DNA DAMAGE AND REPAIR: INDUCTION AND REMOVAL OF THYMINE DIMERS IN ULTRAVIOLET LIGHT IRRADIATED INTACT WATER PLANTS

Abstract— The production of UV-induced thymine dimers and their fate upon post-irradiation incubation in the dark was studied in DNA of the intact water plants Wolffia microscopica and Spirodela polyrhiza. The results demonstrate production of thymine dimers, and the ability of the plant cells to remove the dimers from their DNA. The rate of removal is rapid during the first few h of post-irradiation incubation in the dark. It continues at a slower rate for the next 24–48 h, at which time it is essentially complete. The disappearance of thymine dimers in light or in the dark is analogous to the well-known processes in other biological systems, namely, photoreactivation and dark excision.     

PHOTOREVERSIBILITY OF UV-INDUCED THYMINE DIMERS AND ABNORMAL MORPHOGENESIS IN SEA-URCHIN EMBRYOS

Abstract— Irradiation of synchronously dividing 16-cell embryos of a sea-urchin ( Hemicentrotus pul-cherrimus ) with 200 J m⁻² of UV light (254 nm) resulted in the complete inhibition of normal pluteus-larva formation when the embryos were cultured in the dark after UV-irradiation. Illumination of the UV-irradiated embryos with visible light (11 W m⁻²) for 1 h immediately after the UV-irradiation reversed the abnormal morphogenesis. Measurement of thymine dimers indicates that the degree of UV-induced abnormal morphogenesis is greatly correlated with the amount of thymine dimers in the DNA of the embryos. The degree of the photoreversal decreased with an increase in the interval between UV-irradiation and exposure to visible light. Visible light was ineffective as to the reversibility of both thymine dimers and the abnormal morphogenesis at 60 min after the UV-irradiation, when the UV-irradiated 16-cell embryos entered the next cell cycle.     

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.     

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.     

ENHANCEMENT OF PHOTOREPAIR OF ULTRAVIOLET-DAMAGE BY PREILLUMINATION WITH FLUORESCENT LIGHT IN CULTURED FISH CELLS

Fluorescent light (FL) illumination of RBCF-1 cells, derived from a goldfish, prior to 254 nm UV-irradiation enhanced their ability to photorepair. The cells were illuminated with FL for 1 h (29 W/M2) and incubated for 8 h in the dark before being irradiated with 10 J/m2 UV. The surviving fraction of FL-treated cells after UV-irradiation rose about 7-fold (from 3 to 20%) by 20 min photorepair treatment with the same FL source, whereas 4-fold (from 1.6 to 6%) in the FL non-treated cells. Flow cytometric analysis showed that FL treatment did not affect the distribution of cell cycle phase at the time of UV-irradiation (8 h after FL treatment). Pyrimidine dimers induced by UV were measured by the use of UV endonuclease of Micrococcus luteus and alkaline agarose gel electrophoresis. Initial yields of dimers after exposure to 10 J/m2 UV were almost the same (about 0.11 dimer/kb) between FL treated and non-treated cells. But after 20 min photorepair treatment, about 70% of dimers were removed in the FL treated samples, while less than 20% were removed in the non FL-treated ones.     

ENHANCEMENT OF PHOTOREPAIR OF ULTRAVIOLET-INDUCED PYRIMIDINE DIMERS BY PREILLUMINATION WITH FLUORESCENT LIGHT IN THE GOLDFISH CELL LINE. THE RELATIONSHIP BETWEEN SURVIVAL AND YIELD OF PYRIMIDINE DIMERS

The enhancement of photorepair of UV-induced pyrimidine dimers by preillumination with fluorescent light, previously reported with RBCF-1 cells derived from caudal fin of a goldfish, was studied in terms of clonogenic ability and yields of dimers. In the logarithmic growth phase, the ability of photorepair increased with the time after preillumination, reached a maximum at 8 h, and gradually declined. At 8 h, the dose decrement with the photorepair-treatment for 20 min at 7.5 J/m2 UV increased by preillumination for 1 h from 1.6 to 3.1 J/m2 in terms of restoration of survival and from 1.2 to 4.3 J/m2 in terms of the disappearance of dimers. Incubation of the preilluminated cells in the medium containing cycloheximide (0.5 microgram/mL) after preillumination until UV-irradiation diminished their enhancement of photorepair. In the density-inhibited state, the ability of photorepair was higher than in the log phase, and it was hardly enhanced by preillumination.     

