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 tumour suppressor p53 protein plays an important role in maintaining genetic integrity. Recently, p53 was shown to have an intrinsic 3'-->5' exonuclease activity. The current study has extended the characterization of purified wild-type recombinant p53-associated 3'-->5' exonuclease function to demonstrate proofreading activity. p53-associated 3'-->5' exonuclease shows clear preference for degradation of ssDNA over dsDNA substrate. On partial duplex structures, this exonucleolytic activity displays a marked preference for excision of a mismatched vs. a correctly paired 3' terminus which enables the p53 protein to act as a proofreader. However, p53 displays variation in excision of mismatched base pairs. The results demonstrate that p53 exhibits mispair excision with a specificity of A:A > A:G > A:C opposite the template adenine residue and with a specificity of G:A > G:G > G:T opposite the template guanine residue. Hence, the observed specificity of mismatch excision shows that p53 exonucleolytic proofreading preferentially repairs transversion mutations. As part of an investigation of the functional interaction between p53 and DNA polymerase, the influence of p53 on the accuracy of DNA synthesis was determined with exonuclease-deficient murine leukemia virus (MLV) reverse transcriptase (RT), representing a relatively low fidelity enzyme. Using an in vitro biochemical assay with 3'-terminal mismatch-containing DNA template primers, it was shown that wild-type recombinant p53 protein enhanced the DNA replication fidelity of MLV RT. A functional interaction between the exonuclease (p53) and polymerase (MLV RT) activities was observed; excision of mispairs by p53 was followed by further elongation onto correctly base-paired 3'-termini by MLV RT. Furthermore, the formation of 3'-mispair and subsequent mispair extension by the enzyme were decreased substantially in the presence of p53. The fact that the exonuclease-deficient MLV RT is more accurate in the presence of p53, suggests that p53 protein may function as an external proofreading exonuclease for viral enzyme. The observed decrease in initial nucleotide misincorporation and 3'-terminal mispair extension by MLV RT in the presence of p53, indicates the mechanism by which p53 affects the DNA replication fidelity of exonuclease-deficient DNA polymerase.
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PMID:Exonucleolytic proofreading by p53 protein. 1127 27

We assessed the status of P53 in 32 surgically treated non-small cell lung cancers (NSCLC) by using yeast functional assay. For functional assay, total RNA extracted from fresh-frozen specimens was reverse transcribed and P53 cDNAs were PCR-amplified using Pfu DNA polymerase (Stratagene). The transcriptional competence of the P53 cDNA was then tested in a yeast reporter strain. 20 of the 32 (69%) NSCLC patients contained mutant P53 in the yeast functional assay with the higher frequency in squamous cell carcinoma (14/17, 82%) than in adenocarcinoma (5/10, 50%) and large cell carcinoma (3/5, 60%) (p<0.01, chi2 test). No significant difference was observed with respect to the TNM. Preliminary survival analysis showed that patients scoring positive for the yeast test had shorter disease-free survival (median = 10 months) than those that scored negative (median > 21 months). Our results suggest that yeast functional assay is not only an improved method to examine the status of P53, but might hopefully improve understanding of the role of mutant P53 in the clinical evaluation of NSCLC.
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PMID:Detection of P53 abnormalities in non-small cell lung cancer by yeast functional assay. 1137 99

