Damage Recognition In Nucleotide Excision Repair Research Articles

The Transcription-Repair Coupling Factor Mfd Prevents and Promotes Mutagenesis in a Context-Dependent Manner.

The mfd (mutation frequency decline) gene was identified by screening an auxotrophic Escherichia coli strain exposed to UV and held in a minimal medium before plating onto rich or minimal agar plates. It was found that, under these conditions, holding cells in minimal (nongrowth) conditions resulted in mutations that enabled cells to grow on minimal media. Using this observation as a starting point, a mutant was isolated that failed to mutate to auxotrophy under the prescribed conditions, and the gene responsible for this phenomenon (mutation frequency decline) was named mfd. Later work revealed that mfd encoded a translocase that recognizes a stalled RNA polymerase (RNAP) at damage sites and binds to the stalled RNAP, recruits the nucleotide excision repair damage recognition complex UvrA2UvrB to the site, and facilitates damage recognition and repair while dissociating the stalled RNAP from the DNA along with the truncated RNA. Recent single-molecule and genome-wide repair studies have revealed time-resolved features and structural aspects of this transcription-coupled repair (TCR) phenomenon. Interestingly, recent work has shown that in certain bacterial species, mfd also plays roles in recombination, bacterial virulence, and the development of drug resistance.

Roles of High Mobility Group Box Proteins in Nucleotide Excision Repair‐associated Processing of DNA Interstrand Crosslinks

Many traditional anti‐cancer chemotherapeutic agents induce DNA interstrand crosslinks (ICLs), lesions that form covalent bonds between the DNA strands. ICLs are highly cytotoxic if not properly repaired because they can block basic cellular processes such as transcription and replication. Nucleotide excision repair (NER) is a critical repair mechanism in processing ICLs in human cells. In addition to NER, ICLs are also processed through DNA double‐strand break repair pathways (e.g. homologous recombination) in S‐phase. We have previously demonstrated that the high mobility group box protein (HMGB1), a non‐histone architectural protein, can bind to site‐directed ICLs with high affinity and modulate error‐free repair processing of such lesions. In addition, we have found that HMGB1 associates with the NER damage recognition protein XPA in human cells and facilitates the recruitment of XPA to the damaged site. Further, we have demonstrated that HMGB1 can architecturally modify the damaged substrate by inducing negative supercoils, which may facilitate DNA damage processing by NER. We hypothesize that HMGB1 can modulate NER processing of ICLs by aiding NER damage‐recognition factors in locating damaged DNA. To test this hypothesis we are using a mutation‐reporter system to measure mutation frequencies and spectra generated by site‐directed ICLs in human cells. There are two NER subpathways that recognize DNA damage via different mechanisms. I am investigating in which pathway(s) HMGB1 is involved by utilizing various cell lines that are proficient or deficient for an essential recognition protein in each pathway. Additionally, we are investigating if HMGB2 and HMGB3, protein family members that are highly similar in structure to HMGB1, are also co‐factors in NER. Preliminary evidence suggests that HMGB1 may be involved in transcription coupled‐NER of site‐directed ICLs. If future evidence supports these data, this would indicate that HMGB1 could associate with transcription machinery and aid in recruiting other NER co‐factors, such as XPA. Future genetic, molecular biological, and biochemical assays will provide additional insight as to the roles of the HMGB proteins in ICL repair. The processing and repair of ICLs in human cells is not completely understood, and therefore a detailed study to define the molecular mechanisms of ICL processing is warranted. Identifying new proteins involved in ICL processing may lead to new pharmacological targets, which may help us to improve the outcome of cancer treatment.Support or Funding InformationNIH/NCI to K.V. (CA093729) and NSF GRFP to J.G.This abstract is from the Experimental Biology 2019 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.

