UMLS:C0043346 - FACTA Search

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

The capacity of human and other eukaryotic cells to recognize a disparate variety of damaged sites in DNA, and selectively excise and repair them, resides in a deceptively small simple protein, a 38-42 kDa zinc-finger binding protein, XPA (xeroderma pigmentosum group A), that has no inherent catalytic properties. One key to its damage-recognition ability resides in a DNA-binding domain which combines a zinc finger and a single-strand binding region which may infiltrate small single-stranded regions caused by helix-destabilizing lesions. Another is the augmentation of its binding capacity by interactions with other single-stranded binding proteins and helicases which co-operate in the binding and are unloaded at the binding site to facilitate further unwinding of the DNA and subsequent catalysis. The properties of these reactions suggest there must be considerable conformational changes in XPA and associated proteins to provide a flexible fit to a wide variety of damaged structures in the DNA.
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PMID:The DNA damage-recognition problem in human and other eukaryotic cells: the XPA damage binding protein. 935 27

With the aim to devise a long-term gene therapy protocol for skin cancers in individuals affected by the inherited autosomal recessive xeroderma pigmentosum we transferred the human DNA repair XPA, XPB/ERCC3 and XPC cDNAs, by using the recombinant retroviral vector LXSN, into primary and immortalized fibroblasts obtained from two XP-A, one XP-B (associated with Cockayne's syndrome) and two XP-C patients. After transduction, the complete correction of DNA repair deficiency and functional expression of the transgenes were monitored by UV survival, unscheduled DNA synthesis and recovery of RNA synthesis, and Western blots. The results show that the recombinant retroviruses are highly efficient vectors to transfer and stably express the human DNA repair genes in XP cells and correct the defect of DNA repair of group A, B and C. With our previous results with XPD/ERCC2, the present work extends further promising issues for the gene therapy strategy for most patients suffering from this cancer-prone syndrome.
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PMID:Retrovirus-mediated gene transfer corrects DNA repair defect of xeroderma pigmentosum cells of complementation groups A, B and C. 941 14

The human autosomal recessive disease, xeroderma pigmentosum (XP), can result from mutations in any one of seven genes, designated XPA through XPG. Of these, the XPB and XPD genes encode proteins that are subunits of a general transcription factor, TFIIH, involved in both nucleotide excision repair (NER) and initiation of mRNA transcription by RNA polymerase II. In humans, mutation of the XPB or XPD gene impairs NER, resulting in hyper-sensitivity to sunlight and greatly increased skin tumor formation. However, no transcription deficiency has been demonstrated in either XP-B or XP-D. We have employed an optimized cell-free RNA transcription assay to analyze transcription activity of XP-B and XP-D. Although the growth rate was normal, the XP-B and XP-D cells contained reduced amounts of TFIIH. Extracts prepared from XP-B and XP-D lymphoblastoid cells exhibited similar transcription activity from the adenovirus major late promoter when compared to that in extracts from normal cells. Thus, we conclude that the XP-B and XP-D lymphoblastoid cells do not have impaired RNA transcription activity. We consider the possible consequences of the reduced cellular content of TFIIH for the clinical symptoms in XP-B or XP-D patients, and discuss a 'conditional phenotype' that may involve an impairment of cellular function only under certain growth conditions.
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PMID:Competent transcription initiation by RNA polymerase II in cell-free extracts from xeroderma pigmentosum groups B and D in an optimized RNA transcription assay. 942 33

The MSSE gene predisposes to the development of multiple invasive but self-healing skin tumours (multiple self-healing squamous epitheliomata, MSSE). MSSE (previously named ESS1) was mapped to chromosome 9q by linkage analysis; haplotype analysis in families then suggested a common founder mutation and indicated that the gene lies in the interval D9S1-D9S29 (9q22-q31). Squamous cell carcinomata also develop as one of the complications of xeroderma pigmentosum, and one of the xeroderma pigmentosum genes (XPA) maps within the MSSE interval. We have investigated the hypothesis that a novel dominant mutation in XPA is responsible for MSSE. We screened the entire coding region, 3' untranslated region (UTR) and 5'UTR of XPA for germline mutations in MSSE families by single-stranded conformation polymorphism analysis and by direct DNA sequencing. No mutations were detected but a novel intragenic polymorphism was identified in the 5'UTR of XPA, in both MSSE-affected and unrelated normal individuals. This XPA polymorphism and nine new polymorphic markers that map in the MSSE region were typed in eleven MSSE families; XPA was excluded as the MSSE gene and the most likely location of MSSE was reduced to the interval between D9S197 and (D9S287, D9S1809). The Patched (PTCH) gene, which is mutated in naevoid basal cell carcinoma syndrome (NBCCS or Gorlin syndrome) lies in this interval and all MSSE families have been shown to share a common haplotype at three novel intragenic PTCH polymorphisms. Although no mutation has been detected in MSSE families, PTCH has not been excluded as the MSSE gene.
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PMID:Mapping the multiple self-healing squamous epithelioma (MSSE) gene and investigation of xeroderma pigmentosum group A (XPA) and PATCHED (PTCH) as candidate genes. 943 61