High-risk human papillomaviruses (HPVs) have been proposed to be associated with a subset of head and neck cancers (HNSCCs). However, clear biological evidence linking HPV-mediated oncogenesis to the development of HNSCC is hardly available. An important biological mechanism underlying HPV-mediated carcinogenesis is the inactivation of p53 by the HPV E6 oncoprotein. In the present study we investigated this biological relationship between HPV and HNSCC. In total 84 HNSCC tumors were analyzed for the presence of high-risk HPV nucleic acids by DNA polymerase chain reaction-enzyme immunoassay (PCR-EIA) and E6 reverse transcriptase (RT)-PCR as well as for the presence of mutations in the p53 gene. We found 20/84 HPV16 DNA-positive cases with one or more DNA assays, 10 of which were consistently positive with all assays. Only 9/20 cases showed E6 mRNA expression, indicative for viral activity. Only these nine E6 mRNA-positive cases all lacked a p53 mutation, whereas both the other HPV DNA-positive and HPV-DNA negative tumors showed p53 mutations in 36% and 63% of the cases, respectively. Moreover, only in lymph node metastases of HPV E6 mRNA-positive tumors both viral DNA and E6 mRNA were present. Our study provides strong biological evidence for a plausible etiological role of high-risk HPV in a subgroup of HNSCC. Analysis of E6 mRNA expression by RT-PCR or alternatively, semiquantitative analyses of the viral load, seem more reliable assays to assess HPV involvement in HNSCC than the very sensitive DNA PCR analyses used routinely.
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PMID:Biological evidence that human papillomaviruses are etiologically involved in a subgroup of head and neck squamous cell carcinomas. 1141 Aug 71

Conflicting results regarding the association of a polymorphism at codon 72 of the p53 tumour suppressor gene and susceptibility to develop human papilloma virus (HPV)-associated cervical cancer have been published over the last year, implicating differences in ethnic background, sample origin, sample size and/or detection assay. The material for this study was collected in the identical geographical region as for 2 previous reports with contradictory results regarding the association of codon 72 genotype with squamous cell cancer (SCC). We have used an alternative detection assay, based on pyrosequencing technology, that interrogates the variable position by the accuracy of DNA polymerase. In addition to cervical clinical specimens from SCC, HPV16- and HPV18-infected adenocarcinoma cases as well as cervical intraepithelial neoplasia (CIN) were investigated. No significant association was found between p53 codon 72 genotype and the risk to develop adenocarcinoma, SCC or CIN in the Swedish population.
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PMID:HPV-related cancer susceptibility and p53 codon 72 polymorphism. 1150 50

We previously found that p53 upregulation by hypertonicity protected renal inner medullary collecting duct (mIMCD3) cells from apoptosis. The purpose of the present study was to investigate the mechanism by which p53 protects the cells. We now find that hypertonicity (NaCl added to a total of 500 mosmol) inhibits DNA replication and delays G(1)-S transition as concluded from analysis of cell cycle distributions and bromodeoxyuridine (BrDU) incorporation rates. Lowering of p53 with p53 antisense oligonucleotide attenuated such effects of hypertonicity, resulting in an increased number of apoptotic cells in S phase and cells with >4 N DNA. Results with synchronized cells are similar, showing that cells in the early S phase are more sensitive to hypertonicity. Immunocytochemistry revealed that p53 becomes phosphorylated on Ser(15) and translocates to the nucleus in S both in isotonic and hypertonic conditions. Caffeine (2 mM) greatly reduces the p53 level and Ser(15) phosphorylation, followed by a remarkable increase of DNA replication rate, by failure of hypertonicity to inhibit it, and by reduction of cell number during hypertonicity. Finally, inhibition of DNA replication by the DNA polymerase inhibitor aphidicolin significantly improves cell survival, confirming that keeping cells in G(1) and decreasing the rate of DNA replication is protective and that these actions of p53 most likely are what normally help protect cells against hypertonicity.
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PMID:p53 Protects renal inner medullary cells from hypertonic stress by restricting DNA replication. 1150 1