Inorganic arsenic inhibits the nucleotide excision repair pathway and reduces the expression of XPC

Chronic exposure to arsenic, most often through contaminated drinking water, has been linked to several types of cancer in humans, including skin and lung cancer. However, the mechanisms underlying its role in causing cancer are not well understood. There is evidence that exposure to arsenic can enhance the carcinogenicity of UV light in inducing skin cancers and may enhance the carcinogenicity of tobacco smoke in inducing lung cancers. The nucleotide excision repair (NER) pathway removes different types of DNA damage including those produced by UV light and components of tobacco smoke. The aim of the present study was to investigate the effect of sodium arsenite on the NER pathway in human lung fibroblasts (IMR-90 cells) and primary mouse keratinocytes. To measure NER, we employed a slot-blot assay to quantify the introduction and removal of UV light-induced 6-4 photoproducts (6-4 PP) and cyclobutane pyrimidine dimers (CPDs). We find a concentration-dependent inhibition of the removal of 6-4 PPs and CPDs in both cell types treated with arsenite. Treatment of both cell types with arsenite resulted in a significant reduction in the abundance of XPC, a protein that is critical for DNA damage recognition in NER. The abundance of RNA expressed from several key NER genes was also significantly reduced by treatment of IMR-90 cells with arsenite. Finally, treatment of IMR-90 cells with MG-132 abrogated the reduction in XPC protein, suggesting an involvement of the proteasome in the reduction of XPC protein produced by treatment of cells with arsenic. The inhibition of NER by arsenic may reflect one mechanism underlying the role of arsenic exposure in enhancing cigarette smoke-induced lung carcinogenesis and UV light-induced skin cancer, and it may provide some insights into the emergence of arsenic trioxide as a chemotherapeutic agent.

Triplex structures induce DNA double strand breaks via replication fork collapse in NER deficient cells.

Structural alterations in DNA can serve as natural impediments to replication fork stability and progression, resulting in DNA damage and genomic instability. Naturally occurring polypurine mirror repeat sequences in the human genome can create endogenous triplex structures evoking a robust DNA damage response. Failures to recognize or adequately process these genomic lesions can result in loss of genomic integrity. Nucleotide excision repair (NER) proteins have been found to play a prominent role in the recognition and repair of triplex structures. We demonstrate using triplex-forming oligonucleotides that chromosomal triplexes perturb DNA replication fork progression, eventually resulting in fork collapse and the induction of double strand breaks (DSBs). We find that cells deficient in the NER damage recognition proteins, XPA and XPC, accumulate more DSBs in response to chromosomal triplex formation than NER-proficient cells. Furthermore, we demonstrate that XPC-deficient cells are particularly prone to replication-associated DSBs in the presence of triplexes. In the absence of XPA or XPC, deleterious consequences of triplex-induced genomic instability may be averted by activating apoptosis via dual phosphorylation of the H2AX protein. Our results reveal that damage recognition by XPC and XPA is critical to maintaining replication fork integrity and preventing replication fork collapse in the presence of triplex structures.

SUMO and ubiquitin-dependent XPC exchange drives nucleotide excision repair.

XPC recognizes UV-induced DNA lesions and initiates their removal by nucleotide excision repair (NER). Damage recognition in NER is tightly controlled by ubiquitin and SUMO modifications. Recent studies have shown that the SUMO-targeted ubiquitin ligase RNF111 promotes K63-linked ubiquitylation of SUMOylated XPC after DNA damage. However, the exact regulatory function of these modifications in vivo remains elusive. Here we show that RNF111 is required for efficient repair of ultraviolet-induced DNA lesions. RNF111-mediated ubiquitylation promotes the release of XPC from damaged DNA after NER initiation, and is needed for stable incorporation of the NER endonucleases XPG and ERCC1/XPF. Our data suggest that RNF111, together with the CRL4DDB2 ubiquitin ligase complex, is responsible for sequential XPC ubiquitylation, which regulates the recruitment and release of XPC and is crucial for efficient progression of the NER reaction, thereby providing an extra layer of quality control of NER.

