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 deficiencies of nucleotide excision repair (NER) factors are genetic diseases, xeroderma pigmentosum (XP) increasing risk of developing cancer on sun-exposed areas of the skin. However, the abnormality of NER factors in human sporadic carcinoma remains unclear. Loss of heterozygosity (LOH) analysis for the XP, XPA, XPB, XPC, XPD, XPE, XPF, XPG and the transcription-coupled repair factor, Cockayne syndrome B (CSB) revealed that NER factors were abnormal in 62.1 % of ovarian tumors (18/29), 16.7% of colon (2/12) and 22.2% lung (2/9) carcinomas. Furthermore, 13.8% of ovarian, 8.3% of colon and 22% of lung carcinomas exhibited LOH for NER factors without LOH for tumor suppressor genes such as p53, FHIT, APC, BRCAI, BRCA2 and DCC. Although both microsatellite instability and LOH of NER factors were observed in some cases, there was no strong association between them in the present study. These observations raise the possibility that alterations of NER factors may be frequent in human sporadic carcinomas. Further study should be needed to find the direct evidence of NER gene abnormalities in human sporadic carcinoma tissues.
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PMID:Loss of heterozygosity of nucleotide excision repair factors in sporadic ovarian, colon and lung carcinomas: implication for their roles of carcinogenesis in human solid tumors. 1168 86

Xeroderma pigmentosum (XP) is a rare autosomal recessive disease in which repair of ultraviolet (UV)-induced DNA damage is impaired or is totally absent due to mutations in genes controlling the DNA repair pathway known as nucleotide excision repair (NER). XP is characterized, in part, by extreme sensitivity of the skin to sunlight, and XP patients have a more than 1000-fold increased risk of developing cancer at sun-exposed areas of the skin. To study the role of NER in chemical-induced tumorigenesis in more detail, the authors developed Xpa-/- homozygous knockout mice with a complete defect in NER (designated as Xpa mice or XPA model). Xpa mice develop skin tumors at high frequency when exposed to UV light, and as such, they mimic the phenotype of human XP. Moreover, the Xpa mice also appear to be susceptible to genotoxic carcinogens given orally. Based on these phenotypic characteristics, the Xpa mice were considered to be an attractive candidate mouse model for use in identifying human carcinogens. In an attempt to further increase both the sensitivity and specificity of the XPA model in carcinogenicity testing, the authors crossed Xpa mice with mice having a heterozygous defect in the tumor suppressor gene p53. Xpa/p53+/- double knockout mice develop tumors earlier and with higher incidences upon exposure to carcinogens as compared to their single knockout counterparts. Here the authors describe the development and features of the Xpa mouse and present some examples of the Xpa and Xpa/p53+/- mouse models' sensitivity towards genotoxic carcinogens. It appeared that the Xpa/p53+/- double knockout mouse model is favorable over both the Xpa and p53+/- single knockout models in short-term carcinogenicity testing. In addition to the fact that the double knockout mice respond more robustly to carcinogens, they also appear to respond in a very discriminative way. All compounds identified thus far are true (human) carcinogens, and, therefore, the authors believe that the Xpa/p53+/- mouse model is an excellent candidate for a future replacement of the chronic mouse bioassay, at least for certain classes of chemicals.
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PMID:DNA repair-deficient Xpa and Xpa/p53+/- knock-out mice: nature of the models. 1169 46

We previously reported that transcription-coupled repair (TCR)-deficient human fibroblasts are extremely sensitive to UV-induced apoptosis and this sensitivity correlated with the induction of the p53 tumour suppressor. However, we have also found that p53 can be protective against UV-induced apoptosis. Thus, prior to this study, it was not clear whether the induction of p53 in TCR-deficient fibroblasts contributed to their death. To address this issue, we have expressed human papillomavirus E6 (HPV-E6) in primary fibroblasts derived from patients affected with xeroderma pigmentosum (complementation groups A, B and C) and Cockayne syndrome (complementation group B). We found that TCR-deficient (XP-A, XP-B and CS-B) fibroblasts were more sensitive than TCR-proficient cells (XP-C and normal) to both UV light and cisplatin treatment and this increase in sensitivity was not p53 dependent. Importantly, HPV-E6 expression increased the sensitivity of TCR-proficient normal and XP-C fibroblasts to UV- and cisplatin-induced apoptosis. This increase in sensitivity correlated with a decrease in the capacity of HPV-E6 expressing cells to recover mRNA synthesis following UV-irradiation. Therefore, we propose that p53 protects against UV- and cisplatin-induced apoptosis in a TCR-dependent manner and that p53 does not contribute strongly to the induction of apoptosis in TCR-deficient fibroblasts.
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PMID:P53 plays a protective role against UV- and cisplatin-induced apoptosis in transcription-coupled repair proficient fibroblasts. 1170 15

