EXCISION REPAIR OF PYRIMIDINE DIMERS IN MARSUPIAL CELLS

Monodelphis domestica was further characterized as a model for photobiological studies by measuring the excision repair capabilities of this mammal's cells both in vivo and in vitro. Excision repair capability of the established marsupial cell line, Pt K2 ( Potorous tridactylus ), was also determined. In animals held in the dark, we observed that ˜50% of the dimers were removed by 12 and 15 h after irradiation with 400 J m⁻² and 600 J m⁻², respectively, from an FS-40 sunlamp (280–400 nm). Cells from primary cultures of M. domestica excised ˜50% of the dimers by 24 h after irradiating with 50 J m⁻² and 36 h after exposure to 100 J m⁻² with no loss of dimers observed 24 h following a fluence of 300 J m⁻². Pt K2 cells were observed to have removed -50% of the dimers at -12 h after 50 J m⁻² with only -10% of the dimers removed at 24 h following 300 J m⁻². The observed loss of pyrimidine dimers from epidermal DNA of UV-irradiated animals and from fibroblasts in culture, held in the dark, suggests that these marsupial cells are capable of DNA excision repair.     

PYRIMIDINE DIMERS INDUCED IN ESCHERICHIA COLI DNA BY ULTRAVIOLET RADIATION PRESENT IN SUNLIGHT

Abstract— Escherichia coli DNA was irradiated with various wavelengths of monochromatic UV light from 254 to 320 nm, and the relative yields of the different cyclobutane pyrimidine dimers determined. Cytosine–thymine dimers (C < > T) were more frequent than thymine dimers (T < > T) at low fluences of 300 and 313 nm light, whereas the reverse was true at either longer or shorter wavelengths. Thus, in the solar UV range deemed responsible for skin cancer (i.e. 295–315 nm), C < > T are probably more important than T < > T.     

EXCISION REPAIR OF UVR-INDUCED PYRIMIDINE DIMERS IN CORNEAL DNA

Abstract— We measured excision repair of ultraviolet radiation (UVR)-induced pyrimidine dimers in DNA of the corneal epithelium of the marsupial, Monodelphis domestica , using damage-specific nucleases from Micrococcus luteus in conjunction with agarose gel electrophoresis. We observed that 100 J ^-2 of UVR from aFS–40 sunlamp(280–400 nm) induced an average of 2.2 ± 0.2 times 10^-2 endonuclease-sensitive sites per kilobase (ESS/kb) (pyrimidine dimers) and that ∼ 50% of the dimers were repaired within 12 h after exposure. We also determined that an exposure of 400 J m^-2 was needed to induce comparable numbers of pyrimidine dimers (2.5 times 10^-2) in the DNA of skin of M. domestica in vivo . In addition, we found that 50% of the dimers were also removed from the epidermal cells of M. domestica within 12 h after exposure. A dose of 100 J m^-2 was necessary to induce similar levels of pyrimidine dimers (2.0 ± 0.2 times 10^-2) in the DNA of the cultured marsupial cell line Pt K2 ( Potorous tridactylus ).     

THE ROLE OF PYRIMIDINE DIMERS AND NON-DIMER DAMAGE IN THE INACTIVATION OF ESCHERICHIA COLI BY UV RADIATION

Abstract— We have quantitated the role of pyrimidine dimers and non-dimer damage in the inactivation of Escherichia coli by far-UV radiation, near-UV radiation, and triplet state sensitized near-UV radiation. The extent of photoreactivation in vivo of an excision and postreplication repair-deficient strain of E. coli after the different radiation treatments has been correlated with the relative proportion of pyrimidine dimers and non-dimer lesions produced. Using an excision deficient strain of E. coli, the susceptibility to recA ⁺ -dependent repair of the damage produced by the different radiation treatments has also been quantified.     

MORE EFFICIENT EXCISION REPAIR OF PYRIMIDINE DIMERS IN THE SPECIFIC DNA SEQUENCE THAN IN THE GENOME OVERALL IN GOLDFISH CELLS

Excision repair of pyrimidine dimers induced by 254 nm UV was examined in the genome overall and in a specific sequence containing a transfected gene for hygromycin B resistance, in RBCF-1 cells derived from a goldfish, by the use of UV endonuclease of Micrococcus luteus and alkaline agarose gel electrophoresis. More than 40% of dimers were removed from the specific sequence, while about 20% were removed from the genome overall, within 24 h after exposure to UV (2.5-7.5 J/m2).     

