XPA protein as a limiting factor for nucleotide excision repair and UV sensitivity in human cells

Nucleotide excision repair (NER) acts on a variety of DNA lesions, including damage induced by many chemotherapeutic drugs. Cancer therapy with such drugs might be improved by reducing the NER capacity of tumors. It is not known, however to what extent any individual NER protein is rate-limiting for any step of the repair reaction. We studied sensitivity to UV radiation and repair of DNA damage with regard to XPA, one of the core factors in the NER incision complex. About 150,000-200,000 molecules of XPA protein are present in NER proficient human cell lines, and no XPA protein in the XP-A cell line XP12RO. Transfected XP12RO cell lines expressing 50,000 or more XPA molecules/cell showed UV resistance similar to normal cells. Suppression of XPA protein to approximately 10,000 molecules/cell in a Tet-regulatable system modestly but significantly increased sensitivity to UV irradiation. No removal of cyclobutane pyrimidine dimers was detected in the SV40 immortalized cell lines tested. Repair proficient WI38-VA fibroblasts and transfected XP-A cells expressing 150,000 molecules of XPA/cell removed (6-4) photoproducts from the genome with a half-life of 1h. Cells in which XPA protein was reduced to about 10,000 molecules/cell removed (6-4) photoproducts more slowly, with a half-life of 3h. A reduced rate of repair of (6-4) photoproducts thus results in increased cellular sensitivity towards UV irradiation. These data indicate that XPA levels must be reduced to <10% of that present in a normal cell to render XPA a limiting factor for NER and consequent cellular sensitivity. To inhibit NER, it may be more effective to interfere with XPA protein function, rather than reducing XPA protein levels.     

Human nucleotide excision repair efficiently removes chromium-DNA phosphate adducts and protects cells against chromate toxicity

Intracellular reduction of carcinogenic Cr(VI) leads to the extensive formation of Cr(III)-DNA phosphate adducts. Repair mechanisms for chromium and other DNA phosphate-based adducts are currently unknown in human cells. We found that nucleotide excision repair (NER)-proficient human cells rapidly removed chromium-DNA adducts, with an average t((1/2)) of 7.1 h, whereas NER-deficient XP-A, XP-C, and XP-F cells were severely compromised in their ability to repair chromium-DNA lesions. Activation of NER in Cr(VI)-treated human fibroblasts or lung epithelial H460 cells was manifested by XPC-dependent binding of the XPA protein to the nuclear matrix, which was also observed in UV light-treated (but not oxidant-stressed) cells. Intracellular replication of chromium-modified plasmids demonstrated increased mutagenicity of binary Cr(III)-DNA and ternary cysteine-Cr(III)-DNA adducts in cells with inactive NER. NER deficiency created by the loss of XPA in fibroblasts or by knockdown of this protein by stable expression of small interfering RNA in H460 cells increased apoptosis and clonogenic death by Cr(VI), providing genetic evidence for the role of monofunctional chromium-DNA adducts in the toxic effects of this metal. The rate of NER of chromium-DNA adducts under saturating conditions was calculated to be approximately 50,000 lesions/min/cell. Because chromium-DNA adducts cause only small changes in the DNA helix, rapid repair of these modifications in human cells indicates that the presence of major structural distortions in DNA is not required for the efficient detection of the damaged sites by NER proteins in vivo.     

DNA repair factor XPC is modified by SUMO-1 and ubiquitin following UV irradiation

Nucleotide excision repair (NER) is the major DNA repair process that removes diverse DNA lesions including UV-induced photoproducts. There are more than 20 proteins involved in NER. Among them, XPC is thought to be one of the first proteins to recognize DNA damage during global genomic repair (GGR), a sub-pathway of NER. In order to study the mechanism through which XPC participates in GGR, we investigated the possible modifications of XPC protein upon UV irradiation in mammalian cells. Western blot analysis of cell lysates from UV-irradiated normal human fibroblast, prepared by direct boiling in an SDS lysis buffer, showed several anti-XPC antibody-reactive bands with molecular weight higher than the original XPC protein. The reciprocal immunoprecipitation and siRNA transfection analysis demonstrated that XPC protein is modified by SUMO-1 and ubiquitin. By using several NER-deficient cell lines, we found that DDB2 and XPA are required for UV-induced XPC modifications. Interestingly, both the inactivation of ubiquitylation and the treatment of proteasome inhibitors quantitatively inhibited the UV-induced XPC modifications. Furthermore, XPC protein is degraded significantly following UV irradiation in XP-A cells in which sumoylation of XPC does not occur. Taken together, we conclude that XPC protein is modified by SUMO-1 and ubiquitin following UV irradiation and these modifications require the functions of DDB2 and XPA, as well as the ubiquitin–proteasome system. Our results also suggest that at least one function of UV-induced XPC sumoylation is related to the stabilization of XPC protein.     

