Deficiency in incisions produced by XPF at the site of a DNA interstrand cross-link in Fanconi anemia cells

Repair of DNA interstrand cross-links is a multistep process, critical to which is production of incisions at the site of the lesion resulting in the unhooking of the cross-link from DNA. We have previously shown that XPF is involved in production of incisions at the site of a psoralen interstrand cross-link and that in Fanconi anemia, complementation group A (FA-A) cells, there is a deficiency in these incisions. We now demonstrate that in FA complementation group B, C, D2, F, and G cells there is also a deficiency in production of these incisions. Involvement of FA proteins in this process is demonstrated by the ability of FA cells, corrected with the appropriate FANC cDNAs, to produce these incisions and by inhibition of these incisions by antibodies against these proteins. This incision deficiency correlates with reduced levels of DNA repair synthesis in these cells and is not due to reduced levels of XPF. FA proteins could be influencing this incision process by interacting either with proteins involved in the unhooking step or with damaged DNA, acting as a damage sensor. The results also demonstrate that FA cells are undergoing apoptosis by 12 h after interstrand cross-link damage. It is thus proposed that the single-strand breaks known to be created in DNA during apoptosis could mask the deficiency in ability of FA cells to incise cross-linked DNA and could account for the reported discrepancy as to whether FA cells are deficient in the incision step of the repair process.     

DNA base composition determines the specificity of UvrABC endonuclease incision of a psoralen cross-link

The sequences flanking a psoralen interstrand cross-link may determine how it is repaired. Our comparison of the Escherichia coli UvrABC endonuclease incision of a variety of specific cross-link sequences in a single natural DNA fragment showed that DNA base composition determines which of two cross-linked DNA strands will be incised. G/C enrichment of the region 6-12 bases 5' of the modified T on the furan-side strand results in preferential incision of the furan-side strand. When the G/C-rich region is on the 3' side, or on neither side, incisions occur on either strand. These effects of DNA base composition suggest that UvrAB can bind in two ways to a psoralen cross-link.     

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.     

Activity of individual ERCC1 and XPF subunits in DNA nucleotide excision repair

ERCC1–XPF is a structure-specific nuclease with two subunits, ERCC1 and XPF. The enzyme cuts DNA at junctions where a single strand moves 5′ to 3′ away from a branch point with duplex DNA. This activity has a central role in nucleotide excision repair (NER), DNA cross-link repair and recombination. To dissect the activities of the nuclease it is necessary to investigate the subunits individually, as studies of the enzyme so far have only used the heterodimeric complex. We produced recombinant ERCC1 and XPF separately in Escherichia coli as soluble proteins. Activity was monitored by a sensitive dual incision assay for NER by complementation of cell extracts. XPF and ERCC1 are unstable in mammalian cells in the absence of their partners but we found, surprisingly, that ERCC1 alone could confer some repair to extracts from ERCC1-defective cells. A version of ERCC1 lacking the first 88 non-conserved amino acids was also functional. This indicated that a small amount of active XPF was present in ERCC1 extracts, and immunoassays showed this to be the case. Some repair in XPF-defective extracts could be achieved by adding ERCC1 and XPF proteins together, but not by adding only XPF. The results show for the first time that functional ERCC1–XPF can be formed from separately produced subunits. Protein sequence comparison revealed similarity between the ERCC1 family and the C-terminal region of the XPF family, including the regions of both proteins that are necessary for the ERCC1–XPF heterodimeric interaction. This suggests that the ERCC1 and XPF families are related via an ancient duplication.     

