Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UMLS:C0043346 (xeroderma pigmentosum)
2,924 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

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.
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PMID:Suppression of UV-induced apoptosis by the human DNA repair protein XPG. 1616 68

Mitomycin C (MMC) induces various types of DNA damages that cause significant cytotoxicity to cells. Accordingly, repair of MMC-induced damages involves multiple repair pathways such as nucleotide excision repair, homologous recombination repair and translesion bypass repair pathways. Nonetheless, repair of the MMC-induced DNA damages in mammals have not been fully delineated. In this study, we investigated potential roles for Xeroderma pigmentosum (XP) proteins in the repair of MMC-induced DNA damages using an assay that detects the ssDNA patches generated following treatment with MMC or 8'-methoxy-psoralen (8-MOP) + UVA (ultraviolet light A). Human wild-type cells formed distinctive ssDNA foci following treatment with MMC or 8-MOP + UVA, but not with those inducing alkylation damage, oxidative damage or strand-break damage, suggesting that the foci represent ssDNA patches formed during the crosslink repair. In contrast to wild-type cells, mutant defective in XPE orXPG did not form the ssDNA foci following MMC treatment, while XPF mutant cells showed a significantly delayed response in forming the foci. A positive role for XPG in the repair of MMC-induced DNA damages was further supported by observations that cells treated with MMC induced a tight association of XPG with chromatin, and a targeted inhibition of XPG abolished MMC-induced ssDNA foci formation, rendering cells hypersensitive to MMC. Together, our results suggest that XPG along with XPE and XPF play unique role(s) in the repair of MMC-induced DNA damages.
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PMID:An in vivo analysis of MMC-induced DNA damage and its repair. 1625 76

Xeroderma pigmentosum is characterized by increased sensitivity of the affected individuals to sunlight and light-induced skin cancers and, in some cases, to neurological abnormalities. The disease is caused by a mutation in genes XPA through XPG and the XP variant (XPV) gene. The proteins encoded by the XPA, -B, -C, -D, -F, and -G genes are required for nucleotide excision repair, and the XPV gene encodes DNA polymerase eta, which carries out translesion DNA synthesis. In contrast, the mechanism by which the XPE gene product prevents sunlight-induced cancers is not known. The gene (XPE/DDB2) encodes the small subunit of a heterodimeric DNA binding protein with high affinity to UV-damaged DNA (UV-damaged DNA binding protein [UV-DDB]). The DDB2 protein exists in at least four forms in the cell: monomeric DDB2, DDB1-DDB2 heterodimer (UV-DDB), and as a protein associated with both the Cullin 4A (CUL4A) complex and the COP9 signalosome. To better define the role of DDB2 in the cellular response to DNA damage, we purified all four forms of DDB2 and analyzed their DNA binding properties and their effects on mammalian nucleotide excision repair. We find that DDB2 has an intrinsic damaged DNA binding activity and that under our assay conditions neither DDB2 nor complexes that contain DDB2 (UV-DDB, CUL4A, and COP9) participate in nucleotide excision repair carried out by the six-factor human excision nuclease.
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PMID:Xeroderma pigmentosum complementation group E protein (XPE/DDB2): purification of various complexes of XPE and analyses of their damaged DNA binding and putative DNA repair properties. 1626 May 96

Epidemiological data has implicated heterozygosity for xeroderma pigmentosum (XP) as a risk factor for lung cancer. XP has 8 known complementation groups, 7 of which are caused by mutations in genes encoding components of the nucleotide excision repair (NER) pathway. To formally investigate the role of XP-related NER genes in lung cancer susceptibility, we screened germline DNA from 92 familial early-onset lung cancer patients for mutations in all coding regions and intron-exon boundaries of XPA, XPC, XPD, XPF, XPB, XPG and DDB2. Forty-one exonic variants were identified. Twenty-four were nonsynonymous, of which 14 were previously documented polymorphisms. Ten missense variants had not been previously described; none of which were detected in germline DNA from 278 cancer-free controls. Two of the novel missense changes are predicted to be functionally deleterious. Our findings are compatible with XP heterozygosity being a risk factor for lung cancer susceptibility.
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PMID:Evaluation of xeroderma pigmentosum XPA, XPC, XPD, XPF, XPB, XPG and DDB2 genes in familial early-onset lung cancer predisposition. 1655 Jun 8