Cancer cells are characterized by limitless proliferative autonomy and immunity to inhibitory and apoptotic signals, thus ensuring growth and metastasis [1]. Epidemiological studies have long implicated human papillomavirus (HPV) as a pathogenic agent in cervical cancer. Progress in cancer research now provides an understanding of how these characteristics are achieved by the interaction of HPV proteins with the cell cycle machinery. Expression of oncoproteins E7 and E6 induces immortalization of cells through their inhibitory effects on tumor suppressor proteins pRb and p53, respectively. Undermining of pRb's growth-inhibitory role with release of E2F transcription factors renders the cells independent of mitogenic stimuli. The abundance of growth transcription factors grants limitless proliferative potential by allowing expression of products such as cyclins A, E, and B, dihydrofolate reductase, and DNA polymerase which fuel the various stages of the cell cycle. There is subsequent disruption of both the G1-S and G2-M cell cycle checkpoints. Overexpression of cyclin E results in chromosomal instability and possible unmasking of genetic mutations, allowing disease progression. Cyclin A grants anchorage-independent growth, facilitating tissue invasion and tumor spread. Apoptotic and growth-inhibitory mechanisms are also evaded. p53 is degraded by E6 and its own downstream protein mdm2. Its other downstream protein, p21 is rendered ineffective against cyclin-cyclin-dependent kinase units by E7, as is p27. The understanding of the molecular pathology of disease will provide us with the ability to prognosticate and treat patients more effectively.
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PMID:Cell cycle aberrations in the pathogenesis of squamous cell carcinoma of the uterine cervix. 1153 Dec 73

Detection of mutations in disease genes will be a significant application of genomic research. Methods for detecting mutations at the single nucleotide level are required in highly mutated genes such as the tumor suppressor p53. Resequencing of an individual patient's DNA by conventional Sanger methods is impractical, calling for novel methods for sequence analysis. Toward this end, an arrayed primer extension (APEX) method for identifying sequence alterations in primary DNA structure was developed. A two-dimensional array of immobilized primers (DNA chip) was fabricated to scan p53 exon 7 by single bases. Primers were immobilized with 200 microm spacing on a glass support. Oligonucleotide templates of length 72 were used to study individual APEX resequencing reactions. A template-dependent DNA polymerase extension was performed on the chip using fluorescein-labeled dideoxynucleotides (ddNTPs). Labeled primers were evanescently excited and the induced fluorescence was imaged by CCD. The average signal-to-noise ratio (S/N) observed was 30:1. Software was developed to analyze high-density DNA chips for sequence alterations. Deletion, insertion, and substitution mutations were detected. APEX can be used to scan for any mutation (up to two-base insertions) in a known region of DNA by fabricating a DNA chip comprising complementary primers addressing each nucleotide in the wild-type sequence. Since APEX is a parallel method for determining DNA sequence, the time required to assay a region is independent of its length. APEX has a high level of accuracy, is sequence-based, and can be miniaturized to analyze a large DNA region with minimal reagents.
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PMID:APEX disease gene resequencing: mutations in exon 7 of the p53 tumor suppressor gene. 1155 65

The nitrosamine 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK) is an important tobacco-specific carcinogen associated with lung cancer. Its complex enzymatic activation, leading to methyl and pyridyloxobutyl (POB)-modified DNA, makes DNA damage difficult to characterize and quantify. Therefore, we use the NNK analogue 4-[(acetoxymethyl)nitrosamino]-1-(3-pyridyl)-1-butanone (NNKOAc) to induce damage in genomic DNA, and to map the sites and frequency of adducts at nucleotide resolution using ligation-mediated polymerase chain reaction and terminal transferase-dependent polymerase chain reactions (LMPCR and TDPCR). NNKOAc induced single-strand breaks in a concentration-dependent manner. Post-alkylation treatments, including hot piperidine or digestion with the enzymes Escherichia coli 3-methyladenine-DNA glycosylase II, formamidopyrimidine-DNA glycosylase, Escherichia coli endonuclease III, or phage T4 UV endonuclease V did not increase the level of DNA breaks in NNKOAc-treated DNA. Detection of DNA damage using LMPCR was possible only when POB-DNA was 5'-phosphorylated prior to the LMPCR procedure. NNKOAc generated damage at all four bases with the decreasing order guanine>adenine>cytosine>thymine. In contrast to NNKOAc damage distribution patterns, those induced by N-nitroso(acetoxymethyl)methylamine, a methylating NNK analog, induced damage principally at G positions detectable by enzymatic means that did not require phosphorylation. Analysis of damage distribution patterns, reveals a high frequency of damage in the p53 gene in codons 241 and 245 and a lower frequency of damage in codon 248. We analyzed the 3' termini of the NNKOAc induced single-strand breaks using a (32)P-post-labeling assay or a nucleotide exchange reaction at the 3'-termini catalyzed by T4 DNA polymerase combined with endonuclease IV treatment. Both methods indicate that the 3' termini of the single-strand breaks are not hydroxyl groups and are blocked by an unknown chemical structure that is not recognized by endonuclease IV. These data are consistent with POB-phosphotriester hydrolysis leading to strand breaks in DNA. The POB-damage could be mutagenic because NNKOAc produces single-strand breaks with the products being a 5'-hydroxyl group and a 3'-blocking group and strand breaks. These results represent the first step in determining if NNK pyridyloxobutylates DNA with sequence specificity similar to those observed with other model compounds.
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PMID:Characterization and mapping of DNA damage induced by reactive metabolites of 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK) at nucleotide resolution in human genomic DNA. 1167 38

