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

Cellular capacity for postreplication repair (PRR) and sensitivity to transformation to anchorage independence (AI) were quantified in normal foreskin and xeroderma pigmentosum (XP) variant fibroblasts after treatment with UV or benzo(a)pyrene-diol-epoxide I (BPDE-I). PRR is defined here as a collection of pathways that facilitate the replication of DNA damaged by genotoxic agents. It is recognized biochemically as the process by which nascent DNA grows longer than the average distance between two lesions in the DNA template. PRR refers more directly to the elimination of gaps in the daughter-strand DNA by mechanisms which remain to be determined for human cells, but which may include translesion replication and recombination. PRR was measured in diploid human fibroblasts by analysis of the dose kinetics for inhibition of DNA strand growth in carcinogen-treated cells. Logarithmically growing foreskin fibroblasts (NHF1) displayed D0 values of 4.3 J/m2 and 0.14 microM for the inhibition of DNA synthesis in active replicons by UV and BPDE-I, respectively. XP variant cells (CRL1162) exhibited corresponding D0 values of 1.5 J/m2 and 0.16 microM. The increased sensitivity to inhibition of DNA replication by UV in these XP variant fibroblasts (2.9-fold greater than normal) was mirrored by an enhanced frequency of transformation to AI. XP variant fibroblasts (CRL1162) were 3.2 times more sensitive to transformation to AI by UV than were the normal foreskin fibroblasts. As predicted by the PRR studies, both cell types exhibited similar frequencies of AI colonies induced by BPDE-I. Apparent thresholds were observed for induction of AI by UV (normal fibroblasts, 2.7 J/m2; XP variant fibroblasts, 0.3 J/m2) and BPDE-I (both, 0.05 microM). Doses of UV and BPDE-I above these thresholds produced proportional increases in the inhibition of DNA replication in operating replicons and in the induced frequency of anchorage-independent colonies. At doses of UV and BPDE-I that produced the same degree of inhibition of DNA strand growth, BPDE-I induced a greater number of cells capable of anchorage-independent growth than did UV in both normal and XP variant fibroblasts.
Cancer Res 1991 Jun 01
PMID:Role of postreplication repair in transformation of human fibroblasts to anchorage independence. 190 28

Xeroderma pigmentosum is a very rare precancerous skin disease that is triggered by sunlight. It is caused by a defect in the DNA repair system and causes benign and malignant transformations. Only eye tissues that come into contact with UV light are affected, such as the lids, conjunctiva and cornea. We describe a patient who suffered from xeroderma pigmentosum type C, showing the typical skin alterations but no sign of malignancy. A perforating keratoplasty was performed on both eyes because of the dense opacity of the corneas. The corneal buttons obtained were examined by light and transmission electron microscopy. Degeneration was found only in the basal-cell layer of the corneal epithelium. The most severe morphological changes were seen in Bowman's layer, the subepithelial stroma, Descemet's membrane and the corneal epithelium. Bowman's layer was often interrupted or replaced by a degenerative pannus, which extended into the underlaying stroma. Subepithelial "channels" were localized in the basal epithelium and protruded into the subepithelial stroma. In both corneas, Descemet's membrane contained different amounts of so-called lattice collagen, and the remaining endothelial cells in the left cornea contained numerous melanin granules.
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PMID:Histology and transmission electron microscopy of the cornea in xeroderma pigmentosum type C. 191 29

A method for measuring nucleotide excision repair in response to UV irradiation and chemical-induced DNA damage has been developed, validated, and field tested in cultured human lymphocytes. The methodology is amenable to population-based screening and should facilitate future epidemiological studies seeking to investigate associations between DNA repair proficiency and cancer susceptibility. The impetus for such endeavors derives from the suggestion that the high incidence of skin cancer in the genetic disorder xeroderma pigmentosum is manifested as a result of the reduced capacity of patients' cells to repair DNA damaged by UV-mimetic agents. For the assay, damaged, nonreplicating, recombinant plasmid DNA harboring a chloramphenicol acetyltransferase (cat) reporter gene is introduced into lymphocytes by using a DEAE-dextran/DNA complex short-term transfection conditions. Excision repair of the damaged bacterial cat gene is monitored proportionately as a function of reactivated CAT enzyme activity following a 40-h repair/expression incubation period. The validity of the approach was indicated by the ability of the assay to discriminate xeroderma pigmentosum virus-transformed lymphocyte cell lines of both severe (complementation groups A and D) and moderate (complementation group C) excision repair deficiencies from repair-proficient cell lines. Similar results were observed when a mitogen-stimulated peripheral blood lymphocyte culture from an xeroderma pigmentosum A patient was assayed concurrently with mitogen-stimulated peripheral blood lymphocytes obtained from healthy individuals. Adaptation of this DNA repair assay as a field test in a pilot-tested select group of basal cell carcinoma patients and cancer-free controls led to the preliminary identification of a specific subset at risk for this disease as a consequence of significant reduction to the repair of photochemically (UV)-damaged plasmid DNA.
Cancer Res 1991 Nov 01
PMID:Development and field-test validation of an assay for DNA repair in circulating human lymphocytes. 193 49