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.     

In situ PYRIMIDINE DIMER DETERMINATION BY LASER CYTOMETRY

By using antiserum against pyrimidine dimers and argon-laser imaging microspectrofluorometry, we established a new method to determine UV-induced pyrimidine dimers and their repair in individual human cells. The method was sensitive enough to determine dimers induced by UV dose as low as 2 J/m2. Normal human cells repaired 50 and 60% of total damage within 8 and 24 h after UV irradiation (20 J/m2), but Xeroderma pigmentosum cells (complementation group A) were unable to repair any within the same period. Therefore, the method proved to be a quick, easy, sensitive and accurate means to determine pyrimidine dimers in situ.     

Peculiar properties of chlorophyll thermoluminescence emission of autotrophically or mixotrophically grown Chlamydomonas reinhardtii

The microalgae Chlamydomonas reinhardtii and Chlorella sp. CCAP 211/84 were grown autotrophically and mixotrophically and their thermoluminescence emissions were recorded above 0 °C after excitation by 1, 2 or 3 xenon flashes or by continuous far-red light. An oscillation of the B band intensity according to the number of flashes was always observed, with a maximum after 2 flashes, accompanied by a downshift of the B band temperature maximum in mixotrophic compared to autotrophic grown cells, indicative of a dark stable pH gradient. Moreover, new flash-induced bands emerged in mixotrophic Chlamydomonas grown cells, at temperatures higher than that of the B band. In contrast to the afterglow band observed in higher plants, in Chlamydomonas these bands were not inducible by far-red light, were fully suppressed by 2 μM antimycin A, and peaked at different temperatures depending on the flash number and growth stage, with higher temperature maxima in cells at a stationary compared to an exponential growth stage. These differences are discussed according to the particular properties of cyclic electron transfer pathways in C. reinhardtii.     

Repair processes on deoxyribonucleic acid

Many cells have the ability to recognize and eliminate damage to their DNA, particularly thymine dimers formed by UV light. The elimination of this damage may be achieved by enzymatic, light-dependent cleavage of the dimers into the monomers (photoreactivation) or more frequently by dark repair, in which the damaged part is completely removed from the, DNA. In this repair process, the DNA is incised by an endonuclease in the immediate vicinity of the thymine dimers. Oligonucleotides containing the thymine dimer are removed hydrolytically from the DNA by the 5→3′ exonuclease activity of DNA polymerase I (Kornberg enzyme). The resulting gaps are immediately closed by a de novo synthesis with the aid of the same DNA polymerase I, the complementary strand serving as a template (excision repair). The final step is the formation of the phosphodiester bond between the newly synthesized DNA fragment and the old DNA strand by a DNA ligase. Xeroderma pigmentosum patients lack the endonuclease as a result of a genetic defect; they therefore cannot eliminate thymine dimers from their DNA, and are extremely sensitive to sunlight. All information so far suggests that genetic recombination and DNA repair are performed by the same enzyme system.     

CHARACTERIZATION OF ANTIBODIES SPECIFIC FOR UV-DAMAGED DNA BY ELISA

Abstract— The specificity of affinity purified antibodies raised against UV-irradiated DNA was examined using an enzyme-linked immunosorbent assay. DNA irradiated with UV doses higher than needed for saturation with pyrimidine dimers bound increasing amounts of antibody. Photosensitized DNA, containing high amounts of pyrimidine dimers, showed very poor binding of antibody. When UV-irradiated DNA was given a second dose of 340-nm UV light, the binding of antibodies was abrogated. Taken together, this indicates a major specificity for (6-4)-photoproducts, which are photochemically reversed by UV light in the 340-nm region. The antibodies also showed little but detectable binding to pyrimidine glycols produced in DNA by oxidation with O_sO₄. Previously, we have used these antibodies for the detection of UV-induced DNA damage and its repair in human skin in vivo. These findings indicate that (6-4)-photoproducts, considered highly mutagenic, are repaired in human skin.     

