Poly(ADP-ribose) Contributes to an Association between Poly(ADP-ribose) Polymerase-1 and Xeroderma Pigmentosum Complementation Group A in Nucleotide Excision Repair

Exposure to ultraviolet radiation (UVR) promotes the formation of UVR-induced, DNA helix distorting photolesions such as (6-4) pyrimidine-pyrimidone photoproducts and cyclobutane pyrimidine dimers. Effective repair of such lesions by the nucleotide excision repair (NER) pathway is required to prevent DNA mutations and chromosome aberrations. Poly(ADP-ribose) polymerase-1 (PARP-1) is a zinc finger protein with well documented involvement in base excision repair. PARP-1 is activated in response to DNA damage and catalyzes the formation of poly(ADP-ribose) subunits that assist in the assembly of DNA repair proteins at sites of damage. In this study, we present evidence for PARP-1 contributions to NER, extending the knowledge of PARP-1 function in DNA repair beyond the established role in base excision repair. Silencing the PARP-1 protein or inhibiting PARP activity leads to retention of UVR-induced photolesions. PARP activation following UVR exposure promotes association between PARP-1 and XPA, a central protein in NER. Administration of PARP inhibitors confirms that poly(ADP-ribose) facilitates PARP-1 association with XPA in whole cell extracts, in isolated chromatin complexes, and in vitro. Furthermore, inhibition of PARP activity decreases UVR-stimulated XPA chromatin association, illustrating that these relationships occur in a meaningful context for NER. These results provide a mechanistic link for PARP activity in the repair of UVR-induced photoproducts.     

The UV-damaged DNA binding protein mediates efficient targeting of the nucleotide excision repair complex to UV-induced photo lesions

Previous studies point to the XPC-hHR23B complex as the principal initiator of global genome nucleotide excision repair (NER) pathway, responsible for the repair of UV-induced cyclobutane pyrimidine dimers (CPD) and 6-4 photoproducts (6-4PP) in human cells. However, the UV-damaged DNA binding protein (UV-DDB) has also been proposed as a damage recognition factor involved in repair of UV-photoproducts, especially CPD. Here, we show in human XP-E cells (UV-DDB deficient) that the incision complex formation at UV-induced lesions was severely diminished in locally damaged nuclear spots. Repair kinetics of CPD and 6-4PP in locally and globally UV-irradiated normal human and XP-E cells demonstrate that UV-DDB can mediate efficient targeting of XPC-hHR23B and other NER factors to 6-4PP. The data is consistent with a mechanism in which UV-DDB forms a stable complex when bound to a 6-4PP, allowing subsequent repair proteins--starting with XPC-hHR23B--to accumulate, and verify the lesion, resulting in efficient 6-4PP repair. These findings suggest that (i) UV-DDB accelerates repair of 6-4PP, and at later time points also CPD, (ii) the fraction of 6-4PP that can be bound by UV-DDB is limited due to its low cellular quantity and fast UV dependent degradation, and (iii) in the absence of UV-DDB a slow XPC-hHR23B dependent pathway is capable to repair 6-4PP, and to some extent also CPD.     

Nuclear translocation contributes to regulation of DNA excision repair activities

DNA mutations are circumvented by dedicated specialized excision repair systems, such as the base excision repair (BER), nucleotide excision repair (NER), and mismatch repair (MMR) pathways. Although the individual repair pathways have distinct roles in suppressing changes in the nuclear DNA, it is evident that proteins from the different DNA repair pathways interact [Y. Wang, D. Cortez, P. Yazdi, N. Neff, S.J. Elledge, J. Qin, BASC, a super complex of BRCA1-associated proteins involved in the recognition and repair of aberrant DNA structures, Genes Dev. 14 (2000) 927–939; M. Christmann, M.T. Tomicic, W.P. Roos, B. Kaina, Mechanisms of human DNA repair: an update, Toxicology 193 (2003) 3–34; N.B. Larsen, M. Rasmussen, L.J. Rasmussen, Nuclear and mitochondrial DNA repair: similar pathways? Mitochondrion 5 (2005) 89–108]. Protein interactions are not only important for function, but also for regulation of nuclear import that is necessary for proper localization of the repair proteins. This review summarizes the current knowledge on nuclear import mechanisms of DNA excision repair proteins and provides a model that categorizes the import by different mechanisms, including classical nuclear import, co-import of proteins, and alternative transport pathways. Most excision repair proteins appear to contain classical NLS sequences directing their nuclear import, however, additional import mechanisms add alternative regulatory levels to protein import, indirectly affecting protein function. Protein co-import appears to be a mechanism employed by the composite repair systems NER and MMR to enhance and regulate nuclear accumulation of repair proteins thereby ensuring faithful DNA repair.     