Complementation group A of xeroderma pigmentosum (XP) represents one of the most prevalent and serious forms of this cancer-prone disorder. Because of a marked defect in DNA excision repair, cells from individuals with XP-A are hypersensitive to the toxic and mutagenic effects of ultraviolet light and many chemical agents. We report here the isolation of the XP-A DNA repair protein by complementation of cell extracts from a repair-defective human XP-A cell line. XP-A protein purified from calf thymus migrates on denaturing gel electrophoresis as a doublet of 40 and 42 kilodaltons. The XP-A protein binds preferentially to ultraviolet light-irradiated DNA, with a preference for damaged over nondamaged nucleotides of approximately 10(3). This strongly suggests that the XP-A protein plays a direct role in the recognition of and incision at lesions in DNA. We further show that this protein corresponds to the product encoded by a recently isolated gene that can restore excision repair to XP-A cells. Thus, excision repair of plasmid DNA by cell extracts sufficiently resembles genomic repair in cells to reveal accurately the repair defect in an inherited disease. The general approach described here can be extended to the identification and isolation of other human DNA repair proteins.
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PMID:Complementation of DNA repair in xeroderma pigmentosum group A cell extracts by a protein with affinity for damaged DNA. 193 10

The human XPBC/ERCC-3 was cloned by virtue of its ability to correct the excision repair defect of UV-sensitive rodent mutants of complementation group 3. The gene appeared to be in addition implicated in the human, cancer prone repair disorder xeroderma pigmentosum group B, which is also associated with Cockayne's syndrome. Here we present the genomic architecture of the gene and its expression. The XPBC/ERCC-3 gene consists of at least 14 exons spread over approximately 45 kb. Notably, the donor splice site of the third exon contains a GC instead of the canonical GT dinucleotide. The promoter region, first exon and intron comprise a CpG island with several putative GC boxes. The promoter was confined to a region of 260 bp upstream of the presumed cap site and acts bidirectionally. Like the promoter of another excision repair gene, ERCC-1, it lacks classical promoter elements such as CAAT and TATA boxes, but it shares with ERCC-1 a hitherto unknown 12 nucleotide sequence element, preceding a polypyrimidine track. Despite the presence of (AU)-rich elements in the 3'-untranslated region, which are thought to be associated with short mRNA half-life actinomycin-D experiments indicate that the mRNA is very stable (t 1/2 greater than 3h). Southern blot analysis revealed the presence of XPBC/ERCC-3 cross-hybridizing fragments elsewhere in the genome, which may belong to a related gene.
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PMID:Structure and expression of the human XPBC/ERCC-3 gene involved in DNA repair disorders xeroderma pigmentosum and Cockayne's syndrome. 195 89

Mutations have been studied for several decades in order to understand biological processes of great significance and the selection of better-adapted species. Our knowledge both of mutation spectra induced by genotoxic agents and the mechanisms involved in DNA damage processing is more advanced in bacteria than in animal cells. However, the use of new technologies such as shuttle vectors or the polymerase chain reaction will undoubtedly allow rapid progress in the next few years. Shuttle vectors consist of target sequences for monitoring mutagenic activity and additional sequences permitting DNA replication and selection, both in bacteria and in mammalian cells. These plasmids are very efficient in allowing the production of mutation spectra of a particular genotoxin in animal cells. In most cases, base substitutions occur predominantly at the sites of base damage and the type of substitution depends on the kind of damage. This has been well characterized using ultraviolet (UV) light as a mutagen. UV-induced mutations are targeted opposite pyrimidine-pyrimidine sites, where the two major UV lesions are produced. The direct relationships existing between mutation and cancer are exemplified by some hereditary diseases where deficiency in an enzymatic repair system is linked to a high incidence of tumours. Similarly, activation of some cellular proto-oncogenes occurs via specific point mutations. A correlation does exist between the mutation spectra found in model systems and the specific mutation found in the activated oncogene in tumours induced by a given genotoxin. This is particularly well illustrated in the DNA repair deficiency syndrome, xeroderma pigmentosum. The specific mutations found in activated ras oncogenes isolated from UV-stimulated skin tumours correlate well with the mutagenic properties of unrepaired UV-induced DNA lesions.
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PMID:Mechanisms and consequences of mutation induction in mammalian cells. 196 99

Chromosome analysis was carried out in cultured fibroblasts from unaffected skin of five unrelated xeroderma pigmentosum (XP) patients and nine family members. Structural chromosome changes were observed in cultures from all examined individuals. Furthermore, in one XPD patient and in one XPC patient and his parents, cytogenetically abnormal clones were detected. Some of these clones were present starting from the primary explant. This cytogenetic pattern is similar to that observed in an XPC patient previously studied by us. The analysis of breakpoint distribution from clonal and non-clonal chromosome rearrangements showed that some breakpoints were more frequent and common to different families or to different family members although definite evidence of preferential involvement of chromosome bands was not obtained. This investigation indicates that there is a consistent tendency toward chromosome instability in XP mutation carriers. The instability could be related to the multiple chromosome anomalies characterizing skin tumors in XP subjects.
Cancer Genet Cytogenet 1991 Jan
PMID:Chromosome rearrangements in normal fibroblasts from xeroderma pigmentosum homozygotes and heterozygotes. 198 53