Xeroderma pigmentosum group A protein loads as a separate factor onto DNA lesions

Nucleotide excision repair (NER) is the main DNA repair pathway in mammals for removal of UV-induced lesions. NER involves the concerted action of more than 25 polypeptides in a coordinated fashion. The xeroderma pigmentosum group A protein (XPA) has been suggested to function as a central organizer and damage verifier in NER. How XPA reaches DNA lesions and how the protein is distributed in time and space in living cells are unknown. Here we studied XPA in vivo by using a cell line stably expressing physiological levels of functional XPA fused to green fluorescent protein and by applying quantitative fluorescence microscopy. The majority of XPA moves rapidly through the nucleoplasm with a diffusion rate different from those of other NER factors tested, arguing against a preassembled XPA-containing NER complex. DNA damage induced a transient ( approximately 5-min) immobilization of maximally 30% of XPA. Immobilization depends on XPC, indicating that XPA is not the initial lesion recognition protein in vivo. Moreover, loading of replication protein A on NER lesions was not dependent on XPA. Thus, XPA participates in NER by incorporation of free diffusing molecules in XPC-dependent NER-DNA complexes. This study supports a model for a rapid consecutive assembly of free NER factors, and a relatively slow simultaneous disassembly, after repair.     

Defective repair of cisplatin-induced DNA damage caused by reduced XPA protein in testicular germ cell tumours

Metastatic cancer in adults usually has a fatal outcome. In contrast, advanced testicular germ cell tumours are cured in over 80% of patients using cisplatin-based combination chemotherapy [1]. An understanding of why these cells are sensitive to chemotherapeutic drugs is likely to have implications for the treatment of other types of cancer. Earlier measurements indicate that testis tumour cells are hypersensitive to cisplatin and have a low capacity to remove cisplatin-induced DNA damage from the genome [2] [3]. We have investigated the nucleotide excision repair (NER) capacity of extracts from the well-defined 833K and GCT27 human testis tumour cell lines. Both had a reduced ability to carry out the incision steps of NER in comparison with extracts from known repair-proficient cells. Immunoblotting revealed that the testis tumour cells had normal amounts of most NER proteins, but low levels of the xeroderma pigmentosum group A protein (XPA) and the ERCC1-XPF endonuclease complex. Addition of XPA specifically conferred full NER capacity on the testis tumour extracts. These results show that a low XPA level in the testis tumour cell lines is sufficient to explain their poor ability to remove cisplatin adducts from DNA and might be a major reason for the high cisplatin sensitivity of testis tumours. Targeted inhibition of XPA could sensitise other types of cells and tumours to cisplatin and broaden the usefulness of this chemotherapeutic agent.     

An interaction between the DNA repair factor XPA and replication protein A appears essential for nucleotide excision repair.

Replication protein A (RPA) is required for simian virus 40-directed DNA replication in vitro and for nucleotide excision repair (NER). Here we report that RPA and the human repair protein XPA specifically interact both in vitro and in vivo. Mapping of the RPA-interactive domains in XPA revealed that both of the largest subunits of RPA, RPA-70 and RPA-34, interact with XPA at distinct sites. A domain involved in mediating the interaction with RPA-70 was located between XPA residues 153 and 176. Deletion of highly conserved motifs within this region identified two mutants that were deficient in binding RPA in vitro and highly defective in NER both in vitro and in vivo. A second domain mediating the interaction with RPA-34 was identified within the first 58 residues in XPA. Deletion of this region, however, only moderately affects the complementing activity of XPA in vivo. Finally, the XPA-RPA complex is shown to have a greater affinity for damaged DNA than XPA alone. Taken together, these results indicate that the interaction between XPA and RPA is required for NER but that only the interaction with RPA-70 is essential.     

