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.     

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.     

Photoreactivating Enzyme for (6–4) Photoproducts in Cultured Goldfish Cells

We previously reported that when cultured goldfish cells are illuminated with fluorescent light, photorepair ability for both cyclobutane pyrimidine dimers and (6–4) photoproducts increased. In the present study, it was found that the duration of the induced photorepair ability for cyclobutane pyrimidine dimers was longer than that for (6–4) photoproducts, suggesting the presence of different photolyases for repair of these two major forms of DNA damage. A gel shift assay was then performed to show the presence of protein(s) binding to (6–4) photoproducts and its dissociation from (6–4) photoproducts under fluorescent light illumination. In addition, at 8 h after fluorescent light illumination of the cell, the binding of pro-tein(s) to (6–4) photoproducts increased. The restriction enzymes that have recognition sites containing TT or TC sequences failed to digest the UV-irradiated DNA pho-toreactivated by using Escherichia coli photolyase for cyclobutane pyrimidine dimers, indicating that restriction enzymes could not function because (6–4) photoproducts remained in recognition sites. But, when UV-irradiated DNA depleted of cyclobutane pyrimidine dimers was incubated with extract of cultured goldfish cells under fluorescent light illumination, it was digested with those restriction enzymes. These results suggested the presence of (6–4) photolyase in cultured goldfish cells as in Dro-sophila, Xenopus and Crotalus.     

UV INDUCED (6-4) PHOTOPRODUCTS ARE DISTRIBUTED DIFFERENTLY THAN CYCLOBUTANE DIMERS IN NUCLEOSOMES

We have compared the distributions of two stable UV photoproducts in nucleosome core DNA at the single-nucleotide level using a T4 polymerase-exonuclease mapping procedure. The distribution of pyrimidine-pyrimidone (6-4) dimers was uncovered by reversing the major UV photo-product, cis-syn cyclobutane pyrimidine dimer, with E. coli DNA photolyase and photoreactivating light. Whereas the distribution of total UV photoproducts in nucleosome core DNA forms a striking 10.3 base periodic pattern, the distribution of (6-4) dimers is much more random throughout the nucleosome core domain. Therefore, histone-DNA interactions in nucleosomes strongly modulate formation of the major class of UV-induced photoproducts, while having either a constant effect or no effect on (6-4) dimer formation.     

Kinetics of Repair of UV-induced DNA Damage in Repair-proficient and -deficient Cells as Determined by Quantitative Polymerase Chain Reaction

Abstract— Advances in methodologies to monitor gene-specific repair in human cells have facilitated a detailed understanding of the complexity of the nucleotide excision repair system. One of these procedures, quantitative polymerase chain reaction (QPCR), holds significant promise for dissecting the fine structure of the repair of UV-induced DNA damage. This assay was used to study the repair of UV photoproducts in both actively transcribed and nontranscribed genes from human cells that were capable of (1) repair of both cyclobutane pyrimidine dimers and 6-4 photoproducts; (2) removal of neither dinners nor 6-4 photoproducts; (3) strong preferential repair of 6-4 photoproducts relative to dimers; and (4) severely depressed rates of 6-4 photoproducts and dimers. Detailed kinetic analyses revealed that repair of both active and inactive genes can be studied with a very fine degree of precision and that the repair status of the cells can easily be detected by use of the procedures described.     

Repair of the main UV-induced thymine dimeric lesions within Arabidopsis thaliana DNA: evidence for the major involvement of photoreactivation pathways.

The UV-B induced formation of thymine cis-syn cyclobutane dimer and related (6-4) photoproduct was monitored within DNA of cultured cells and plants of Arabidopsis thaliana. This was achieved using a sensitive and accurate HPLC-tandem mass spectrometry assay. It was found that the cyclobutane pyrimidine dimer was formed in a ninefold higher yield than the (6-4) photoproduct. The removal of the lesions was then studied by incubating irradiated cells either in the darkness, under visible light or upon exposure to UV-A radiation. Dark repair of both cyclobutane dimers and (6-4) photoproducts was found to be very ineffective. In contrast, a rapid decrease in the level of photoproducts was observed when UV-B-irradiated cells were exposed to UV-A and, to a lesser extent, to visible light. The removal of (6-4) adducts was found to occur more efficiently. These results strongly suggest that repair of UV-induced photolesions in plants is mainly mediated by photolyases.     

Repair of (6‐4) Lesions in DNA by (6‐4) Photolyase: 20 Years of Quest for the Photoreaction Mechanism

Exposure of DNA to ultraviolet (UV) light from the Sun or from other sources causes the formation of harmful and carcinogenic crosslinks between adjacent pyrimidine nucleobases, namely cyclobutane pyrimidine dimers and pyrimidine(6–4)pyrimidone photoproducts. Nature has developed unique flavoenzymes, called DNA photolyases, that utilize blue light, that is photons of lower energy than those of the damaging light, to repair these lesions. In this review, we focus on the chemically challenging repair of the (6–4) photoproducts by (6–4) photolyase and describe the major events along the quest for the reaction mechanisms, over the 20 years since the discovery of (6‐4) photolyase.     

