Structural basis for the recruitment of ERCC1-XPF to nucleotide excision repair complexes by XPA

The nucleotide excision repair (NER) pathway corrects DNA damage caused by sunlight, environmental mutagens and certain antitumor agents. This multistep DNA repair reaction operates by the sequential assembly of protein factors at sites of DNA damage. The efficient recognition of DNA damage and its repair are orchestrated by specific protein-protein and protein-DNA interactions within NER complexes. We have investigated an essential protein-protein interaction of the NER pathway, the binding of the XPA protein to the ERCC1 subunit of the repair endonuclease ERCC1-XPF. The structure of ERCC1 in complex with an XPA peptide shows that only a small region of XPA interacts with ERCC1 to form a stable complex exhibiting submicromolar binding affinity. However, this XPA peptide is a potent inhibitor of NER activity in a cell-free assay, blocking the excision of a cisplatin adduct from DNA. The structure of the peptide inhibitor bound to its target site reveals a binding interface that is amenable to the development of small molecule peptidomimetics that could be used to modulate NER repair activities in vivo.     

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.     

Isolation of human complexes proficient in nucleotide excision repair.

More than 20 polypeptides are required for the process of nucleotide excision repair (NER) in both human and yeast cells. This pathway of excision repair has most often been viewed as an ordered multi-step process involving steps of damage recognition, incision/excision and finally repair DNA synthesis. Here we present evidence for the existence of a complex of human NER proteins pre-assembled in the absence of damaged DNA. This multi-protein complex was initially isolated from HeLa cell extracts by affinity chromatography on a matrix containing the damage recognition protein XPA. Subsequent co-immunoprecipitation and gel filtration experiments demonstrated that a significant portion of the human NER proteins was present in the form of a high molecular weight complex and that these complexes, or repairosomes, were capable of performing all steps of NER in vitro . Consistent with studies indicating that DNA polymerasesdeltaandstraightepsiloncan both function in NER, these two polymerases are found in these repairosome complexes.     

Strand-specific binding of RPA and XPA to damaged duplex DNA

The nucleotide excision repair (NER) pathway is a major pathway used to repair bulky adduct DNA damage. Two proteins, xeroderma pigmentosum group A protein (XPA) and replication protein A (RPA), have been implicated in the role of DNA damage recognition in the NER pathway. The particular manner in which these two damage recognition proteins align themselves with respect to a damaged DNA site was assessed using photoreactive base analogues within specific DNA substrates to allow site-specific cross-linking of the damage recognition proteins. Results of these studies demonstrate that both RPA and XPA are in close proximity to the adduct as measured by cross-linking of each protein directly to the platinum moiety. Additional studies demonstrate that XPA contacts both the damaged and undamaged strands of the duplex DNA. Direct evidence is presented demonstrating preferential binding of RPA to the undamaged strand of a duplex damaged DNA molecule.     

The yeast Rad7/Rad16/Abf1 complex generates superhelical torsion in DNA that is required for nucleotide excision repair

Nucleotide excision repair (NER) in eukaryotes removes DNA base damage as an oligonucleotide in a complex series of reactions. The nature of the dual incision reactions on either side of the damaged base has been extensively investigated. However, the precise mechanism of cleavage of the phosphodiester backbone of the DNA by the NER endonucleases and how this relates to removal of the damage-containing oligonucleotide during the excision process has not been determined. We previously isolated a stable heterotrimeric complex of Rad7/Rad16/Abf1 from yeast which functions in the conserved global genome repair (GGR) pathway. GGR removes lesions from DNA that is not actively transcribing. We have shown previously that the Rad7/Rad16/Abf1 heterotrimer is required to observe DNA repair synthesis and oligonucleotide excision during in vitro NER, but not needed to detect NER-dependent incision in such reactions. Here we report that this protein complex generates superhelicity in DNA through the catalytic activity of the Rad16 component. The torsion generated in the DNA by this complex is necessary to remove the damage-containing oligonucleotide during NER--a process referred to as excision. We conclude that in yeast the molecular mechanism of NER includes the generation of superhelical torsion in DNA.     

Regulation of DNA damage response pathways by the cullin-RING ubiquitin ligases

Eukaryotic cells repair ultraviolet light (UV)- and chemical carcinogen-induced DNA strand-distorting damage through the nucleotide excision repair (NER) pathway. Concurrent activation of the DNA damage checkpoints is also required to arrest the cell cycle and allow time for NER action. Recent studies uncovered critical roles for ubiquitin-mediated post-translational modifications in controlling both NER and checkpoint functions. In this review, we will discuss recent progress in delineating the roles of cullin-RING E3 ubiquitin ligases in orchestrating the cellular DNA damage response through ubiquitination of NER factors, histones, and checkpoint effectors.     

