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.     

Photoreactivity of UV-b damage in bacteriophage phi X174 DNA

Abstract— The fraction of biological damage in isolated single-strand and double-strand forms of bac-teriophage DNA resulting from pyrimidine dimers following exposure to germicidal UV (254 nm) and UV-B (280-320. nm) radiation has been compared. Radiation from a Westinghouse FS-40 sunlamp filtered through a cellulose acetate sheet was used as the UV-B radiation source. Biological damage from pyrimidine dimers was determined by measuring the survival of the viral DNA with and without photoreactivation, an enzymatic process specific for repair of pyrimidine dimers. The same fraction of biological damage in the single strand and double–strand forms of φX174 DNA is repairable by photo-reactivation following exposures to germicidal UV and UV-B radiation.     

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.     

QUANTITATION OF PYRIMIDINE DIMERS BY IMMUNOSLOT BLOT FOLLOWING SUBLETHAL UV-IRRADIATION OF HUMAN CELLS

An immunoslot blot assay was developed to detect pyrimidine dimers induced in DNA by sublethal doses of UV (254 nm) radiation. Using this assay, one dimer could be detected in 10 megabase DNA using 200 ng or 0.5 megabase DNA using 20 ng irradiated DNA. The level of detection, as measured by dimer specific antibody binding, was proportional to the dose of UV and amount of irradiated DNA used. The repair of pyrimidine dimers was measured in human skin fibroblastic cells in culture following exposure to 0.5 to 5 J m^-2 of 254 nm UV radiation. The half-life of repair was approximately 24, 7 and 6 h in cells exposed to 0.5, 2 and 5 J m^-2 UV radiation, respectively. This immunological approach utilizing irradiated DNA immobilized to nitrocellulose should allow the direct quantitation of dimers following very low levels of irradiation in small biological samples and isolated gene fragments.     

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.     

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.     

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.     

Photorepair of pyrimidine dimers in the epidermis of the marsupial Monodelphis domestica

Abstract Induction and fate of ultraviolet radiation-induced pyrimidine dimers in DNA have been measured in the epidermis of the marsupial, Monodelphis domestica, using damage-specific endonucleases from Micrococcus luteus. Approximately 90% of the dimers are lost when irradiated animals are subjected to photoreactivating light for 180 min. No loss of dimers was detected when the animals were held for a similar period of time in the dark. The capacity of these epithelial cells to photorepair pyrimidine dimers may provide a useful whole animal system in which to determine the role of pyrimidine dimers in photobiological responses of the skin.     

PHOTOREACTIVATION OF ULTRAVIOLET IRRADIATED NON-DIVIDING POPULATIONS OF ICR 2A FROG CELLS

Abstract— Ultraviolet (UV) irradiation of non-dividing populations of ICR 2A frog cells led to their detachment from the surface of the culture dish and eventual lysis. Exposure of the cells to photoreactivating light after UV irradiation prevented cell killing and was accompanied by a loss of endonuclease sensitive sites from DNA. This photoreversal did not take place when the cells were exposed at 4°C to photoreactivating light indicating that the reversal was the result of photoenzymatic repair. As the action of photoreactivating enzyme is specific for the repair of pyrimidine dimers in DNA, these results suggest that pyrimidine dimers in DNA are the critical lesions leading to the death of non-dividing populations of UV irradiated cells.     

Excision-repair capacity of UV-irradiated strains of Escherichia coli and Streptococcus pneumoniae, estimated by plasmid recovery

Although the biological role of many bacterial repair genes is known, there is still an interest in evaluating the capacity of repair pyrimidine dimers in some strains. For this purpose, we have developed a rapid assay. Cells bearing a plasmid are UV irradiated and incubated to allow recovery. The plasmid DNA is extracted, purified and treated with UV endonuclease from Micrococcus luteus that specifically produces single strand breaks at the site of pyrimidine dimers. The amount of open circular and covalently closed circular forms of the plasmid DNA after treatment and post-incubation provides an estimate of the repair capability of the host strain. The wild type strain and the uvrA mutant of Escherichia coli were used to adjust the assay. The lexA mutant of E. coli has been tested and its repair capability is equivalent to that of wild-type strain. The assay has been extended to Streptococcus pneumoniae, which is naturally deficient in photoreactivation and SOS-like functions. This strain is efficient in the repair of pyrimidine dimers, formed after UV irradiation.     