Tumor suppressor p53 dependent recruitment of nucleotide excision repair factors XPC and TFIIH to DNA damage

Functional tumor suppressor p53 is mainly required for efficient global genomic repair (GGR), a subpathway of nucleotide excisions repair (NER). In this study, the regulatory effect of p53, on the spaciotemporal recruitment of XPC and TFIIH to DNA damage sites, was investigated in repair-proficient and -deficient human cells in situ. Photoproducts were induced through micropore UV irradiation of discrete subnuclear areas of intact cells and the specific lesions, as well as recruited repair factors, were detected by immunofluorescent intensity and density of the damaged DNA subnuclear spots (SNS). Both cyclobutane pyrimidine dimers (CPD) and 6-4 photoproducts (6-4PP) were visualized in situ at SNS within irradiated nuclear foci. The in situ repair kinetics revealed that p53-WT normal fibroblasts are proficient for the repair of both CPD and 6-4PP, whereas, p53-Null Li-Fraumeni syndrome (LFS) fibroblasts fail to efficiently repair CPD but not 6-4PP. Colocalization experiments of the NER factors showed that in normal human cells, XPC and TFIIH are rapidly and efficiently recruited to DNA damage within SNS. By contrast, recruitment of both XPC and TFIIH to DNA damage in SNS occurred much less efficiently in p53-Null or p53-compromised cells. The total cellular levels of XPC and XPB were similar in both p53-WT and -Null cells and remained unchanged up to 24h following UV irradiation. The results also showed that dispersal of recruited XPC and TFIIH from DNA damage SNS occurs within a short period after DNA damage. Such dispersal requires functional XPA, XPF and XPG proteins. Taken together, the results demonstrated that p53 plays a pronounced role in the damage recognition and subsequent assembly of repair machinery during GGR and the recruitment of XPC and TFIIH to CPD is p53-dependent. Most likely mechanism of this p53 action is through its downstream effector protein, DDB2.     

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.     

Reversible protein phosphorylation modulates nucleotide excision repair of damaged DNA by human cell extracts.

Nucleotide excision repair of DNA in mammalian cells uses more than 20 polypeptides to remove DNA lesions caused by UV light and other mutagens. To investigate whether reversible protein phosphorylation can significantly modulate this repair mechanism we studied the effect of specific inhibitors of Ser/Thr protein phosphatases. The ability of HeLa cell extracts to carry out nucleotide excision repair in vitro was highly sensitive to three toxins (okadaic acid, microcystin-LR and tautomycin), which block PP1- and PP2A-type phosphatases. Repair was more sensitive to okadaic acid than to tautomycin, suggesting the involvement of a PP2A-type enzyme, and was insensitive to inhibitor-2, which exclusively inhibits PP1-type enzymes. In a repair synthesis assay the toxins gave 70% inhibition of activity. Full activity could be restored to toxin-inhibited extracts by addition of purified PP2A, but not PP1. The p34 subunit of replication protein A was hyperphosphorylated in cell extracts in the presence of phosphatase inhibitors, but we found no evidence that this affected repair. In a coupled incision/synthesis repair assay okadaic acid decreased the production of incision intermediates in the repair reaction. The formation of 25-30mer oligonucleotides by dual incision during repair was also inhibited by okadaic acid and inhibition could be reversed with PP2A. Thus Ser/Thr- specific protein phosphorylation plays an important role in the modulation of nucleotide excision repair in vitro.     