Hexavalent chromium (Cr (VI)) is reduced intracellularly to Cr (V), Cr (IV) and Cr (III) by ascorbate (Asc), cysteine and glutathione (GSH). These metabolites induce a spectrum of genomic DNA damage resulting in the inhibition of DNA replication. Our previous studies have shown that treatment of DNA with Cr (III) or Cr (VI) plus Asc results in the formation of DNA-Cr-DNA crosslinks (Cr-DDC) and guanine-specific arrests of both prokaryotic and mammalian DNA polymerases. GSH not only acts as a reductant of Cr (VI) but also becomes crosslinked to DNA by Cr, thus, the focus of the present study was to examine the role of GSH in Cr-induced DNA damage and polymerase arrests. Co-incubation of Cr (III) with plasmid DNA in the presence of GSH led to the crosslinking of GSH to DNA. GSH co-treatment with Cr (III) also led to a decrease in the degree of Cr-induced DNA interstrand crosslinks relative to Cr (III) alone, without affecting total Cr DNA binding. DNA polymerase arrests were observed following treatment of DNA with Cr (III) alone, but were markedly reduced when GSH was added to the reaction mixture. Pre-formed polymerase-arresting lesions (Cr-DDC) were not removed by subsequent addition of GSH. Treatment of DNA with Cr (VI), in the presence of GSH, resulted in crosslinking of GSH to DNA, but failed to produce detectable DNA interstrand crosslinks or polymerase arrests. The inhibitory effect of GSH on Cr-induced polymerase arrest was further confirmed in human genomic DNA using quantitative PCR (QPCR) analysis. Treatment of genomic DNA with Cr (III) resulted in a marked inhibition of the amplification of a 1.6 kb target fragment of the p53 gene by Taq polymerase. This was almost completely prevented by co-treatment with GSH and Cr (III). These results indicate that Cr-induced DNA interstrand crosslinks, and not DNA-Cr-GSH crosslinks, are the principal lesions responsible for blocking DNA replication. Moreover, the formation of DNA-Cr-GSH crosslinks may actually preclude the formation of the polymerase arresting lesions.
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PMID:Effects of glutathione on chromium-induced DNA crosslinking and DNA polymerase arrest. 1167 99

Proliferating cell nuclear antigen (PCNA) protein is one of the central molecules responsible for decisions of life and death of the cell. The PCNA gene is induced by p53, while PCNA protein interacts with p53-controlled proteins Gadd45, MyD118, CR6 and, most importantly, p21, in the process of deciding cell fate. If PCNA protein is present in abundance in the cell in the absence of p53, DNA replication occurs. On the other hand, if PCNA protein levels are high in the cell in the presence of p53, DNA repair takes place. If PCNA is rendered non-functional or is absent or present in low quantities in the cell, apoptosis occurs. The evolution from prokaryotes to eukaryotes involved a change of function of PCNA from a 'simple' sliding clamp protein of the DNA polymerase complex to an executive molecule controlling critical cellular decision pathways. The evolution of multicellular organisms led to the development of multicellular processes such as differentiation, senescence and apoptosis. PCNA, already an essential molecule in the life of single cellular organisms, then became a protein critical for the survival of multicellular organisms.
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PMID:Proliferating cell nuclear antigen (PCNA): ringmaster of the genome. 1168 6

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