Mutagenicity associated with O6-methylguanine-DNA damage and mechanism of nucleotide flipping by AGT during repair

Methylated guanine damage at O6 position (i.e. O6MG) is dangerous due to its mutagenic and carcinogenic character that often gives rise to G:C-A:T mutation. However, the reason for this mutagenicity is not known precisely and has been a matter of controversy. Further, although it is known that O6-alkylguanine-DNA alkyltransferase (AGT) repairs O6MG paired with cytosine in DNA, the complete mechanism of target recognition and repair is not known completely. All these aspects of DNA damage and repair have been addressed here by employing high level density functional theory in gas phase and aqueous medium. It is found that the actual cause of O6MG mediated mutation may arise due to the fact that DNA polymerases incorporate thymine opposite to O6MG, misreading the resulting O6MG:T complex as an A:T base pair due to their analogous binding energies and structural alignments. It is further revealed that AGT mediated nucleotide flipping occurs in two successive steps. The intercalation of the finger residue Arg128 into the DNA double helix and its interaction with the O6MG:C base pair followed by rotation of the O6MG nucleotide are found to be crucial for the damage recognition and nucleotide flipping.     

Base flipping in nucleotide excision repair

UvrB, the ultimate damage-binding protein in bacterial nucleotide excision repair is capable of binding a vast array of structurally unrelated lesions. A beta-hairpin structure in the protein plays an important role in damage-specific binding. In this paper we have monitored DNA conformational alterations in the UvrB-DNA complex, using the fluorescent adenine analogue 2-aminopurine. We show that binding of UvrB to a DNA fragment with cholesterol damage moves the base adjacent to the lesion at the 3' side into an extrahelical position. This extrahelical base is not accessible for acrylamide quenching, suggesting that it inserts into a pocket of the UvrB protein. Also the base opposite this flipped base is extruded from the DNA helix. The degree of solvent exposure of both residues varies with the type of cofactor (ADP/ATP) bound by UvrB. Fluorescence of the base adjacent to the damage is higher when UvrB is in the ADP-bound configuration, but concomitantly this UvrB-DNA complex is less stable. In the ATP-bound form the UvrB-DNA complex is very stable and in this configuration the base in the non-damaged strand is more exposed. Hairpin residue Tyr-95 is specifically involved in base flipping in the non-damaged strand. We present evidence that this conformational change in the non-damaged strand is important for 3' incision by UvrC.     

6‐phenylpyrrolocytosine as a fluorescent probe to examine nucleotide flipping catalyzed by a DNA repair protein

Cellular exposure to tobacco‐specific nitrosamines causes formation of promutagenic O⁶‐[4‐oxo‐4‐(3‐pyridyl)but‐1‐yl]guanine (O⁶‐POB‐G) and O⁶‐methylguanine (O⁶‐Me‐G) adducts in DNA. These adducts can be directly repaired by O⁶‐alkylguanine‐DNA alkyltransferase (AGT). Repair begins by flipping the damaged base out of the DNA helix. AGT binding and base‐flipping have been previously studied using pyrrolocytosine as a fluorescent probe paired to the O⁶‐alkylguanine lesion, but low fluorescence yield limited the resolution of steps in the repair process. Here, we utilize the highly fluorescent 6‐phenylpyrrolo‐2′‐deoxycytidine (6‐phenylpyrrolo‐C) to investigate AGT‐DNA interactions. Synthetic oligodeoxynucleotide duplexes containing O⁶‐POB‐G and O⁶‐Me‐G adducts were placed within the CpG sites of codons 158, 245, and 248 of the p53 tumor suppressor gene and base‐paired to 6‐phenylpyrrolo‐C in the opposite strand. Neighboring cytosine was either unmethylated or methylated. Stopped‐flow fluorescence measurements were performed by mixing the DNA duplexes with C145A or R128G AGT variants. We observe a rapid, two‐step, nearly irreversible binding of AGT to DNA followed by two slower steps, one of which is base‐flipping. Placing 5‐methylcytosine immediately 5′ to the alkylated guanosine causes a reduction in rate constant of nucleotide flipping. O⁶‐POB‐G at codon 158 decreased the base flipping rate constant by 3.5‐fold compared with O⁶‐Me‐G at the same position. A similar effect was not observed at other codons.     

