Strong functional interactions of TFIIH with XPC and XPG in human DNA nucleotide excision repair, without a preassembled repairosome

In mammalian cells, the core factors involved in the damage recognition and incision steps of DNA nucleotide excision repair are XPA, TFIIH complex, XPC-HR23B, replication protein A (RPA), XPG, and ERCC1-XPF. Many interactions between these components have been detected, using different physical methods, in human cells and for the homologous factors in Saccharomyces cerevisiae. Several human nucleotide excision repair (NER) complexes, including a high-molecular-mass repairosome complex, have been proposed. However, there have been no measurements of activity of any mammalian NER protein complex isolated under native conditions. In order to assess relative strengths of interactions between NER factors, we captured TFIIH from cell extracts with an anti-cdk7 antibody, retaining TFIIH in active form attached to magnetic beads. Coimmunoprecipitation of other NER proteins was then monitored functionally in a reconstituted repair system with purified proteins. We found that all detectable TFIIH in gently prepared human cell extracts was present in the intact nine-subunit form. There was no evidence for a repair complex that contained all of the NER components. At low ionic strength TFIIH could associate with functional amounts of each NER factor except RPA. At physiological ionic strength, TFIIH associated with significant amounts of XPC-HR23B and XPG but not other repair factors. The strongest interaction was between TFIIH and XPC-HR23B, indicating a coupled role of these proteins in early steps of repair. A panel of antibodies was used to estimate that there are on the order of 10(5) molecules of each core NER factor per HeLa cell.     

Diversity of the damage recognition step in the global genomic nucleotide excision repair in vitro

The XPC-HR23B complex, a mammalian factor specifically involved in global genomic nucleotide excision repair (NER) has been shown to bind various forms of damaged DNA and initiate DNA repair in cell-free reactions. To characterize the binding specificity of this factor in more detail, a method based on immunoprecipitation was developed to assess the relative affinity of XPC-HR23B for defined lesions on DNA. Here we show that XPC-HR23B preferentially binds to UV-induced (6-4) photoproducts (6-4PPs) as well as to cholesterol, but not to the cyclobutane pyrimidine dimer (CPD), 8-oxoguanine (8-oxo-G), O6-methylguanine (O6-Me-G), or a single mismatch. Human whole cell extracts could efficiently excise 6-4PPs and cholesterol in an XPC-HR23B-dependent manner, but not 8-oxo-G, O6-Me-G or mismatches. Thus, there was good correlation between the binding specificity of XPC-HR23B for certain types of lesion and the ability of human cell extracts to excise these lesions, supporting the model that XPC-HR23B initiates global genomic NER. Although, XPC-HR23B does not preferentially bind to CPDs, the excision of CPDs in human whole cell extracts was found to be absolutely dependent on XPC-HR23B, in agreement with the in vivo observation that CPDs are not removed from the global genome in XP-C mutant cells. These results suggest that, in addition to the excision repair pathway initiated by XPC-HR23B, there exists another sub-pathway for the global genomic NER that still requires XPC-HR23B but is not initiated by XPC-HR23B. Possible mechanisms will be discussed.     

A molecular mechanism for DNA damage recognition by the xeroderma pigmentosum group C protein complex

The XPC-HR23B complex is involved in DNA damage recognition and the initiation of global genomic nucleotide excision repair (GG-NER). Our previous studies demonstrate that XPC-HR23B recognizes and binds DNA containing a helix distortion, regardless of the presence or absence of damaged bases. Here, we describe an extended analysis of the DNA binding specificity of XPC-HR23B using various defined DNA substrates. Although XPC-HR23B showed significantly higher affinity for single-stranded DNA than double-stranded DNA, specific secondary structures of DNA, involving a single- and double-strand junction, were strongly preferred by the complex. This indicates that the presence of bases, which cannot form normal Watson-Crick base pairs in double-stranded DNA, is a critical factor in determining the specificity of XPC-HR23B binding. A DNase I footprint analysis, using a looped DNA substrate, revealed that a single XPC-HR23B complex protected a distorted site in an asymmetrical manner, consistent with the preferred secondary structure. The specific binding of XPC-HR23B is undoubtedly an important molecular process, based on which NER machinery detects a wide variety of lesions that vary in terms of chemical structure during DNA repair.     