EFFECT OF PHOTOREACTIVATING LIGHT ON LETHAL AND PRE-MUTATIONAL UV LESIONS IN ESCHERICHIA COLI WP2s CARRYING THE R46 MUTATOR PLASMID

Abstract—An excision-deficient E. coli strain carrying the R46 mutator plasmid showed a different response towards photo-reactivation after UV irradiation than the same strain without plasmid. While the photoreactivation of lethal lesions was comparable in both strains, the number of UV-induced mutants per 10⁶ survivors was slightly reduced for the plasmid bearing strain by photoreactivating light at UV fluences below 60 mJ/m² but increased at higher fluences. To explain this it is proposed that some UV photoproduct(s) of DNA other than cyclobutane dipyrimidine dimers are pre-mutational lesions for error-prone DNA repair by the plasmid, P-repair, but not for SOS-repair.     

RETARDATION OF ULTRAVIOLET LIGHT ACCELERATED CHLOROSIS BY VISIBLE LIGHT OR BY BENZYLADENINE IN NICOTIAN A GLUTINOSA LEAVES: CHANGES IN AMINO ACID CONTENT AND CHLOROPLAST ULTRASTRUCTURE*

Abstract— Low doses (180–720 Jm^-2) of ultraviolet light (254 nm) are known to accelerate the chlorosis of detached leaves in darkness. The development of such chlorosis is prevented by a photoreactivation treatment. However, we found that delayed light exposure or benzyladenine treatments (which were not effective in photorepair of UV-induced thymine dimers in cell DNA) were also effective in retarding the UV-accelerated chlorosis. Small drops of benzyladenine solution placed on the UV irradiated leaf formed green islands which acted as strong sinks for the accumulation of free amino acids during dark incubation. To a lesser degree, non–irradiated green tissues surrounded by irradiated yellow leaf tissue also acted as sinks for amino acid accumulation. The accelerated chlorophyll loss in UV-irradiated leaves was correlated with degradation of chloroplast ultrastructure. Visible light or benzyladenine retarded this chloroplast degradation. The accelerated senescence of UV irradiated leaf tissue, therefore, is ultrastructurally and physiologically similar to normal senescence of detached dark-incubated leaves, but progresses at a faster rate. When the lower leaf surface was irradiated with high UV doses (3600–10,800 Jm^-2), the chloroplast ultrastructure of the spongy cells (except the envelope) was preserved for 3 days after dark incubation. However, the chloroplasts of the palisade cells were in a late stage of senescence. Since the spongy cells were dead (plasmalemma, tonoplast and chloroplast envelope disappeared), the maintenance of green color and ultrastructure of chloroplasts could have been due to inhibition of degrading enzymes normally associated with senescence.     

COMPARATIVE STUDIES ON THE CORRELATION BETWEEN PYRIMIDINE DIMER FORMATION and TYROSINASE ACTIVITY IN CLOUDMAN S91 MELANOMA CELLS AFTER ULTRAVIOLET-IRRADIATION

We compared the induction of pyrimidine dimer densities after UV-irradiation in mouse melanoma cells before and after treatment with cholera toxin. Treatment with cholera toxin stimulated tyrosinase activity up to 50-fold, leading to a marked, visually apparent increase in cellular melanin concentrations. Irradiation of treated and untreated cells was therefore designed to establish whether intracellular melanin protected cells from UV-induced DNA damage. In experiments described here, we determined cytosine-thymine (C-T) as well as thymine-thymine dimer levels (T-T) by high pressure liquid chromatography in cholera toxin-treated and untreated Cloudman S91 mouse melanoma cells after irradiation with UVC (less than 290 nm) and UVB light (290-320 nm). Surprisingly, induction of melanization had no effect on the formation of pyrimidine dimers by UVC or UVB irradiation. These results indicate that de novo melanin pigmentation induced via the c-AMP pathway is not involved in protection against UV-induced thymine-containing pyrimidine dimers. In separate experiments, irradiation of toxin-treated and untreated mouse melanoma cells with UVC or UVB light produced a 20-30% lower dimer density compared to irradiated human skin fibroblasts. This finding suggests that melanin has some protection properties against UV-induced pyrimidine dimers, although the exact defense mechanism seems highly complex.     

