UMLS:C0268140 - FACTA Search

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Query: UMLS:C0268140 (XPF)
549 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The nucleotide excision repair (NER) protein ERCC1 is part of a functional complex, which harbors in addition the repair correcting activities of ERCC4, ERCC11 and human XPF. ERCC1 is not associated with a defect in any of the known human NER disorders: xeroderma pigmentosum, Cockayne's syndrome or trichothiodystrophy. Here we report the partial purification and characterization of the ERCC1 complex. Immunoprecipitation studies tentatively identified a subunit in the complex with an apparent MW of approximately 120 kDa. The complex has affinity for DNA, but no clear preference for ss, ds or UV-damaged DNA substrates. The size of the entire complex determined by non-denaturing gradient gels (approximately 280 kDa) is considerably larger than previously found using size separation on glycerol gradients (approximately 120 kDa). Stable associations of the ERCC1 complex with other known repair factors (XPA, XPC, XPG and TFIIH complex) could not be detected.
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PMID:Partial characterization of the DNA repair protein complex, containing the ERCC1, ERCC4, ERCC11 and XPF correcting activities. 759 55

Nucleotide excision repair is the principal way by which human cells remove UV damage from DNA. Human cell extracts were fractionated to locate active components, including xeroderma pigmentosum (XP) and ERCC factors. The incision reaction was then reconstituted with the purified proteins RPA, XPA, TFIIH (containing XPB and XPD), XPC, UV-DDB, XPG, partially purified ERCC1/XPF complex, and a factor designated IF7. UV-DDB (related to XPE protein) stimulated repair but was not essential. ERCC1- and XPF-correcting activity copurified with an ERCC1-binding polypeptide of 110 kDa that was absent in XP-F cell extract. Complete repair synthesis was achieved by combining these factors with DNA polymerase epsilon, RFC, PCNA, and DNA ligase I. The reconstituted core reaction requires about 30 polypeptides.
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PMID:Mammalian DNA nucleotide excision repair reconstituted with purified protein components. 769 16

Recent studies have revealed that the general transcription factor TFIIH is also a general excision repair factor which, along with several other proteins, is required for transcription-independent excision reaction. As a general transcription factor, TFIIH is recruited to RNA polymerase II-promoter complex by another general transcription factor called TFIIE. We were interested in knowing whether TFIIE is also involved in recruiting TFIIH to the excision repair complex. We found that cell-free extract depleted of TFIIE carried out excision repair at a normal rate, leading us to conclude that TFIIE is not involved in recruiting TFIIH to the damage site and has no role in general excision repair. In contrast, the human damage recognition protein XPA specifically binds to TFIIH and apparently recruits it to the damage site. The carboxyl-terminal half of XPA is responsible for specific interaction with TFIIH. The C261S/C264S mutant of XPA bound the ERCC1-XPF complex normally, but failed to bind TFIIH and failed to complement an XP-A mutant cell-free extract indicating that the XPA-TFIIH interaction is essential to effecting the excision reaction. Interestingly, XPA also binds to the p34 subunit of TFIIE specifically and in competition with the p56 subunit of TFIIE. This latter interaction has no apparent role in general excision repair but may be relevant in the transcription-coupled repair reaction.
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PMID:The general transcription-repair factor TFIIH is recruited to the excision repair complex by the XPA protein independent of the TFIIE transcription factor. 787 63

Nucleotide excision repair consists of removal of the damaged nucleotide(s) from DNA by dual incision of the damaged strand on both sides of the lesion, followed by filling of the resulting gap and ligation. In humans, 14-16 polypeptides are required for the dual incision step. We have purified the required proteins to homogeneity and reconstituted the dual incision activity (excision nuclease) in a defined enzyme/substrate system. The system was highly efficient, removing >30% of the thymine dimers under optimal conditions. All of the six fractions that constitute the excision nuclease were required for dual incision of the thymine dimer substrate. However, when a cholesterol-substituted oligonucleotide was used as substrate, excision occurred in the absence of the XPC-HHR23B complex, reminiscent of transcription-coupled repair in the XP-C mutant cell line. Replication protein A is absolutely required for both incisions. The XPG subunit is essential to the formation of the preincision complex, but the repair complex can assemble and produce normal levels of 3'-incision in the absence of XPF-ERCC1. Kinetic experiments revealed that the 3'-incision precedes the 5'-incision. Consistent with the kinetic data, uncoupled 5'-incision was never observed in the reconstituted system. Two forms of TFIIH were used in the reconstitution reaction, one containing the CDK7-cyclin H pair and one lacking it. Both forms were equally active in excision. The excised oligomer dissociated from the gapped DNA in a nucleoprotein complex. In total, these results provide a detailed account of the reactions occurring during damage removal by human excision nuclease.
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PMID:Reaction mechanism of human DNA repair excision nuclease. 862 23

Nucleotide excision repair by mammalian enzymes removes DNA damage as part of approximately 30-mer oligonucleotides by incising phosphodiester bonds on either side of a lesion. We analyzed this dual incision reaction at a single 1,3-intrastrand d(GpTpG)-cisplatin cross-link in a closed circular duplex DNA substrate. Incisions were formed in the DNA with human cell extracts in which DNA repair synthesis was inhibited. The nicks were mapped by restriction fragment end labeling and primer extension analysis. Principal sites of cleavage were identified at the 9th phosphodiester bond 3' to the lesion and at the 16th phosphodiester bond 5' to the lesion. The predominant product was found to be a 26-mer platinated oligonucleotide by hybridization to a 32P-labeled complementary DNA probe. Oligonucleotides were formed at the same rate as the 3' cleavage, suggesting that both incisions are made in a near-synchronous manner. There was, however, a low frequency of 5' incisions in the absence of 3' cleavage. The dual incision reaction was reconstituted using the purified mammalian proteins XPA, RPA, XPC, TFIIH, XPG, and a fraction containing ERCC1-XPF and IF7. All of these components were required in order to observe any cleavage.
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PMID:Analysis of incision sites produced by human cell extracts and purified proteins during nucleotide excision repair of a 1,3-intrastrand d(GpTpG)-cisplatin adduct. 863 55