Xeroderma pigmentosum (XP) is an inherited disease in which cells from patients exhibit defects in nucleotide excision repair (NER). XP proteins A-G are crucial in the processes of DNA damage recognition and incision, and patients with XP can carry mutations in any of the genes that specify these proteins. In mammalian cells, NER is a dynamic process in which a variety of proteins interact with one another, via modular domains, to carry out their functions. XP proteins are key players in several steps of the NER process, including DNA strand discrimination (XPA, in complex with replication protein A), repair complex formation (XPC, in complex with hHR23B; XPF, in complex with ERCC1) and repair factor recruitment (transcription factor IIH, in complex with XPG). Through these protein-protein interactions, various types of bulky DNA adducts can be recognized and repaired. Communication between the NER system and other cellular pathways is also achieved by selected binding of the various structural domains. Here, we summarize recent studies on the domain structures of human NER components and the regulatory networks that utilize these proteins. Data provided by these studies have helped to illuminate the complex molecular interactions among NER factors in the context of DNA repair.
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PMID:The protein shuffle. Sequential interactions among components of the human nucleotide excision repair pathway. 1662 97

There are more than 50 subtypes of soft tissue sarcomas, among which 30% are associated with specific genetic alterations, including translocations. Several studies have reported associations between cancer risk and polymorphisms of DNA repair genes from the nucleotide excision repair (NER) pathway. NER involves more than 20 proteins whose inactivation leads to xeroderma pigmentosum (XP) or cockayne syndrome (CS), among which XPD, a helicase allowing DNA strand excision by the endonuclease XPG. DNA from 93 patients with synovial sarcomas, myxoid liposarcomas, dermatofibrosarcomas protuberans (DFSP), malignant fibrous histiocytomas and leiomyosarcomas were genotyped for both XPD Lys751Gln and XPG Asp1104His polymorphisms. Departure from Hardy-Weinberg was highly significant for the XPG polymorphism with an excess of heterozygotes in synovial sarcomas (p = 1.5 x 10(-5)), myxoid liposarcomas (p = 1.5 x 10(-4)) and to a lesser extent in DFSP (p = 0.028). In the case of XPD, a significant deviation was observed in synovial sarcomas (p = 3 x 10(-6)) and DFSP (p = 0.0014). When tumors were pooled according to their genetic alterations, the proportion of carriers of the variant XPG allele was significantly increased in sarcomas with specific translocations as compared to sarcomas with complex genetics (p < 10(-9)). No difference was found for XPD. Genotyping of the tumor samples in synovial sarcomas and myxoid liposarcomas revealed frequent loss of heterozygosity for XPG, mostly due to the loss of the frequent allele. For XPD, both alleles were lost with a similar frequency. Our results raise the potential implication of the XPG Asp1104His polymorphism in the occurrence of chromosomal translocations associated with specific subtypes of sarcomas.
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PMID:Genetic polymorphisms of the XPG and XPD nucleotide excision repair genes in sarcoma patients. 1664 69

Several mouse models with defects in genes encoding components of the nucleotide excision repair (NER) pathway have been developed. In NER two different sub-pathways are known, i.e. transcription-coupled repair (TC-NER) and global-genome repair (GG-NER). A defect in one particular NER protein can lead to a (partial) defect in GG-NER, TC-NER or both. GG-NER defects in mice predispose to cancer, both spontaneous as well as UV-induced. As such these models (Xpa, Xpc and Xpe) recapitulate the human xeroderma pigmentosum (XP) syndrome. Defects in TC-NER in humans are associated with Cockayne syndrome (CS), a disease not linked to tumor development. Mice with TC-NER defects (Csa and Csb) are - except for the skin - not susceptible to develop (carcinogen-induced) tumors. Some NER factors, i.e. XPB, XPD, XPF, XPG and ERCC1 have functions outside NER, like transcription initiation and inter-strand crosslink repair. Deficiencies in these processes in mice lead to very severe phenotypes, like trichothiodystrophy (TTD) or a combination of XP and CS. In most cases these animals have a (very) short life span, display segmental progeria, but do not develop tumors. Here we will overview the available NER-related mouse models and will discuss their phenotypes in terms of (chemical-induced) tissue-specific tumor development, mutagenesis and premature aging features.
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PMID:Tissue specific mutagenic and carcinogenic responses in NER defective mouse models. 1676 89

