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)

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 cyclin-dependent kinase inhibitor p21(WAF1/CIP1/SDI1/CAP20) exists in normal human fibroblasts in a quaternary complex with a cyclin, a cyclin-dependent kinase, and proliferating cell nuclear antigen. A model was proposed in which, during p53-mediated suppression of cell proliferation following treatment with 254 nm UV radiation (UVC), the enhanced expression of p21 might inhibit DNA replication by virtue of its interactions with proliferating cell nuclear antigen. To test this model, we examined the mechanisms of inhibition of DNA replication in diploid human fibroblasts that express human papillomavirus type 16 E6, which inactivates p53. E6-expressing cells were defective in G1 checkpoint responses of induction of p21 and G1 arrest after ionizing radiation-induced damage to DNA. Accordingly, E6-expressing cells were resistant to inactivation of single-cell colony formation by ionizing radiation. E6 cells also displayed normal S-phase checkpoint responses of inhibition and recovery of replicon initiation following exposure to ionizing radiation and normal ability to bypass pyrimidine dimers during DNA replication soon after UVC irradiation (i.e., postreplication repair). However, DNA replication 6 h after UVC exposure was significantly inhibited in E6 cells in comparison to isogenic controls. This failure to maintain DNA replication in S-phase cells was associated with enhanced sensitivity to inactivation of single-cell colony formation by UVC. These results indicate that the p53-induced p21 pathway is not involved in the immediate S-phase responses to radiation-induced DNA damage of inhibition of replicon initiation and translesion bypass. However, our results demonstrate that p53 and, conceivably, p21 contribute to the ability of normal human fibroblasts to sustain DNA replication activity and form colonies following UVC irradiation.
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PMID:p53-dependent signaling sustains DNA replication and enhances clonogenic survival in 254 nm ultraviolet-irradiated human fibroblasts. 958 44

Sunlight is a carcinogen to which everyone is exposed. Epidemiology indicates that most carcinogenic sunlight exposure takes place several decades before the tumor arises. Some of the early events have been identified by searching for genes having ultraviolet (UV)-specific mutations. Over 90% of squamous cell carcinomas and more than 50% of basal cell carcinomas from New England patients contain UV-like mutations in the p53 tumor suppressor gene. From the mutation pattern, it can be concluded that the carcinogenic DNA lesions were pyrimidine-cytosine photoproducts caused by the UVB portion of sunlight. Particular codons of the p53 gene are most susceptible, apparently because of slower DNA repair at specific sites. Sunlight is sufficiently mutagenic often to mutate both p53 alleles. These mutations are also found in the precancer for squamous cell carcinoma, actinic keratosis, implying an early role. The function of p53 in normal skin is indicated by the observation that inactivating p53 in mouse skin reduces the appearance of sunburn cells, apoptotic keratinocytes generated by UV overexposure. Skin thus appears to possess a p53-dependent "cellular proofreading" response to DNA damage in which precancerous cells self-destruct. If this response is reduced in a single cell by a prior p53 mutation, sunburn can thereafter select for clonal expansion of the p53-mutated cell into an actinic keratosis. Sunlight appears to act twice: as tumor initiator and as tumor promoter.
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PMID:Sunlight and sunburn in human skin cancer: p53, apoptosis, and tumor promotion. 962 7

Exposure to the solar ultraviolet spectrum that penetrates the Earth's stratosphere (UVA and UVB) causes cellular DNA damage within skin cells. This damage is elicited directly through absorption of energy (UVB), and indirectly through intermediates such as sensitizer radicals and reactive oxygen species (UVA). DNA damage is detected as strand breaks or as base lesions, the most common lesions being 8-hydroxydeoxyguanosine (8OHdG) from UVA exposure and cyclobutane pyrimidine dimers from UVB exposure. The presence of these products in the genome may cause misreading and misreplication. Cells are protected by free radical scavengers that remove potentially mutagenic radical intermediates. In addition, the glutathione-S-transferase family can catalyze the removal of epoxides and peroxides. An extensive repair capacity exists for removing (1) strand breaks, (2) small base modifications (8OHdG), and (3) bulky lesions (cyclobutane pyrimidine dimers). UV also stimulates the cell to produce early response genes that activate a cascade of signaling molecules (e.g., protein kinases) and protective enzymes (e.g., haem oxygenase). The cell cycle is restricted via p53-dependent and -independent pathways to facilitate repair processes prior to replication and division. Failure to rescue the cell from replication block will ultimately lead to cell death, and apoptosis may be induced. The implications for UV-induced genotoxicity in disease are considered.
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PMID:Molecular and cellular effects of ultraviolet light-induced genotoxicity. 966 76