DNA binding, nucleotide flipping, and the helix-turn-helix motif in base repair by O6-alkylguanine-DNA alkyltransferase and its implications for cancer chemotherapy

O(6)-Alkylguanine-DNA alkyltransferase (AGT) is a crucial target both for the prevention of cancer and for chemotherapy, since it repairs mutagenic lesions in DNA, and it limits the effectiveness of alkylating chemotherapies. AGT catalyzes the unique, single-step, direct damage reversal repair of O(6)-alkylguanines by selectively transferring the O(6)-alkyl adduct to an internal cysteine residue. Recent crystal structures of human AGT alone and in complex with substrate DNA reveal a two-domain alpha/beta fold and a bound zinc ion. AGT uses its helix-turn-helix motif to bind substrate DNA via the minor groove. The alkylated guanine is then flipped out from the base stack into the AGT active site for repair by covalent transfer of the alkyl adduct to Cys145. An asparagine hinge (Asn137) couples the helix-turn-helix DNA binding and active site motifs. An arginine finger (Arg128) stabilizes the extrahelical DNA conformation. With this newly improved structural understanding of AGT and its interactions with biologically relevant substrates, we can now begin to unravel the role it plays in preserving genetic integrity and discover how it promotes resistance to anticancer therapies.     

Mechanistic link between DNA methyltransferases and DNA repair enzymes by base flipping

Rotation of a DNA nucleotide out of the double helix and into a protein binding pocket (“base flipping”) was first observed in the structure of a DNA methyltransferase. There is now evidence that a variety of proteins, particularly DNA repair enzymes, use base flipping in their interactions with DNA. Though the mechanisms for base movement into extrahelical positions are still unclear, the focus of this review is how base recognition is modulated by the stringency of binding to the extrahelical base(s) or sugar moiety. © 1997 John Wiley & Sons, Inc. Biopoly 44: 139–151, 1997     

Uncoupling of nucleotide flipping and DNA bending by the t4 pyrimidine dimer DNA glycosylase

Bacteriophage T4 pyrimidine dimer glycosylase (T4-Pdg) is a base excision repair protein that incises DNA at cyclobutane pyrimidine dimers that are formed as a consequence of exposure to ultraviolet light. Cocrystallization of T4-Pdg with substrate DNA has shown that the adenosine opposite the 5'-thymine of a thymine-thymine (TT) dimer is flipped into an extrahelical conformation and that the DNA backbone is kinked 60 degrees in the enzyme-substrate (ES) complex. To examine the kinetic details of the precatalytic events in the T4-Pdg reaction mechanism, investigations were designed to separately assess nucleotide flipping and DNA bending. The fluorescent adenine base analogue, 2-aminopurine (2-AP), placed opposite an abasic site analogue, tetrahydrofuran, exhibited a 2.8-fold increase in emission intensity when flipped in the ES complex. Using the 2-AP fluorescence signal for nucleotide flipping, kon and koff pre-steady-state kinetic measurements were determined. DNA bending was assessed by fluorescence resonance energy transfer using fluorescent donor-acceptor pairs located at the 5'-ends of oligonucleotides in duplex DNA. The fluorescence intensity of the donor fluorophore was quenched by 15% in the ES complex as a result of an increased efficiency of energy transfer between the labeled ends of the DNA in the bent conformation. Kinetic analyses of the bending signal revealed an off rate that was 2.5-fold faster than the off rate for nucleotide flipping. These results demonstrate that the nucleotide flipping step can be uncoupled from the bending of DNA in the formation of an ES complex.     

Reversible protein phosphorylation modulates nucleotide excision repair of damaged DNA by human cell extracts.

Nucleotide excision repair of DNA in mammalian cells uses more than 20 polypeptides to remove DNA lesions caused by UV light and other mutagens. To investigate whether reversible protein phosphorylation can significantly modulate this repair mechanism we studied the effect of specific inhibitors of Ser/Thr protein phosphatases. The ability of HeLa cell extracts to carry out nucleotide excision repair in vitro was highly sensitive to three toxins (okadaic acid, microcystin-LR and tautomycin), which block PP1- and PP2A-type phosphatases. Repair was more sensitive to okadaic acid than to tautomycin, suggesting the involvement of a PP2A-type enzyme, and was insensitive to inhibitor-2, which exclusively inhibits PP1-type enzymes. In a repair synthesis assay the toxins gave 70% inhibition of activity. Full activity could be restored to toxin-inhibited extracts by addition of purified PP2A, but not PP1. The p34 subunit of replication protein A was hyperphosphorylated in cell extracts in the presence of phosphatase inhibitors, but we found no evidence that this affected repair. In a coupled incision/synthesis repair assay okadaic acid decreased the production of incision intermediates in the repair reaction. The formation of 25-30mer oligonucleotides by dual incision during repair was also inhibited by okadaic acid and inhibition could be reversed with PP2A. Thus Ser/Thr- specific protein phosphorylation plays an important role in the modulation of nucleotide excision repair in vitro.     

