Spontaneous and photosensitiser-induced DNA single-strand breaks and formamidopyrimidine-DNA glycosylase sensitive sites at nucleotide resolutionin the nuclear and mitochondrial DNA of Saccharomyces cerevisiae.

A system is described for mapping oxidative DNA damage (sites sensitive to formamidopyrimidine-DNA glycosylase and single-strand breaks) at nucleotide resolution in the nuclear and mitochondrial DNA of Saccharomyces cerevisiae. Our 3' end labelling method is sensitive and was first developed using the well-studied inducer of oxidative DNA damage, methylene blue (MB) plus light. We treated yeast DNA in vitro with this so as to maximise levels of damage for assay development. Unfortunately, MB does not remain in yeast cells and yeast DNA repair mutants sensitive to active oxygen species are not sensitive to this agent, thus for in vivo experiments we turned to a polycyclic aromatic, RO 19-8022 (RO). This resulted in oxidative DNA damage when light was applied to yeast cells in its presence. The spectra of enzyme-sensitive sites and single-strand breaks induced by MB in vitro or by RO plus light in vivo or in vitro were examined in two yeast reporter genes: the nuclear MFA2 and the mitochondrial OLI1. The experiments revealed that most of the enzyme-sensitive sites and single-strand breaks induced by MB or RO plus light are at the same positions in these sequences, and that these are guanines.     

UV-B light induces an adaptive response to UV-C exposure via photoreactivation activity in Euglena gracilis.

Phytoplankton such as Euglena are constantly exposed to solar light which is used for photosynthesis. Although the solar ultraviolet (UV) induces DNA damage such as cyclobutane-pyrimidine dimers (CPDs), many kinds of living organisms can repair CPDs by photoreactivation (PR) utilizing the near-UV/blue light component in sunlight. Euglena cells are known to possess such PR activity. In the present paper, the formation of CPDs induced by UV-C exposure and the photoreactivation PR repair of these CPDs by UV-A are demonstrated. To clarify the adaptive responses prior UV-B irradiation on PR activity, cells were cultured in the dark or under UV-B light. When the cells were cultured in the dark for 3 d prior to UV-C exposure, PR activity decreased. When the cells were cultured under UV-B light, however, PR activity increased. These results suggest that exposing the cells to UV-B prior to exposure to UV-C induced an adaptive response towards DNA damage caused by UV-C exposure, and this UV-C induced damage was repaired through PR activity.     

Cyclobutane pyrimidine dimer (CPD) photolyase repairs ultraviolet-B-induced CPDs in rice chloroplast and mitochondrial DNA

Plants use sunlight as energy for photosynthesis; however, plant DNA is exposed to the harmful effects of ultraviolet‐B (UV‐B) radiation (280–320 nm) in the process. UV‐B radiation damages nuclear, chloroplast and mitochondrial DNA by the formation of cyclobutane pyrimidine dimers (CPDs), which are the primary UV‐B‐induced DNA lesions, and are a principal cause of UV‐B‐induced growth inhibition in plants. Repair of CPDs is therefore essential for plant survival while exposed to UV‐B‐containing sunlight. Nuclear repair of the UV‐B‐induced CPDs involves the photoreversal of CPDs, photoreactivation, which is mediated by CPD photolyase that monomerizes the CPDs in DNA by using the energy of near‐UV and visible light (300–500 nm). To date, the CPD repair processes in plant chloroplasts and mitochondria remain poorly understood. Here, we report the photoreactivation of CPDs in chloroplast and mitochondrial DNA in rice. Biochemical and subcellular localization analyses using rice strains with different levels of CPD photolyase activity and transgenic rice strains showed that full‐length CPD photolyase is encoded by a single gene, not a splice variant, and is expressed and targeted not only to nuclei but also to chloroplasts and mitochondria. The results indicate that rice may have evolved a CPD photolyase that functions in chloroplasts, mitochondria and nuclei, and that contains DNA to protect cells from the harmful effects of UV‐B radiation.     

Nucleotide excision repair of the 5 S ribosomal RNA gene assembled into a nucleosome

A-175-base pair fragment containing the Xenopus borealis somatic 5 S ribosomal RNA gene was used as a model system to determine the effect of nucleosome assembly on nucleotide excision repair (NER) of the major UV photoproduct (cyclobutane pyrimidine dimer (CPD)) in DNA. Xenopus oocyte nuclear extracts were used to carry out repair in vitro on reconstituted, positioned 5 S rDNA nucleosomes. Nucleosome structure strongly inhibits NER at many CPD sites in the 5 S rDNA fragment while having little effect at a few sites. The time course of CPD removal at 35 different sites indicates that >85% of the CPDs in the naked DNA fragment have t(12) values <2 h, whereas <26% of the t(12) values in nucleosomes are <2 h, and 15% are >8 h. Moreover, removal of histone tails from these mononucleosomes has little effect on the repair rates. Finally, nucleosome inhibition of repair shows no correlation with the rotational setting of a 14-nucleotide-long pyrimidine tract located 30 base pairs from the nucleosome dyad. These results suggest that inhibition of NER by mononucleosomes is not significantly influenced by the rotational orientation of CPDs on the histone surface, and histone tails play little (or no) role in this inhibition.     