DNA damage can lead to either DNA repair with cell survival or to apoptotic cell death. Although the biochemical processes underlying DNA repair and apoptosis have been extensively studied, the mechanisms by which cells determine whether the damage will be repaired or the apoptotic pathway will be activated is largely unknown. We have studied the role of nucleotide excision repair (NER) in cisplatin DNA damage-induced apoptotic cell death using both normal human fibroblasts and NER-defective xeroderma pigmentosum (XP) XPA and XPG cells. The caspase-3 activation experiment demonstrated a greatly increased casapse-3 activation in the NER-defective cells following cisplatin treatment. The flow cytometry experiment revealed an altered cell cycle arrest pattern of the NER-defective cells following cisplatin treatment. The results obtained from the Western blot experiment showed that NER defects resulted in enhanced CHK1 phosphorylation and p21 induction after cisplatin treatment. The cisplatin treatment-induced ATM phosphorylation, however, was attenuated in NER-defective cells. The results obtained from our immunoprecipitation experiment further demonstrated that the ATM protein interacted with the TFIIH basal transcription factor and the XPG protein of the NER pathway. It also showed that a functional XPC protein was required for the association of the ATM protein to genomic DNA. These results suggest that the NER process may prevent the cisplatin treatment-induced apoptosis by activating the ATM protein, and that the presence of the XPC protein is essential for recruiting the ATM protein to the DNA template.
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PMID:The involvement of ataxia-telangiectasia mutated protein activation in nucleotide excision repair-facilitated cell survival with cisplatin treatment. 1684 32

Interindividual differences in DNA repair capacity (DRC) may play a critical role in breast cancer risk. Previously, we determined that DRC measured via removal of in vitro-induced benzo[a]pyrene diolepoxide-DNA adducts in lymphoblastoid cell lines was lower in cases compared with controls among sisters discordant for breast cancer from the Metropolitan New York Registry of Breast Cancer Families. We have now determined genotypes for seven single nucleotide polymorphisms in five nucleotide excision repair genes, including Xeroderma pigmentosum complementation group A (XPA +62T>C), group C (XPC Lys939Gln and Ala499Val), group D (XPD Asp312Asn and Lys751Gln), and group G (XPG His1104Asp) and ERCC1 (8092 C>A) in a total of 160 sister pairs for whom DRC phenotype data were available. Overall, there were no statistically significant differences in average DRC for most of the genotypes. A final multivariate conditional logistic model, including three single nucleotide polymorphisms (XPA +62T>C, XPC Ala499Val, and XPG His1104Asp) and smoking status, only modestly predicted DRC after adjusting for case-control status and age of blood donation. The overall predictive accuracy was 61% in the model with a sensitivity of 78% and specificity of 39%. These findings suggest that those polymorphisms we have investigated to date in nucleotide excision repair pathway genes explain only a small amount of the variability in DRC.
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PMID:Polymorphisms in nucleotide excision repair genes and DNA repair capacity phenotype in sisters discordant for breast cancer. 1698 21

Since arsenite is known to induce oxidative DNA damage in human cells, we asked if it induces other types of DNA damage and how the DNA damage is repaired. Treatment of human promyelocytic leukemia NB4 cells with 0.5muM As(2)O(3) for 30 min induced no DNA breaks, as analyzed by a standard comet assay. However, breaks were detected if these cells were then digested with endonuclease III (EnIII), formamidopyrimidine-DNA glycosylase (Fpg), or a nuclear extract (NE) of NB4 cells. Using either H(2)O(2)-Fe-treated nuclei or As(2)O(3)-treated cells, digestion with either NE or EnIII + Fpg generated the same amount of breaks, and subsequent treatment with EnIII + Fpg resulted in no increase in breaks in NE-digested cells and vice versa. The human cell lines, defective in nucleotide excision protein, such as xeroderma pigmentosum (XP) A, XPD, and XPG, excised Ultraviolet C-induced adducts less rapidly than normal fibroblasts, but excised As(2)O(3) adducts at the same rate as the normal cells. Immunodepletion of the NE with antibody against 8-oxoguanine DNA glycosylase (OGG1) or MutY homolog (MYH) decreased the incision of As(2)O(3)-induced adducts, while antibodies against XPA, XPB, XPD, XPF, or XPG, did not. These results suggest that As(2)O(3) induces the formation of only oxidative DNA adducts and that OGG1 and MYH are involved in this incision process.
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PMID:8-Oxoguanine DNA glycosylase and MutY homolog are involved in the incision of arsenite-induced DNA adducts. 1710 20


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