Repair of an interstrand DNA cross-link initiated by ERCC1-XPF repair/recombination nuclease

Interstrand DNA cross-link damage is a severe challenge to genomic integrity. Nucleotide excision repair plays some role in the repair of DNA cross-links caused by psoralens and other agents. However, in mammalian cells there is evidence that the ERCC1-XPF nuclease has a specialized additional function during interstrand DNA cross-link repair, beyond its role in nucleotide excision repair. We placed a psoralen monoadduct or interstrand cross-link in a duplex, 4-6 bases from a junction with unpaired DNA. ERCC1-XPF endonucleolytically cleaved within the duplex on either side of the adduct, on the strand having an unpaired 3' tail. Cross-links that were cleaved only on the 5' side were purified and reincubated with ERCC1-XPF. A second cleavage was then observed on the 3' side. Relevant partially unwound structures near a cross-link may be expected to arise frequently, for example at stalled DNA replication forks. The results show that the single enzyme ERCC1-XPF can release one arm of a cross-link and suggest a novel mechanism for interstrand cross-link repair.     

Defects in interstrand cross-link uncoupling do not account for the extreme sensitivity of ERCC1 and XPF cells to cisplatin

The anticancer drug cisplatin reacts with DNA leading to the formation of interstrand and intrastrand cross-links that are the critical cytotoxic lesions. In contrast to cells bearing mutations in other components of the nucleotide excision repair apparatus (XPB, XPD, XPG and CSB), cells defective for the ERCC1-XPF structure-specific nuclease are highly sensitive to cisplatin. To determine if the extreme sensitivity of XPF and ERCC1 cells to cisplatin results from specific defects in the repair of either intrastrand or interstrand cross-links we measured the elimination of both lesions in a range of nucleotide excision repair Chinese hamster mutant cell lines, including XPF- and ERCC1-defective cells. Compared to the parental, repair-proficient cell line all the mutants tested were defective in the elimination of both classes of adduct despite their very different levels of increased sensitivity. Consequently, there is no clear relationship between initial incisions at interstrand cross-links or removal of intrastrand adducts and cellular sensitivity. These results demonstrate that the high cisplatin sensitivity of ERCC1 and XPF cells likely results from a defect other than in excision repair. In contrast to other conventional DNA cross-linking agents, we found that the repair of cisplatin adducts does not involve the formation of DNA double-strand breaks. Surprisingly, XRCC2 and XRCC3 cells are defective in the uncoupling step of cisplatin interstrand cross-link repair, suggesting that homologous recombination might be initiated prior to excision of this type of cross-link.     

Complementation of the DNA repair-deficient swi10 mutant of fission yeast by the human ERCC1 gene.

In human cells DNA damage caused by UV light is mainly repaired by the nucleotide excision repair pathway. This mechanism involves dual incisions on both sides of the damage catalyzed by two nucleases. In mammalian cells XPG cleaves 3' of the DNA lesion while the ERCC1-XPF complex makes the 5' incision. The amino acid sequence of the human excision repair protein ERCC1 is homologous with the fission yeast Swi10 protein. In order to test whether these proteins are functional homologues, we overexpressed the human gene in a Schizosaccharomyces pombe swi10 mutant. A swi10 mutation has a pleiotropic effect: it reduces the frequency of mating type switching (a mitotic transposition event from a silent cassette into the expression site) and causes increased UV sensitivity. We found that the full-length ERCC1 gene only complements the transposition defect of the fission yeast mutant, while a C-terminal truncated ERCC1 protein also restores the DNA repair capacity of the yeast cells. Using the two-hybrid system of Saccharomyces cerevisiae we show that only the truncated human ERCC1 protein is able to interact with the S . pombe Rad16 protein, which is the fission yeast homologue of human XPF. This is the first example yet known that a human gene can correct a yeast mutation in nucleotide excision repair.     

