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)

Biologic responses to cytokines are mediated by intracellular pathways involving induction of signaling and metabolic cascades. Interferon (IFN) regulatory factor-1 (IRF-1) is a major transcription factor induced not only by IFN-gamma but also by other cytokines including tumor necrosis factor-alpha (TNF-alpha). Possible IRF-1 binding sequence elements have been located in the promoter regions of several genes, including p53, inducible nitric oxide synthase, and cyclin D1. IFN-gamma and TNF-alpha can inhibit hematopoiesis in vitro and have been implicated in the pathophysiology of bone marrow (BM) failure. We investigated whether the inhibitory effects of these cytokines were intracellularly mediated through the expression of IRF-1 or -2 in target cells. In total BM cells, IRF-1 mRNA expression increased after stimulation with IFN-gamma and TNF-alpha; the stronger effect was observed with IFN-gamma. In contrast, IRF-2 mRNA expression was constitutive and not altered by cytokine stimulation. By gene amplification, low levels of IRF-1 mRNA were present in unstimulated, highly purified CD34+ cells; on exposure to IFN-gamma and TNF-alpha, amplified IRF-1 mRNA showed a much stronger signal than control. When CD34+ cells were treated with IFN-gamma and TNF-alpha, IRF-1 antisense oligodeoxynucleotide (ODN) partially reversed the suppressive effects on CD34+ cell-derived colony formation by IFN-gamma but not those by TNF-alpha. In parallel experiments, IRF-1 antisense ODN decreased both IRF-1 protein and mRNA expression. The effects of ODN were sequence-specific and concentration-dependent. These results suggest that the inhibitory hematopoietic effects of IFN-gamma and TNF-alpha are mediated by different pathways. For IFN-gamma, IRF-1 is involved in the activation of cellular genes responsible for IFN-gamma suppressive effects.
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PMID:Hematopoietic inhibition by interferon-gamma is partially mediated through interferon regulatory factor-1. 757 40

Lymphocytes are particularly susceptible to DNA damage-induced apoptosis, a response which may serve as a form of 'altruistic suicide' to counter their intrinsic high potential for mutation and clonal expansion. The tumour suppressor p53 has been shown to regulate this type of apoptosis in thymocytes, but an as yet unknown, p53-independent pathway(s) appears to mediate the same event in mitogen-activated mature T lymphocytes. Here we show DNA damage-induced apoptosis in these T lymphocytes is dependent on the antioncogenic transcription factor interferon regulatory factor (IRF)-1. Thus two different anti-onco-genic transcription factors, p53 and IRF-1, are required for distinct apoptotic pathways in T lymphocytes. We also show that mitogen induction of the interleukin-1 beta converting enzyme (ICE) gene, a mammalian homologue of the Caenorhabditis elegans cell death gene ced-3, is IRF-1-dependent. Ectopic overexpression of IRF-1 results in the activation of the endogenous gene for ICE and enhances the sensitivity of cells to radiation-induced apoptosis.
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PMID:An IRF-1-dependent pathway of DNA damage-induced apoptosis in mitogen-activated T lymphocytes. 763 9

Normally growing cells promptly cease DNA synthesis when exposed to genotoxic stresses, such as radiation, and this cell-cycle arrest prevents the accumulation of mutations. The transcription factor interferon regulatory factor (IRF)-1 is essential for the regulation of the interferon system, inhibits cell growth, and manifests tumour-suppressor activities. Here we show that mouse embryonic fibroblasts (EFs) lacking IRF-1 are deficient in their ability to undergo DNA-damage-induced cell-cycle arrest. A similar phenotype has been observed in EFs lacking the tumour suppressor p53 (refs 8, 9), although the expression of IRF-1 and p53 are independent of one another. Furthermore, we show that transcriptional induction of the gene encoding p21 (WAF1, CIP1), a cell-cycle inhibitor, by gamma-irradiation is dependent on both p53 and IRF-1, and that the p21 promoter is activated, either directly or indirectly, by both in a transient cotransfection assay. These two tumour-suppressor transcription factors therefore converge functionally to regulate the cell cycle through the activation of a common target gene.
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PMID:Cooperation of the tumour suppressors IRF-1 and p53 in response to DNA damage. 875 76