MULTIPLE EFFECTS OF FLUORESCENT LIGHT ON REPAIR OF ULTRAVIOLET-INDUCED DNA LESIONS IN CULTURED GOLDFISH CELLS

Abstract— It is known that fluorescent light illumination prior to UV irradiation (FL preillumination) of cultured fish cells increases photorepair (PR) ability. In the present study, it was found that FL preillumination also enhanced UV resistance of logarithmically growing cells in the dark. This enhancement of UV resistance differs from induction of PR because it was not suppressed by cycloheximide (CH) and it occurred immediately after FL preillumination. The effects of FL preillumination on repair of UV-induced DNA lesions in the dark were examined by an endonuclease-sensitive site assay to measure the repair of cyclobutyl pyrimidine dimers, and by enzyme-linked immunosorbent assay to quantitate the repair of (6-4) photoproducts. It was found that excision repair ability for (6-4) photoproducts in the genome overall was increased by FL preillumination. Moreover, a decrease in (6-4) photoproducts by FL illumination immediately after UV irradiation of the cells was found, the decrement being enhanced by FL preillumination with or without CH.     

PHOTOREACTIVATION OF ULTRAVIOLET LIGHT-INDUCED DAMAGE IN CULTURED FISH CELLS AS REVEALED BY INCREASED COLONY FORMING ABILITY AND DECREASED CONTENT OF PYRIMIDINE DIMERS

Abstract— Cultured cells derived from a goldfish were irradiated with 254nm ultraviolet light. Cell survival and splitting of pyrimidine dimers after photoreactivation treatment with white fluorescent lamps were examined by colony forming ability and by a direct dimer assay, respectively. When UV-irradiated (5 J/m²) cells were illuminated by photoreactivating light, cell survival was enhanced up to a factor of 9 (40min) followed by a decline after prolonged exposures. Exposure of UV-irradiated (15 J/m²) cells to radiation from white fluorescent lamps reduced the amounts of thymine-containing dimers in a photoreactivating fluence dependent manner, up to about 60% reduction at 120 min exposure. Keeping UV-irradiated cells in the dark for up to 120min did not affect either cell survival or the amount of pyrimidine dimers in DNA, indicating that there were not detectable levels of a dark-repair system in the cells under our conditions. Correlation between photoreactivation of colony forming ability and photoreactivation of the pyrimidine dimers was demonstrated, at least at relatively low fluences of photoreactivating light.     

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.     

DNA REPAIR IN THE VARIABLE PLATYFISH (Xiphophorus variatus) IRRADIATED in vivo WITH ULTRAVIOLET B LIGHT

Abstract— Dark- and light-dependent DNA repair processes were studied in vivo in the variable platyfish, Xiphophorus vuriatus . Excision (dark) repair of the (6–4) photoproduct was more efficient than that of the cyclobutane dimer with ∼ 70% of the (6–4) photoproducts reniovcd by 24 h post-UVB radiation compared to ∼30% of the cyclobutane dimers. Exposure to photoreactivating light resulted in rapid loss of most (>90%) of the cyclobutane dimers and increased excision repair of the (6–4) photoproduct. Preexposure to photoreactivating light 8 h prior to UVB radiation increased the rate of photoreactivation two-fold.     

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).     

RECOVERY OF SUBCHROMOSOMAL DNA SYNTHESIS IN SYNCHRONOUS V-79 CHINESE HAMSTER CELLS AFTER ULTRAVIOLET LIGHT EXPOSURE

Abstract— Previous work obtained from Chinese hamster V-79 cells indicated that, immediately following exposure, UV-induced lesions acted as blocks to elongation of nascent strands, but gradually lost that ability over a 10 h period after exposure to 10 J/m². The work reported herein attempted to examine possible cell cycle mediated alterations in the recovery of DNA synthesis. Kinetic incorporation of radiolabeled thymidine studies indicated that there may have been a more rapid recovery of DNA synthesis in cells irradiated in G₁ or G₂ vs cells irradiated in S phase. DNA fiber autoradiograms prepared from synchronous cells indicated that after irradiation in any phase of the cell cycle, the length of newly synthesized DNA was equal to control lengths 1 h after exposure to 5.0 J/m² (or 1 h after entering S phase for cells irradiated in G₁ or G₂). This observed recovery was not solely due to an excision process. No cell cycle mediated difference in the number of dimers induced or removed as a function of cell cycle position was observed. These results appear to be consistent with a continuum of effects, with initiation effects dominating the response at low fluences, gapped synthesis at intermediate fluences and elongation inhibition at high fluences. The fluences at which each event dominates may be cell-line specific.