Mitomycin C (MMC) is a DNA crosslinking agent that is used in cancer chemotherapy. Unlike the DNA crosslinks formed by cisplatin or psoralen, which significantly distort the DNA helix, the MMC crosslink does not significantly disturb the B-DNA helical structure. Nonetheless, MMC interstrand crosslinks and total MMC adducts are rapidly removed in vivo. We investigated whether mammalian nuclear proteins can recognize and bind to a model 23 bp DNA duplex containing a single MMC lesion. Electrophoretic mobility shift assays identified two complexes in nuclear extracts from rodent cell lines and three complexes in human cell lines, containing proteins that appeared to specifically recognize the MMC interstrand crosslink. Nuclear extracts from normal and excision repair-defective mutant Chinese hamster ovary (CHO) cell lines, from human Xeroderma Pigmentosum (XP) complementation group A and E cell lines, and a Fanconi's Anemia cell line were also examined. The UV-20 CHO line, defective in ERCC-1, was missing one of the two rodent complexes. Two of the three human complexes were also absent in the XPA human cell line and the intensity of the third complex was significantly diminished. Based on these results, a model for MMC crosslink recognition is proposed in which ERCC-1 and XPA each participate in formation of one or more multimeric complexes on the crosslinked DNA and XPA also aids in the formation, but is not a component of a higher molecularweight multimeric complex that may contain ERCC-1.
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PMID:Binding of nuclear proteins associated with mammalian DNA repair to the mitomycin C-DNA interstrand crosslink. 946 18

It is generally presumed that xeroderma pigmentosum (XP) patients are extremely sensitive to developing UV erythema, and that they have a more than 1000-fold increased skin cancer risk. Recently established mouse models for XP can be employed to investigate the mechanism of these increased susceptibilities. In line with human data, both XPA and XPC knockout mice have been shown to have an increased susceptibility to UVB induced squamous cell carcinomas. In XPA knockouts, nucleotide excision repair of UV induced DNA photolesions is completely defective (i.e., both global genome repair and transcription coupled repair are defective). We determined the strand specific removal of cyclobutane pyrimidine dimers and pyrimidine [6-4] pyrimidone photoproducts from the p53 gene in cells from XPC knockout mice and wild-type littermates. Analogous to human XPC cells, embryonic fibroblasts from XPC knockout mice are only capable of performing transcription coupled repair of DNA photolesions. We show that these XPC knockout mice, in striking contrast to XPA knockout mice, do not have a lower minimal erythema/edema dose than their wild-type littermates. Hence, defective global genome repair appears to lead to skin cancer susceptibility, but does not influence the sensitivity to acute effects of UVB radiation, such as erythema and edema. The latter phenomena thus relate to the capacity to perform transcription coupled repair, which suggests that blockage of RNA synthesis is a key event in the development of UV erythema and edema.
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PMID:Defective global genome repair in XPC mice is associated with skin cancer susceptibility but not with sensitivity to UVB induced erythema and edema. 954 Sep 83

The rare hereditary disease xeroderma pigmentosum (XP) is clinically characterized by extreme sun sensitivity and an increased predisposition for developing skin cancer. Cultured cells from XP patients exhibit hypersensitivity to ultraviolet (UV) radiation due to the defect in nucleotide excision repair (NER), and other cellular abnormalities. Seven genes identified in the classical XP forms, XPA to XPG, are involved in the NER pathway. In view of developing a strategy of gene therapy for XP, we devised recombinant retrovirus-carrying DNA repair genes for transfer and stable expression of these genes in cells from XP patients. Results showed that these retroviruses are efficient tools for transducing XP fibroblasts and correcting repair-defective cellular phenotypes by recovering normal UV survival, unscheduled DNA synthesis, and RNA synthesis after UV irradiation, and also other cellular abnormalities resulting from NER defects. These results imply that the first step of cellular gene therapy might be accomplished successfully.
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PMID:Retrovirus-mediated DNA repair gene transfer into xeroderma pigmentosum cells: perspectives for a gene therapy. 955 21