Mammalian cells in culture react to ultraviolet irradiation with the massive transcriptional activation of several genes and with the stabilization of the p53 protein. While U.V.-induced transcription of several immediate-response genes depends on U.V.-induced activation of signal transduction generated by non-nuclear mechanisms, stabilization of p53 and the transcription of several delayed-response genes are triggered by U.V.-induced DNA damage. By comparing dose responses for the activation by U.V. of delayed-responsive genes (collagenase 1, metallothionein IIA) in cells from patients with different DNA repair deficiencies (complementation groups of Xeroderma pigmentosum, Cockayne's syndrome and Trichothiodystrophy), we show here that U.V.-induced transcription of these genes does depend on pyrimidine dimers in transcribed regions of the genome (but not on damage in its silent part). Since all cells with defects in DNA repair that had been tested and which lack different enzymes, respond to U.V. with expression of these same genes, functional repair does not appear to be required for the induction of expression, and repair intermediates (which would not be identical in cells of different repair deficiency) cannot be responsible for signal generation.
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PMID:Photoproducts in transcriptionally active DNA induce signal transduction to the delayed U.V.-responsive genes for collagenase and metallothionein. 967 3

A possible role of p53-dependent transcription in the induction of DNA repair was explored by transfecting a UV-irradiated chloramphenicol acetyl transferase (CAT) reporter plasmid (pRGC.FOS.CAT), containing a minimal FOS promoter driven by a consensus p53 binding site, into a p53 negative-mouse cell line [(10)1]. When a p53-expressing plasmid (pSV.p53) was cotransfected into these cells, CAT expression levels persisted even after prolonged UV irradiation. In comparison, CAT expression from pSV2.CAT, which lacks a p53-responsive element in its SV40 promoter, dropped off much more precipitously after UV irradiation in the absence or presence of WT p53 expression. A similar sharp drop was observed with three other constructs when the reporter gene was under the control of the ras, beta-actin or fos promoter. Mouse cells (A1-5) that constitutively express a temperature-sensitive mutant (135 AV) of mouse p53 also generated, at 32 degrees C, higher levels of enzyme expressed from UV-irradiated pRGC.FOS.CAT than from UV-irradiated pSV2.CAT. The frequency of cyclobutane pyrimidine dimers in UV-irradiated pRGC.FOS.CAT was determined with T4 endo V, and the probability of having an undamaged CAT coding strand was calculated by the Poisson distribution for various times of UV-irradiation. The observed relative CAT expression levels from irradiated pSV2.CAT and pRGC.FOS.CAT in the absence of p53 were consistent with those numbers. These results show that WT p53-mediated transcription directs a resistance of the transcribed DNA to UV inactivation and reactivates the reporter gene. Furthermore, some single point substitution mutants of p53 that maintain a near normal ability to activate transcription had lost their ability to extend CAT gene expression after UV irradiation. Conversely, other mutants with reduced transcriptional activity retained this ability. This indicates that although resistance to UV inactivation is transcriptionally-dependent, these two activities are genetically distinct. These data, taken together, suggest that the transcription of UV-damaged DNA by a p53-dependent process promotes its repair.
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PMID:p53-mediated transcription induces resistance of DNA to UV inactivation. 969 32

Ultraviolet light (UV) induced DNA lesions efficiently block transcript elongation and induce the p53 response. Although p53 contributes to transcriptional activation of the p21waf1 and bax genes, accumulation of these proteins requires that these genes are free of UV induced pyrimidine dimers. We assessed the level of expression of p53 and the p53 regulated p21waf1 and bax gene products in normal diploid fibroblasts (NDF) and several nucleotide excision repair deficient fibroblasts following UV-irradiation. At low UV fluences, increased expression of p53, p21waf1 and bax was only observed in fibroblasts deficient in transcription coupled repair (TCR). Whereas p53 protein levels increased in all cell types at high UV fluences, p21waf1 levels initially decreased and then recovered in a manner dependent on TCR. At later times, expression of p21waf1 and bax was only elevated in TCR-proficient cells. The lack of TCR strongly correlated with an enhanced induction of apoptosis. Furthermore, we assessed the effect of modulation of the p53/p21waf1/pRb pathway on clonogenic survival following UV irradiation. Expression of E2F-1, E2F-4, and the large tumour antigens of SV40 and Polyomavirus conferred UV sensitivity to NDF whereas p21waf1 protected cells against UV treatment. We propose that the fluence dependent attenuation of protective functions of p53 by blockage of transcription favours apoptosis following UV exposure.
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PMID:Persistent DNA damage induced by ultraviolet light inhibits p21waf1 and bax expression: implications for DNA repair, UV sensitivity and the induction of apoptosis. 970 20