The effect of flanking bases on direct and triplet sensitized cyclobutane pyrimidine dimer formation in DNA depends on the dipyrimidine,wavelength and the photosensitizer

Cyclobutane pyrimidine dimers (CPDs) are the major products of DNA produced by direct absorption of UV light, and result in C to T mutations linked to human skin cancers. Most recently a new pathway to CPDs in melanocytes has been discovered that has been proposed to arise from a chemisensitized pathway involving a triplet sensitizer that increases mutagenesis by increasing the percentage of C-containing CPDs. To investigate how triplet sensitization may differ from direct UV irradiation, CPD formation was quantified in a 129-mer DNA designed to contain all 64 possible NYYN sequences. CPD formation with UVB light varied about 2-fold between dipyrimidines and 12-fold with flanking sequence and was most frequent at YYYR and least frequent for GYYN sites in accord with a charge transfer quenching mechanism. In contrast, photosensitized CPD formation greatly favored TT over C-containing sites, more so for norfloxacin (NFX) than acetone, in accord with their differing triplet energies. While the sequence dependence for photosensitized TT CPD formation was similar to UVB light, there were significant differences, especially between NFX and acetone that could be largely explained by the ability of NFX to intercalate into DNA.     

Repair of DNA Damage Induced by Solar UV

Solar UV radiation induces significant levels of DNA damage in living things. This damage, if left unrepaired, is lethal in humans. Recent work has demonstrated that plants possess several repair pathways for UV-induced DNA damage, including pathways for the photoreactivation of both 6-4 products and cyclobutane pyrimidine dimers (CPDs), the two lesions most frequently induced by UV. Plants also possess the more general nucleotide excision repair (NER) pathway as well as bypass polymerases that enable the plant to replicate its DNA in the absence of DNA repair.This revised version was published online in October 2005 with corrections to the Cover Date.     

A Light-Dependent Pathway for the Elimination of UV-Induced Pyrimidine (6-4) Pyrimidinone Photoproducts in Arabidopsis

Light-dependent repair of UV-induced cyclobutane pyrimidine dimers (CPDs) and pyrimidine (6-4) pyrimidinone dimers (6-4 products) was investigated in an excision repair-deficient Arabidopsis mutant. As previously described, exposure to broad-spectrum lighting was found to greatly enhance the rate of repair of CPDs. We demonstrate that 6-4 products are also efficiently eliminated in a light-dependent manner and that this photoreactivation of 6-4 products occurs independently of the previously described 6-4 product dark repair pathway. The light-dependent repair of both 6-4 products and CPDs occurs in the presence of blue light (435 nm) but not upon exposure to light of longer wavelengths. We also found that high-level expression of the CPD-specific photoreactivating activity in the Arabidopsis seedling requires induction by exposure to light prior to as well as during the period of repair while the 6-4 photoreactivating activity is constitutively expressed. This differential regulation of the photoreactivating activities suggests that the Arabidopsis seedling produces at least two distinct photolyases: one specific for CPDs and the other specific for 6-4 products.     

UV light-induced DNA damage and tolerance for the survival of nucleotide excision repair-deficient human cells

DNA damage can cause cell death unless it is either repaired or tolerated. The precise contributions of repair and tolerance mechanisms to cell survival have not been previously evaluated. Here we have analyzed the cell killing effect of the two major UV light-induced DNA lesions, cyclobutane pyrimidine dimers (CPDs) and 6-4 pyrimidine-pyrimidone photoproducts (6-4PPs), in nucleotide excision repair-deficient human cells by expressing photolyase(s) for light-dependent photorepair of either or both lesions. Immediate repair of the less abundant 6-4PPs enhances the survival rate to a similar extent as the immediate repair of CPDs, indicating that a single 6-4PP lesion is severalfold more toxic than a CPD in the cells. Because UV light-induced DNA damage is not repaired at all in nucleotide excision repair-deficient cells, proliferation of these cells after UV light irradiation must be achieved by tolerance of the damage at replication. We found that RNA interference designed to suppress polymerase zeta activity made the cells more sensitive to UV light. This increase in sensitivity was prevented by photorepair of 6-4PPs but not by photorepair of CPDs, indicating that polymerase zeta is involved in the tolerance of 6-4PPs in human cells.     

