UNIPROT:P04637 - FACTA Search

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Query: UNIPROT:P04637 (p53)
77,613 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The mutagenic spectrum induced by aflatoxin-DNA lesions in DNA repair deficient and repair proficient human cells was investigated. The reactive metabolite aflatoxin B1-8,9-epoxide was synthesized and reacted in vitro with the shuttle vector plasmid pS189. Plasmids were transfected into human fibroblasts and allowed to replicate, and the recovered plasmids were screened in indicator bacteria for plasmid survival and mutations in the supF marker gene. Sequence data were obtained from 71 independently arising mutants recovered from DNA repair deficient xeroderma pigmentosum (XP) cells [XP12BE(SV40)] and 60 mutants recovered from a DNA repair proficient cell line (GM0637). Plasmid survival was lower and mutation frequency higher with the XP cells, and the mutation hotspots differed substantially for the 2 cell lines. Most mutations (> 90%) were base substitutions at G:C pairs, only about one-half of which were G:C-->T:A transversions, the expected predominant mutation. One-third of the mutations at GG sites and none of those at isolated Gs were G:C-->A:T transitions. Tandem base substitutions also occurred only at GG sites and were found only with XP cells. The location of mutation hotspots with either cell line did not correlate with the level of modification within the sequence as assessed by a DNA polymerase stop assay. These results suggest that the DNA repair deficiency associated with XP can influence not only the overall frequency of mutations but also the distribution of mutations within a gene. The finding of transition mutations exclusively at GG sites may be of predictive value in attempts to link dietary aflatoxin exposure to cancers associated with specific mutations in the c-ras oncogene and the p53 tumor suppressor gene.
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PMID:Sequence specificity of aflatoxin B1-induced mutations in a plasmid replicated in xeroderma pigmentosum and DNA repair proficient human cells. 139 91

We have established and characterized an immortalized xeroderma pigmentosum (XP), group C, cell line. Transformation of the human fibroblasts was carried out with a recombinant plasmid, pLAS-wt, containing SV40 DNA encompassing the entire early region with a defective origin of DNA replication. The transformed XP cell line, XP4PA-SVwt, and the normal transformed fibroblasts AS3-SVwt, both express SV40 T antigen together with enhanced levels of the transformation-associated cellular protein, p53. XP4PA-SVwt retains the XP UV-repair defective phenotype as demonstrated by low levels of unscheduled DNA synthesis and by the reduced survival of irradiated SV40 virus. Analysis of cellular DNA shows a single major, stable, integration site of pLAS-wt in the XP4PA-SVwt cells. The T antigen in these cells supports efficiently the replication of SV40 based shuttle vectors and should prove suitable for the introduction, expression and selection of genes related to DNA repair and to the study of mutagenesis using defined molecular probes.
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PMID:An immortalized xeroderma pigmentosum, group C, cell line which replicates SV40 shuttle vectors. 302 84

Size separation after UV-endonuclease digestion of DNA from UV-irradiated human cells using denaturing conditions fractionates the genome based on cyclobutane pyrimidine dimer content. We have examined the largest molecules available (50-80 kb; about 5% of the DNA) after fractionation and those of average size (5-15 kb) for content of some specific genes. We find that the largest molecules are not a representative sampling of the genome. Three contiguous genes located in a G+C-rich isochore (tyrosine hydroxylase, insulin, insulin-like growth factor II) have concentrations two to three times greater in the largest molecules. This shows that this genomic region has fewer pyrimidine dimers than most other genomic regions. In contrast, the beta-actin genomic region, which has a similar G+C content, has an equal concentration in both fractions as do the p53 and beta-globin genomic regions, which are A+T-rich. These data show that DNA damage in the form of cyclobutane pyrimidine dimers occurs with different probabilities in specific isochores. Part of the reason may be the relative G+C content, but other factors must play a significant role. We also report that the transcriptionally inactive insulin region is repaired at the genome-overall rate in normal cells and is not repaired in xeroderma pigmentosum complementation group C cells.
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PMID:Identification of a large genomic region in UV-irradiated human cells which has fewer cyclobutane pyrimidine dimers than most genomic regions. 748 Jan 36

In a molecular epidemiological study of DNA repair, host reactivation assay was used to measure the DNA repair capacity of cryopreserved lymphocytes from 88 primary basal cell carcinoma (BCC) patients and 135 cancer-free controls. In this study population, reduced repair of ultraviolet radiation-induced DNA damage contributed to the risk of sunlight-induced BCC. A family history of BCC is associated with low DNA repair. Repair of ultraviolet radiation-damaged DNA declines at a rate of approximately 1%/year in noncancerous controls. Reduced DNA repair is more likely seen in young BCC patients, indicating that BCC is a premature aging disease of the skin. The persistence of photochemical damage because of reduced repair results in point mutations in the p53 gene and allelic loss of the nevoid BCC gene located on chromosome 9q. Xeroderma pigmentosum appears to be a valid paradigm for the role of DNA repair in BCC in the general population.
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PMID:DNA repair and epidemiology of basal cell carcinoma. 749 45