Xeroderma pigmentosum (XP) patients with a defect in the nucleotide excision repair gene XPA, develop tumors with a high frequency on sun-exposed areas of the skin. Here we describe that hairless XPA-deficient mice also develop skin tumors with a short latency time and a 100% prevalence after daily exposure to low doses of U.V.B. Surprisingly and in contrast to U.V.B.-exposed repair proficient hairless mice who mainly develop squamous cell carcinomas, the XPA-deficient mice developed papillomas with a high frequency (31%) at a U.V. dose of 32 J/m2 daily. At the highest daily dose of 80 J/m2 mainly squamous cell carcinomas (56%) and only 10% of papillomas were found in XPA-deficient hairless mice. p53 gene mutations were examined in exons 5, 7 and 8 and were detected in only 3 out of 37 of these skin tumors, whereas in tumors of control U.V.B.-irradiated wild type littermates this frequency was higher (45%) and more in line with our previous data. Strikingly, a high incidence of activating ras gene mutations were observed in U.V.B.-induced papillomas (in 11 out of 14 tumors analysed). In only two out of 14 squamous cell carcinomas we found similar ras gene mutations. The observed shift from squamous cell carcinomas in wild type hairless mice to papillomas in XPA-deficient hairless mice, and a corresponding shift in mutated cancer genes in these tumors, provide new clues on the pathogenesis of chemically- versus U.V.B.-induced skin carcinogenesis.
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PMID:XPA-deficiency in hairless mice causes a shift in skin tumor types and mutational target genes after exposure to low doses of U.V.B. 961 29

Xeroderma pigmentosum (XP) patients are hypersensitive to sunlight and have a high predisposition to developing cancer. At the cellular level, XP patients are defective in nucleotide excision repair (NER). Recently, mice have been generated via gene targeting that are deficient in the expression of the XPA gene [A. de Vries et al., Nature (Lond.), 377: 169-173, 1995]. We have assessed the consequences of defective NER for mutagenesis in normal and XPA mice exposed to benzo(a)pyrene and 2-acetylaminofluorene. To study mutagenesis, mature T lymphocytes were isolated from the spleen and stimulated to proliferate in vitro to select for mutants at the endogenous Hprt locus. Background mutant frequencies in normal and XPA mice were very similar and not influenced by age. Single doses of benzo(a)pyrene administered i.p. resulted in a dose-dependent increase of the Hprt mutant frequency in normal mice. In addition, after chronic exposure to benzo(a)pyrene, Hprt mutants were readily detectable in XPA mice at an early onset of treatment but only at a later stage in normal mice. In contrast, chronic treatment of either normal or XPA mice with 2-acetylaminofluorene did not increase Hprt mutant frequency above the background frequency. This absence of significant induction of Hprt mutants can be entirely attributed to the low frequency of 2-acetylaminofluorene-induced DNA adducts in lymphoid tissue. These results provide the first direct evidence in mammals that deficient NER leads to enhanced mutagenesis in endogenous genes in internal tissue after exposure to relevant environmental mutagens, such as benzo(a)pyrene.
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PMID:Elevated frequencies of benzo(a)pyrene-induced Hprt mutations in internal tissue of XPA-deficient mice. 966 1

A series of xeroderma pigmentosum group A cell lines from 19 patients and cell lines from 13 other family members were examined for XPA mutations to find previously unidentified mutations from American and European patients, to establish pedigrees in represented families, and to develop a database for XPA diagnosis. Most mutations were deletions and splice site mutations observed previously in other XPA patients, in exon III, intron III, or exon IV, that resulted in frameshifts within the DNA binding region-including an Afl III RFLP (G to C) in four unrelated families. One new mutation was a point mutation within intron III (A to G) creating a new splice acceptor site that may compete with the original splice acceptor site. Missplicing at this new site inserts 11 nucleotides in the mRNA creating a frameshift. A small amount of normal splicing to give wild-type XPA protein is the likely molecular mechanism for the relatively mild clinical features of this patient. In another patient, a new 2 bp deletion in the RPA70 binding region was identified in the same region as a 20 bp deletion previously characterized in an unrelated patient. Mutations in the DNA binding region of XPA were from patients with the more severe disease often associated with neurological complications, whereas mutations in the C-terminal end of the protein, which interacts with the TFIIH transcription factor, were from patients with milder skin disease only. The rarity of naturally occurring missense mutations in the DNA binding region of XPA suggests that amino acid changes might be sufficiently tolerated that patients would have mild symptoms and escape detection.
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PMID:Distribution of mutations in the human xeroderma pigmentosum group A gene and their relationships to the functional regions of the DNA damage recognition protein. 967 Dec 71

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