Coordination of dual incision and repair synthesis in human nucleotide excision repair

Nucleotide excision repair (NER) requires the coordinated sequential assembly and actions of the involved proteins at sites of DNA damage. Following damage recognition, dual incision 5′ to the lesion by ERCC1‐XPF and 3′ to the lesion by XPG leads to the removal of a lesion‐containing oligonucleotide of about 30 nucleotides. The resulting single‐stranded DNA (ssDNA) gap on the undamaged strand is filled in by DNA repair synthesis. Here, we have asked how dual incision and repair synthesis are coordinated in human cells to avoid the exposure of potentially harmful ssDNA intermediates. Using catalytically inactive mutants of ERCC1‐XPF and XPG, we show that the 5′ incision by ERCC1‐XPF precedes the 3′ incision by XPG and that the initiation of repair synthesis does not require the catalytic activity of XPG. We propose that a defined order of dual incision and repair synthesis exists in human cells in the form of a ‘cut‐patch‐cut‐patch’ mechanism. This mechanism may aid the smooth progression through the NER pathway and contribute to genome integrity.     

Thermodynamic and structural factors in the removal of bulky DNA adducts by the nucleotide excision repair machinery

The function of the human nucleotide excision repair (NER) apparatus is to remove bulky adducts from damaged DNA. In an effort to gain insights into the molecular mechanisms involved in the recognition and excision of bulky lesions, we investigated a series of site specifically modified oligonucleotides containing single, well-defined polycyclic aromatic hydrocarbon (PAH) diol epoxide-adenine adducts. Covalent adducts derived from the bay region PAH, benzo[a]pyrene, are removed by human NER enzymes in vitro. In contrast, the stereochemically analogous N(6)-dA adducts derived from the topologically different fjord region PAH, benzo[c]phenanthrene, are resistant to repair. The evasion of DNA repair may play a role in the observed higher tumorigenicity of the fjord region PAH diol epoxides. We are elucidating the structural and thermodynamic features of these adducts that may underlie their marked distinction in biologic function, employing high-resolution nuclear magnetic resonance studies, measurements of thermal stabilities of the PAH diol epoxide-modified oligonucleotide duplexes, and molecular dynamics simulations with free energy calculations. Our combined findings suggest that differences in the thermodynamic properties and thermal stabilities are associated with differences in distortions to the DNA induced by the lesions. These structural effects correlate with the differential NER susceptibilities and stem from the intrinsically distinct shapes of the fjord and bay region PAH diol epoxide-N(6)-adenine adducts.     

A nonsense mutation in the Xeroderma pigmentosum complementation group F (XPF) gene is associated with gastric carcinogenesis

XPF/ERCC1 endonuclease is required for DNA lesion repair. To assess effects of a C2169A nonsense mutation in XPF at position 2169 in gastric cancer tissues and cell lines, genomic DNA was extracted from blood samples of 488 cancer patients and 64 gastric tumors. The mutation was mapped using a TaqMan MGB probe. In addition, gastric cancer cell lines were transfected with mutated XPF to explore XPF/ERCC1 interaction, XPF degradation, and DNA repair by a comet assay. The C2169A mutation was not detected in 488 samples of blood genomic DNA, yet was found in 32 of 64 gastric cancer tissue samples (50.0%), resulting in a 194C-terminal amino acid loss in XPF protein and lower expression. Laser micro-dissection confirmed that this point mutation was not present in surrounding normal tissues from the same patients. The truncated form of XPF (tXPF) impaired interaction with ERCC1, was rapidly degraded via ubiquitination, and resulted in reduced DNA repair. In gastric cancers, the mutation was monoallelic, indicating that XPF is a haplo-insufficient DNA repair gene. As the C2169A mutation is closely associated with gastric carcinogenesis in the Chinese population, our findings shine light on it as a therapeutic target for early diagnosis and treatment of gastric cancer.     