The tumour suppressor gene, p53, has proved to be one of the genes most often modified in human cancers. These alterations consist mainly of point mutations located in the evolutionarily conserved sequences which render the protein inactive for its normal biological functions. In fact the p53 gene presents nearly 300 potential mutation sites whose analysis should enable the correlation of specific mutation spectra with different causal agents in cancer development. In this study we have analysed the mutation spectrum of the p53 gene in skin tumours from normal individuals and repair-deficient xeroderma pigmentosum (XP) patients in comparison with mutations found in internal cancers. Point mutations are mainly GC-->AT transitions in skin tumours (74% in non-XP, 87% in XP), and also to a lesser extent in internal tumours (47%) where, however, they are mainly located at CpG (63%) sequences probably due to the deamination of the unstable 5-MeC. Moreover, mutations are targeted at py-py sequences in over 90% of skin tumours whereas the distribution of mutations in internal malignancies is proportional to the frequency of py-py sites (61%) and other sequences (39%) at mutable sites. Indeed, in XP skin tumours 100% of the mutations are targeted at py-py sequences and 55% of these are tandem CC-->TT transitions considered as a signature of UV-induced lesions. In skin tumours from normal individuals, 14% of the p53 mutations are double mutations and as in XP skin tumours all these are CC-->TT transitions. In contrast, internal tumours rarely contain tandem mutations (0.8%), and of these only 2/14 were CC-->TT transitions. Finally, nearly all (95%) of the mutations in XP are located on the non-transcribed strand while internal or non-XP skin tumours do not show this strand bias. Hence, the mutation spectrum analysed in XP skin tumours also demonstrates for the first time the existence of preferential repair in humans. In conclusion, the specificity of UV-induced p53 mutation spectra in skin tumours shows that this gene is a particularly appropriate candidate for the correlation of mutation spectra with specific damaging agents.
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PMID:Can we predict solar ultraviolet radiation as the causal event in human tumours by analysing the mutation spectra of the p53 gene? 751 18

The XPA gene was initially cloned based on the ability of its cDNA to improve survival of cells from xeroderma pigmentosum complementation group A (XP-A) patients following irradiation of the cells with UV. We used plasmid host cell reactivation assays to compare UV mutagenesis and the proficiency of DNA repair in a cell line from an XP-A patient, XP2OS(SV40), two derivative cell lines stably expressing XPA cDNAs and in a DNA repair proficient human cell line. Expression of XPA protein in XP2OS cells allowed them to repair UV-treated plasmid pRSVCAT, increasing activity of the damaged CAT marker gene > 100-fold to levels produced by similarly damaged plasmids in normal cells. Expression of the XPA protein in XP2OS cells improved replication of the UV-treated shuttle vector pSP189, increasing plasmid survival and decreasing plasmid mutation frequency to the levels measured in normal cells. The sequence locations of most mutation hotspots in the plasmid marker gene were similar for the three cell lines and the differences did not correlate with the DNA repair status of the cells. This suggests that the location of mutation hotspots is not directly influenced by DNA repair. Expression of the XPA protein did cause a shift in the types of mutations seen in the plasmid gene. In the XP2OS cells > 95% of the plasmid mutations were G:C-->A:T transition mutations. In contrast, XP2OS cells expressing XPA produced other types of mutations: three times as many transversion mutations and a 12-fold increase in mutations at A:T base pairs. Furthermore, the distribution of these types of mutations was similar to the proportions measured in normal cells. Strikingly similar patterns of transition and transversion mutations were found by examination of reports of XP and non-XP skin carcinomas containing mutations in the p53 tumor suppressor gene, suggesting that the repair status of the cells influenced mutagenesis associated with these skin cancers. Our data suggest that loss of XPA gene function may be sufficient to effect the quantitative and qualitative changes in mutagenesis associated with the large increase in skin cancers seen in XP-A patients.
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PMID:Expression of a transfected DNA repair gene (XPA) in xeroderma pigmentosum group A cells restores normal DNA repair and mutagenesis of UV-treated plasmids. 761 89