Antibiotic amoxicillin induces DNA lesions in mammalian cells possibly via the reactive oxygen species

Amoxicillin is a commonly prescribed drug for anti- bacterial infection. In this study, we are interested in the effect of the drug on the cellular DNA integrity. Amoxicillin was added to the human or hamster cells in culture, and the DNA lesions induced by the drug were assessed by a comet assay with nuclear extract incubation (Wang et al., 2005 Anal Biochem 337: 70-75). Amoxicillin at 5mM rapidly induced DNA lesions in human AGS cells. The level of DNA lesions attained a maximum at about 1h, and then declined steadily and reached almost the basal level at 6h following the drug treatment. Similar induction pattern of DNA lesions was found with amoxicillin-related antibiotics such as ampicillin but not with the unrelated antibiotics such as kanamycin. For studying the repair kinetics, the cells were treated with amoxicillin for only 1h and continued culture in the absence of the drug for a certain period of time before subsequent analysis. Repair of the amoxicillin-induced DNA lesions was essentially completed within 4h. Such repair may not involve nucleotide excision repair (NER) pathway because the repair was completed with similar kinetics in both NER proficient Chinese hamster CHO-K1 cells and its isogenic NER deficient UV24 cells. Instead, the repair may involve base excision repair (BER) pathway because immunodepletion of OGG1/2, glycosylases involved in BER rendered the nuclear extract unable to excise DNA lesions induced by amoxicillin in the modified comet assay. Furthermore, amoxicillin induced intracellular reactive oxygen species (ROS) at the tempo similar to that of DNA lesions induction. Thus, we hypothesize that amoxicillin causes oxidative DNA damage in mammalian cells via ROS.     

A functional NR4A nuclear receptor DNA‐binding domain is required for organ development in Caenorhabditis elegans

NR4A nuclear receptors are a diverse group of orphan nuclear receptors with critical roles in regulating cell proliferation and cell differentiation. The ortholog of the NR4A nuclear receptor in Caenorhabditis elegans, NHR‐6, also has a role in cell proliferation and cell differentiation during organogenesis of the spermatheca. Here we show that NHR‐6 is able to bind the canonical NR4A monomer response element and can transactivate from this site in mammalian HEK293 cells. Using a functional GFP‐tagged NHR‐6 fusion, we also demonstrate that NHR‐6 is nuclear localized during development of the spermatheca. Mutation of the DNA‐binding domain of NHR‐6 abolishes its activity in genetic rescue assays, demonstrating a requirement for the DNA‐binding domain. This study represents the first genetic demonstration of an in vivo requirement for an NR4A nuclear receptor DNA‐binding domain in a whole organism. genesis 48:485–491, 2010. © 2010 Wiley‐Liss, Inc.     

Replication protein A stimulates proliferating cell nuclear antigen-dependent repair of abasic sites in DNA by human cell extracts.

Base excision repair (BER) pathway is the major cellular process for removal of endogenous base lesions and apurinic/apyrimidinic (AP) sites in DNA. There are two base excision repair subpathways in mammalian cells, characterized by the number of nucleotides synthesized into the excision patch. They are the "single-nucleotide" (one nucleotide incorporated) and the "long-patch" (several nucleotides incorporated) BER pathways. Proliferating cell nuclear antigen (PCNA) is known to be an essential factor in long-patch base excision repair. We have studied the role of replication protein A (RPA) in PCNA-dependent, long-patch BER of AP sites in human cell extracts. PCNA and RPA were separated from the other BER proteins by fractionation of human whole-cell extract on a phosphocellulose column. The protein fraction PC-FII (phosphocellulose fraction II), which does not contain RPA and PCNA but otherwise contains all core BER proteins required for PCNA-dependent BER (AP endonuclease, DNA polymerases delta, beta and DNA ligase, and FEN1 endonuclease), had reduced ability to repair plasmid DNA containing AP sites. Purified PCNA or RPA, when added separately, could only partially restore the PC-FII repair activity of AP sites. However, additions of both proteins together greatly stimulated AP site repair by PC-FII. These results demonstrate a role for RPA in PCNA-dependent BER of AP sites.     