Critical role of DNA intercalation in enzyme-catalyzed nucleotide flipping

Nucleotide flipping is a common feature of DNA-modifying enzymes that allows access to target sites within duplex DNA. Structural studies have identified many intercalating amino acid side chains in a wide variety of enzymes, but the functional contribution of these intercalating residues is poorly understood. We used site-directed mutagenesis and transient kinetic approaches to dissect the energetic contribution of intercalation for human alkyladenine DNA glycosylase, an enzyme that initiates repair of alkylation damage. When AAG flips out a damaged nucleotide, the void in the duplex is filled by a conserved tyrosine (Y162). We find that tyrosine intercalation confers 140-fold stabilization of the extrahelical specific recognition complex, and that Y162 functions as a plug to slow the rate of unflipping by 6000-fold relative to the Y162A mutant. Surprisingly, mutation to the smaller alanine side chain increases the rate of nucleotide flipping by 50-fold relative to the wild-type enzyme. This provides evidence against the popular model that DNA intercalation accelerates nucleotide flipping. In the case of AAG, DNA intercalation contributes to the specific binding of a damaged nucleotide, but this enhanced specificity comes at the cost of reduced speed of nucleotide flipping.     

A role for the human single-stranded DNA binding protein HSSB/RPA in an early stage of nucleotide excision repair.

The human single-stranded DNA binding protein (HSSB/RPA) is involved in several processes that maintain the integrity of the genome including DNA replication, homologous recombination, and nucleotide excision repair of damaged DNA. We report studies that analyze the role of HSSB in DNA repair. Specific protein-protein interactions appear to be involved in the repair function of HSSB, since it cannot be replaced by heterologous single-stranded DNA binding proteins. Anti-HSSB antibodies that inhibit the ability of HSSB to stimulate DNA polymerase alpha also inhibit repair synthesis mediated by human cell-free extracts. However, antibodies that neutralize DNA polymerase alpha do not inhibit repair synthesis. Repair is sensitive to aphidicolin, suggesting that DNA polymerase epsilon or delta participates in nucleotide excision repair by cell extracts. HSSB has a role other than generally stimulating synthesis by DNA polymerases, as it does not enhance the residual damage-dependent background synthesis displayed by repair-deficient extracts from xeroderma pigmentosum cells. Significantly, when damaged DNA is incised by the Escherichia coli UvrABC repair enzyme, human cell extracts can carry out repair synthesis even when HSSB has been neutralized with antibodies. This suggests that HSSB functions in an early stage of repair, rather than exclusively in repair synthesis. A model for the role of HSSB in repair is presented.     

DDB2 (Damaged-DNA binding protein 2) in nucleotide excision repair and DNA damage response

DDB2 was identified as a protein involved in the Nucleotide Excision Repair (NER), a major DNA repair mechanism that repairs UV damage to prevent accumulation of mutations and tumorigenesis. However, recent studies indicated additional functions of DDB2 in the DNA damage response pathway. Herein, we discuss the proposed mechanisms by which DDB2 activates NER and programmed cell death upon DNA damage through its E3 ligase activity.     