Checkpoint arrest signaling in response to UV damage is independent of nucleotide excision repair in Saccharomyces cerevisiae

The recognition of DNA double-stranded breaks or single-stranded DNA gaps as a precondition for cell cycle checkpoint arrest has been well established. However, how bulky base damage such as UV-induced pyrimidine dimers elicits a checkpoint response has remained elusive. Nucleotide excision repair represents the main pathway for UV dimer removal that results in strand interruptions. However, we demonstrate here that Rad53p hyperphosphorylation, an early event of checkpoint signaling in Saccharomyces cerevisiae, is independent of nucleotide excision repair (NER), even if replication as a source of secondary DNA damage is excluded. Thus, our data hint at primary base damage or at UV damage (primary or secondary) that does not need to be processed by NER as the relevant substrate of damage-sensing checkpoint proteins.     

Repair of DNA damage induced by anthanthrene, a polycyclic aromatic hydrocarbon (PAH) without bay or fjord regions

Polycyclic aromatic hydrocarbons (PAHs) are environmental pollutants, formed during incomplete burning of coal, oil and gas. Several PAHs have carcinogenic and mutagenic potencies, but these compounds must be activated in order to exert their mutagenic effects. One of the principal pathways proposed for metabolic activation of PAHs involves the cytochrome P450 enzymes. The DNA damaging potential of cytochrome P450-activated PAHs is generally associated with their bay and fjord regions, and the DNA repair response of PAHs containing such regions has been thoroughly studied. However, little is known about the repair of DNA damage resulting from metabolites from PAHs without bay and fjord regions. We have investigated the six-ringed PAH anthanthrene (dibenzo[def,mno]chrysene), which does not posses bay or fjord motifs. We analyzed the repair profile of human cell extracts and of cell cultures in response to DNA damage induced by cytochrome P450-activated anthanthrene. In cell extracts, functional nucleotide excision repair (NER) and mismatch repair (MMR) activities were necessary to trigger a response to anthanthrene metabolite-induced DNA damage. In cell cultures, NER was responsible for the repair of anthanthrene metabolite-induced DNA damage. However, when the NER pathway was inactivated, a residual repair pathway performed the DNA repair.     

Base excision repair sensitizes cells to sulfur mustard and chloroethyl ethyl sulfide

DNA repair generally functions to improve survival and reduce mutagenesis of cells that have suffered DNA damage. In this study we examine the role of nucleotide excision repair (NER) and base excision repair (BER) in recovery, mutagenesis and DNA repair in response to DNA damage inflicted by the mustard compounds, sulfur mustard (SM) and chloroethyl ethyl sulfide (CEES) in bacteria and mammalian cells. SM and CEES are compared because SM produces cross-links and monoadducts, whereas CEES produces only monoadducts that are similar to those produced by SM, thus allowing the examination of which types of lesions may be responsible for the effects seen. We find that the presence of a functional NER pathway increases survival and reduces mutagenesis, whereas the presence of a functional BER pathway reduces survival, increases mutagenesis, and decreases repair. The deleterious effects of BER appear to be due to an interaction between the DNA glycosylases and the lesions produced by SM and CEES. Possible mechanisms for BER-mediated sensitization by glycosylase action on mustard lesions are discussed.     

Role of p21WAF1 in the cellular response to UV

UV or g irradiation mediated DNA damage activates p53 and induces cell cycle arrest. Induction of cyclin dependent kinase inhibitor p21WAF1 by p53 after DNA damage plays an important role in cell cycle arrest after gamma irradiation. The p53 mediated cell cycle arrest has been postulated to allow cells to repair the DNA damage. Repair of UV damaged DNA occurs primarily by the nucleotide excision pathway (NER). It is known that p21WAF1 binds PCNA and inhibits PCNA function in DNA replication. PCNA is also required for repair by NER but there have been conflicting reports on whether p21WAF1 can inhibit PCNA function in NER. It has therefore been difficult to integrate the UV induced cell cycle arrest by p21 in the context of repair of UV damaged DNA. A recent study reported that p21WAF1 protein is degraded after low but not high doses of UV irradiation, that cell cycle arrest after UV is p21 independent, and that at low dose UV irradiation p21WAF1 degradation is essential for optimal DNA repair. These findings shed new light on the role of p21 in the cellular response to UV and clarify some outstanding issues concerning p21WAF1 function.     