The INK4a-ARF locus, localized on 9p21, encodes two tumor suppressor proteins, p16INK4a and p14ARF, acting respectively through the CDK4-pRb and the p53 pathways. Familial melanoma (comprising between 8 and 12% of all melanoma cases) is a genodermatosis transmitted as an autosomal dominant trait, often associated with clinically atypical moles (AN). Germline mutations of p16INK4a are found in up to 20-30% of melanoma prone families. Mutated families often contain more than three family members affected and/or comprise at least one relative with multiple melanomas. Most of these mutations have been shown to affect p16INK4a protein function (i.e. CDK4 binding or pRB phosphorylation). Germline mutations of p16INK4a are also found in a lesser extend in sporadic multiple melanoma and in familial pancreatic cancer. The INK4a-ARF locus plays also an important role in skin carcinogenesis. P16INK4a UV induced mutations (CC:GG > TT:AA tandem transition or C:G > T:A transition at dipyrimidic site) are found in 12% of sporadic skin carcinomas, mainly in epidermoid tumors, and seem to occur independently of p53 mutations. Xeroderma pigmentosum (XP) is characterized by an inheritable DNA repair defect (involving the nucleotid excision repair (NER) system) predisposing to skin carcinomas. In skin tumors from (XP) patients, p16INK4a UV induced mutations occur more frequently, are often multiple, and significantly associated with the presence of p53 mutations. Such data, which could be related to the XP genetic instability and indicates a possible cooperative effect of inactivation of these pathways in the tumoral process of XP skin tumors.
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PMID:[The INK4a-ARF locus: role in the genetic predisposition to familial melanoma and in skin carcinogenesis]. 1174 99

Skin cancer is unique among human cancers in its etiology, accessibility and the volume of detailed knowledge now assembled concerning its molecular mechanisms of origin. The major carcinogenic agent for most skin cancers is well established as solar ultraviolet light. This is absorbed in DNA with the formation of UV-specific dipyrimidine photoproducts. These can be repaired by nucleotide excision repair or replicated by low fidelity class Y polymerases. Insufficient repair followed by errors in replication produce characteristic mutations in dipyrimidine sequences that may represent initiation events in carcinogenesis. Chronic exposure to UVB results in disruption of the epithelial structure and expansion of pre-malignant clones which undergo further genomic changes leading to full malignancy. Genetic diseases in DNA repair, xeroderma pigmentosum, Cockayne syndrome and trichothiodystrophy, show varied elevated symptoms of sun sensitivity involving skin cancers and other symptoms including neurological degeneration and developmental delays. In humans, only xeroderma pigmentosum shows high levels of cancer, but mouse strains, with any of the genes corresponding to these diseases knocked-out, show elevated skin carcinogenesis. The three major skin cancers exhibit characteristic molecular changes defined by certain genes and associated pathways. Squamous cell carcinoma involves mutations in the p53 gene; basal cell carcinoma involves mutations in the PATCHED gene, and melanoma in the p16 gene. The subsequent development of malignant tumors involves many additional genomic changes that have yet to be fully cataloged.
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PMID:UV damage, DNA repair and skin carcinogenesis. 1189 51

Basal cell carcinoma (BCC) of the skin is the most common type of cancer in humans. Like squamous cell carcinomas, they are also believed to be ultraviolet (UV)-induced, but several data suggest that some differences might exist in the mechanisms of their UV induction. The originating cells may arise from interfollicular basal cells, hair follicles or sebaceous glands, thus from a deeper zone than the SCC ones, which probably means exposure to different doses or wavelengths of UV. The p53 gene and the patched gene (PTCH) are major targets of UV for BCC induction. Mutations in p53 are present in about 56% of human BCC, even small early lesions. The "UV signature" is observed in 65% of them. Mutations in the PTCH play also a major role in BCC development, being responsible for hereditary BCCs in Gorlin's syndrome, sporadic BCC, and BCCs isolated from xeroderma pigmentosum, although with a lower incidence of "UV signature". Smoothened-activating mutations and PTCH2 mutations are also involved in BCC formation. Transgenic mice overexpressing Smoothened or Sonic hedgehog in the skin spontaneously produce skin lesions resembling human BCCs, but contrary to findings in the hairless albino mouse and with SCC, no data on experimental UV induction of BCCs are available.
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PMID:Carcinogenesis of basal cell carcinomas: genetics and molecular mechanisms. 1196 27