NMR study on the interaction between RPA and DNA decamer containing cis-syn cyclobutane pyrimidine dimer in the presence of XPA: implication for damage verification and strand-specific dual incision in nucleotide excision repair

In mammalian cells, nucleotide excision repair (NER) is the major pathway for the removal of bulky DNA adducts. Many of the key NER proteins are members of the XP family (XPA, XPB, etc.), which was named on the basis of its association with the disorder xerodoma pigmentosum. Human replication protein A (RPA), the ubiquitous single-stranded DNA-binding protein, is another of the essential proteins for NER. RPA stimulates the interaction of XPA with damaged DNA by forming an RPA–XPA complex on damaged DNA sites. Binding of RPA to the undamaged DNA strand is most important during NER, because XPA, which directs the excision nucleases XPG and XPF, must bind to the damaged strand. In this study, nuclear magnetic resonance (NMR) spectroscopy was used to assess the binding of the tandem high affinity DNA-binding domains, RPA-AB, and of the isolated domain RPA-A, to normal DNA and damaged DNA containing the cyclobutane pyrimidine dimer (CPD) lesion. Both RPA-A and RPA-AB were found to bind non- specifically to both strands of normal and CPD- containing DNA duplexes. There were no differences observed when binding to normal DNA duplex was examined in the presence of the minimal DNA-binding domain of XPA (XPA-MBD). However, there is a drastic difference for CPD-damaged DNA duplex as both RPA-A and RPA-AB bind specifically to the undamaged strand. The strand-specific binding of RPA and XPA to the damaged duplex DNA shows that RPA and XPA play crucial roles in damage verification and guiding cleavage of damaged DNA during NER.     

Physical and functional interaction between DDB and XPA in nucleotide excision repair

Damaged DNA-binding protein (DDB), consisting of DDB1 and DDB2 subunits recognizes a wide spectrum of DNA lesions. DDB is dispensable for in vitro nucleotide excision repair (NER) reaction, but stimulates this reaction especially for cyclobutane pyrimidine dimer (CPD). Here we show that DDB directly interacts with XPA, one of core NER factors, mainly through DDB2 subunit and the amino-acid residues between 185 and 226 in XPA are important for the interaction. Interestingly, the point mutation causing the substitution from Arg-207 to Gly, which was previously identified in a XP-A revertant cell-line XP129, diminished the interaction with DDB in vitro and in vivo. In a defined system containing R207G mutant XPA and other core NER factors, DDB failed to stimulate the excision of CPD, although the mutant XPA was competent for the basal NER reaction. Moreover, in vivo experiments revealed that the mutant XPA is recruited to damaged DNA sites with much less efficiency compared with wild-type XPA and fails to support the enhancement of CPD repair by ectopic expression of DDB2 in SV40-transformed human cells. These results suggest that the physical interaction between DDB and XPA plays an important role in the DDB-mediated NER reaction.     

Nucleotide Excision Repair Is Associated with the Replisome and Its Efficiency Depends on a Direct Interaction between XPA and PCNA

Proliferating cell nuclear antigen (PCNA) is an essential protein for DNA replication, DNA repair, cell cycle regulation, chromatin remodeling, and epigenetics. Many proteins interact with PCNA through the PCNA interacting peptide (PIP)-box or the newly identified AlkB homolog 2 PCNA interacting motif (APIM). The xeroderma pigmentosum group A (XPA) protein, with a central but somewhat elusive role in nucleotide excision repair (NER), contains the APIM sequence suggesting an interaction with PCNA. With an in vivo based approach, using modern techniques in live human cells, we show that APIM in XPA is a functional PCNA interacting motif and that efficient NER of UV lesions is dependent on an intact APIM sequence in XPA. We show that XPA^−/− cells complemented with XPA containing a mutated APIM sequence have increased UV sensitivity, reduced repair of cyclobutane pyrimidine dimers and (6–4) photoproducts, and are consequently more arrested in S phase as compared to XPA^−/− cells complemented with wild type XPA. Notably, XPA colocalizes with PCNA in replication foci and is loaded on newly synthesized DNA in undamaged cells. In addition, the TFIIH subunit XPD, as well as XPF are loaded on DNA together with XPA, and XPC and XPG colocalize with PCNA in replication foci. Altogether, our results suggest a presence of the NER complex in the vicinity of the replisome and a novel role of NER in post-replicative repair.     

Damaged DNA-binding protein DDB stimulates the excision of cyclobutane pyrimidine dimers in vitro in concert with XPA and replication protein A

Human cells contain a protein that binds to UV-irradiated DNA with high affinity. This protein, damaged DNA-binding protein (DDB), is a heterodimer of two polypeptides, p127 and p48. Recent in vivo studies suggested that DDB is involved in global genome repair of cyclobutane pyrimidine dimers (CPDs), but the mechanism remains unclear. Here, we show that in vitro DDB directly stimulates the excision of CPDs but not (6-4)photoproducts. The excision activity of cell-free extracts from Chinese hamster AA8 cell line that lacks DDB activity was increased 3-4-fold by recombinant DDB heterodimer but not p127 subunit alone. Moreover, the addition of XPA or XPA + replication protein A (RPA), which themselves enhanced excision, also enhanced the excision in the presence of DDB. DDB was found to elevate the binding of XPA to damaged DNA and to make a complex with damaged DNA and XPA or XPA + RPA as judged by both electrophoretic mobility shift assays and DNase I protection assays. These results suggest that DDB assists in the recognition of CPDs by core NER factors, possibly through the efficient recruitment of XPA or XPA.RPA, and thus stimulates the excision reaction of CPDs.     

