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 human telomerase RNA (hTR), together with the telomerase reverse transcriptase, hTERT, constitute the core components of telomerase that is essential for telomere maintenance. While hTR is ubiquitously expressed, hTERT is normally restricted to germ cells and certain stem cells, but both are often deregulated during tumorigenesis. Here, we investigated the effects of changes in hTR cellular levels. Surprisingly, while inhibition of hTR expression triggers a rapid, telomerase-independent, growth arrest associated with p53 and CHK1 activation, its increased expression neutralizes activation of these pathways in response to genotoxic stress. These hTR effects are mediated through ATR and are sufficiently strong to impair ATR-mediated DNA-damage checkpoint responses. Furthermore, in response to low UV radiation, which activates ATR, endogenous hTR levels increase irrespective of telomerase status. Thus, we uncovered a novel, telomerase-independent, function of hTR that restrains ATR activity and participates in the recovery of cells from UV radiation.
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PMID:Telomerase-independent regulation of ATR by human telomerase RNA. 1709 43

Four tumour suppressor genes (Chk1, Chk2, Apaf1 and Rb1) in nine human malignant melanoma cell lines were screened for a loss of gene expression, point mutations and small deletions/insertions by cDNA-based DGGE/SCCP analysis. In two cell lines alterations of the investigated genes could be demonstrated. This result confirms our assumption of the participation of dysfunctional p53 inducer/effector genes in human melanoma aetiology. Furthermore, it points towards the probable principal role of diverse alternative p53-pathway disruption mechanisms in this highly therapy-resistant malignancy without affecting p53 itself. To our knowledge, this is the first CHK1/CHK2 mutation screening in human melanoma.
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PMID:Mutational analysis of Chk1, Chk2, Apaf1 and Rb1 in human malignant melanoma cell lines. 1714 90

Genetic and biochemical studies have shown that Ser(20) phosphorylation in the transactivation domain of p53 mediates p300-catalyzed DNA-dependent p53 acetylation and B-cell tumor suppression. However, the protein kinases that mediate this modification are not well defined. A cell-free Ser(20) phosphorylation site assay was used to identify a broad range of calcium calmodulin kinase superfamily members, including CHK2, CHK1, DAPK-1, DAPK-3, DRAK-1, and AMPK, as Ser(20) kinases. Phosphorylation of a p53 transactivation domain fragment at Ser(20) by these enzymes in vitro can be mediated in trans by a docking site peptide derived from the BOX-V domain of p53, which also harbors the ubiquitin signal for MDM2. Evaluation of these calcium calmodulin kinase superfamily members as candidate Ser(20) kinases in vivo has shown that only CHK1 or DAPK-1 can stimulate p53 transactivation and induce Ser(20) phosphorylation of p53. Using CHK1 as a prototypical in vivo Ser(20) kinase, we demonstrate that (i) CHK1 protein depletion using small interfering RNA can attenuate p53 phosphorylation at Ser(20), (ii) an enhanced green fluorescent protein (EGFP)-BOX-V fusion peptide can attenuate Ser(20) phosphorylation of p53 in vivo, (iii) the EGFP-BOX-V fusion peptide can selectively bind to CHK1 in vivo, and (iv) the Deltap53 spliced variant lacking the BOX-V motif is refractory to Ser(20) phosphorylation by CHK1. These data indicate that the BOX-V motif of p53 has evolved the capacity to bind to enzymes that mediate either p53 phosphorylation or ubiquitination, thus controlling the specific activity of p53 as a transcription factor.
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PMID:The MDM2 ubiquitination signal in the DNA-binding domain of p53 forms a docking site for calcium calmodulin kinase superfamily members. 1733 37