Nucleotide excision repair endonuclease genes in Drosophila melanogaster

Nucleotide excision repair (NER) is the primary pathway for the removal of ultraviolet light-induced damage and bulky adducts from DNA in eukaryotes. During NER, the helix is unwound around the damaged site, and incisions are made on the 5' and 3' sides, to release an oligonucleotide carrying the lesion. Repair synthesis can then proceed, using the intact strand as a template. The incisions flanking the lesion are catalyzed by different structure-specific endonucleases. The 5' incision is made by a heterodimer of XPF and ERCC1 (Rad1p-Rad10p in Saccharomyces cerevisiae), and the 3' incision is made by XPG (Rad2p in S. cerevisiae). We previously showed that the Drosophila XPF homologue is encoded by the meiotic recombination gene mei-9. We report here the identification of the genes encoding the XPG and ERCC1 homologues (XPG(Dm) and ERCC1(Dm)). XPG(Dm) is encoded by the mus201 gene; we found frameshift mutations predicted to produce truncated XPG(Dm) proteins in each of two mus201 alleles. These mutations cause defects in nucleotide excision repair and hypersensitivity to alkylating agents and ultraviolet light, but do not cause hypersensitivity to ionizing radiation and do not impair viability or fertility. ERCC1(Dm) interacts strongly in a yeast two-hybrid assay with MEI-9, indicative of the presumed requirement for these polypeptides to dimerize to form the functional endonuclease. The Drosophila Ercc1 gene maps to polytene region 51D1-2. The nucleotide excision repair gene mus210 maps nearby (51E-F) but is distinct from Ercc1.     

Biophysical characterization of the interaction domains and mapping of the contact residues in the XPF-ERCC1 complex

XPF and ERCC1 exist as a heterodimer to be stable and active in cells and catalyze DNA cleavage on the 5'-side of a lesion during nucleotide excision repair. To characterize the specific interaction between XPF and ERCC1, we expressed the human ERCC1 binding domain of XPF (XPF-EB) and the XPF binding domain of ERCC1 (ERCC1-FB) in Escherichia coli. Milligram quantities of a heterodimer were characterized with gel filtration chromatography, an Ni(2+)-NTA binding assay, and analytical ultracentrifugation. Cross-linking experiments at high salt concentrations revealed that XPF interacts with ERCC1 mainly through hydrophobic interactions. XPF-EB was also shown to homodimerize in the absence of ERCC1. NMR cross-saturation methods were applied to map the residues involved in formation of the XPF-EB.XPF-EB homodimer and the XPF-EB.ERCC1-FB heterodimer. Helix H3 and the C-terminal region of XPF-EB were either within or in close proximity to the homodimer interface, whereas the ERCC1-FB binding site of XPF-EB was distributed across helix H1, a small part of H2, H3, and the C-terminal region, most of which exhibited large changes in chemical shift upon ERCC1 binding. The XPF-EB heterodimeric interface is larger than the XPF-EB homodimeric one, which could explain why XPF has a stronger affinity for ERCC1 than for a second molecule of XPF. The XPF binding sites of ERCC1 were located in helices H1 and H3 and in the C-terminal region, similar to the involved surface of XPF. We used cross-saturation data and the crystal structure of related proteins to model the two complexes.     

RPA activates the XPF‐ERCC1 endonuclease to initiate processing of DNA interstrand crosslinks

During replication‐coupled DNA interstrand crosslink (ICL) repair, the XPF‐ERCC1 endonuclease is required for the incisions that release, or “unhook”, ICLs, but the mechanism of ICL unhooking remains largely unknown. Incisions are triggered when the nascent leading strand of a replication fork strikes the ICL. Here, we report that while purified XPF‐ERCC1 incises simple ICL‐containing model replication fork structures, the presence of a nascent leading strand, modelling the effects of replication arrest, inhibits this activity. Strikingly, the addition of the single‐stranded DNA (ssDNA)‐binding replication protein A (RPA) selectively restores XPF‐ERCC1 endonuclease activity on this structure. The 5′–3′ exonuclease SNM1A can load from the XPF‐ERCC1‐RPA‐induced incisions and digest past the crosslink to quantitatively complete the unhooking reaction. We postulate that these collaborative activities of XPF‐ERCC1, RPA and SNM1A might explain how ICL unhooking is achieved in vivo.     