The ubiquitin receptor Rad23: At the crossroads of nucleotide excision repair and proteasomal degradation

A protein that exemplifies the intimate link between the ubiquitin/proteasome system (UPS) and DNA repair is the yeast nucleotide excision repair (NER) protein Rad23 and its human orthologs hHR23A and hHR23B. Rad23, which was originally identified as an important factor involved in the recognition of DNA lesions, also plays a central role in targeting ubiquitylated proteins for proteasomal degradation, an activity that it shares with other ubiquitin receptors like Dsk2 and Ddi1. Although the finding that Rad23 serves as a ubiquitin receptor explains to a large extent its importance in proteasomal degradation, the precise mode of action of Rad23 in NER and the possible link with the UPS is less clear. In this review, we discuss our present knowledge on the functions of Rad23 in protein degradation and DNA repair and speculate on the importance of the dual roles of Rad23 for the cell's ability to cope with stress conditions.     

Micro-irradiation tools to visualize base excision repair and single-strand break repair

Microscopy and micro-irradiation imaging techniques have significantly advanced our knowledge of DNA damage tolerance and the assembly of DNA repair proteins at the sites of damage. While these tools have been extensively applied to the study of nucleotide excision repair and double-strand break repair, their application to the repair of oxidatively-induced base lesions and single-strand breaks is just beginning to yield new insights. This review will focus on examining micro-irradiation techniques reported to create base lesions and single-strand breaks; these lesions are considered to be primarily addressed by proteins involved in the base excision repair (BER) pathway. By examining conditions for generating these DNA lesions and reviewing information on the assembly and dissociation of repair complexes at the induced lesion sites, we hope to promote further investigations into BER and to stimulate further development and enhancement of these techniques for the study of BER.     

Interaction of nucleotide excision repair proteins with DNA containing bulky lesion and apurinic/apyrimidinic site

The interaction of nucleotide excision repair (NER) proteins (XPC-HR23b, RPA, and XPA) with 48-mer DNA duplexes containing the bulky lesion-mimicking fluorescein-substituted derivative of dUMP (5-{3-[6-(carboxyamidofluo-resceinyl)amidocapromoyl]allyl}-2′-deoxyuridine-5′-monophosphate) in a cluster with a lesion of another type (apurinic/apyrimidinic (AP) site) has been studied. It is shown that XPC-HR23b is modified to a greater extent by the DNA duplex containing an AP site opposite nucleotide adjacent to the fluorescein residue than by DNA containing an AP site shifted to the 3′-or 5′-end of the DNA strand. The efficiency of XPA modification by DNA duplexes containing both AP site and fluorescein residue is higher than that by DNA lacking the bulky lesion; the modification pattern in this case depends on the AP site position. In accordance with its major function, RPA interacts more efficiently with single-stranded DNA than with DNA duplexes, including those bearing bulky lesions. The observed interaction between the proteins involved in nucleotide excision repair and DNA structures containing a bulky lesion processed by NER and the AP site repaired via base excision repair may be significant for both these repair pathways in cells and requires the specific sequence of repair of clustered DNA lesions.     

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.     

DNA repair triggered by sensors of helical dynamics

Nucleotide excision repair is a constitutive stress response that eliminates DNA lesions induced by multiple genotoxic agents. Unlike the immune system, which generates billions of immunoglobulins and T cell receptors for antigen recognition, the nucleotide excision repair complex uses only a few generic factors to detect an astounding diversity of DNA modifications. New data favor an unexpected strategy whereby damage recognition is initiated by the detection of abnormal oscillations in the undamaged strand opposite to DNA lesions. Another core subunit recognizes the increased susceptibility of DNA to be kinked at injured sites. We suggest that early nucleotide excision repair factors gain substrate versatility by avoiding direct contacts with modified residues and exploiting instead the altered dynamics of damaged DNA duplexes.     