Insight in DNA Repair of UV‐induced Pyrimidine Dimers by Chromatographic Methods

UV‐induced formation of pyrimidine dimers in DNA is a major deleterious event in both eukaryotic and prokaryotic cells. Accumulation of cyclobutane pyrimidine dimers and pyrimidine (6‐4) pyrimidone photoproducts can lead to cell death or be at the origin of mutations. In skin, UV induction of DNA damage is a major initiating event in tumorigenesis. To counteract these deleterious effects, all cell types possess DNA repair machinery, such as nucleotide excision repair and, in some cell types, direct reversion. Different analytical approaches were used to assess the efficiency of repair and decipher the enzymatic mechanisms. We presently review the information provided by chromatographic methods, which are complementary to biochemical assays, such as immunological detection and electrophoresis‐based techniques. Chromatographic assays are interesting in their ability to provide quantitative data on a wide range of damage and are also valuable tools for the identification of repair intermediates.     

DNA光复活作用机理的研究进展*

"环丁烷型嘧啶二聚体(Pyr< > Pyr) 是太阳光中紫外线造成DNA 损伤的主要光化学产物。DNA 光复活酶(或称光解酶) 能够利用可见光裂解二聚体的环丁烷环而修复DNA。本文对DNA 光复活过程中的光解酶对Pyr< > Pyr 的识别和光催化Pyr< > Pyr 裂解反应进行了综述, 介绍了DNA 光解酶的结构、DNA 的主要UV 光化学产物。较详尽地评述了国际上在光解酶催化二聚体裂解的途径以及模型研究方面的最新进展, 并预测了该领域的发展前景。     

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.     

PHOTOPHYSICS AND PHOTOCHEMISTRY OF PHOTOREACTIVATION

Abstract— Photoreactivating enzyme (PRE) monomerizes cyclobutyl pyrimidine dimers formed in DNA by UV light ( Λ < 300 nm). The enzyme requires near UV and visible wavelengths (300 < Λ < 600 nm) for activity. Possible mechanisms of action of the PRE are suggested by non-enzymatic processes in which pyrimidine dimers are monomerized by UV and visible light. Two such non-enzymatic processes are (a) photolysis of dimers resulting from direct absorption of UV, and (b) sensitized monomerization involving charge transfer complexes. Several lines of evidence suggest that the mechanism of action of the PRE more closely resembles (b) than (a). Recent experiments on the PRE from E. coli reveal the presence of new long wavelength absorption which may indicate the presence of a ground state complex. The known ability of PRE to monomerize dimers of thymine, cytosine and uracil suggests that the carbonyl groups at 2 position of the pyrimidine ring may be important in the interaction between enzyme and dimer.     

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.     

DNA as a solar dosimeter in the ocean.

Stratospheric ozone depletion may result in increased solar UV-B radiation to the ocean's upper layers and may cause deleterious effects on marine organisms. The primary UV-B damage induced in biological systems is to DNA. While physical measurements of solar UV-B penetration into the sea have been made, the effective depth and magnitude of actual DNA damage have not been determined. In the experiments reported here, UV-B-induced photoproducts (cyclobutane pyrimidine dimers) have been quantified in DNA molecules exposed to solar UV at the surface and at various depths in clear, tropical marine waters off Lee Stocking Island (23 degrees 45' N, 76 degrees 0.7' W), Exuma Cays, Bahamas. (14C)thymidine-labeled DNA or unlabeled bacteriophage phi X174 DNA was placed in specially designed quartz tubes at various depths for up to five days. Following exposure, DNA samples were removed to the laboratory where UV-B-induced pyrimidine dimers were quantified using a radiochromatographic assay, and bacteriophage DNA inactivation by solar UV-B was assayed by plaque formation in spheroplasts of Escherichia coli. Pyrimidine dimer induction was linear with time but the accumulation of dimers in DNA with time varied greatly with depth. Attenuation of dimer formation with depth of water was exponential. DNA at 3 m depth had only 17% of the pyrimidine dimers found at the surface. Bacteriophage phi X174 DNA, while reduced 96% in plaque-forming ability by a one day exposure to solar UV at the surface of the water, showed no effect on plaque formation after a similar exposure at 3 m. The data collected at the water's surface showed a "surface-enhanced dose" in that DNA damages at the real surface were greater than at the imaginary surface, which was obtained by extrapolating the data at depth to the surface. These results show the sensitivity of both the biochemical (dimers) and biological (phage plaques) DNA dosimeters. DNA dosimeters offer a sensitive, convenient and relatively inexpensive monitoring system, having both biochemical and biological endpoints for monitoring the biologically effective UV-B flux in the marine environment. Unlike physical dosimeters, DNA dosimeters do not have to be adjusted for biological effectiveness since they are sensitive only to DNA-mediated biologically effective UV-B radiation. Results of pyrimidine dimer induction in DNA by solar UV accurately predicted UV doses to the phage DNA.     