The mutational specificity of UV-light is characterized by an abundance of C to T transition mutations at dipyrimidines containing cytosine or 5-methylcytosine. A significant percentage of these mutations are CC to TT double transitions. Of the major types of UV-induced DNA lesions, the cis-syn cyclobutane pyrimidine dimers (CPDs) are thought to be the most mutagenic lesions, at least in mammalian cells. It has been proposed that the CPDs become mutagenic perhaps only after cytosine bases within these dimers deaminate to uracil and the resulting U-containing photolesions are correctly bypassed by DNA polymerases. In order to assess the significance of this proposed mutagenic mechanism, we have developed two methods to specifically measure deaminated CPDs in UV-irradiated human cells or DNA. The first method is based on enzymatic photoreversal of CPDs, followed by cleavage of the DNA with uracil DNA glycosylase, an AP lyase activity, and ligation-mediated PCR to map the resulting strand breaks. The second method, which can be used to detect double deamination events (CC to UU), is PCR amplification of photolyase-treated DNA using primers complemetary to the deaminated sequences. We have measured deamination events in the human p53 gene, which contains a large percentage of C to T transitions in skin cancers. The deamination reactions are specific for cytosine within CPDs, are negligible immediately after irradiation, and are time-dependent and DNA sequence context-dependent. Twenty four hours after irradiation of human fibroblasts with UVB light, between 10 and 60% of most CPD signals are converted to the deaminated form, depending on the sequence. Significant deamination occurs at skin cancer mutation sites in the p53 gene. Double deamination also occurs and this reaction can involve dimers containing 5-methylcytosine or cytosine. These double events are expected to occur more frequently in cells with a DNA repair defect because there is more time for deamination in unrepaired lesions. This may explain the relatively high frequency of CC to TT mutations in skin cancers from xeroderma pigmentosum patients. In summary, these novel detection techniques demonstrate that deamination of cytosine in pyrimidine dimers is a significant event that most likely contributes to the mutational specificity of UVB irradiation in human cells.
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PMID:Sequence and time-dependent deamination of cytosine bases in UVB-induced cyclobutane pyrimidine dimers in vivo. 981 19

The mechanisms by which the hepatitis B x protein (HBx) contributes to hepatocarcinogenesis remain unclear. However, interaction with the tumor suppressor gene p53 and inhibition of p53-dependent cellular functions, including nucleotide excision repair, could be central to this process. We studied the levels of global repair (removal of cyclobutane pyrimidine dimers (CPDs) and 6-4 photoproducts) and transcription-coupled repair (removal of CPDs in both strands of the dihydrofolate reductase gene) in primary wild-type and p53-null mouse hepatocytes. We show that global repair of CPDs appears to be more efficient in mouse hepatocytes than in other commonly studied rodent cells and approaches the levels of human cells and that p53 is required for global genomic DNA repair of CPDs but not for transcription-coupled repair. We then investigated the effect of HBx expression on hepatocyte nucleotide excision repair. We demonstrate that HBx expression affects DNA repair in a p53-dependent manner. Transient HBx expression reduces global DNA repair in wild-type cells to the level of p53-null hepatocytes and has no effect on the repair of a transfected damaged plasmid. Therefore, in viral hepatitis, the hepatitis B virus could inhibit the p53-dependent component of global repair leading, over time, to accumulation of genetic defects and fostering carcinogenesis.
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PMID:Hepatitis B x protein inhibits p53-dependent DNA repair in primary mouse hepatocytes. 983 6

Normal mammalian cells arrest primarily in G1 in response to N-(phosphonacetyl)-L-aspartate (PALA), which starves them for pyrimidine nucleotides, and do not generate or tolerate amplification of the CAD gene, which confers resistance to PALA. Loss of p53, accompanied by loss of G1 arrest, permits CAD gene amplification and the consequent formation of PALA-resistant colonies. We have found rat and human cell lines that retain wild-type p53 but have lost the ability to arrest in G1 in response to PALA. However, these cells still fail to give PALA-resistant colonies and are protected from DNA damage through the operation of a second checkpoint that arrests them reversibly within S-phase. This S-phase arrest, unmasked in the absence of the G1 checkpoint, is dependent on p53 and independent of p21/waf1.
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PMID:A p53-dependent S-phase checkpoint helps to protect cells from DNA damage in response to starvation for pyrimidine nucleotides. 984 65

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