Low efficiency of DNA repair system in mitochondria

Under the action of endogenous reactive oxygen species and exogenous chemical and physical agents, significantly more lesions occur in mitochondrial DNA (mtDNA) than in nuclear DNA (nDNA). However, the mechanisms of DNA repair in mitochondria are less efficient that in the nuclei. The mechanisms of nucleotide excision repair capable of removing UV-induced lesions or other complex adducts induced by chemical compounds are not operative in mitochondria at all. At the same time, mitochondria of some kinds contain a photoreactivation enzyme providing monomerization of cyclobutane pyrimidine dimers. Also, the enzyme system for DNA base excision repair (BER) and O6-alkylguanine-DNA alkyl transferase are functional in mitochondria. However, the rate of BER-controlled repair of lesions in mtDNA is lower than that in nDNA. The literature data suggest that the controlling system for the delay of DNA replication till the repair complexion (cell cycle checkpoint) cannot be provided in mitochontria. Besides, it remains unclear whether the mismatch repair mechanisms are operable in mammalian mitochondria. On the other hand, double-strand breaks in mammalian mtDNA are possibly repaired by involving the DNA-dependent protein kinase complex, and the process of BER is affected by poly(ADP-ribosyl)ation of proteins. Possible consequences of induction of the increased level of damage in mtDNA and the low efficiency of repair systems in mitochondria are discussed in this review.     

Genotoxic stress in plants: shedding light on DNA damage, repair and DNA repair helicases

Plant cells are constantly exposed to environmental agents and endogenous processes that inflict damage to DNA and cause genotoxic stress, which can reduce plant genome stability, growth and productivity. Plants are most affected by solar UV-B radiation, which damage the DNA by inducing the formation of two main UV photoproducts such as cyclobutane pyrimidine dimers (CPDs) and pyrimidine (6-4) pyrimidone photoproducts (6-4PPs). Reactive oxygen species (ROS) are also generated extra- or intra-cellularly, which constitute yet another source of genotoxic stress. As a result of this stress, the cellular DNA-damage responses (DDR) are activated, which transiently arrest the cell cycle and allow cells to repair DNA before proceeding into mitosis. DDR requires the activation of Ataxia telangiectasia-mutated (ATM) and Rad3-related (ATR) genes, which regulate the cell cycle and transmit the damage signals to downstream effectors of cell-cycle progression. Since genomic protection and stability are fundamental to ensure and sustain plant diversity and productivity, therefore, repair of DNA damages is essential. In plants the bulky DNA lesions, CPDs and 6-4PPs, are repaired by a simple and error-free mechanism: photoreactivation, which is a light-dependent mechanism and requires CPD or 6-4PP specific photolyases. In addition to this direct repair process, the plants also have sophisticated light-independent general repair mechanisms, such as the nucleotide excision repair (NER) and base excision repair (BER). The completed plant genome sequences reveal that most of the genes involved in NER and BER are present in higher plants, which suggests that the network of in-built DNA-damage repair mechanisms is conserved. This article describes the insight underlying the DNA damage and repair pathways in plants. The comet assay to measure the DNA damage and the role of DNA repair helicases such as XPD and XPB are also covered.     

Long patch base excision repair with purified human proteins. DNA ligase I as patch size mediator for DNA polymerases delta and epsilon

Among the different base excision repair pathways known, the long patch base excision repair of apurinic/apyrimidinic sites is an important mechanism that requires proliferating cell nuclear antigen. We have reconstituted this pathway using purified human proteins. Our data indicated that efficient repair is dependent on six components including AP endonuclease, replication factor C, proliferating cell nuclear antigen, DNA polymerases delta or epsilon, flap endonuclease 1, and DNA ligase I. Fine mapping of the nucleotide replacement events showed that repair patches extended up to a maximum of 10 nucleotides 3' to the lesion. However, almost 70% of the repair synthesis was confined to 2-4-nucleotide patches and DNA ligase I appeared to be responsible for limiting the repair patch length. Moreover, both proliferating cell nuclear antigen and flap endonuclease 1 are required for the production and ligation of long patch repair intermediates suggesting an important role of this complex in both excision and resynthesis steps.