ALPHA POLYMERASE INVOLVEMENT IN EXCISION REPAIR OF DAMAGE INDUCED BY SOLAR RADIATION AT DEFINED WAVELENGTHS IN HUMAN FIBROBLASTS

Abstract Cultured fibroblasts derived from normal human skin have been irradiated at a series of monochromatic wavelengths throughout the ultraviolet region and exposed to the specific α polymerase inhibitor, aphidicolin (1 μg/m l , 2 days) prior to assay for colony forming ability. Repair of 75-80% of the lethal damage induced by UVC (254 nm) or UVB (302 nm, 313 nm) radiation is inhibited by aphidicolin suggesting that such damage is repaired by a common α polymerase dependent pathway. Exposure to aphidicolin after irradiation at longer UVA (334 nm, 365 nm) or a visible (405 nm) wavelength leads to slight protection from inactivation implying that the processing of damage induced in this wavelength region is quite distinct from that occurring at the shorter wavelengths and does not involve α polymerase.     

EXCISION OF CYCLOBUTANE DIMERS IN GENOMIC AND EPISOMAL DNA IN HUMAN CELLS

Abstract Direct determination has been made of cyclobutyl pyrimidine dimer induction and excision repair in an episomal SV40 DNA population in vivo . Maintaining SV40-transformed human (GM637) cells in confluent culture results in amplification of a mutant SV40 episome to high copy number. T4 endonuclease V was used to quantify the induction and repair of cyclobutane dimers in the SV40 episome and genomic DNA of the same cells. Differences in both parameters were observed cyclobutane dimers were induced at 1.5–2-fold greater frequency in episomal DNA and excised at a reduced rate compared to genomic DNA in the host cells.     

EFFICIENCY OF REPAIR OF PYRIMIDINE DIMERS AND PSORALEN MONOADDUCTS IN NORMAL AND XERODERMA PIGMENTOSUM HUMAN CELLS

Abstract —Repair of DNA damage produced by ultraviolet light or 5-methylisopsoralen in normal and xeroderma pigmentosum human cells involves many similar steps. Aphidicolin and cytosine arabinoside block repair of both kinds of damage with similar efficiency, indicating that DNA polymerase a has a major role in repair for these lesions. In xeroderma pigmentosum cells of various complementation groups, the relative efficiency of excision repair for both ultraviolet- and 5-methylisopsoralen-induced damage was group A < C < D, indicating a close resemblance between both kinds of lesions in relation to the repair deficiencies in these groups. At high doses, the maximum rate of repair of damage by ultraviolet light was about twice that for methylisopsoralen damage, possibly because ultraviolet-induced damage forms a substrate that is more readily recognized and excised than that of the psoralen adducts. Differences in the structural distortions to DNA caused by these kinds of damage could be detected using single strand specific nucleases which excised dimers but not 5-MIP adducts from double strand DNA.     

STUDY OF PYRIMIDINE DIMERS IN MAMMALIAN CELLS SURVIVING LOW DOSES OF ULTRAVIOLET RADIATION*

Abstract— Ultraviolet-induced pyrimidine dimers were not found to be excided from the DNA of Chinese hamster cells in small oligounucleotides. At doses whereby many cells survive the radiation, the dimers were still associates with the large polynucleotides even after 48 hr of postirradiation incubation.     

REPAIR OF CYCLOBUTANE DIMERS AND (6–4) PHOTOPRODUCTS IN ICR 2A FROG CELLS

Abstract— The removal of cyclobutane dimers and Pyr(6–4)Pyo photoproducts from the DNA of UV-irradiated ICR 2A frog cells was determined by radioimmunoassay. In the absence of photoreactivat-ing light, 15% of the cyclobutane dimers and 60% of the (6–4) photoproducts were removed 24 h post-irradiation with 10 J m⁻², Exposure to 30 kJ m⁻² photoreactivating light resulted in removal of 80% of the cyclobutane dimers and an enhanced rate of repair of (6–4) photoproducts, resulting in a loss of 50% of these lesions in 3 h. The preferential removal of (6–4) photoproducts by excision repair resembles previously published data for mammalian cells.     

CORRELATION BETWEEN INACTIVATION OF HUMAN CELLS and NUMBERS OF PYRIMIDINE DIMERS INDUCED BY A SUN LAMP and 254 nm RADIATION

Abstract— Nondividing human fibroblasts are inactivated by radiation from a source (a Westinghouse sun lamp) that simulates the UV spectrum of sunlight. Survival curves determined for a DNA excision repair-proficient and a repair-deficient strain (XP12BE) are related to those determined using germicidal light (254 nm) by constant fluence modification factors. In addition, the same fraction of XP12BE cells are killed per pyrimidine dimer by 254 nm and sun lamp light. These results, when related to other survival and photoreactivation studies, suggest that the mechanism for inactivation of nondividing human cells by sun lamp light is the same as that by 254 nm and that pyrimidine dimers are the major responsible photolesion. Repair reverses some of the lethal effects of this light. We suggest that these conclusions apply to sunlight-irradiated skin cells in vivo.     