Single-molecule analysis reveals human UV-damaged DNA-binding protein (UV-DDB) dimerizes on DNA via multiple kinetic intermediates.

How human DNA repair proteins survey the genome for UV-induced photoproducts remains a poorly understood aspect of the initial damage recognition step in nucleotide excision repair (NER). To understand this process, we performed single-molecule experiments, which revealed that the human UV-damaged DNA-binding protein (UV-DDB) performs a 3D search mechanism and displays a remarkable heterogeneity in the kinetics of damage recognition. Our results indicate that UV-DDB examines sites on DNA in discrete steps before forming long-lived, nonmotile UV-DDB dimers (DDB1-DDB2)2 at sites of damage. Analysis of the rates of dissociation for the transient binding molecules on both undamaged and damaged DNA show multiple dwell times over three orders of magnitude: 0.3-0.8, 8.1, and 113-126 s. These intermediate states are believed to represent discrete UV-DDB conformers on the trajectory to stable damage detection. DNA damage promoted the formation of highly stable dimers lasting for at least 15 min. The xeroderma pigmentosum group E (XP-E) causing K244E mutant of DDB2 found in patient XP82TO, supported UV-DDB dimerization but was found to slide on DNA and failed to stably engage lesions. These findings provide molecular insight into the loss of damage discrimination observed in this XP-E patient. This study proposes that UV-DDB recognizes lesions via multiple kinetic intermediates, through a conformational proofreading mechanism.

Structure-function analysis of the EF-hand protein centrin-2 for its intracellular localization and nucleotide excision repair

Centrin-2 is an evolutionarily conserved, calmodulin-related protein, which is involved in multiple cellular functions including centrosome regulation and nucleotide excision repair (NER) of DNA. Particularly to exert the latter function, complex formation with the XPC protein, the pivotal NER damage recognition factor, is crucial. Here, we show that the C-terminal half of centrin-2, containing two calcium-binding EF-hand motifs, is necessary and sufficient for both its localization to the centrosome and interaction with XPC. In XPC-deficient cells, nuclear localization of overexpressed centrin-2 largely depends on co-overexpression of XPC, and mutational analyses of the C-terminal domain suggest that XPC and the major binding partner in the centrosome share a common binding surface on the centrin-2 molecule. On the other hand, the N-terminal domain of centrin-2 also contains two EF-hand motifs but shows only low-binding affinity for calcium ions. Although the N-terminal domain is dispensable for enhancement of the DNA damage recognition activity of XPC, it contributes to augmenting rather weak physical interaction between XPC and XPA, another key factor involved in NER. These results suggest that centrin-2 may have evolved to bridge two protein factors, one with high affinity and the other with low affinity, thereby allowing delicate regulation of various biological processes.

The Efficiencies of Damage Recognition and Excision Correlate with Duplex Destabilization Induced by Acetylaminofluorene Adducts in Human Nucleotide Excision Repair

Nucleotide excision repair (NER) removes lesions caused by environmental mutagens or UV light from DNA. A hallmark of NER is the extraordinarily wide substrate specificity, raising the question of how one set of proteins is able to recognize structurally diverse lesions. Two key features of good NER substrates are that they are bulky and thermodynamically destabilize DNA duplexes. To understand what the limiting step in damage recognition in NER is, we set out to test the hypothesis that there is a correlation of the degree of thermodynamic destabilization induced by a lesion, binding affinity to the damage recognition protein XPC-RAD23B, and overall NER efficiency. We chose to use acetylaminofluorene (AAF) and aminofluorene (AF) adducts at the C8 position of guanine in different positions within the NarI (GGCGCC) sequence, as it is known that the structures of the duplexes depend on the position of the lesion in this context. We found that the efficiency of NER and the binding affinity of the damage recognition factor XPC-RAD23B correlated with the thermodynamic destabilization induced by the lesion. Our study is the first systematic analysis correlating these three parameters and supports the idea that initial damage recognition by XPC-RAD23B is a key rate-limiting step in NER.