Human cells from patients suffering with xeroderma pigmentosum (XP) characterized by extreme sensitivity to UV light and a high incidence of skin tumors fall into seven complementation groups, XPA to XPG, and are lacking a functional helicase, endonuclease, or lesion-recognizing protein involved in the initial steps during nucleotide excision repair (NER); a number of proteins involved in DNA repair are termed XPA to XPG depending on which one is defective in a particular complementation group of XP and include: (i) proteins involved in the recognition of (6-4) photoproducts (XPE) and of a broad range of lesions such as pyrimidine dimers (XPA); (ii) proteins that are DNA helicases and integral parts of the general transcription factor TFIIH functioning in both transcription and repair (XPB, XPD); (iii) endonucleases that perform the two incisions, the XPG incising six nucleotides (nt) to the 3' side from a photodimer and the ERCC1-XPF protein complex incising 22 nt to the 5' side of the lesion; and (iv) single-strand DNA-binding proteins (XPC). The ERCC6 helicase is largely responsible for coupling transcription to repair whereas XPC seems to be responsible for the repair of the inactive parts of the genome as well as for the repair of the nontranscribed strand in active genes. p53 recognizes insertion/deletion mismatches as well as free ends of DNA produced by ionizing radiation to arrest the cell cycle. Most of the human DNA repair proteins have their counterparts in both budding and fission yeasts and some of them also in E. coli evoking an evolutionary conservation of DNA repair pathways. Accumulation of mutations within repair genes in single cells followed by their escape from the immune surveillance and in clonal expansion may greatly contribute to the appearance and development of human cancers.
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PMID:Xeroderma pigmentosum and molecular cloning of DNA repair genes. 868 16

The human XPF-ERCC1 protein complex is one of several factors known to be required for general nucleotide excision repair. Genetic data indicate that both proteins of this complex are necessary for the repair of interstrand cross-links, perhaps via recombination. To determine whether XPF-ERCC1 completes a set of six proteins that are sufficient to carry out excision repair, the human XPF and ERCC1 cDNAs were coexpressed in Sf21 insect cells from a baculovirus vector. The purified complex contained the anticipated 5' junction-specific endonuclease activity that is stimulated through a direct interaction between XPF and replication protein A (RPA). The recombinant complex also complemented extracts of XP-F cells and Chinese hamster ovary mutants assigned to complementation groups 1, 4, and 11. Furthermore, reconstitution of the human excision nuclease was observed with a mixture of five repair factors (XPA, XPC, XPG, TFIIH, and RPA) and the recombinant XPF-ERCC1, thus verifying that no additional protein factors are needed for the specific dual incisions characteristic of human excision repair.
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PMID:Reconstitution of human excision nuclease with recombinant XPF-ERCC1 complex. 901 42

During nucleotide excision repair in human cells, a damaged DNA strand is cleaved by two endonucleases, XPG on the 3' side of the lesion and ERCC1-XPF on the 5' side. These structure-specific enzymes act at junctions between duplex and single-stranded DNA. ATP-dependent formation of an open DNA structure of approximately 25 nt around the adduct precedes this dual incision. We investigated the mechanism of open complex formation and find that mutations in XPB or XPD, the DNA helicase subunits of the transcription and repair factor TFIIH, can completely prevent opening and dual incision in cell-free extracts. A deficiency in XPC protein also prevents opening. The absence of RPA, XPA or XPG activities leads to an intermediate level of strand separation. In contrast, XPF or ERCC1-defective extracts open normally and generate a 3' incision, but fail to form the 5' incision. This same repair defect was observed in extracts from human xeroderma pigmentosum cells with an alteration in the C-terminal domain of XPB, suggesting that XPB has an additional role in facilitating 5' incision by ERCC1-XPF nuclease. These data support a mechanism in which TFIIH-associated helicase activity and XPC protein catalyze initial formation of the key open intermediate, with full extension to the cleavage sites promoted by the other core nucleotide excision repair factors. Opening is followed by dual incision, with the 3' cleavage made first.
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PMID:Mechanism of open complex and dual incision formation by human nucleotide excision repair factors. 935 36

Nucleotide excision repair in humans is a complex reaction involving 14 polypeptides in six repair factors for dual incisions on either sides of a DNA lesion. To identify the reaction intermediates that form by the human excision repair nuclease, we adopted three approaches: purification of functional DNA.protein complexes, permanganate footprinting, and the employment as substrate of presumptive DNA reaction intermediates containing unwound sequences 5' to, 3' to, or encompassing the DNA lesion. The first detectable reaction intermediate was formed by substrate binding of XPA, RPA, XPC.HHR23B plus TFIIH (preincision complex 1, PIC1). In this complex the DNA was unwound on either side of the lesion by no more than 10 bases. Independent of the XPG nuclease function, the XPG protein stabilized this complex, forming a long lived preincision complex 2 (PIC2). The XPF.ERCC1 complex bound to PIC2, forming PIC3, which led to dual incisions and the release of the excised oligomer. With partially unwound DNAs, thymine cyclobutane dimer was excised at a fast rate independent of XPC.HHR23B, indicating that a major function of this protein is to stabilize the unwound DNA or to aid lesion unwinding in preincision complexes.
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PMID:Characterization of reaction intermediates of human excision repair nuclease. 936 Sep 69

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.
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PMID:DNA damage recognition during nucleotide excision repair in mammalian cells. 1021 8

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