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.     

DIFFERENTIAL EXPRESSION OF PYRIMIDINE DIMER-BINDING PROTEINS IN NORMAL AND UV LIGHT-TREATED VERTEBRATE CELLS

Abstract— The expression of UV damage-specific DNA-binding proteins was examined in various phylogenetically distant species with differing DNA repair phenotypes. Two distinct constitutive DNA-binding activities, one specific for cyclobutane pyrimidine dimers and the other for non-cyclobutane dimer photoproducts, were detected. The expression of these binding activity was found to be variable throughout the animal kingdom: cold-blooded vertebrastes show a constitutive cyclobutance dimer-binding activity excusively, and primates reveal only non-cyclobutane expression (rather than the constitutive presence)of these UV damage-specific DNA-binding activities after UV traeatment correlate with the cell's capacity for DNA repair. In addition, cyclobutane pyrimidine dimer-binding activities could be detected only in cells with eestablished photoreactivating activity     

The relative cytotoxicity of (6-4) photoproducts and cyclobutane dimers in mammalian cells

Abstract— The significance of the pyrimidine(6-4)pyrimidone photoproduct in mammalian cell killing is considered. Photochemical data indicate that the(6–4) photoproduct is induced at a substantial frequency compared to the cyclobutane dimer and that the action spectra for the induction of both lesions are equivalent. The repair of(6–4) photoproducts in various normal and UV-hypcrsensitive mammalian cell lines, including several recently derived somatic cell hybrids and transformants, is presented. The sensitivity of these cells to ultraviolet irradiation correlates better with the capacity to repair(6–4) photoproducts than cyclobutane dimers. These data are used to support that idea that the(6–4) photoproduct is one of the major cytotoxic lesions induced in DNA by ultraviolet light.     

Induction, distribution and repair of UV photodamage in the platyfish, Xiphophorus signum

The genus Xiphophorus is an important model for investigating the etiology and genetics of sunlight-induced melanoma as well as other cancers. We used immunological techniques to determine the induction, distribution and repair of cyclobutane pyrimidine dimers (CPD) and pyrimidine(6-4)pyrimidone dimers ([6-4]PD) in different tissues of Xiphophorus signum exposed to ultraviolet-B light. We found that the (6-4)PD was induced at 5 to 10-fold lower frequency than the CPD and that scalation provided considerable photoprotection against both photoproducts. Photoenzymatic repair (PER) was very efficient in X. signum with most of the lesions removed within 20 min; PER of CPD occurred at about twice the rate of (6-4)PD. Nucleotide excision repair (NER) was much less efficient than PER and the rates of CPD and (6-4)PD removal were comparable. PER was more efficient in the caudal fin compared to the lateral epidermis; the opposite was true for NER. Although the initial rate of CPD excision was five-fold faster in the lateral epidermis compared to the caudal fin a considerable amount of residual damage remained in both tissues. The diverse photochemical and photobiological responses observed in X. signum suggest that heritable traits governing deoxyribonucleic acid damage induction and repair may be involved in the susceptibility of other Xiphophorus species to melanomagenesis.     

Nucleotide excision repair proteins rapidly accumulate but fail to persist in human XP-E (DDB2 mutant) cells

The xeroderma pigmentosum (XP-E) DNA damage binding protein (DDB2) is involved in early recognition of global genome DNA damage during DNA nucleotide excision repair (NER). We found that skin fibroblasts from four newly reported XP-E patients with numerous skin cancers and DDB2 mutations had slow repair of 6-4 photoproducts (6-4PP) and markedly reduced repair of cyclobutane pyrimidine dimers (CPD). NER proteins (XPC, XPB, XPG, XPA and XPF) colocalized to CPD and 6-4PP positive regions immediately (<0.1 h) after localized UV irradiation in cells from the XP-E patients and normal controls. While these proteins persist in normal cells, surprisingly, within 0.5 h these repair proteins were no longer detectable at the sites of DNA damage in XP-E cells. Our results indicate that DDB2 is not required for the rapid recruitment of NER proteins to sites of UV photoproducts or for partial repair of 6-4PP but is essential for normal persistence of these proteins for CPD photoproduct removal.     

PREFERENTIAL INHIBITION OF NUCLEOSOME ASSEMBLY BY ULTRAVIOLET-INDUCED (6-4)PHOTOPRODUCTS

We reconstituted nucleosomes in vitro using two kinds of damaged pBR322 plasmid DNA carrying cyclobutane pyrimidine dimers (CPD) or (6-4)photoproducts. The results indicate that nucleosome assembly is inhibited preferentially by (6-4)photoproducts compared with CPD, suggesting that the regions carrying (6-4)photoproducts retain their nucleosome-free form, i.e. linker-like conformation until completion of the repair processes.     