SIMULTANEOUS ESTABLISHMENT OF MONOCLONAL ANTIBODIES SPECIFIC FOR EITHER CYCLOBUTANE PYRIMIDINE DIMER OR (6-4)PHOTOPRODUCT FROM THE SAME MOUSE IMMUNIZED WITH ULTRAVIOLET-IRRADIATED DNA

Six new monoclonal antibodies (TDM-2, TDM-3, 64M-2, 64M-3, 64M-4 and 64M-5) specific for ultraviolet (UV) induced DNA damage have been established. In the antibody characterization experiments, two TDM antibodies were found to show a dose-dependent binding to UV-irradiated DNA (UV-DNA), decrease of binding to UV-DNA after cyclobutane pyrimidine dimer photoreactivation, binding to DNA containing cyclobutane thymine dimers, and unchanged binding to UV-DNA after photoisomerization of (6-4)photoproducts to Dewar photoproducts. These results indicated that the epitope of TDM monoclonal antibodies was the cyclobutane pyrimidine dimer in DNA. On the other hand, four 64M antibodies were found to show a dose-dependent binding to UV-DNA, unchanged binding to UV-DNA after cyclobutane pyrimidine dimer photoreactivation, undetectable binding to DNA containing thymine dimers, and decrease of binding to UV-DNA after photoisomerization of (6-4)photoproducts. These results indicated that the epitope of 64M antibodies was the (6-4)photoproduct in DNA. This is the first report of the simultaneous establishment of monoclonal antibodies against the two different types of photolesions from the same mouse. By using these monoclonal antibodies, we have succeeded in measuring both cyclobutane pyrimidine dimers and (6-4)photoproducts in the DNA from human primary cells irradiated with physiological UV doses.     

Ultraviolet Light‐Induced Cyclobutane Pyrimidine Dimers in Rabbit Eyes

Sunlight exposure of the eye leads to pathologies including photokeratitis, cortical cataracts, pterygium, actinic conjunctivitis and age‐related macular degeneration. It is well established that exposure to ultraviolet (UV) radiations leads to DNA damage, mainly cyclobutane pyrimidine dimers (CPDs). CPD formation is the principal factor involved in skin cancer. However, the exact mechanism by which sunlight induces ocular pathologies is not well understood. To shed light on this issue, we quantified the CPD formation onto DNA of rabbit ocular cells following UVB exposure. We found that CPDs were induced only in the structures of the ocular anterior chamber (cornea, iris and lens) and were more concentrated in the corneal epithelium. Residual UVB that pass through the cornea are completely absorbed by the anterior layers of the iris. CPDs were also detected in the central portion of the lens that is not protected by the iris (pupil). By determining the UV‐induced DNA damage formation in eyes, we showed that anterior ocular structures are a reliable physical barrier that protects the subjacent structures from the toxic effects of UV. Although the corneal epithelium is the structure where most of the CPDs were detected, no cancer is related to solar exposure.     

INTRODUCTION OF PYRIMIDINE DIMERS INTO DIFFERENT INTRACELLULAR FORMS OF SIMIAN VIRUS 40

We examined the production of pyrimidine dimers by UV radiation in different intracellular forms of simian virus 40 DNA. Virus and chromatin or previrions were selectively labeled with [^l4C]-thymidine and [³H]-thymidine, respectively, in the same monolayer of infected cells. Viral DNA was extracted immediately after irradiation, and pyrimidine dimers were detected as sites sensitive to the UV-endonuclease encoded by bacteriophage T4. No difference in the number of dimers introduced into chromatin, previrions. or virions was detected.     

Chlorella virus pyrimidine dimer glycosylase excises ultraviolet radiation- and hydroxyl radical-induced products 4,6-diamino-5-formamidopyrimidine and 2,6-diamino-4-hydroxy-5-formamidopyrimidine from DNA

A DNA glycosylase specific for UV radiation-induced pyrimidine dimers has been identified from the Chlorella virus Paramecium Bursaria Chlorella virus-1. This enzyme (Chlorella virus pyrimidine dimer glycosylase [cv-pdg]) exhibits a 41% amino acid identity with endonuclease V from bacteriophage T4 (T4 pyrimidine dimer glycosylase [T4-pdg]), which is also specific for pyrimidine dimers. However, cv-pdg possesses a higher catalytic efficiency and broader substrate specificity than T4-pdg. The latter excises 4,6-diamino-5-formamidopyrimidine (FapyAde), a UV radiation- and hydroxyl radical-induced monomeric product of adenine in DNA. Using gas chromatography-isotope-dilution mass spectrometry and y-irradiated DNA, we show in this work that cv-pdg also displays a catalytic activity for excision of FapyAde and, in addition, it excises 2,6-diamino-4-hydroxy-5-formamidopyrimidine (FapyGua). Kinetic data show that FapyAde is a better substrate for cv-pdg than FapyGua. On the other hand, cv-pdg possesses a greater efficiency for the extension of FapyAde than T4-pdg. These two enzymes exhibit different substrate specificities despite substantial structural similarities.