PHOTOREACTIVATION OF ICR 2A FROG CELLS AFTER EXPOSURE TO MONOCHROMATIC ULTRAVIOLET RADIATION IN THE 252–313 nm RANGE

Abstract— Exposure of ICR 2A frog cells to photoreactivating light after treatment with monochromatic ultraviolet (UV) radiation in the 252–313 nm range resulted in an increase in survival with similar photoreactivable sectors for each of the wavelengths tested. As photoreactivating enzyme is specific for the repair of pyrimidine dimers in DNA, these findings support the hypothesis that these are critical lesions responsible for killing of cells exposed to UV radiation in this wavelength range. The action spectra for cell killing and production of UV-endonuclease sensitive sites were similar to the DNA absorption spectrum though not identical. Because the number of endonuclease sensitive sites is a reflection of the yield of pyrimidine dimers, these data also suggest that the induction of dimers in DNA by UV radiation in the 252–313 nm range is the principal event leading to cell death.     

PHOTOREACTIVATION and EXCISION REPAIR OF UV INDUCED PYRIMIDINE DIMERS IN THE UNICELLULAR CYANOBACTERIUM GLOEOCAPSA ALPICOLA (SYNECHOCYSTIS PCC 6308)

Abstract— The survival curve obtained after UV irradiation of the unicellular cyanobacterium Synecho-cystis is typical of a DNA repair competent organism. Inhibition of DNA replication, by incubating cells in the dark, increased resistance to the lethal effects of UV at higher fluences. Exposure of irradiated cells to near ultraviolet light(350–500 nm) restored viability to pre-irradiation levels. In order to measure DNA repair activity, techniques have been developed for the chromatographic analysis of pyrimidine dimers in Synechocystis. The specificity of this method was established using a haploid strain of Sacchar-omyces cerevisiae. In accordance with the physiological responses of irradiated cells to photoreactivating light, pyrimidine dimers were not detected after photoreactivation treatment. Incubation of irradiated cells under non-photoreactivating growth conditions for 15 h resulted in complete removal of pyrimidine dimers. It is concluded that Synechocystis contains photoreactivation and excision repair systems for the removal of pyrimidine dimers.     

SITES OF PHOTODYNAMICALLY INDUCED DNA REPAIR IN HUMAN CELLS

Abstract Human REH cells were incubated with the photosensitizers meso -tetra(4-sulfonatophenyl)porphyrin (TSPP=TPPS₄) or meso -tetra(3-hydroxyphenyl)porphyrin (3-THPP). The relatively hydrophilic TSPP was partly found in the cytoplasm and partly in the nuclei, whereas the lipophilic 3-THPP was found apparently in membranes and not inside the nuclei. After illumination, sites of DNA repair were labeled by means of a monoclonal antibody against proliferating cell nuclear antigen (PCNA) bound in the nuclei. The amount of bound PCNA in non-S-phase cells was proportional to the light dose. The bound PCNA was homogeneously distributed in the nuclei 0.5 h after photodynamic treatment (PDT) with TSPP. In contrast, for cells given PDT with 3-THPP, the periphery of the nuclei was selectively labeled, indicating that the initial DNA damage was localized close to the sensitizer at the nuclear membrane.     

IN VIVO EXCISION OF PYRIMIDINE DIMERS IS MEDIATED BY A DNA N-GLYCOSYLASE IN MICROCOCCUS LUTEUS BUT NOT IN HUMAN FIBROBLASTS

Abstract It has been previously shown that Micrococcus luteus possesses a pyrimidine dimer-specific endonuclease which in vitro , functions as both an endonuclease and DNA-glycosylase. To determine if these combined activities function in vivo , we have isolated and examined the excision products of UV-irradiated M. luteus . In addition, we have devised a procedure to isolate and examine the excision products from UV-irradiated human fibroblasts to determine if an endonuclease/glycosylase activity functions in the excision of UV-induced pyrimidine dimers in human fibroblasts. We find that, in vivo , an endonuclease/glycosylase mechanism is utilized extensively in the repair of pyrimidine dimers by M. luteus , but that human fibroblasts do not appear to use this mechanism.     