In vivo formation and repair of cyclobutane pyrimidine dimers and 6-4 photoproducts measured at the gene and nucleotide level in Escherichia coli

In vivo formation and repair of the major UV-induced DNA photoproducts, cyclobutane pyrimidine dimers (CPDs) and 6-4 pyrimidine-pyrimidone photoproducts (6-4 PPs), have been examined at the gene and nucleotide level in Escherichia coli. Each type of DNA photoproduct has individually been studied using photoreactivation and two newly developed assays; the multiplex QPCR assay for damage detection at the gene level and the reiterative primer extension (PE) assay for damage detection at the nucleotide level. In the E. coli lacI and lacZ genes, CPDs and 6-4 PPs form in a 2:1 ratio, respectively, during UV irradiation. Repair of 6-4 PPs is more efficient than repair of CPDs since, on the average, 42% of 6-4 PPs are repaired in both genes in the first 40 min following 200 J/m² UV irradiation, while 1% of CPDs are repaired. The location, relative frequency of formation, and efficiency of repair of each type of photoproduct was examined in the first 52 codons of the E. coli lacI gene at the nucleotide level. Hotspots of formation were found for each type of lesion. Most photoproducts are at sites where both CPDs and 6-4 PPs are formed. Allowing 40 min of recovery following 200 J/m² shows that in vivo repair of 6-4 PPs is about fourfold more efficient than the repair of CPDs. Comparison of the lesion-specific photoproduct distribution of the lacI gene with a UV-induced mutation spectrum from wild-type cells shows that most mutational hotspots are correlated with sites of a majority of CPD formation. However, 6-4 PPs are also formed at some of these sites with relatively high frequency. This information, taken together with the observation that 6-4 PPs are repaired faster than CPDs, suggest that the cause of mutagenic hotspots in wild-type E. coli is inefficient repair of CPDs.     

CPDs and 6-4PPs play different roles in UV-induced cell death in normal and NER-deficient human cells

Ultraviolet (UV) light generates two major DNA lesions: cyclobutane pyrimidine dimers (CPDs) and pyrimidine-(6-4)-pyrimidone photoproducts (6-4PPs), but the specific participation of these two lesions in the deleterious effects of UV is a longstanding question. In order to discriminate the precise role of unrepaired CPDs and 6-4PPs in UV-induced responses triggering cell death, human fibroblasts were transduced by recombinant adenoviruses carrying the CPD-photolyase or 6-4PP-photolyase cDNAs. Both photolyases were able to prevent UV-induced apoptosis in cells deficient for nucleotide excision repair (NER) to a similar extent, while in NER-proficient cells UV-induced apoptosis was prevented only by CPD-photolyase, with no effects observed when 6-4PPs were removed by the specific photolyase. These results strongly suggest that both CPDs and 6-4PPs contribute to UV-induced apoptosis in NER-deficient cells, while in NER-proficient cells, CPDs are the only lesions responsible for UV-killing, probably due to the rapid repair of 6-4PPs by NER. As a consequence, the difference in skin photosensitivity, including carcinogenesis, of most of the xeroderma pigmentosum patients and of normal people is probably not only a quantitative aspect, but depends on the type of DNA damage induced by sunlight and its rate of repair.     

DDB accumulates at DNA damage sites immediately after UV irradiation and directly stimulates nucleotide excision repair.

Damaged DNA-binding protein, DDB, is a heterodimer of p127 and p48 with a high specificity for binding to several types of DNA damage. Mutations in the p48 gene that cause the loss of DDB activity were found in a subset of xeroderma pigmentosum complementation group E (XP-E) patients and have linked to the deficiency in global genomic repair of cyclobutane pyrimidine dimers (CPDs) in these cells. Here we show that with a highly defined system of purified repair factors, DDB can greatly stimulate the excision reaction reconstituted with XPA, RPA, XPC.HR23B, TFIIH, XPF.ERCC1 and XPG, up to 17-fold for CPDs and approximately 2-fold for (6-4) photoproducts (6-4PPs), indicating that no additional factor is required for the stimulation by DDB. Transfection of the p48 cDNA into an SV40-transformed human cell line, WI38VA13, was found to enhance DDB activity and the in vivo removal of CPDs and 6-4PPs. Furthermore, the combined technique of recently developed micropore UV irradiation and immunostaining revealed that p48 (probably in the form of DDB heterodimer) accumulates at locally damaged DNA sites immediately after UV irradiation, and this accumulation is also observed in XP-A and XP-C cells expressing exogenous p48. These results suggest that DDB can rapidly translocate to the damaged DNA sites independent of functional XPA and XPC proteins and directly enhance the excision reaction by core repair factors.     

Nucleosome positioning,nucleotide excision repair and photoreactivation in Saccharomyces cerevisiae

The position of nucleosomes on DNA participates in gene regulation and DNA replication. Nucleosomes can be repressors by limiting access of factors to regulatory sequences, or activators by facilitating binding of factors to exposed DNA sequences on the surface of the core histones. The formation of UV induced DNA lesions, like cyclobutane pyrimidine dimers (CPDs), is modulated by DNA bending around the core histones. Since CPDs are removed by nucleotide excision repair (NER) and photolyase repair, it is of paramount importance to understand how DNA damage and repair are tempered by the position of nucleosomes. In vitro, nucleosomes inhibit NER and photolyase repair. In vivo, nucleosomes slow down NER and considerably obstruct photoreactivation of CPDs. However, over-expression of photolyase allows repair of nucleosomal DNA in a second time scale. It is proposed that the intrinsic abilities of nucleosomes to move and transiently unwrap could facilitate damage recognition and repair in nucleosomal DNA.