Multiple DNA binding domains mediate the function of the ERCC1-XPF protein in nucleotide excision repair

ERCC1-XPF is a heterodimeric, structure-specific endonuclease that cleaves single-stranded/double-stranded DNA junctions and has roles in nucleotide excision repair (NER), interstrand crosslink (ICL) repair, homologous recombination, and possibly other pathways. In NER, ERCC1-XPF is recruited to DNA lesions by interaction with XPA and incises the DNA 5' to the lesion. We studied the role of the four C-terminal DNA binding domains in mediating NER activity and cleavage of model substrates. We found that mutations in the helix-hairpin-helix domain of ERCC1 and the nuclease domain of XPF abolished cleavage activity on model substrates. Interestingly, mutations in multiple DNA binding domains were needed to significantly diminish NER activity in vitro and in vivo, suggesting that interactions with proteins in the NER incision complex can compensate for some defects in DNA binding. Mutations in DNA binding domains of ERCC1-XPF render cells more sensitive to the crosslinking agent mitomycin C than to ultraviolet radiation, suggesting that the ICL repair function of ERCC1-XPF requires tighter substrate binding than NER. Our studies show that multiple domains of ERCC1-XPF contribute to substrate binding, and are consistent with models of NER suggesting that multiple weak protein-DNA and protein-protein interactions drive progression through the pathway. Our findings are discussed in the context of structural studies of individual domains of ERCC1-XPF and of its role in multiple DNA repair pathways.     

DNA bending by M.EcoKI methyltransferase is coupled to nucleotide flipping

The maintenance methyltransferase M.EcoKI recognizes the bipartite DNA sequence 5'-AACNNNNNNGTGC-3', where N is any nucleotide. M.EcoKI preferentially methylates a sequence already containing a methylated adenine at or complementary to the underlined bases in the sequence. We find that the introduction of a single-stranded gap in the middle of the non-specific spacer, of up to 4 nt in length, does not reduce the binding affinity of M.EcoKI despite the removal of non-sequence-specific contacts between the protein and the DNA phosphate backbone. Surprisingly, binding affinity is enhanced in a manner predicted by simple polymer models of DNA flexibility. However, the activity of the enzyme declines to zero once the single-stranded region reaches 4 nt in length. This indicates that the recognition of methylation of the DNA is communicated between the two methylation targets not only through the protein structure but also through the DNA structure. Furthermore, methylation recognition requires base flipping in which the bases targeted for methylation are swung out of the DNA helix into the enzyme. By using 2-aminopurine fluorescence as the base flipping probe we find that, although flipping occurs for the intact duplex, no flipping is observed upon introduction of a gap. Our data and polymer model indicate that M.EcoKI bends the non-specific spacer and that the energy stored in a double-stranded bend is utilized to force or flip out the bases. This energy is not stored in gapped duplexes. In this way, M.EcoKI can determine the methylation status of two adenine bases separated by a considerable distance in double-stranded DNA and select the required enzymatic response.     

Functions of base flipping in E. coli nucleotide excision repair

UvrB is the main damage recognition protein in bacterial nucleotide excision repair and is capable of recognizing various structurally unrelated types of damage. Previously we have shown that upon binding of Escherichia coli UvrB to damaged DNA two nucleotides become extrahelical: the nucleotide directly 3' to the lesion and its base-pairing partner in the non-damaged strand. Here we demonstrate using a novel fluorescent 2-aminopurine-menthol modification that the position of the damaged nucleotide itself does not change upon UvrB binding. A co-crystal structure of B. caldotenax UvrB and DNA has revealed that one nucleotide is flipped out of the DNA helix into a pocket of the UvrB protein where it stacks on Phe249 [J.J. Truglio, E. Karakas, B. Hau, H. Wang, M.J. DellaVecchia, B. van Houten, C. Kisker, Structural basis for DNA recognition and processing by UvrB, Nat. Struct. Mol. Biol. 13 (2006) 360-364]. By mutating the equivalent of Phe249 (Tyr249) in the E. coli UvrB protein we show that on damaged DNA neither of the extrahelical nucleotides is inserted into this protein pocket. The mutant UvrB protein, however, resulted in an increased binding and incision of undamaged DNA showing that insertion of a base into the nucleotide-binding pocket is important for dissociation of UvrB from undamaged sites. Replacing the nucleotides in the non-damaged strand with a C3-linker revealed that the extruded base in the non-damaged strand is not directly involved in UvrB-binding or UvrC-mediated incision, but that its displacement is needed to allow access for residues of UvrB or UvrC to the neighboring base, which is directly opposite the DNA damage. This interaction is shown to be essential for optimal 3'-incision by UvrC. After 3'-incision base flipping in the non-damaged DNA strand is lost, indicative for a conformational change needed to prepare the UvrB-DNA complex for 5'-incision.     