Construction of DNA substrates modified with psoralen at a unique site and study of the action mechanism of ABC excinuclease on these uniformly modified substrates

Psoralens bind to DNA noncovalently and upon exposure to near UV (320-400 nm) light produce covalent adducts. Thymidine residues in DNA, especially those at 5'-TpA-3' sequences, are most susceptible to the photochemical reaction. This property of the reaction and the recent advances in oligonucleotide synthesis and separation has enabled us to construct DNA fragments containing psoralen adducts at a specific site. The octanucleotide 5'-TCGTAGCT-3' was photoreacted (in the presence of the complementary strand) with the synthetic psoralen 4'-hydroxymethyl-4,5',8-trimethylpsoralen to obtain oligonucleotides adducted via the furan or pyrone ring at the internal thymine. These modified octanucleotides were ligated to nonmodified oligonucleotides to obtain a 40-base pair DNA fragment containing a psoralen adduct at a central location. The modified fragment having the thymine-furan side 4'-hydroxymethyl-4,5',8-trimethylpsoralen adduct was irradiated with 360 nm of light to produce an interstrand cross-link, and this cross-linked DNA was purified to homogeneity. These uniquely modified DNAs were used as substrates for Escherichia coli ABC excinuclease to determine its incision mechanism unambiguously and to determine the contact sites of the enzyme. ABC excinuclease mediates the cleavage of the 8th and 5th phosphodiester bonds 5' and 3', respectively, to psoralen monoadducts, and the 9th (5') and 3rd (3') phosphodiester bonds to the furan-side thymine of the cross-link. Preliminary DNaseI footprinting studies show that ABC excinuclease protects the whole 40-base pair fragment from DNaseI, and binding of the A and B subunits to the furan side-monoadducted substrate produces two hypersensitive phosphodiester bonds in the vicinity of the 5' incision site of ABC excinuclease.     

Interstrand Cross-Links Induce DNA Synthesis in Damaged and Undamaged Plasmids in Mammalian Cell Extracts

Mammalian cell extracts have been shown to carry out damage-specific DNA repair synthesis induced by a variety of lesions, including those created by UV and cisplatin. Here, we show that a single psoralen interstrand cross-link induces DNA synthesis in both the damaged plasmid and a second homologous unmodified plasmid coincubated in the extract. The presence of the second plasmid strongly stimulates repair synthesis in the cross-linked plasmid. Heterologous DNAs also stimulate repair synthesis to variable extents. Psoralen monoadducts and double-strand breaks do not induce repair synthesis in the unmodified plasmid, indicating that such incorporation is specific to interstrand cross-links. This induced repair synthesis is consistent with previous evidence indicating a recombinational mode of repair for interstrand cross-links. DNA synthesis is compromised in extracts from mutants (deficient in ERCC1, XPF, XRCC2, and XRCC3) which are all sensitive to DNA cross-linking agents but is normal in extracts from mutants (XP-A, XP-C, and XP-G) which are much less sensitive. Extracts from Fanconi anemia cells exhibit an intermediate to wild-type level of activity dependent upon the complementation group. The DNA synthesis deficit in ERCC1- and XPF-deficient extracts is restored by addition of purified ERCC1-XPF heterodimer. This system provides a biochemical assay for investigating mechanisms of interstrand cross-link repair and should also facilitate the identification and functional characterization of cellular proteins involved in repair of these lesions.     

The C-terminal region of the Escherichia coli UvrC protein, which is homologous to the C-terminal region of the human ERCC1 protein, is involved in DNA binding and 5'-incision.

The incisions in the DNA at the 3'- and 5'-side of a DNA damage during nucleotide excision repair in Escherichia coli occur in a complex consisting of damaged DNA, UvrB and UvrC. The exact requirements for the two incision events, however, are different. It has previously been shown that the 3'-incision requires the interaction between the C-terminal domain of UvrB and a homologous region in UvrC. This interaction, however, is dispensable for the 5'-incision. Here we show that the C-terminal domain of the UvrC protein is essential for the 5'-incision, whereas this domain can be deleted without affecting the 3'-incision. The C-terminal domain of UvrC is homologous with the C-terminal part of the ERCC1 protein which, in a complex with XPF, is responsible for the 5'-incision reaction in human nucleotide excision repair. Both in the UvrC and the ERCC1 domain a Helix-hairpin-Helix (HhH) motif can be indicated, albeit at different positions. Such a motif also has been found in a large variety of DNA binding proteins and it has been suggested to form a structure involved in non-sequence-specific DNA binding. In contrast to the full length UvrC protein, a truncated UvrC protein (UvrC554) lacking the entire ERCC1 homology including the HhH motif no longer binds to ssDNA. Analysis of protein-DNA complexes using bandshift experiments showed that this putative DNA binding domain of UvrC is required for stabilisation of the UvrBC-DNA complex after the 3'-incision has taken place. We propose that after the initial 3'-incision the HhH motif recognises a specific DNA structure, thereby positioning the catalytic site for the subsequent 5'-incision reaction.     