Proper regulation of cell cycle progression is pivotal for maintaining genome stability. In a search for DNA damage-inducible, CHK1-modulated genes, we have identified BTG3 (B-cell translocation gene 3) as a direct p53 target. The p53 transcription factor binds to a consensus sequence located in intron 2 of the gene both in vitro and in vivo, and depletion of p53 by small interfering RNA (siRNA) abolishes DNA damage-induced expression of the gene. Furthermore, ablation of BTG3 by siRNA in cancer cells results in accelerated exit from the DNA damage-induced G2/M block. In vitro, BTG3 binds to and inhibits E2F1 through an N-terminal domain including the conserved box A. Deletion of the interaction domain in BTG3 abrogates not only its growth suppression activity, but also its repression on E2F1-mediated transactivation. We also present evidence that by disrupting the DNA binding activity of E2F1, BTG3 participates in the regulation of E2F1 target gene expression. Therefore, our studies have revealed a previously unidentified pathway through which the activity of E2F1 may be guarded by activated p53.
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PMID:The candidate tumor suppressor BTG3 is a transcriptional target of p53 that inhibits E2F1. 1769 Jun 88

The multi-functionality of the DNA mismatch repair (MMR) proteins has been demonstrated by their role in regulation of the cell cycle and apoptosis, as well as DNA repair. Using a unique MSH2-/- non-tumor human lymphoblastoid cell line we show that MMR facilitates G2/M arrest after UVB-induced DNA damage. Deficiency in MSH2 leads to a decrease in the induction of G2/M cell cycle checkpoint following UVB radiation in MSH2-null non-tumor cells. We also show evidence that the above-mentioned cells deficient in MSH2 have decreased levels of key cell cycle proteins such as CHK1 phosphorylated at Ser345, CDC25C phosphorylated at Ser216 and CDC2 phosphorylated at Tyr15, Thr14, compared to MSH2-proficient cells after UVB radiation. In addition, we demonstrate an altered p53 protein in the MSH2-null cell line. Our data show that the MMR protein MSH2 is involved in the regulation of normal cell cycle response after UVB-induced DNA damage.
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PMID:Non-tumor cells from an MSH2-null individual show altered cell cycle effects post-UVB. 1798 23

When cells progressing in G(1) phase are irradiated with UV light, two damage checkpoint pathways are activated: CHK1-Cdc25A and p53-p21WAF1/CIP1, both targeting Cdk2 but the latter inducing long lasting inactivation. In similarly irradiated S phase cells, however, p21WAF1/CIP1-dependent checkpoint is largely inactive. We report here that p21-dependent checkpoint can effectively be activated and induce a prolonged S phase arrest with similarly extended inactivation of Cdk2 by association of p21 if mid-S phase cells are damaged with a base-modifying agent instead of UV light, indicating that the poor utilization of p21-dependent checkpoint is not an innate property of S phase cells.
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PMID:Chemical DNA damage activates p21 WAF1/CIP1-dependent intra-S checkpoint. 1806 63

When cells progressing in mid-S phase are damaged with a base-modifying chemical, they arrest in S phase long after the CHK1 checkpoint signal fades out, partly because of p53-mediated long-lasting induction of the cyclin-dependent kinase inhibitor p21(WAF1/CIP1). We have recently found that enforced expression of Cdc6, the assembler of prereplicative complexes, markedly advances recovery from the prolonged S-phase arrest and reactivation of Cdk2 despite the presence of a high level of induced p21. Here, we report that Cdc6 protein can activate p21-associated Cdk2 in an ATP-dependent manner in vitro. Consistently, Cdc6 mutated for ATPase or a putative cyclin binding motif is no longer able to activate the Cdk2 in vitro or promote reinitiation of S-phase progression and reactivation of Cdk2 in vivo. These results reveal the never anticipated function of Cdc6 and redefine its role in the control of S-phase progression in mammalian cells.
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PMID:ATP-dependent activation of p21WAF1/CIP1-associated Cdk2 by Cdc6. 1835 1

