultraviolet light

Abstract—The influence of photoreactivating light on the fate of UV-induced DNA damage has been measured in the epidermis of hairless mice using damage-specific endonuclease from Micrococcus luteus. Groups of mice were exposed to varying fluences of UV at 297nm or from an FS40 fluorescent sun lamp to induce UV photoproducts. The same fluence-dependent DNA damage was observed in high molecular weight epidermal DNA regardless of whether the mice were killed immediately, or maintained in the dark or under photoreactivating light for 20 h after UV. Thus, no detectable photoreactivation of UV-induced pyrimidine dimers could be demonstrated in mouse epithelial cells in vivo.     

TOXICITY, DNA DAMAGE AND INHIBITION OF DNA REPAIR SYNTHESIS IN HUMAN MELANOMA CELLS BY CONCENTRATED SUNLIGHT

A 1 m diameter water lens was used to focus solar radiation, giving an 8-fold concentration of the total spectrum and a cytocidal flux similar to that of laboratory UV sources. Survival curves for human melanoma cells were similar for sunlight and 254 nm UV, in that D _q, was usually larger than D _o. An xeroderma pigmentosum lymphoblastoid line was equally sensitive to both agents and human cell lines sensitive to ionizing radiation (lymphoblastoid lines), crosslinking agents or monofunctional alkylating agents (melanoma lines) had the same 254 nm UV and solar survival responses as appropriate control lines. Two melanoma sublines derived separately by 16 cycles of treatment with sunlight or 254 nm UV were crossresistant to both agents. In one melanoma cell line used for further studies, DNA strand breaks and DNA-protein crosslinking were induced in melanoma cells by sunlight but pyrimidine dimers (paper chromatography) and DNA interstrand crosslinking (alkaline elution) could not be detected. The solar fiuence response of DNA repair synthesis was much less than that from equitoxic 254 nm UV, reaching a maximum near the D _o value and then declining; semiconservative DNA synthesis on the other hand remained high. These effects were not due to changes in thymidine pool sizes. Solar exposure did not have a major effect on 254 nm UV-induced repair synthesis.     

SUNLIGHT-INDUCED PYRIMIDINE DIMERS IN HUMAN SKIN FIBROBLASTS IN COMPARISON WITH DIMERIZATION AFTER ARTIFICIAL UV-IRRADIATION

Abstract— We compared artificial UV-sources such as germicidal- or sun-lamps with summer noon sunlight in Switzerland for selective efficiency in the induction of pyrimidine dimers in the DNA of human cells. In our studies we determined cytosine-thymine (C-T) as well as thymine-thymine dimer densities (T-T) by high pressure liquid chromatography in cultures of xeroderma pigmentosum cells of group A. Using far-UV light from a germicidal lamp, we found a rate of formation per Jirr² for C-T and T-T of 0.0019% and 0.0024%, respectively, of the total thymine radioactivity in hydrolysates of [³H]thymidine labeled cells. After irradiation with an unfiltered sunlamp we measured a rate of formation of 0.0005% per Jm-² both for C-T and T-T, based on the sunlamp emission of 297 ±4 nm wavelength. Utilization of Kodacel- or Mylar-filters lowered the rate of dimerization by a factor of 2 and 60, respectively. One hour of irradiation with noon summer sunlight induced 0.038 ±0.012% C-T and 0.036 ±0.011% T-T. This extent of dimer production is equivalent to 15 Jm^-2 of far-UV exposure at 254 nm.     

INDUCTION OF phr GENE EXPRESSION BY PYRIMIDINE DIMERS IN Escherichia coli

The photoreactivating enzyme (PRE) is concerned with mainly two kinds of light wavelength. The PRE splits UVC (254 nm)-induced pyrimidine dimer by absorbing UVA (320–380 nm) or visible light in its chromophore. The present paper demonstrates that the phr gene expression was efficiently induced in an excision defective strain (uvrA∼) after irradiation by UVC and UVB (290-320 nm), but not by UVA and visible light. In addition, the induced activity was significantly depressed by irradiation with UVA and visible light. Therefore we conclude that the phr gene expression can be induced by pyrimidine dimers.     

IRRADIATION OF CIRCULAR DNA WITH 254 nm RADIATION OR SENSITIZATION IN THE PRESENCE OF Ag+ EVIDENCE FOR UNWINDING BY PHOTOPRODUCTS OTHER THAN PYRIMIDINE DIMERS

Abstract— Structural alterations of DNA irradiated with UV light were analyzed by the agarose gel technique. Relaxed, circular pAT 153 DNA molecules were sensitized by broad band radiation with a maximum at 313 nm in the presence of silver ions or irradiated with 254 nm light in buffer only. In both cases the electrophoretic mobility of DNA topoisomers was altered as a linear function of UV exposure. For DNA irradiated in the sensitized reaction the unwinding angle per site sensitive to Micrococcus luteus pyrimidine dimer endonuclease was found tobe–11.4°. This value is significantly smaller thanthe–14.3° already known for DNA topoisomers irradiated with 254 nm light. The irradiated DNAs were a very good substrate for the Escherichia coli photoreactivating enzyme (PRE). However, the photoenzymic removal of all sites sensitive to the endonuclease specific for pyrimidine dimers was not coupled to a full restoration of the original electrophoretic mobility. Thirty and 23% of the unwinding were still present in the photoreactivated topoisomers and the unwinding angles per pyrimidine dimer were then recalculatedas–10.1°and–8.7° for DNAs irradiated with 254 nm and sensitized, respectively. The limited difference between these two values could result from the different base composition of the pyrimidine dimers generated in the conditions of irradiation used. These results show that the tertiary structure of DNA is measureably altered by UV photodamages other than pyrimidine dimers.     

ULTRAVIOLET LIGHT IRRADIATION OF DEFINED-SEQUENCE DNA UNDER CONDITIONS OF CHEMICAL PHOTOSENSITIZATION

Abstract— The formation of cyclobutane pyrimidine dimers and UV light-induced (6-4) products was examined under conditions of triplet state photosensitization. DNA fragments of defined sequence were irradiated with 313 nm light in the presence of either acetone qr silver ion. UV irradiation in the presence of both silver ion and acetone enhanced the formation of TT cyclobutane dimers, yet no (6-4) photoproducts were formed at appreciable levels. When photoproduct formation was also measured in pyrimidine dinucleotides, only cyclobutane dimers were formed when the dinucleotides were exposed to 313 nm light in the presence of photosensitizer. The relative distribution of each type of cyclobutane dimer formed was compared for DNA fragments that were irradiated with 254, 313, or 313 nm UV light in the presence of acetone. The dimer distribution for DNA irradiated with 254 and 313 nm UV light were very similar, whereas the distribution for DNA irradiated with 313 nm light in the presence of acetone favored TT dimers. Alkaline labile lesions at guanine sites were also seen when DNA was irradiated with 313 nm light in the presence of acetone.