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.     

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.     

Photoregulation of DMA Photolyases in Broom Sorghum Seedlings

Abstract— Using dark-grown 3 day-old Sorghum bicolor seedlings, photorepair of cyclobutane pyrimidine dimers (CPD) by CPD-photoIyase and pyrimidine-(6–4)pyrimidinone photoproducts ([6–4]PP) by [6–4]PP-photolyase was studied in vivo and in vitro. The two types of DNA photoproducts were measured with specific monoclonal antibodies. Sorghum seedlings have different photorepair enzymes for CPD and [6–4]PP. The CPD-photolyase was found to be increased in response to light with maximal efficiency in the UVA/blue spectral range, whereas [6–4]PP-photolyase was not influenced by light.     

Targeted Inactivation of DNA Photolyase Genes in Medaka Fish (Oryzias latipes)

Proteins of the cryptochrome/photolyase family (CPF) exhibit sequence and structural conservation, but their functions are divergent. Photolyase is a DNA repair enzyme that catalyzes the light‐dependent repair of ultraviolet (UV)‐induced photoproducts, whereas cryptochrome acts as a photoreceptor or circadian clock protein. Two types of DNA photolyase exist: CPD photolyase, which repairs cyclobutane pyrimidine dimers (CPDs), and 6‐4 photolyase, which repairs 6‐4 pyrimidine–pyrimidone photoproducts (6‐4PPs). Although the Cry‐DASH protein is classified as a cryptochrome, it also has light‐dependent DNA repair activity. To determine the significance of the three light‐dependent repair enzymes in recovering from solar UV‐induced DNA damage at the organismal level, we generated mutants in each gene in medaka using the CRISPR genome editing technique. The light‐dependent repair activity of the mutants was examined in vitro in cultured cells and in vivo in skin tissue. Light‐dependent repair of CPD was lost in the CPD photolyase‐deficient mutant, whereas weak repair activity against 6‐4PPs persisted in the 6‐4 photolyase‐deficient mutant. These results suggest the existence of a heretofore unknown 6‐4PP repair pathway and thus improve our understanding of the mechanisms of defense against solar UV in vertebrates.     

Crystal Structure of the T(6‐4)C Lesion in Complex with a (6‐4) DNA Photolyase and Repair of UV‐Induced (6‐4) and Dewar Photolesions

UV‐light irradiation induces the formation of highly mutagenic lesions in DNA, such as cis‐syn cyclobutane pyrimidine dimers (CPD photoproducts), pyrimidine(6‐4)pyrimidone photoproducts ((6‐4) photoproducts) and their Dewar valence isomers ((Dew) photoproducts). Here we describe the synthesis of defined DNA strands containing these lesions by direct irradiation. We show that all lesions are efficiently repaired except for the T(Dew)T lesion, which cannot be cleaved by the repair enzyme under our conditions. A crystal structure of a T(6‐4)C lesion containing DNA duplex in complex with the (6‐4) photolyase from Drosophila melanogaster provides insight into the molecular recognition event of a cytosine derived photolesion for the first time. In light of the previously postulated repair mechanism, which involves rearrangement of the (6‐4) lesions into strained four‐membered ring repair intermediates, it is surprising that the not rearranged T(6‐4)C lesion is observed in the active site. The structure, therefore, provides additional support for the newly postulated repair mechanism that avoids this rearrangement step and argues for a direct electron injection into the lesion as the first step of the repair reaction performed by (6‐4) DNA photolyases.     

CYCLOBUTANE DIMERS AND (6-4)PHOTOPRODUCTS IN HUMAN CELLS ARE MENDED WITH THE SAME PATCH SIZES

The size of excision repair patches corresponding to excision of (6-4) pyrimidine-pyrimidone photoproducts and (5-5, 6-6) cyclobutane dimers have been independently determined by using bromodeoxyuridine substitution and density increases in isopycnic gradients of small DNA fragments. The two classes of photoproducts were distinguished by using (a) a xeroderma pigmentosum (XP) revertant cell line that excises (6-4) photoproducts normally, but does not excise cyclobutane dimers from bulk DNA or from an actively transcribed sequence; (b) an XP cell line containing the denV gene of bacteriophage T4, which repairs only cyclobutane dimers by a unique glycosylase mechanism, and (c) normal cells analyzed during time intervals in which cyclobutane dimer repair is the main repair process in action. The patch sizes for the two lesions were similar under all conditions and were estimated to be approximately 30-40 bases. These values are slightly large than corresponding estimates for Escherichia coli and Saccharomyces cerevisiae but close to estimates from in vitro experiments with human cell extracts. The size of 30 bases may consequently be very close to the actual distance between cleavage sites made on either side of a photoproduct during repair.