Delineating the requirements for spontaneous DNA damage resistance pathways in genome maintenance and viability in Saccharomyces cerevisiae

Cellular metabolic processes constantly generate reactive species that damage DNA. To counteract this relentless assault, cells have developed multiple pathways to resist damage. The base excision repair (BER) and nucleotide excision repair (NER) pathways remove damage whereas the recombination (REC) and postreplication repair (PRR) pathways bypass the damage, allowing deferred removal. Genetic studies in yeast indicate that these pathways can process a common spontaneous lesion(s), with mutational inactivation of any pathway increasing the burden on the remaining pathways. In this study, we examine the consequences of simultaneously compromising three or more of these pathways. Although the presence of a functional BER pathway alone is able to support haploid growth, retention of the NER, REC, or PRR pathway alone is not, indicating that BER is the key damage resistance pathway in yeast and may be responsible for the removal of the majority of either spontaneous DNA damage or specifically those lesions that are potentially lethal. In the diploid state, functional BER, NER, or REC alone can support growth, while PRR alone is insufficient for growth. In diploids, the presence of PRR alone may confer a lethal mutation load or, alternatively, PRR alone may be insufficient to deal with potentially lethal, replication-blocking lesions.     

Role of p21WAF1 in the Cellular Response to UV

UV or gamma irradiation mediated DNA damage activates p53 and induces cell cycle arrest. Induction of cyclin-dependent kinase inhibitor p21WAF1 by p53 after DNA damage plays an important role in cell cycle arrest after gamma irradiation. The p53 mediated cell cycle arrest has been postulated to allow cells to repair the DNA damage. Repair of UV damaged DNA occurs primarily by the nucleotide excision pathway (NER). It is known that p21WAF1 binds PCNA and inhibits PCNA function in DNA replication. PCNA is also required for repair by NER but there have been conflicting reports on whether p21 can inhibit PCNA function in NER. It has therefore been difficult to integrate the UV induced cell cycle arrest by p21 in the context of repair of UV damaged DNA. A recent study reported that p21WAF1 protein is degraded after low but not high doses of UV irradiation, that cell cycle arrest after UV is p21 independent, and that at low dose UV irradiation p21 degradation is essential for optimal DNA repair. These findings shed new light on the role of p21 in the cellular response to UV and clarify some outstanding issues concerning p21 function.     

Nitrogen mustard- and half-mustard-induced damage in Escherichia coli requires different DNA repair pathways

Bifunctional alkylating agents are used in tumor chemotherapy to induce the death of malignant cells through blockage of DNA replication. Nitrogen mustards are commonly used chemotherapeutic agents that can bind mono- or bifunctionally to guanines in DNA. Mustard HN1 is considered a monofunctional analog of bifunctional mustard HN2 (mechlorethamine). Escherichia coli K12 mutant strains deficient in nucleotide excision repair (NER) or base excision repair (BER) were submitted to increasing concentrations of HN2 or HN1, and the results revealed that damage induced by each chemical demands different DNA repair pathways. Damage induced by HN2 demands the activity of NER with a minor requirement of the BER pathway, while HN1 damage repair depends on BER action, without any requirement of NER function. Taken together, our data suggest that HN1 and HN2 seem to induce different types of damage, since their repair depends on distinct pathways in E. coli.     

Genetic interactions of DNA repair pathways in the pathogen Neisseria meningitidis

The current increase in the incidence and severity of infectious diseases mandates improved understanding of the basic biology and DNA repair profiles of virulent microbes. In our studies of the major pathogen and model organism Neisseria meningitidis, we constructed a panel of mutants inactivating genes involved in base excision repair, mismatch repair, nucleotide excision repair (NER), translesion synthesis, and recombinational repair pathways. The highest spontaneous mutation frequency among the N. meningitidis single mutants was found in the MutY-deficient strain as opposed to mutS mutants in Escherichia coli, indicating a role for meningococcal MutY in antibiotic resistance development. Recombinational repair was recognized as a major pathway counteracting methyl methanesulfonate-induced alkylation damage in the N. meningitidis. In contrast to what has been shown in other species, meningococcal NER did not contribute significantly to repair of alkylation-induced DNA damage, and meningococcal recombinational repair may thus be one of the main pathways for removal of abasic (apurinic/apyrimidinic) sites and strand breaks in DNA. Conversely, NER was identified as the main meningococcal defense pathway against UV-induced DNA damage. N. meningitidis RecA single mutants exhibited only a moderate decrease in survival after UV exposure as opposed to E. coli recA strains, which are extremely UV sensitive, possibly reflecting the lack of a meningococcal SOS response. In conclusion, distinct differences between N. meningitidis and established DNA repair characteristics in E. coli and other species were identified.