p53-dependent G(1) and G(2) cell cycle checkpoints are activated in response DNA damage that help to maintain genomic stability. p53 also helps to protect cells from damage that occurs during S phase, for example, when the cells are starved for DNA precursors or irradiated with a low dose of UV. p53 is activated in normal cells starved for pyrimidine nucleotides by treatment with N-(phosphonacetyl)-l-aspartate (PALA). The treated cells progress through a first S phase with kinetics similar to those of untreated cells. However, the DNA of the treated cells begins to become damaged rapidly, within 12 h, as revealed by a comet assay, which detects broken DNA, and by staining for phosphorylated histone H2AX, which accumulates at sites of DNA damage. Because the cells survive, the damage must be reversible, suggesting single-strand breaks or gaps as the most likely possibility. The transiently damaged DNA stimulates activation of ATR and CHK1, which in turn catalyze the phosphorylation and accumulation of p53. Although PALA-induced DNA damage occurs only in dividing cells, the p53 that is activated is only competent to transcribe genes such as p21 and macrophage inhibitory cytokine 1 (whose products regulate G(2) and G(1) or S phase checkpoints, respectively) after the cells have exited the S phase during which damage occurs. We propose that p53 is activated by stimulation of mismatch repair in response to the misincorporation of deoxynucleotides into newly synthesized DNA, long before the lack of pyrimidine nucleoside triphosphates causes the rate of DNA synthesis to slow appreciably.
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PMID:DNA synthesis from unbalanced nucleotide pools causes limited DNA damage that triggers ATR-CHK1-dependent p53 activation. 1843 39

Regular consumption of mesalazine has been associated with a reduced risk of colorectal cancer (CRC) in patients with inflammatory bowel disease. The molecular mechanisms underlying the antineoplastic effect of 5-aminosalicylic acid remain, however, poorly characterized. In this study, we examined whether mesalazine affects cell cycle progression and analyzed specific checkpoint pathways in experimental models of CRC. Mesalazine inhibited the growth of HCT-116 and HT-29 cells, two CRC cell lines that express either a wild-type or mutated p53. Cell cycle analysis revealed that mesalazine induced cells to accumulate in S phase. This effect was associated with a sustained phosphorylation of the cyclin-dependent kinase (CDK)2 at threonine 14 and tyrosine 15 residues, an event that inactivates the CDK2-cyclin complex and blocks S-G(2) phase cell cycle transition. Consistently, mesalazine reduced the protein content of CDC25A, a phosphatase that regulates CDK2 phosphorylation status. Analysis of upstream kinases that negatively control CDC25A expression showed that mesalazine enhanced the activation of CHK1 and CHK2. However, silencing of CHK1 and CHK2 did not prevent the mesalazine-induced CDC25A protein downregulation. In contrast, CDC25A protein ubiquitination and degradation and accumulation of cells in S phase following mesalazine exposure were reverted by proteasome inhibitors. Notably, mesalazine also inhibited CDC25A in human CRC explants. Finally, we showed that mesalazine downregulated CDC25A in CT26, a murine CRC cell line, and prevented the formation of CT26-derived tumors in mice. Data show that mesalazine negatively regulates CDC25A protein expression, thus delaying CRC cell progression.
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PMID:Mesalazine negatively regulates CDC25A protein expression and promotes accumulation of colon cancer cells in S phase. 1849 57

Efficacy of camptothecins (CPTs) such as irinotecan has been recognized in chemotherapy of cancers including melanoma. However, the majority of responding patients will gradually acquire drug resistance. Little is known of the genes responsible for the acquired CPT-resistance in cancer. To gain global insight into acquired CPT-resistance, we established irinotecan-resistant clones derived from melanoma cells and compared their whole genomes by high resolution array-CGH. A novel gain at 14q23.2-31.1 was revealed by alignment of whole genome profiles of parental cell line and irinotecan-resistant clones. Further analysis of this amplicon indicates that it encompassed genes involved in DNA repair (RAD51L, MLH3), reactive oxygen species (GPX2, CSTZ1, NGB, RDH11, ZADH1), and transportome (ABCD4, ATP6V1D, SLC10A6). Moreover, losses were also detected at the loci of topoisomerases (TOP1, SPO11, TOP3B) as well as at the loci of genes guarding chromosomal stability (TP53, ZW10, H2AFX, CHK1, CCDN1, MCM5, CENPB, DNMT3B), which would facilitate the development of drug resistance. Furthermore, quantitative real-time PCR demonstrated that mRNA changes of selected novel genes (CENPB, H2AFX, MCM5, ZADH1 and NGB) in irinotecan-resistant clones vs. parental clone were in agreement with array-CGH results. Taken together, our data suggest that genes involved in genome stability may greatly contribute to the development of CPTs-resistance. In addition, genes located at 14q23.3-31.1 would be promising targets to overcome acquired CPT-resistance in melanoma.
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PMID:Genomic analyses identify gene candidates for acquired irinotecan resistance in melanoma cells. 1849 97

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