Mutational analysis of the human nucleotide excision repair gene ERCC1.

The human DNA repair protein ERCC1 resides in a complex together with the ERCC4, ERCC11 and XP-F correcting activities, thought to perform the 5' strand incision during nucleotide excision repair (NER). Its yeast counterpart, RAD1-RAD10, has an additional engagement in a mitotic recombination pathway, probably required for repair of DNA cross-links. Mutational analysis revealed that the poorly conserved N-terminal 91 amino acids of ERCC1 are dispensable for both repair functions, in contrast to a deletion of only four residues from the C-terminus. A database search revealed a strongly conserved motif in this C-terminus sharing sequence homology with many DNA break processing proteins, indicating that this part is primarily required for the presumed structure-specific endonuclease activity of ERCC1. Most missense mutations in the central region give rise to an unstable protein (complex). Accordingly, we found that free ERCC1 is very rapidly degraded, suggesting that protein-protein interactions provide stability. Survival experiments show that the removal of cross-links requires less ERCC1 than UV repair. This suggests that the ERCC1-dependent step in cross-link repair occurs outside the context of NER and provides an explanation for the phenotype of the human repair syndrome xeroderma pigmentosum group F.     

Recruitment and positioning determine the specific role of the XPF‐ERCC1 endonuclease in interstrand crosslink repair

XPF‐ERCC1 is a structure‐specific endonuclease pivotal for several DNA repair pathways and, when mutated, can cause multiple diseases. Although the disease‐specific mutations are thought to affect different DNA repair pathways, the molecular basis for this is unknown. Here we examine the function of XPF‐ERCC1 in DNA interstrand crosslink (ICL) repair. We used Xenopus egg extracts to measure both ICL and nucleotide excision repair, and we identified mutations that are specifically defective in ICL repair. One of these separation‐of‐function mutations resides in the helicase‐like domain of XPF and disrupts binding to SLX4 and recruitment to the ICL. A small deletion in the same domain supports recruitment of XPF to the ICL, but inhibited the unhooking incisions most likely by disrupting a second, transient interaction with SLX4. Finally, mutation of residues in the nuclease domain did not affect localization of XPF‐ERCC1 to the ICL but did prevent incisions on the ICL substrate. Our data support a model in which the ICL repair‐specific function of XPF‐ERCC1 is dependent on recruitment, positioning and substrate recognition.     

The structure of the XPF-ssDNA complex underscores the distinct roles of the XPF and ERCC1 helix- hairpin-helix domains in ss/ds DNA recognition

Human XPF/ERCC1 is a structure-specific DNA endonuclease that nicks the damaged DNA strand at the 5' end during nucleotide excision repair. We determined the structure of the complex of the C-terminal domain of XPF with 10 nt ssDNA. A positively charged region within the second helix of the first HhH motif contacts the ssDNA phosphate backbone. One guanine base is flipped out of register and positioned in a pocket contacting residues from both HhH motifs of XPF. Comparison to other HhH-containing proteins indicates a one-residue deletion in the second HhH motif of XPF that has altered the hairpin conformation, thereby permitting ssDNA interactions. Previous nuclear magnetic resonance studies showed that ERCC1 in the XPF-ERCC1 heterodimer can bind dsDNA. Combining the two observations gives a model that underscores the asymmetry of the human XPF/ERCC1 heterodimer in binding at an ss/ds DNA junction.     