Mathematical modeling of nucleotide excision repair reveals efficiency of sequential assembly strategies

Nucleotide excision repair (NER) requires the concerted action of many different proteins that assemble at sites of damaged DNA in a sequential fashion. We have constructed a mathematical model delineating hallmarks and general characteristics for NER. We measured the assembly kinetics of the putative damage-recognition factor XPC-HR23B at sites of DNA damage in the nuclei of living cells. These and other in vivo kinetic data allowed us to scrutinize the dynamic behavior of the nucleotide excision repair process in detail. A sequential assembly mechanism appears remarkably advantageous in terms of repair efficiency. Alternative mechanisms for repairosome formation, including random assembly and preassembly, can readily become kinetically unfavorable. Based on the model, new experiments can be defined to gain further insight into this complex process and to critically test model predictions. Our work provides a kinetic framework for NER and rationalizes why many multiprotein processes within the cell nucleus show sequential assembly strategy.     

Nucleotide excision repair of 5-formyluracil in vitro is enhanced by the presence of mismatched bases

5-Formyluracil (fU) is a major thymine lesion produced by reactive oxygen radicals and photosensitized oxidation. Although this residue is a potentially mutagenic lesion and is removed by several base excision repair enzymes, it is unknown whether fU is the substrate of nucleotide excision repair (NER). Here, we analyzed the binding specificity of XPC-HR23B, which initiates NER, and cell-free NER activity on fU opposite four different bases. The result of the gel mobility shift assay showed that XPC-HR23B binds the fU-containing substrates in the following order: fU:C > fU:T > fU:G > fU:A. Furthermore, in the presence of XPC-HR23B, the dual incision activity was the same as the order of the binding affinity of XPC-HR23B to fU. Therefore, it is concluded that even fU, regarded as a shape mimic of thymine, can be recognized as a substrate of NER incision, and the efficiency depends on instability of the base pair.     

Interaction of nucleotide excision repair factors XPC-HR23B, XPA, and RPA with damaged DNA

The interaction of nucleotide excision repair factors--xeroderma pigmentosum complementation group C protein in complex with human homolog of yeast Rad23 protein (XPC-HR23B), replication protein A (RPA), and xeroderma pigmentosum complementation group A protein (XPA)--with 48-mer DNA duplexes imitating damaged DNA structures was investigated. All studied proteins demonstrated low specificity in binding to damaged DNA compared with undamaged DNA duplexes. RPA stimulates formation of XPC-HR23B complex with DNA, and when XPA and XPC-HR23B are simultaneously present in the reaction mixture a synergistic effect in binding of these proteins to DNA is observed. RPA crosslinks to DNA bearing photoreactive 5I-dUMP residue on one strand and fluorescein-substituted dUMP analog as a lesion in the opposite strand of DNA duplex and also stimulates cross-linking with XPC-HR23B. Therefore, RPA might be one of the main regulation factors at various stages of nucleotide excision repair. The data are in agreement with the cooperative binding model of nucleotide excision repair factors participating in pre-incision complex formation with DNA duplexes bearing damages.     

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.     

Crosslinking of nucleotide excision repair proteins with DNA containing photoreactive damages

Photoreactive DNA duplexes mimicking substrates of nucleotide excision repair (NER) system were used to analyze the interaction of XPC-HR23B, RPA, and XPA with damaged DNA. Photoreactive groups in one strand of DNA duplex (arylazido-dCMP or 4-thio-dUMP) were combined with anthracenyl-dCMP residue at the opposite strand to analyze contacts of NER factors with damaged and undamaged strands. Crosslinking of XPC-HR23B complex with photoreactive 48-mers results in modification of XPC subunit. XPC-HR23B did not crosslink with DNA duplex bearing bulky residues in both strands while this modification does not prevent interaction of DNA with XPA. The data on crosslinking of XPA and RPA with photoreactive DNA duplexes containing bulky group in one of the strands are in favor of XPA preference to interact with the damaged strand and RPA preference for the undamaged strand. The results support the understanding and set the stage for dynamically oriented experiments of how the pre-incision complex is formed in the early stage of NER.     