The Ino80 chromatin-remodeling complex restores chromatin structure during UV DNA damage repair

Chromatin structure is modulated during deoxyribonucleic acid excision repair, but how this is achieved is unclear. Loss of the yeast Ino80 chromatin-remodeling complex (Ino80-C) moderately sensitizes cells to ultraviolet (UV) light. In this paper, we show that INO80 acts in the same genetic pathway as nucleotide excision repair (NER) and that the Ino80-C contributes to efficient UV photoproduct removal in a region of high nucleosome occupancy. Moreover, Ino80 interacts with the early NER damage recognition complex Rad4-Rad23 and is recruited to chromatin by Rad4 in a UV damage-dependent manner. Using a modified chromatin immunoprecipitation assay, we find that chromatin disruption during UV lesion repair is normal, whereas the restoration of nucleosome structure is defective in ino80 mutant cells. Collectively, our work suggests that Ino80 is recruited to sites of UV lesion repair through interactions with the NER apparatus and is required for the restoration of chromatin structure after repair.

Human HMGB1 directly facilitates interactions between nucleotide excision repair proteins on triplex-directed psoralen interstrand crosslinks

Psoralen is a chemotherapeutic agent that acts by producing DNA interstrand crosslinks (ICLs), which are especially cytotoxic and mutagenic because their complex chemical nature makes them difficult to repair. Proteins from multiple repair pathways, including nucleotide excision repair (NER), are involved in their removal in mammalian cells, but the exact nature of their repair is poorly understood. We have shown previously that HMGB1, a protein involved in chromatin structure, transcriptional regulation, and inflammation, can bind cooperatively to triplex-directed psoralen ICLs with RPA, and that mammalian cells lacking HMGB1 are hypersensitive to psoralen ICLs. However, whether this effect is mediated by a role for HMGB1 in DNA damage recognition is still unknown. Given HMGB1's ability to bind to damaged DNA and its interaction with the RPA protein, we hypothesized that HMGB1 works together with the NER damage recognition proteins to aid in the removal of ICLs. We show here that HMGB1 is capable of binding to triplex-directed psoralen ICLs with the dedicated NER damage recognition complex XPC-RAD23B, as well as XPA-RPA, and that they form a higher-order complex on these lesions. In addition, we demonstrate that HMGB1 interacts with XPC-RAD23B and XPA in the absence of DNA. These findings directly demonstrate interactions between HMGB1 and the NER damage recognition proteins, and suggest that HMGB1 may affect ICL repair by enhancing the interactions between NER damage recognition factors.

UV-DDB-dependent regulation of nucleotide excision repair kinetics in living cells

Although the basic principle of nucleotide excision repair (NER), which can eliminate various DNA lesions, have been dissected at the genetic, biochemical and cellular levels, the important in vivo regulation of the critical damage recognition step is poorly understood. Here we analyze the in vivo dynamics of the essential NER damage recognition factor XPC fused to the green fluorescence protein (GFP). Fluorescence recovery after photobleaching analysis revealed that the UV-induced transient immobilization of XPC, reflecting its actual engagement in NER, is regulated in a biphasic manner depending on the number of (6-4) photoproducts and titrated by the number of functional UV-DDB molecules. A similar biphasic UV-induced immobilization of TFIIH was observed using XPB-GFP. Surprisingly, subsequent integration of XPA into the NER complex appears to follow only the low UV dose immobilization of XPC. Our results indicate that when only a small number of (6-4) photoproducts are generated, the UV-DDB-dependent damage recognition pathway predominates over direct recognition by XPC, and they also suggest the presence of rate-limiting regulatory steps in NER prior to the assembly of XPA.