Substitution of active site tyrosines with tryptophan alters the free energy for nucleotide flipping by human alkyladenine DNA glycosylase

Human alkyladenine DNA glycosylase (AAG) locates and excises a wide variety of structurally diverse alkylated and oxidized purine lesions from DNA to initiate the base excision repair pathway. Recognition of a base lesion requires flipping of the damaged nucleotide into a relatively open active site pocket between two conserved tyrosine residues, Y127 and Y159. We have mutated each of these amino acids to tryptophan and measured the kinetic effects on the nucleotide flipping and base excision steps. The Y127W and Y159W mutant proteins have robust glycosylase activity toward DNA containing 1,N(6)-ethenoadenine (εA), within 4-fold of that of the wild-type enzyme, raising the possibility that tryptophan fluorescence could be used to probe the DNA binding and nucleotide flipping steps. Stopped-flow fluorescence was used to compare the time-dependent changes in tryptophan fluorescence and εA fluorescence. For both mutants, the tryptophan fluorescence exhibited two-step binding with essentially identical rate constants as were observed for the εA fluorescence changes. These results provide evidence that AAG forms an initial recognition complex in which the active site pocket is perturbed and the stacking of the damaged base is disrupted. Upon complete nucleotide flipping, there is further quenching of the tryptophan fluorescence with coincident quenching of the εA fluorescence. Although these mutations do not have large effects on the rate constant for excision of εA, there are dramatic effects on the rate constants for nucleotide flipping that result in 40-100-fold decreases in the flipping equilibrium relative to wild-type. Most of this effect is due to an increased rate of unflipping, but surprisingly the Y159W mutation causes a 5-fold increase in the rate constant for flipping. The large effect on the equilibrium for nucleotide flipping explains the greater deleterious effects that these mutations have on the glycosylase activity toward base lesions that are in more stable base pairs.     

DNA and RNA binding by the mitochondrial lon protease is regulated by nucleotide and protein substrate

The ATP-dependent Lon protease belongs to a unique group of proteases that bind DNA. Eukaryotic Lon is a homo-oligomeric ring-shaped complex localized to the mitochondrial matrix. In vitro, human Lon binds specifically to a single-stranded GT-rich DNA sequence overlapping the light strand promoter of human mitochondrial DNA (mtDNA). We demonstrate that Lon binds GT-rich DNA sequences found throughout the heavy strand of mtDNA and that it also interacts specifically with GU-rich RNA. ATP inhibits the binding of Lon to DNA or RNA, whereas the presence of protein substrate increases the DNA binding affinity of Lon 3.5-fold. We show that nucleotide inhibition and protein substrate stimulation coordinately regulate DNA binding. In contrast to the wild type enzyme, a Lon mutant lacking both ATPase and protease activity binds nucleic acid; however, protein substrate fails to stimulate binding. These results suggest that conformational changes in the Lon holoenzyme induced by nucleotide and protein substrate modulate the binding affinity for single-stranded mtDNA and RNA in vivo. Co-immunoprecipitation experiments show that Lon interacts with mtDNA polymerase gamma and the Twinkle helicase, which are components of mitochondrial nucleoids. Taken together, these results suggest that Lon participates directly in the metabolism of mtDNA.     

Domain mapping of the DNA binding, endonuclease, and ERCC1 binding properties of the human DNA repair protein XPF.

During nucleotide excision repair, one of the two incisions necessary for removal of a broad spectrum of DNA adducts is made by the human XPF/ERCC1 protein complex. To characterize the biochemical function of XPF, we have expressed and purified the independent 104 kDa recombinant XPF protein from E. coli and determined that it is an endonuclease and can bind DNA in the absence of the ERCC1 subunit. Endonuclease activity was also identified in a stable 70 kDa proteolysis fragment of XPF obtained during protein expression, indicating an N-terminal catalytic domain. Sequence homology and secondary structure predictions indicated a second functional domain at the C-terminus of XPF. To investigate the significance of the two predicted domains, a series of XPF deletion fragments spanning the entire protein were designed and examined for DNA binding, endonuclease activity, and ERCC1 subunit binding. Our results indicate that the N-terminal 378 amino acids of XPF are capable of binding and hydrolyzing DNA, while the C-terminal 214 residues are capable of binding specifically to ERCC1. We propose that the N-terminal domain of XPF contributes to the junction-specific endonuclease activity observed during DNA repair and recombination events. In addition, evidence presented here suggests that the C-terminal domain of XPF is responsible for XPF/ERCC1 complex formation. A working model for the XPF protein is presented illustrating the function of XPF in the nucleotide excision pathway and depicting the two functional domains interacting with DNA and ERCC1.     