Structural dynamics and interactions of Xeroderma pigmentosum complementation group A (XPA98–210) with damaged DNA

Nucleotide excision repair (NER) in higher organisms repair massive DNA abrasions caused by ultraviolet rays, and various mutagens, where Xeroderma pigmentosum group A (XPA) protein is known to be involved in damage recognition step. Any mutations in XPA cause classical Xeroderma pigmentosum disease. The extent to which XPA is required in the NER is still unclear. Here, we present the comparative study on the structural and conformational changes in globular DNA binding domain of XPA_98–210 in DNA bound and DNA free state. Atomistic molecular dynamics simulation was carried out for both XPA_98–210 systems using AMBER force fields. We observed that XPA_98–210 in presence of damaged DNA exhibited more structural changes compared to XPA_98–210 in its free form. When XPA is in contact with DNA, we found marked stability of the complex due to the formation of characteristic longer antiparallel β-sheets consisting mainly lysine residues.     

Cell-type-specific level of DNA nucleotide excision repair in primary human mammary and ovarian epithelial cell cultures

DNA repair, a fundamental function of cellular metabolism, has long been presumed to be constitutive and equivalent in all cells. However, we have previously shown that normal levels of nucleotide excision repair (NER) can vary by 20-fold in a tissue-specific pattern. We have now successfully established primary cultures of normal ovarian tissue from seven women by using a novel culture system originally developed for breast epithelial cells. Epithelial cells in these cultures aggregated to form three-dimensional structures called "attached ovarian epispheres". The availability of these actively proliferating cell cultures allowed us to measure NER functionally and quantitatively by the unscheduled DNA synthesis (UDS) assay, a clinical test used to diagnose constitutive deficiencies in NER capacity. We determined that ovarian epithelial cells manifested an intermediate level of NER capacity in humans, viz., only 25% of that of foreskin fibroblasts, but still 2.5-fold higher than that of peripheral blood lymphocytes. This level of DNA repair capacity was indistinguishable from that of normal breast epithelial cells, suggesting that it might be characteristic of the epithelial cell type. Similar levels of NER activity were observed in cultures established from a disease-free known carrier of a BRCA1 truncation mutation, consistent with previous normal results shown in breast epithelium and blood lymphocytes. These results establish that at least three "normal" levels of such DNA repair occur in human tissues, and that NER capacity is epigenetically regulated during cell differentiation and development.     

Nucleotide excision repair and cancer

Nucleotide excision repair (NER) is the most versatile and best studied DNA repair system in humans. NER can repair a variety of bulky DNA damages including UV-light induced DNA photoproducts. NER consists of a multistep process in which the DNA lesion is recognized and demarcated by DNA unwinding. Then, a ~28 bp DNA damage containing oligonucleotide is excised followed by gap filling using the undamaged DNA strand as a template. The consequences of defective NER are demonstrated by three rare autosomal-rezessive NER-defective syndromes: xeroderma pigmentosum (XP), Cockayne syndrome (CS), and trichothiodystrophy (TTD). XP patients show severe sun sensitivity, freckling in sun exposed skin, and develop skin cancers already during childhood. CS patients exhibit sun sensitivity, severe neurologic abnormalities, and cachectic dwarfism. Clinical symptoms of TTD patients include sun sensitivity, freckling in sun exposed skin areas, and brittle sulfur-deficient hair. In contrast to XP patients, CS and TTD patients are not skin cancer prone. Studying these syndromes can increase the knowledge of skin cancer development including cutaneous melanoma as well as basal and squamous cell carcinoma in general that may lead to new preventional and therapeutic anticancer strategies in the normal population.     

UV-induced ubiquitylation of XPC complex, the UV-DDB-ubiquitin ligase complex, and DNA repair

The DNA nucleotide excision repair (NER) system is our major defense against carcinogenesis. Defects in NER are associated with several human genetic disorders including xeroderma pigmentosum (XP), which is characterized by a marked predisposition to skin cancer. For initiation of the repair reaction at the genome-wide level, a complex containing one of the gene products involved in XP, the XPC protein, must bind to the damaged DNA site. The UV-damaged DNA-binding protein (UV-DDB), which is impaired in XP group E patients, has also been implicated in damage recognition in global genomic NER, but its precise functions and its relationship to the XPC complex have not been elucidated. However, the recent discovery of the association of UV-DDB with a cullin-based ubiquitin ligase has functionally linked the two damage recognition factors and shed light on novel mechanistic and regulatory aspects of global genomic NER. This article summarizes our current knowledge of the properties of the XPC complex and UV-DDB and discusses possible roles for ubiquitylation in the molecular mechanisms that underlie the efficient recognition and repair of DNA damage, particularly that induced by ultraviolet light irradiation, in preventing damage-induced mutagenesis as well as carcinogenesis.     