High mobility group protein B1 enhances DNA repair and chromatin modification after DNA damage

High mobility group protein B1 (HMGB1) is a multifunctional protein with roles in chromatin structure, transcriptional regulation, V(D)J recombination, and inflammation. HMGB1 also binds to and bends damaged DNA, but the biological consequence of this interaction is not clearly understood. We have shown previously that HMGB1 binds cooperatively with nucleotide excision repair damage recognition proteins to triplex-directed psoralen DNA interstrand cross-links (ICLs). Thus, we hypothesized that HMGB1 modulates the repair of DNA damage in mammalian cells. We demonstrate here that mammalian cells lacking HMGB1 are hypersensitive to DNA damage induced by psoralen plus UVA irradiation (PUVA) or UVC radiation, showing less survival and increased mutagenesis. In addition, nucleotide excision repair efficiency is significantly decreased in the absence of HMGB1 as assessed by the repair and removal of UVC lesions from genomic DNA. We also explored the role of HMGB1 in chromatin remodeling upon DNA damage. Immunoblotting demonstrated that, in contrast to HMGB1 proficient cells, cells lacking HMGB1 showed no histone acetylation upon DNA damage. Additionally, purified HMGB1 protein enhanced chromatin formation in an in vitro chromatin assembly system. These results reveal a role for HMGB1 in the error-free repair of DNA lesions. Its absence leads to increased mutagenesis, decreased cell survival, and altered chromatin reorganization after DNA damage. Because strategies targeting HMGB1 are currently in development for treatment of sepsis and rheumatoid arthritis, our findings draw attention to potential adverse side effects of anti-HMGB1 therapy in patients with inflammatory diseases.

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.

New Insights into the Roles of XPA and RPA in DNA Repair and Damage Responses

Xeroderma pigmentosum group A (XPA) and replication protein A (RPA) are two essential proteins for nucleotide excision repair (NER), a DNA repair pathway that removes a large variety of bulky DNA lesions in cells. In addition to its role in NER, RPA also is required for almost all other cellular DNA metabolic pathways, such as DNA replication, recombination, and other repair pathways. Although both proteins have been extensively studied for more than a decade, efforts have been focused mostly on their roles in DNA damage recognition in NER and/or single-stranded DNA binding. Recent advance in understanding the cellular functions of XPA and RPA reveals novel activities of the proteins in DNA damage responses. Briefly, XPA was found to be recruited to a DNA damage site for repair after TFIIH binds. The protein is also able to recognize specific structures of undamaged DNA. In addition, a nuclear import of XPA occurs upon DNA damage and in an ataxia-telangiectasia mutated and Rad3-related (ATR)-dependent manner. Furthermore, XPA undergoes phosphorylation by ATR checkpoint, promoting cell survival in response to UV irradiation. For RPA, the protein was found to play a role in activation of DNA damage checkpoint apparatuses ATR and the Rad9/Rad1/Hus1 complex. RPA also undergoes hyperphosphorylation upon DNA damage, which induces structural changes of the protein. Finally the hyperphosphorylation appears to be involved in modulating the activities of RPA and, thus, the cellular processes in which it participates. Here the molecular mechanisms by which XPA and RPA function in DNA damage responses are discussed in light of our recent understandings. Keywords: XPA, RPA, DNA damage, DNA repair, Checkpoint, Nucleotide excision repair

Crosslinking of the NER damage recognition proteins XPC-HR23B, XPA and RPA to photoreactive probes that mimic DNA damages

A new assay to probe the mechanism of mammalian nucleotide excision repair (NER) was developed. Photoreactive arylazido analogues of dNMP in DNA were shown to be substrates for the human NER system. Oligonucleotides carrying photoreactive “damages” were prepared using the multi-stage protocol including one-nucleotide gap filling by DNA polymerase β using photoreactive dCTP or dUTP analogues followed by ligation of the resulting nick. Photoreactive 60-mers were annealed with single-stranded pBluescript II SK (+) and subsequently primer extension reactions were performed. Incubation of HeLa extracts with the plasmids containing photoreactive moieties resulted in an excision pattern typical of NER. DNA duplexes containing photoreactive analogues were used to analyze the interaction of XPC-HR23B, RPA, and XPA with damaged DNA using the photocrosslinking assay. Crosslinking of the XPC-HR23B complex with photoreactive 60-mers resulted in modification of its XPC subunit. RPA crosslinked to ssDNA or mismatched dsDNA more efficiently than to dsDNA, whereas XPA did not show a preference for any of the DNA species. XPC and XPA photocrosslinking to DNA decreased in the presence of Mg 2+ whereas RPA crosslinking to DNA was not sensitive to this cofactor. Our data establish a photocrosslinking assay for the investigation of the damage recognition step in human nucleotide excision repair.