In order to examine possible cell-type specificity in mutagenic events, a shuttle-vector plasmid, pZ189, carrying a bacterial suppressor tRNA marker gene, was treated with ultraviolet radiation and propagated in Epstein-Barr virus transformed lymphoblastoid cell lines from a patient, XP12BE, with xeroderma pigmentosum (XP), group A, and a normal control. XP is a skin-cancer-prone disorder with UV hypersensitivity and defective DNA repair. Plasmid survival and mutations inactivating the marker gene were scored by transforming an indicator strain of E. coli. An earlier report on this data [Seetharam et al., (1990) J. Mol. Biol., 212, 433] indicated lower survival and higher mutation frequency with the UV-treated plasmid passed through the XP12Be(EBV) line. In the present report, sequence analysis of 198 mutant plasmids revealed a predominance of G:C----A:T transitions with both lymphoblastoid cell lines. This finding is consistent with the bias of polymerases toward insertion of an adenine opposite non-coding photoproducts (dinucleotides or other lesions). Transversion mutagenesis, non-adjacent double mutations, and triple-base mutations may involve other mechanisms. These results were compared to similar data from a fibroblast line from the same patient [Bredberg et al., (1986) Proc. Natl. Acad. Sci. (U.S.A.), 83, 8273]. The frequency of G:C----A:T transitions was higher, and there were fewer plasmids with multiple-base substitutions and with transversion mutations with both XP lymphoblasts and fibroblasts than with the normal lymphoblasts and fibroblasts. There were no significant differences in classes or types of mutations in the UV-treated plasmid replicated in the XP lymphoblasts and the XP fibroblasts. This suggests that the major features of UV mutagenesis in different cell types from the same individual are similar.
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PMID:Ultraviolet mutational spectrum in a shuttle vector propagated in xeroderma pigmentosum lymphoblastoid cells and fibroblasts. 198 77

The contribution of DNA damage to the effects of 193-nm excimer laser radiation on mammalian cells in culture was studied in order to evaluate the mutagenic potential of this UV wavelength in vivo. Two approaches were taken: measurement of pyrimidine dimer-specific endonuclease-sensitive sites/megabase and comparison of the 193-nm radiation-induced cytotoxicity in normal versus DNA repair-deficient cells. The formation of pyrimidine dimer-specific endonuclease-sensitive sites/megabase was inversely related to the thickness of the cytoplasm overlying the nuclei of normal human fibroblasts (NHF) and Chinese hamster ovary cells. The results of these measurements and a calculation of the absorption coefficient of cytoplasm indicate that each 1 micron of cytoplasm attenuates the incident radiation by greater than 90% and, therefore, the nuclear DNA in tissue will be highly protected from 193-nm radiation by overlying cytoplasm. The reduction in colony-forming ability induced by 254-nm, 193-nm, and X-ray radiation was measured in NHF, xeroderma pigmentosum (group A) cells, and ataxia telangiectasia cells. Xeroderma pigmentosum (group A) cells were 16.5 times more sensitive to 254-nm radiation but only 3.5 times more sensitive to 193-nm radiation than NHF cells, indicating that cyclobutylpyrimidine dimers were not the major lethal lesion formed at 193 nm. AT cells were 3.4 times more sensitive to X-rays than NHF cells, but these cell types were almost equally sensitive to 193-nm radiation, indicating that 193 nm did not induce the same type of lethal lesions as X-rays.
Cancer Res 1991 Jan 01
PMID:DNA damage induced by 193-nm radiation in mammalian cells. 198 91

Overall genomic DNA repair efficiencies do not necessarily correlate with cellular sensitivities to radiation and other DNA-damaging agents. My colleagues and I have developed experimental approaches to measure DNA lesions and their repair in defined DNA sequences and we have discovered that for some types of damage, such as the cyclobutane pyrimidine dimers produced in DNA by ultraviolet light (UV), repair is highly selective for transcribed DNA strands in active genes: repair may be directly coupled to the transcription apparatus. Freely diffusing repair complexes may account for the much lower repair efficiencies observed in silent genomic domains. The viability of mammalian cells may be ensured through selective repair of transcription-blocking DNA damage in essential, expressed genes rather than as a consequence of overall genomic repair. Persisting damage in non-transcribed domains may account for some cell-specific mutagenic and carcinogenic phenomena. In UV-irradiated cells from xeroderma pigmentosum (complementation group C) there is a deficiency in the removal of pyrimidine dimers from silent genomic domains, while in Cockayne's syndrome the defect appears to involve the preferential repair of active genes. In contrast to the cancer-prone characteristic of xeroderma pigmentosum the victims of Cockayne's syndrome do not suffer enhanced skin cancer induction by sunlight. Susceptibility to cancer and other biological endpoints is clearly dependent upon the fine structure detail of the DNA repair response.
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PMID:Heterogeneity of DNA repair at the gene level. 201 Nov 38

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