Repair of mitomycin C cross-linked DNA in mammalian cells measured by a host cell reactivation assay

DNA repair capacity in a cell could be detected by a host-cell reactivation assay (HCR). Since relation between DNA repair and genetic susceptibility to cancer remains unclear, it is necessary to identify DNA repair defects in human cancer cells. To assess DNA repair for breast cancer susceptibility, we developed a modified HCR assay using a plasmid containing a firefly luciferase gene damaged by mitomycin C (MMC), which forms interstrand cross-link (ICL) adducts. In particular, interstrand cross-link is thought to induce strand breaks being repaired by homologous recombination. The MMC-ICLs were verified by electrophoresis. Damaged plasmids were transfected into apparently normal human lymphocytes and NER-deficient XP cell lines and the DNA repair capacity of the cells were measured by quantifying the activity of the firefly luciferase. MMC lesion was repaired as much as UV adducts in normal lymphocytes and the XPC cells. However, the XPA cells have a lower repair capacity for MMC lesion than the XPC cell, indicating that the XPA protein may be involved in initial damage recognition of MMC-ICL adducts. Since several repair pathways including NER and recombination participate in MMC-ICL removal, this host cell reactivation assay using MMC-ICLs can be used in exploring DNA repair defects in human cancer cells.     

DNA damage recognition during nucleotide excision repair in mammalian cells

For the bulk of mammalian DNA, the core protein factors needed for damage recognition and incision during nucleotide excision repair (NER) are the XPA protein, the heterotrimeric RPA protein, the 6 to 9-subunit TFIIH, the XPC-hHR23B complex, the XPG nuclease, and the ERCC1-XPF nuclease. With varying efficiencies, NER can repair a very wide range of DNA adducts, from bulky helical distortions to subtle modifications on sugar residues. Several of the NER factors have an affinity for damaged DNA. The strongest binding factor appears to be XPC-hHR23B but preferential binding to damage is also a property of XPA, RPA, and components of TFIIH. It appears that in order to be repaired by NER, an adduct in DNA must have two features: it must create a helical distortion, and there must be a change in DNA chemistry. Initial recognition of the distortion is the most likely function for XPC-hHR23B and perhaps XPA and RPA, whereas TFIIH is well-suited to locate the damaged DNA strand by locating altered DNA chemistry that blocks translocation of the XPB and XPD components.     

Oxidative damage-induced PCNA complex formation is efficient in xeroderma pigmentosum group A but reduced in Cockayne syndrome group B cells.

Proliferating cell nuclear antigen (PCNA), a processivity factor for DNA polymerases delta and epsilon, is essential for both DNA replication and repair. PCNA is required in the resynthesis step of nucleotide excision repair (NER). After UV irradiation, PCNA translocates into an insoluble protein complex, most likely associated with the nuclear matrix. It has not previously been investigated in vivo whether PCNA complex formation also takes place after oxidative stress. In this study, we have examined the involvement of PCNA in the repair of oxidative DNA damage. PCNA complex formation was studied in normal human cells after treatment with hydrogen peroxide, which generates a variety of oxidative DNA lesions. PCNA was detected by two assays, immunofluorescence and western blot analyses. We observed that PCNA redistributes from a soluble to a DNA-bound form during the repair of oxidative DNA damage. PCNA complex formation was analyzed in two human natural mutant cell lines defective in DNA repair: xeroderma pigmentosum group A (XP-A) and Cockayne syndrome group B (CS-B). XP-A cells are defective in overall genome NER while CS-B cells are defective only in the preferential repair of active genes. Immunofluorescent detection of PCNA complex formation was similar in normal and XP-A cells, but was reduced in CS-B cells. Consistent with this observation, western blot analysis in CS-B cells showed a reduction in the ratio of PCNA relocated as compared to normal and XP-A cells. The efficient PCNA complex formation observed in XP-A cells following oxidative damage suggests that formation of PCNA-dependent repair foci may not require the XPA gene product. The reduced PCNA complex formation observed in CS-B cells suggests that these cells are defective in the processing of oxidative DNA damage.     