Differential processing of UV mimetic and interstrand crosslink damage by XPF cell extracts

We have recently developed a mammalian cell free assay in which interstrand crosslinks induce DNA synthesis in both damaged and undamaged plasmids co-incubated in the same extract. We have also shown using hamster mutants that both ERCC1 and XPF are required for the observed incorporation. Here, we show that extracts from an XPF patient cell line differentially process UV mimetic damage and interstrand crosslinks in vitro. XPF extracts are highly defective in the stimulation of repair synthesis by N-acetoxy-N- acetylaminofluorene, but are proficient in the stimulation of DNA synthesis by psoralen interstrand crosslinks. In addition, we show that extracts from the hamster UV140 mutant, which has high UV sensitivity, but moderate mitomycin C sensitivity, are similar in both assays to XPF cell extracts. These findings support the hypothesis that the activities of XPF in nucleotide excision repair (NER) and crosslink repair are separable, and that mutations in XPF patients result in the abolition of NER, but not recombinational repair pathways, which are likely to be essential as has been observed in ERCC1 homozygous –/– mice.     

Defining the roles of nucleotide excision repair and recombination in the repair of DNA interstrand cross-links in mammalian cells

The mechanisms by which DNA interstrand cross-links (ICLs) are repaired in mammalian cells are unclear. Studies in bacteria and yeasts indicate that both nucleotide excision repair (NER) and recombination are required for their removal and that double-strand breaks are produced as repair intermediates in yeast cells. The role of NER and recombination in the repair of ICLs induced by nitrogen mustard (HN2) was investigated using Chinese hamster ovary mutant cell lines. XPF and ERCC1 mutants (defective in genes required for NER and some types of recombination) and XRCC2 and XRCC3 mutants (defective in RAD51-related homologous recombination genes) were highly sensitive to HN2. Cell lines defective in other genes involved in NER (XPB, XPD, and XPG), together with a mutant defective in nonhomologous end joining (XRCC5), showed only mild sensitivity. In agreement with their extreme sensitivity, the XPF and ERCC1 mutants were defective in the incision or "unhooking" step of ICL repair. In contrast, the other mutants defective in NER activities, the XRCC2 and XRCC3 mutants, and the XRCC5 mutant all showed normal unhooking kinetics. Using pulsed-field gel electrophoresis, DNA double-strand breaks (DSBs) were found to be induced following nitrogen mustard treatment. DSB induction and repair were normal in all the NER mutants, including XPF and ERCC1. The XRCC2, XRCC3, and XRCC5 mutants also showed normal induction kinetics. The XRCC2 and XRCC3 homologous recombination mutants were, however, severely impaired in the repair of DSBs. These results define a role for XPF and ERCC1 in the excision of ICLs, but not in the recombinational components of cross-link repair. In addition, homologous recombination but not nonhomologous end joining appears to play an important role in the repair of DSBs resulting from nitrogen mustard treatment.     

The HhH domain of the human DNA repair protein XPF forms stable homodimers

The human XPF-ERCC1 protein complex plays an essential role in nucleotide excision repair by catalysing positioned nicking of a DNA strand at the 5' side of the damage. We have recently solved the structure of the heterodimeric complex of the C-terminal domains of XPF and ERCC1 (Tripsianes et al., Structure 2005;13:1849-1858). We found that this complex comprises a pseudo twofold symmetry axis and that the helix-hairpin-helix motif of ERCC1 is required for DNA binding, whereas the corresponding domain of XPF is functioning as a scaffold for complex formation with ERCC1. Despite the functional importance of heterodimerization, the C-terminal domain of XPF can also form homodimers in vitro. We here compare the stabilities of homodimeric and heterodimeric complexes of the C-terminal domains of XPF and ERCC1. The higher stability of the XPF HhH complexes under various experimental conditions, determined using CD and NMR spectroscopy and mass spectrometry, is well explained by the structural differences that exist between the HhH domains of the two complexes. The XPF HhH homodimer has a larger interaction interface, aromatic stacking interactions, and additional hydrogen bond contacts as compared to the XPF/ERCC1 HhH complex, which accounts for its higher stability.     

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.