Stable binding of human XPC complex to irradiated DNA confers strong discrimination for damaged sites

Nucleotide excision repair (NER) of DNA damage requires an efficient means of discrimination between damaged and non-damaged DNA. Cells from humans with xeroderma pigmentosum group C do not perform NER in the bulk of the genome and are corrected by XPC protein, which forms a complex with hHR23B protein. This complex preferentially binds to some types of damaged DNA, but the extent of discrimination in comparison to other NER proteins has not been clear. Recombinant XPC, hHR23B, and XPC-hHR23B complex were purified. In a reconstituted repair system, hHR23B stimulated XPC activity tenfold. Electrophoretic mobility-shift competition measurements revealed a 400-fold preference for binding of XPC-hHR23B to UV damaged over non-damaged DNA. This damage preference is much greater than displayed by the XPA protein. The discrimination power is similar to that determined here in parallel for the XP-E factor UV-DDB, despite the considerably greater molar affinity of UV-DDB for DNA. Binding of XPC-hHR23B to UV damaged DNA was very fast. Damaged DNA-XPC-hHR23B complexes were stable, with half of the complexes remaining four hours after challenge with excess UV-damaged DNA at 30 degrees C. XPC-hHR23B had a higher level of affinity for (6-4) photoproducts than cyclobutane pyrimidine dimers, and some affinity for DNA treated with cisplatin and alkylating agents. XPC-hHR23B could bind to single-stranded M13 DNA, but only poorly to single-stranded homopolymers. The strong preference of XPC complex for structures in damaged duplex DNA indicates its importance as a primary damage recognition factor in non-transcribed DNA during human NER.     

Reconstitution of damage DNA excision reaction from SV40 minichromosomes with purified nucleotide excision repair proteins

We previously constructed the cell-free nucleotide excision repair (NER) assay system with UV-irradiated SV40 minichromosomes to analyze the mechanism of NER reaction on chromatin DNA. Here we investigate the factor that acts especially on nucleosomal DNA during the damage excision reaction, and reconstitute the damage excision reaction on SV40 minichromosomes. NER-proficient HeLa whole cell extracts were fractionated, and the amounts of known NER factors involved in the column fractions were determined by immunoblot analyses. The column fractions were quantitatively and systematically replaced by highly purified NER factors. Finally, damage DNA excision reaction on SV40 minichromosomes was reconstituted with six highly purified NER factors, XPA, XPC-HR23B, XPF-ERCC1, XPG, RPA and TFIIH, as those essential for the reaction with naked DNA. Further analysis showed that the damages on chromosomal DNA were excised as the same efficiency as those on naked DNA for short incubation. At longer incubation time, however, the damage excision efficiency on nucleosomal DNA was decreased whereas naked DNA was still vigorously repaired. These observations suggest that although the six purified NER factors have a potential to eliminate the damage DNA from SV40 minichromosomes, the chromatin structure may still have some repressive effects on NER.     

Photoactivated DNA analogs of substrates of the nucleotide excision repair system and their interaction with proteins of NER-competent HeLa cell extract

Photoactivated DNA analogs of nucleotide excision repair (NER) substrates have been created that are 48-mer duplexes containing in internal positions pyrimidine nucleotides with bulky substituents imitating lesions. Fluorochloroazidopyridyl, anthracenyl, and pyrenyl groups introduced using spacer fragments at 4N and 5C positions of dCMP and dUMP were used as model damages. The gel retardation and photo-induced affinity modification techniques were used to study the interaction of modified DNA duplexes with proteins in HeLa cell extracts containing the main components of NER protein complexes. It is shown that the extract proteins selectively bind and form covalent adducts with the model DNA. The efficiency and selectivity of protein modification depend on the structure of used DNA duplex. Apparent molecular masses of extract proteins, undergoing modification, were estimated. Mutual influence of simultaneous presence of extract proteins and recombinant NER protein factors XPC-HR23B, XPA, and RPA on interaction with the model DNA was analyzed. The extract proteins and RPA competed for interaction with photoactive DNA, mutually decreasing the yield of modification products. In this case the presence of extract proteins at particular concentrations tripled the increase in yield of covalent adducts formed by XPC. It is supposed that the XPC subunit interaction with DNA is stimulated by endogenous HR23B present in the extract. Most likely, the mutual effect of XPA and extract proteins stimulating formation of covalent adducts with model DNA is due to the interaction of XPA with endogenous RPA of the extract. A technique based on the use of specific antibodies revealed that RPA present in the extract is a modification target for photoactive DNA imitating NER substrates.     