Retrovirus-mediated DNA repair gene transfer into xeroderma pigmentosum cells: Perspectives for a gene therapy

The rare hereditary disease xeroderma pigmentosum (XP) is clinically characterized by extreme sun sensitivity and an increased predisposition for developing skin cancer. Cultured cells from XP patients exhibit hypersensitivity to ultraviolet (UV) radiation due to the defect in nucleotide excision repair (NER), and other cellular abnormalities. Seven genes identified in the classical XP forms, XPA to XPG, are involved in the NER pathway. In view of developing a strategy of gene therapy for XP, we devised recombinant retrovirus-carrying DNA repair genes for transfer and stable expression of these genes in cells from XP patients. Results showed that these retroviruses are efficient tools for transducing XP fibroblasts and correcting repair-defective cellular phenotypes by recovering normal UV survival, unscheduled DNA synthesis, and RNA synthesis after UV irradiation, and also other cellular abnormalities resulting from NER defects. These results imply that the first step of cellular gene therapy might be accomplished successfully.     

Nucleotide excision repair in higher eukaryotes: Mechanism of primary damage recognition

Nucleotide excision repair (NER) is one of the major DNA repair pathways in eukaryotic cells. NER removes structurally diverse lesions such as pyrimidine dimers, arising upon UV irradiation, and bulky chemical adducts, arising upon exposure to carcinogens and some chemotherapeutic drugs. NER defects lead to severe diseases, including some forms of cancer. In view of the broad substrate specificity of NER, it is of interest to study how a certain set of proteins recognizes DNA lesions in contest of a large excess of intact DNA. The review focuses on DNA damage recognition, the key and, as yet, most questionable step of NER. The main models of primary damage recognition and preincision complex assembly are considered. The model of a sequential loading of repair proteins on damaged DNA seems most reasonable in light of the available data.     

Protein oxidation,UVA and human DNA repair

Solar UVB is carcinogenic. Nucleotide excision repair (NER) counteracts the carcinogenicity of UVB by excising potentially mutagenic UVB-induced DNA lesions. Despite this capacity for DNA repair, non-melanoma skin cancers and apparently normal sun-exposed skin contain huge numbers of mutations that are mostly attributable to unrepaired UVB-induced DNA lesions. UVA is about 20-times more abundant than UVB in incident sunlight. It does cause some DNA damage but this does not fully account for its biological impact. The effects of solar UVA are mediated by its interactions with cellular photosensitizers that generate reactive oxygen species (ROS) and induce oxidative stress. The proteome is a significant target for damage by UVA-induced ROS. In cultured human cells, UVA-induced oxidation of DNA repair proteins inhibits DNA repair. This article addresses the possible role of oxidative stress and protein oxidation in determining DNA repair efficiency – with particular reference to NER and skin cancer risk.     

Paracrine regulation of melanocyte genomic stability: a focus on nucleotide excision repair

UV radiation is a major environmental risk factor for the development of melanoma by causing DNA damage and mutations. Resistance to UV damage is largely determined by the capacity of melanocytes to respond to UV injury by repairing mutagenic photolesions. The nucleotide excision repair (NER) pathway is the major mechanism by which cells correct UV photodamage. This multistep process involves the basic steps of damage recognition, isolation, localized strand unwinding, assembly of a repair complex, excision of the damage‐containing strand 3′ and 5′ to the photolesion, synthesis of a sequence‐appropriate replacement strand, and finally ligation to restore continuity of genomic DNA. In melanocytes, the efficiency of NER is regulated by several hormonal pathways including the melanocortin and endothelin signaling pathways. Elucidating molecular mechanisms by which melanocyte DNA repair is regulated offers the possibility of developing novel melanoma‐preventive strategies to reduce UV mutagenesis, especially in UV‐sensitive melanoma‐prone individuals.     

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.