The DDB2 gene, which is mutated in xeroderma pigmentosum group E, enhances global genomic repair of cyclobutane pyrimidine dimers and suppresses UV-induced mutagenesis. Because DDB2 transcription increases after DNA damage in a p53-dependent manner, we searched for and found a region in the human DDB2 gene that binds and responds transcriptionally to p53. The corresponding region in the mouse DDB2 gene shared significant sequence identity with the human gene but was deficient for p53 binding and transcriptional activation. Furthermore, when mouse cells were exposed to UV, DDB2 transcription remained unchanged, despite the accumulation of p53 protein. These results demonstrate direct activation of the human DDB2 gene by p53. They also explain an important difference in DNA repair between humans and mice and show how mouse models can be improved to better reflect cancer susceptibility in humans.
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PMID:p53 Binds and activates the xeroderma pigmentosum DDB2 gene in humans but not mice. 1197 58

The UV-damaged DNA binding protein complex (UV-DDB) is implicated in global genomic nucleotide excision repair (NER) in mammalian cells. The complex consists of a heterodimer of p127 and p48. UV-DDB is defective in one complementation group (XP-E) of the heritable, skin cancer-prone disorder xeroderma pigmentosum. Upon UV irradiation of primate cells, UV-DDB associates tightly with chromatin, concomitant with the loss of extractable binding activity. We report here that an early event after UV, but not ionizing, radiation is the transient dose-dependent degradation of the small subunit, p48. Treatment of human cells with the proteasomal inhibitor NIP-L3VS blocks this UV-induced degradation of p48. In XP-E cell lines with impaired UV-DDB binding, p48 is resistant to degradation. UV-mediated degradation of p48 occurs independently of the expression of p53 and the cell's proficiency for NER, but recovery of p48 levels at later times (12 h and thereafter) is dependent upon the capacity of the cell to repair non-transcribed DNA. In addition, we find that the p127 subunit of UV-DDB binds in vivo to p300, a histone acetyltransferase. The data support a functional connection between UV-DDB binding activity, proteasomal degradation of p48 and chromatin remodeling during early steps of NER.
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PMID:Sequential binding of UV DNA damage binding factor and degradation of the p48 subunit as early events after UV irradiation. 1203 48

The p53 and BRCA1 tumor suppressors are involved in repair processes and may cooperate to transactivate certain genes, including p21WAF/CIP1 and GADD45. We find that the Xeroderma Pigmentosum Complementation group E (XPE) mutated Damaged-DNA binding protein p48 (DDB2) is upregulated by BRCA1 in a p53-dependent manner following UVC, Adriamycin, or Cisplatin exposure. BRCA1 enhances p53 binding to the DDB2 promoter in vivo as well as p53-dependent transactivation of DDB2 promoter-reporter constructs through a classical p53 DNA responsive element. Antisense abrogation of BRCA1 expression abrogates upregulation of DDB2 after UVC or cisplatin exposure. Using a host cell reactivation assay, DNA repair activity is more significantly restored by introduction of BRCA1 into wt as compared to DDB2-deficient cells. Furthermore disappearance of the photoproducts cyclobutane pyrimidine dimer (CPD) and 6-4 photoproduct (6-4PP) was delayed by antisense abrogation of BRCA1 expression in UV-exposed human cells. Thus the DNA repair function of BRCA1 may be attributed in part to p53-dependent transcriptional induction of DDB2. Loss of BRCA1-dependent DDB2 repair function may contribute to cancer susceptibility and cellular sensitivity to DNA damage.
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PMID:BRCA1 transcriptionally regulates damaged DNA binding protein (DDB2) in the DNA repair response following UV-irradiation. 1221 15

Mutations in XPB and XPD TFIIH helicases have been related with three hereditary human disorders: xeroderma pigmentosum, Cockayne syndrome, and trichothiodystrophy. The dual role of TFIIH in DNA repair and transcription makes it difficult to discern which of the mutant TFIIH phenotypes is due to defects in any of these different processes. We used haywire (hay), the Drosophila XPB homolog, to dissect this problem. Our results show that when hay dosage is affected, the fly shows defects in structures that require high levels of transcription. We found a genetic interaction between hay and cdk7, and we propose that some of these phenotypes are due to transcriptional deficiencies. We also found more apoptotic cells in imaginal discs and in the CNS of hay mutant flies than in wild-type flies. Because this abnormal level of apoptosis was not detected in cdk7 flies, this phenotype could be related to defects in DNA repair. In addition the apoptosis induced by p53 Drosophila homolog (Dmp53) is suppressed in heterozygous hay flies.
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PMID:DNA repair and transcriptional effects of mutations in TFIIH in Drosophila development. 1222 Nov 29

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