The UV-damaged DNA binding protein mediates efficient targeting of the nucleotide excision repair complex to UV-induced photo lesions

Previous studies point to the XPC-hHR23B complex as the principal initiator of global genome nucleotide excision repair (NER) pathway, responsible for the repair of UV-induced cyclobutane pyrimidine dimers (CPD) and 6-4 photoproducts (6-4PP) in human cells. However, the UV-damaged DNA binding protein (UV-DDB) has also been proposed as a damage recognition factor involved in repair of UV-photoproducts, especially CPD. Here, we show in human XP-E cells (UV-DDB deficient) that the incision complex formation at UV-induced lesions was severely diminished in locally damaged nuclear spots. Repair kinetics of CPD and 6-4PP in locally and globally UV-irradiated normal human and XP-E cells demonstrate that UV-DDB can mediate efficient targeting of XPC-hHR23B and other NER factors to 6-4PP. The data is consistent with a mechanism in which UV-DDB forms a stable complex when bound to a 6-4PP, allowing subsequent repair proteins--starting with XPC-hHR23B--to accumulate, and verify the lesion, resulting in efficient 6-4PP repair. These findings suggest that (i) UV-DDB accelerates repair of 6-4PP, and at later time points also CPD, (ii) the fraction of 6-4PP that can be bound by UV-DDB is limited due to its low cellular quantity and fast UV dependent degradation, and (iii) in the absence of UV-DDB a slow XPC-hHR23B dependent pathway is capable to repair 6-4PP, and to some extent also CPD.     

Role of base flipping in specific recognition of damaged DNA by repair enzymes

DNA repair enzymes induce base flipping in the process of damage recognition. Endonuclease V initiates the repair of cis, syn thymine dimers (TD) produced in DNA by UV radiation. The enzyme is known to flip the base opposite the damage into a non-specific binding pocket inside the protein. Uracil DNA glycosylase removes a uracil base from G.U mismatches in DNA by initially flipping it into a highly specific pocket in the enzyme. The contribution of base flipping to specific recognition has been studied by molecular dynamics simulations on the closed and open states of undamaged and damaged models of DNA. Analysis of the distributions of bending and opening angles indicates that enhanced base flipping originates in increased flexibility of the damaged DNA and the lowering of the energy difference between the closed and open states. The increased flexibility of the damaged DNA gives rise to a DNA more susceptible to distortions induced by the enzyme, which lowers the barrier for base flipping. The free energy profile of the base-flipping process was constructed using a potential of mean force representation. The barrier for TD-containing DNA is 2.5 kcal mol(-1) lower than that in the undamaged DNA, while the barrier for uracil flipping is 11.6 kcal mol(-1) lower than the barrier for flipping a cytosine base in the undamaged DNA. The final barriers for base flipping are approximately 10 kcal mol(-1), making the rate of base flipping similar to the rate of linear scanning of proteins on DNA. These results suggest that damage recognition based on lowering the barrier for base flipping can provide a general mechanism for other DNA-repair enzymes.     

Suppression of UV-induced apoptosis by the human DNA repair protein XPG

The severe xeroderma pigmentosum/Cockayne syndrome (XP/CS) syndrome is caused by mutations in the XPB, XPD and XPG genes that encode the helicase subunits of TFIIH and the 3' endonuclease of nucleotide excision repair (NER). Because XPB and XPD have been implicated in p53-mediated apoptosis, we examined the possible involvement of XPG in this process. After ultraviolet light (UV) irradiation, primary fibroblasts of XP complementation group G (XP-G) individuals with CS enter apoptosis more readily than other NER-deficient cells, but this is unlinked to unrepaired damage. These XP-G/CS cells accumulate p53 post-UV but they fail to accumulate the 90/92 kDa isoforms of Mdm2 and their cellular distribution of Mdm2 is impaired. Apoptosis levels revert to wild type, Mdm2 90/92 kDa isoforms accumulate, and Mdm2 regains its normal post-UV nuclear location in transduced XP-G/CS cells expressing wild-type XPG, but not an XPG catalytic site mutant. These results suggest that XPG suppresses UV-induced apoptosis and that this suppression, most simply, requires its endonuclease function.