The oncogenic phosphatase WIP1 negatively regulates nucleotide excision repair

Nucleotide excision repair (NER) is the only mechanism in humans to repair UV-induced DNA lesions such as pyrimidine (6-4) pyrimidone photoproducts and cyclobutane pyrimidine dimers (CPDs). In response to UV damage, the ataxia telangiectasia mutated and Rad3-related (ATR) kinase phosphorylates and activates several downstream effector proteins, such as p53 and XPA, to arrest cell cycle progression, stimulate DNA repair, or initiate apoptosis. However, following the completion of DNA repair, there must be active mechanisms that restore the cell to a prestressed homeostatic state. An important part of this recovery must include a process to reduce p53 and NER activity as well as to remove repair protein complexes from the DNA damage sites. Since activation of the damage response occurs in part through phosphorylation, phosphatases are obvious candidates as homeostatic regulators of the DNA damage and repair responses. Therefore, we investigated whether the serine/threonine wild-type p53-induced phosphatase 1 (WIP1/PPM1D) might regulate NER. WIP1 overexpression inhibits the kinetics of NER and CPD repair, whereas WIP1 depletion enhances NER kinetics and CPD repair. This NER suppression is dependent on WIP1 phosphatase activity, as phosphatase-dead WIP1 mutants failed to inhibit NER. Moreover, WIP1 suppresses the kinetics of UV-induced damage repair largely through effects on NER, as XPD-deficient cells are not further suppressed in repairing UV damage by overexpressed WIP1. Wip1 null mice quickly repair their CPD and undergo less UV-induced apoptosis than their wild-type counterparts. In vitro phosphatase assays identify XPA and XPC as two potential WIP1 targets in the NER pathway. Thus WIP1 may suppress NER kinetics by dephosphorylating and inactivating XPA and XPC and other NER proteins and regulators after UV-induced DNA damage is repaired.     

Nucleotide excision repair by mutant xeroderma pigmentosum group A (XPA) proteins with deficiency in interaction with RPA

The xeroderma pigmentosum group A protein (XPA) is a core component of nucleotide excision repair (NER). To coordinate early stage NER, XPA interacts with various proteins, including replication protein A (RPA), ERCC1, DDB2, and TFIIH, in addition to UV-damaged or chemical carcinogen-damaged DNA. In this study, we investigated the effects of mutations in the RPA binding regions of XPA on XPA function in NER. XPA binds through an N-terminal region to the middle subunit (RPA32) of the RPA heterotrimer and through a central region that overlaps with its damaged DNA binding region to the RPA70 subunit. In cell-free NER assays, an N-terminal deletion mutant of XPA showed loss of binding to RPA32 and reduced DNA repair activity, but it could still bind to UV-damaged DNA and RPA. In contrast, amino acid substitutions in the central region reduced incisions at the damaged site in the cell-free NER assay, and four of these mutants (K141A, T142A, K167A, and K179A) showed reduced binding to RPA70 but normal binding to damaged DNA. Furthermore, mutants that had one of the four aforementioned substitutions and an N-terminal deletion exhibited lower DNA incision activity and binding to RPA than XPA with only one of these substitutions or the deletion. Taken together, these results indicate that XPA interaction with both RPA32 and RPA70 is indispensable for NER reactions.     

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.     

Host cell reactivation by excision repair is error-free in human cells

Do host cell repair processes affect the mutagenesis of UV-irradiated virus in human cells? The answer was obtained by investigating the mutagenesis of UV-irradiated herpes simplex virus after the irradiated virus was grown in human cells that possess normal repair capacity (normal) or lack excision repair (XPA) or post-replication repair (XP var). Evidence is presented which indicate that XPA cells express no host cell reactivation, while XP var cells express the normal level. Viral mutagenesis was measured as the fraction of the progeny of the surviving virus capable of plaque formation in the presence of iododeoxycytidine. In the normal and XPA cells mutagenesis of the irradiated virus increased linearly with UV exposure. The UV exposure needed to yield a given mutagenesis level for virus grown in XPA cells was much lower than that for virus grown in normal cells. However, when the mutation frequencies were compared at similar virus survival levels, the data from virus grown in normal cells and in XPA cells were indistinguishable. Mutagenesis in XP var cells increased as dose squared and was similar in magnitude to that in normal cells. Thus the excision repair of normal cells which provided host cell reactivation by removing lethal UV damage also removed mutagenic lesions from the virus with the same efficiency, while the repair deficiency of XP var cells had a minor role in host cell reactivation and in mutagenesis. This demonstrates that in human cells host cell reactivation by excision repair is primarily an error-free process.