Ultraviolet (UV) irradiation emitted by the sun has been clearly implicated as a major carcinogen in the formation of skin cancers in man. Indeed, the high levels of cutaneous tumors in xeroderma pigmentosum patients (XP) who are deficient in repair of UV-induced lesions have confirmed that DNA damage produced by sunlight is directly involved in the cancer development. The tumor suppressor gene, p53, very frequently found modified in human cancers, has proved to be a perfect target gene for correlating mutation spectra with different cancer causing agents as there are nearly 300 potential mutation sites available for analysis. In a comparative analysis of p53 mutations found in internal cancers with those in skin tumours we show here that clear differences exist between the types of spectra obtained. The specificity of UV induced mutations in skin cancers is confirmed when single and tandem mutations are compared. Most of the p53 point mutations found are GC to AT transitions both in skin and internal tumors where in the latter they are located mainly at CpG sequences probably due to the deamination of the unstable 5-MeC. Moreover, mutations are targeted at py-py sequences in over 90% of skin tumors whereas in internal cancers the distribution is proportional to the frequency of bipyrimidine sequences in the p53 gene. Most significantly, all mutations found in XP skin tumors are targeted at py-py sites and more than 50% are tandem CC to TT transitions considered as veritable signatures of UV-induced lesions. Tandem mutations are also relatively common (14%) in skin tumors from normal individuals compared to their very rare occurrence in internal malignancies (0.8%). Finally, nearly all mutations observed in XP skin tumors are due to unrepaired lesions remaining on the coding strand whereas no strand bias is seen in mutation location of internal or skin tumors from normal individuals. In fact the mutation spectrum analysed in XP skin cancers has permitted the first demonstration of the existence of preferential repair in man. In conclusion, using the p53 gene as a probe it is obvious that the mutation spectra from skin tumors are very similar to those observed in UV-treated gene targets in model systems but statistically different from those described in other types of human cancer. This has allowed us to demonstrate, without ambiguity, the major role of UV-induced DNA lesions in sunlight related skin carcinogenesis.
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PMID:The specificity of p53 mutation spectra in sunlight induced human cancers. 763 32

P44 Ro (Mel) is a human malignant melanoma cell line derived from a testicular metastasis in a DNA repair deficient, xeroderma pigmentosum patient. This line harbors a N-ras gene mutated in codon 61. To investigate other cellular genes possibly contributing to the expression of its transformed phenotype, four XP44 revertant cell lines were isolated by different selection procedures and the association of the level of expression of various oncogenes (including N-ras) and tumor suppressor genes with the selection for the revertant phenotype was determined. The revertants exhibited a significant but variable degree of phenotypic reversion, according to the selective pressure to which they were submitted, and a phenotypic stability dependent on their constant maintenance in selective medium. Back-revertant lines were isolated by culturing revertant lines in control medium for several weeks. The comparison between parental, revertant and back-revertant cells has revealed that, beyond the mutation in codon 61 of N-ras, two groups of genes appear to be also implicated in the transformation process of XP44 RO (Mel) cells: one group, comprising pim A, trk, Rb and p53, whose expression is independent of the cell selection conditions; the other group, comprising Ha-ras, N-ras, neu 1, fos and met H, whose expression is more or less dependent upon such conditions. The myc gene is apparently not involved in this phenomenon. These results, besides strengthening the concept that carcinogenesis is a multigenic process, suggest that diverse mechanisms can lead to the transformed phenotype, but that these mechanisms might have some pathway(s) in common.
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PMID:Cellular genes possibly involved in the transformation process of the human melanoma cell line XP44 RO (Mel). 765

Mutations in the p53 gene were analyzed in 23 squamous cell carcinomas (SCCs) and five basal cell carcinomas from 10 xeroderma pigmentosum patients in Tunisia. Fourteen mutations were detected. Most occurred at the dipyrimidine sequences of DNA, suggesting that they were caused by ultraviolet light. A strong correlation was noted between the presence of the p53 mutations and clinical characteristics such as histology and growth of SCC. In well-differentiated grade 1 SCCs, three (27.3%) of 11 tumors had the p53 gene mutations, whereas in grade 2 and grade 3 SCCs, six (85.7%) of seven tumors had the p53 gene mutations (p < 0.05). Tumors less than 8.0 mm in diameter showed a relatively low frequency of mutation (two of 10 tumors, 20.0%), whereas most of the tumors larger than 8.1 mm (seven of eight tumors, 87.5%) had mutations of the p53 gene (p < 0.025). Multiple tumors in the same xeroderma pigmentosum patients also showed this relation. These results suggest that mutations in the p53 gene lead to the invasive and rapid-growing character of SCC.
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PMID:High prevalence of mutations in the p53 gene in poorly differentiated squamous cell carcinomas in xeroderma pigmentosum patients. 766 20

We have developed a DNA-based system, to detect mutations at restriction sites without any selection in culture. DNA is exhaustively digested with a restriction enzyme. Primers flanking a chosen site for this enzyme are used in the polymerase chain reaction (PCR). Only DNA molecules mutated at the chosen site are resistant to digestion and can serve as templates for the PCR. We have initially used this system to demonstrate the generation of mutations by ethyl methanesulphonate (EMS) at a TaqI site in the aprt gene of Chinese hamster cells, and by u.v.-C irradiation at a TaqI site in the hprt gene of human fibroblasts. In repair-deficient xeroderma pigmentosum (XP) cells the u.v.-induced mutant frequency was greatly enhanced. We have been able to detect and analyse mutations in XP cells at TaqI sites in three different genes, hprt, p53 and c-Ha-ras1. Both u.v.-C and u.v.-B irradiation have been used as mutagenic agents with both lymphoblastoid and fibroblast cells from XP patients from complementation group G. The mutant DNA molecules have been sequenced. Following u.v.-C-irradiation, the majority of mutations analysed were GC-->AT transitions, but several double and tandem mutations were also found.
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PMID:U.v.-hypermutability of xeroderma pigmentosum cells demonstrated with a DNA-based mutation system. 776 Nov 6

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