MOLECULAR CLONING OF THE HUMAN GENE SUVCC1 ASSOCIATED WITH THE REPAIR OF NONDIMER DNA DAMAGE INDUCED BY SOLAR UV RADIATION

Abstract— A mutant cell line, DRP 287, sensitive to solar UV radiation and deficient in the repair of solar UV-induced nondimer DNA damage, was derived from ICR 2A frog cells. These cells were transfected with human DNA and a secondary transformant obtained in which normal solar UV sensitivity was restored and the repair defect corrected. The DNA from this secondary transformant was used to construct a genomic DNA library from which a recombinant phage was isolated containing the human gene capable of restoring normal solar UV sensitivity and correcting the repair defect in the DRP 287 cells. This represents the first human gene which has been isolated that is specifically involved in the repair of nondimer DNA damage induced by solar UV radiation. It has been designated SUVCC1 to denote solar UV cross-complementing gene number 1.     

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.     

THE FATE OF PYRIMIDINE DIMERS IN THE DNA OF ULTRAVIOLET-IRRADIATED CHINESE HAMSTER CELLS

Abstract —As an aid to understanding the relationship between dimer repair and cellular recovery, we have studied dimer removal and replication of dimer-containing DNA in Chinese hamster ovary (CHO) cells irradiated with ultraviolet light (254 nm). These investigations demonstrated that (1) dimers are not excised as polynucleotides of less than 500,000 mol. wt, (2) fractionation of the ultraviolet dose does not enhance dimer excision, (3) dimer-containing DNA is replicated in ultraviolet-irradiated CHO cells, and (4) the dimers are conserved in the replicated DNA. These findings support the proposed mechanism of bypass of photoproducts during DNA replication in mammalian cells.     

CORRELATION BETWEEN ENDOGENOUS GLUTATHIONE CONTENT AND SENSITIVITY OF CULTURED HUMAN SKIN CELLS TO RADIATION AT DEFINED WAVELENGTHS IN THE SOLAR ULTRAVIOLET RANGE

Abstract— Glutathione depletion of cultured human skin fibroblasts by treatment with buthionine-S,R-sulfoximine (BSO) sensitises them to radiation at a series of defined wavelengths throughout the solar UV range. We now show that there is a close quantitative correlation between cellular glutathione content (as depleted by BSO) and sensitivity to radiation at 365 nm. A weaker correlation is observed when cells are depleted of glutathione using diethylmaleimide. Both fibroblasts and epidermal keratinocytes derived from the same foreskin biopsy are sensitised to radiation at 313 nm by glutathione depletion. However, the keratinocytes are sensitised to a much lesser extent, an observation which agrees quantitatively with the higher residual levels of cellular glutathione remaining after maximum depletion by BSO (approximately 25% for the keratinocytes vs less than 5% for the fibroblasts). At low to intermediate fluence levels, 10 mM cysteamine present during irradiation at 302 nm is able to almost completely reverse the sensitising effects of glutathione depletion suggesting that the endogenous thiol protects against radiation at this wavelength by a free radical scavenging mechanism. At 313 nm, the sensitisation is not reversed by cysteamine suggesting that glutathione plays a more specific role in protection against radiation at longer wavelengths. Xeroderma pigmentosum group A fibroblasts (excision deficient) are also sensitised to radiation at 313 and 365 nm by depletion of glutathione but since the sensitization is less than that observed for the normal strain, we cannot conclude that glutathione protects against a sector of DNA damage susceptible to excision repair. The results provide further evidence that endogenous glutathione is involved in protecting human skin cells against a wide range of solar radiation damage and suggest that while free radical scavenging is involved at the shortest wavelength (302 nm) tested, a more specific role of glutathione is involved in protection against radiation at longer wavelengths.     

SEQUENCE-SPECIFICITY OF THE ALKALI-SENSITIVE LESIONS INDUCED IN DNA BY HIGH-INTENSITY ULTRAVIOLET LASER RADIATION

The action of high-intensity (10(9)-10(12) W/m2) UV (266 nm) laser radiation pulses (duration ca 10 ns or ca 40 ps) on liquid aqueous solutions of DNA is known to cause not only single- but also two-quantum modification of nucleic bases. The action of hot piperidine on the laser-irradiated DNA results in non-random splitting of polynucleotide chain. Hence, at least some of the modified nucleoside residues are alkali-sensitive lesions (ASLs). The distribution of ASLs along the DNA chain shows that the position of these lesions corresponds with pyrimidines in the PyPy sequences (similar to those formed via single-quantum conversions) as well as with deoxyguanosine residues. The last ASLs result from two-quantum reactions and occur much more efficiently than the direct photo-induced cleavage of the internucleotide (phosphodiester) bond. It has been shown with fragments of plasmids pUC18, pUC19 and pBR322 (total length over 600 base pairs) that the relative efficiency of ASLs at deoxyguanosine sites depends on the primary structure context and can differ by an order of magnitude. The highest efficiency of modification is observed when a purine is 3' neighbour to the 2'-deoxyguanosine, i.e. at 5'-GPu-3' sites. However, considerable variations in the modification efficiency were also found in these sequences.