Xeroderma pigmentosum group C protein interacts physically and functionally with thymine DNA glycosylase

The XPC-HR23B complex recognizes various helix-distorting lesions in DNA and initiates global genome nucleotide excision repair. Here we describe a novel functional interaction between XPC-HR23B and thymine DNA glycosylase (TDG), which initiates base excision repair (BER) of G/T mismatches generated by spontaneous deamination of 5-methylcytosine. XPC-HR23B stimulated TDG activity by promoting the release of TDG from abasic sites that result from the excision of mismatched T bases. In the presence of AP endonuclease (APE), XPC-HR23B had an additive effect on the enzymatic turnover of TDG without significantly inhibiting the subsequent action of APE. Our observations suggest that XPC-HR23B may participate in BER of G/T mismatches, thereby contributing to the suppression of spontaneous mutations that may be one of the contributory factors for the promotion of carcinogenesis in xeroderma pigmentosum genetic complementation group C patients.     

Roles of Rad23 protein in yeast nucleotide excision repair

Nucleotide excision repair (NER) removes many different types of DNA lesions. Most NER proteins are indispensable for repair. In contrast, the yeast Rad23 represents a class of accessory NER proteins, without which NER activity is reduced but not eliminated. In mammals, the complex of HR23B (Rad23 homolog) and XPC (yeast Rad4 homolog) has been suggested to function in the damage recognition step of NER. However, the precise function of Rad23 or HR23B in NER remains unknown. Recently, it was suggested that the primary function of RAD23 protein in NER is its stabilization of XPC protein. Here, we tested the significance of Rad23-mediated Rad4 stabilization in NER, and analyzed the repair and biochemical activities of purified yeast Rad23 protein. Cellular Rad4 was indeed stabilized by Rad23 in the absence of DNA damage. Persistent overexpression of Rad4 in rad23 mutant cells, however, largely failed to complement the ultraviolet sensitivity of the mutant. Consistently, deficient NER in rad23 mutant cell extracts could not be complemented by purified Rad4 protein in vitro. In contrast, partial complementation was observed with purified Rad23 protein. Specific complementation to the level of wild-type repair was achieved by adding purified Rad23 together with small amounts of Rad4 protein to rad23 mutant cell extracts. Purified Rad23 protein was unable to bind to DNA, but stimulated the binding activity of purified Rad4 protein to N-acetyl-2-aminofluorene-damaged DNA. These results support two roles of Rad23 protein in NER: (i) its direct participation in the repair biochemistry, possibly due to its stimulatory activity on Rad4-mediated damage binding/recognition; and (ii) its stabilization of cellular Rad4 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.     

The XPC-HR23B complex displays high affinity and specificity for damaged DNA in a true-equilibrium fluorescence assay

The XPC-HR23B complex is a prime candidate for the initial damage recognition step during global genome nucleotide excision repair. A specific interaction between the XPC-HR23B complex and various types of damaged DNA substrates has been demonstrated in recent work by electrophoretic mobility shift assays or immunoprecipitation. Although these studies allowed the estimation of relative binding affinities for the different types of lesions, the presence of large amounts of competitor DNA or the need for glutaraldehyde fixation prevented the quantification of equilibrium constants. We have performed a quantitative study on the binding of XPC to damaged DNA using fluorescence anisotropy measurements. The XPC-HR23B complex binds with high affinity (K(D) approximately 1-3 nM) to fluorescent 36 bp DNA fragments containing a single cisplatin 1,3-intrastrand adduct or a six-nucleotide mispaired region. From stoichiometric titration experiments, it is concluded that approximately 70% of the XPC-HR23B preparation is active in DNA binding. Binding experiments employing fluorescent probes with a single defined photoproduct reveal a 30-fold preference of XPC for 6,4-photoproducts as compared to a cyclobutane dimer. Competition experiments with undamaged and damaged plasmid DNA indicate that the XPC-HR23B complex discriminates between damaged and undamaged sites with high specificity. The specificity factor is between 100 and 3000, depending on the number of nonspecific sites considered in the calculations. Upon addition of XPA to the XPC binding reaction mixtures, it was not possible to detect cooperative ternary complex formation on the platinated 36 bp probe.