Human XPC-hHR23B interacts with XPA-RPA in the recognition of triplex-directed psoralen DNA interstrand crosslinks

DNA interstrand crosslinks (ICLs) represent a severe form of damage that blocks DNA metabolic processes and can lead to cell death or carcinogenesis. The repair of DNA ICLs in mammals is not well characterized. We have reported previously that a key protein complex of nucleotide excision repair (NER), XPA-RPA, recognizes DNA ICLs. We now report the use of triplex technology to direct a site-specific psoralen ICL to a target DNA substrate to determine whether the human global genome NER damage recognition complex, XPC-hHR23B, recognizes this lesion. Our results demonstrate that XPC-hHR23B recognizes psoralen ICLs, which have a structure fundamentally different from other lesions that XPC-hHR23B is known to bind, with high affinity and specificity. XPC-hHR23B and XPA-RPA protein complexes were also observed to bind psoralen ICLs simultaneously, demonstrating not only that psoralen ICLs are recognized by XPC-hHR23B alone, but also that XPA-RPA may interact cooperatively with XPC-hHR23B on damaged DNA, forming a multimeric complex. Since XPC-hHR23B and XPA-RPA participate in the recognition and verification of DNA damage, these results support the hypothesis that interplay between components of the global genome repair sub-pathway of NER is critical for the recognition of psoralen DNA ICLs in the mammalian genome.

Critical DNA damage recognition functions of XPC-hHR23B and XPA-RPA in nucleotide excision repair.

It has been reported that 80-90% of human cancers may result, in part, from DNA damage. Cell survival depends critically on the stability of our DNA and exquisitely sensitive DNA repair mechanisms have developed as a result. In humans, nucleotide excision repair (NER) protects the DNA against the mutagenic effects of carcinogens and ultraviolet (UV) radiation from sun exposure. By preventing mutations from forming in the DNA, the repair machinery ultimately protects us from developing cancers. DNA damage recognition is the rate-limiting step in repair, and although many details of NER have been elucidated, the mechanisms by which DNA damage is recognized remain to be fully determined. Two primary protein complexes have been proposed as the damaged DNA recognition factor in NER: xeroderma pigmentosum protein A-replication protein A (XPA-RPA) and xeroderma pigmentosum protein C-human homolog of RAD23B (XPC-hHR23B). Here we compare the evidence that supports damage detection by these protein complexes and propose a model for DNA damage recognition in NER based on the current understanding of the roles these proteins may play in the processing of DNA lesions.

Architecture of nucleotide excision repair complexes: DNA is wrapped by UvrB before and after damage recognition.

Nucleotide excision repair (NER) is a major DNA repair mechanism that recognizes a broad range of DNA damages. In Escherichia coli, damage recognition in NER is accomplished by the UvrA and UvrB proteins. We have analysed the structural properties of the different protein-DNA complexes formed by UvrA, UvrB and (damaged) DNA using atomic force microscopy. Analysis of the UvrA(2)B complex in search of damage revealed the DNA to be wrapped around the UvrB protein, comprising a region of about seven helical turns. In the UvrB-DNA pre-incision complex the DNA is wrapped in a similar way and this DNA configuration is dependent on ATP binding. Based on these results, a role for DNA wrapping in damage recognition is proposed. Evidence is presented that DNA wrapping in the pre-incision complex also stimulates the rate of incision by UvrC.