Loss-of-heterozygosity (LOH) has been studied on 3p (von Hippel-Lindau gene locus), 5q and 17p (p53 gene locus) by a polymerase chain reaction (PCR)-based strategy in 42 sporadic renal cell carcinomas (RCC). LOH at seven microsatellite loci on 5q was investigated because a tumor suppressor gene on 5q involved in the development and/or progression of RCC has not yet been identified. LOH was found in seven (17%) RCC at single or multiple loci on 5q, 38% (11/29 informative cases) on 3p, and 6% (2/35 informative cases) on 17p. Replication error (RER) was present in 10% (4/42) RCC at single or multiple loci. The minimum region of deletion on 5q to account for LOH was mapped to 5q31.1 (interferon regulatory factor-1; IRF-1 locus), where LOH was detected in 23% (6/26 informative cases). LOH on 3p and 5q occurred in both stage 2 and more advanced (stage 3 and 4) tumors at similar incidences (41 and 33% on 3p; and 24 and 22% on 5q, respectively), suggesting that LOH on these chromosomes is an early genetic event. All RCC exhibiting LOH on 3p or 5q (IRF-1 locus) were the clear cell or the mixed clear and granular cell types. These findings suggest that LOH on 3p and 5q plays an important role in the genesis of clear cell RCC. In addition, only one tumor exhibited LOH on both 3p and 5q, which suggests that LOH occurs not sequentially but independently.
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PMID:Allelic loss on chromosomes 3p, 5q and 17p in renal cell carcinomas. 908 24

This article attempts to summarize the rapidly advancing field of apoptosis and its regulation, with particular reference to cancer. The long-recognized stereotyped morphology of apoptosis is seen to be the result of convergence of biochemical pathways on common effector mechanisms in which a major element is activation of cysteine proteases with a preference for cleavage at aspartate residues (caspases). The substrates of this reaction are widely dispersed in the nucleus, cytoplasm and cytoskeleton. Caspase activation is the end result of protean stimuli, physiological and pathological. Pathological stimuli include damage to cell membranes, mitochondrial function, DNA and possibly other critical intracellular organelles. Several, distinct agents are known that may be part of the signaling pathways that couple injury to these cellular components to apoptosis: ceramide, collapse of mitochondrial transmembrane potential, p53 activation. Other stimuli are signaled through cytokine receptors (such as fas/APO-1/CD 95 and TNFRI and II) or transcription factors (such as p53, IRF-1 and rb). The transduction of these stimuli into caspase activation is regulated by a large family of proteins (the bcl-2 family). Cancer and apoptosis are related in many ways. In particular, this article explores the possibility that defective apoptosis may permit the persistence of damaged, mutated cells that would otherwise have been deleted. The conditions that lead to this scenario appear to be tissue-specific.
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PMID:Apoptosis and carcinogenesis. 924 79

A novel GM-CSF-dependent myeloid cell line, OHN-GM, was established from a patient who developed acute myelogenous leukaemia (AML) as a consequence of myelodysplastic syndrome (MDS). As the patient had previously received cytotoxic chemotherapy for Hodgkin's disease, the MDS and AML were probably related to such therapy. Sequential karyotypic analysis established a del(5q) as the initial cytogenetic abnormality. Additional alterations, including t(10;13)(q24;q14), had developed subsequently during disease progression. Southern blot analysis of OHN-GM cells suggested deletion of one allele of the IRF-1 gene, although no aberrant transcripts were detected. Fluorescence in situ hybridization analysis revealed the deletion of the Rb gene due to the t(10;13)(q24;q14) translocation, and Western blot analysis demonstrated the absence of Rb protein in OHN-GM cells. Finally, the OHN-GM cells exhibited two missense point mutations in highly conserved regions of the p53 gene. These observations suggest that a multistep process, involving alterations of Rb and p53 genes, may have contributed to the patient's disease development and progression. To our knowledge, OHN-GM is the first cell line derived from a therapy-related AML. These cells may aid the investigation of leukaemogenesis as well as the biology of secondary leukaemia.
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PMID:Alterations of p53 and Rb genes in a novel human GM-CSF-dependent myeloid cell line (OHN-GM) established from therapy-related leukaemia. 926 38

We present evidence of cell death by apoptosis during the development of bone-like tissue formation in vitro. Fetal rat calvaria-derived osteoblasts differentiate in vitro, progressing through three stages of maturation: a proliferation period, a matrix maturation period when growth is downregulated and expression of the bone cell phenotype is induced, and a third mineralization stage marked by the expression of bone-specific genes. Here we show for the first time that cells differentiating to the mature bone cell phenotype undergo programmed cell death and express genes regulating apoptosis. Culture conditions that modify expression of the osteoblast phenotype simultaneously modify the incidence of apoptosis. Cell death by apoptosis is directly demonstrated by visualization of degraded DNA into oligonucleosomal fragments after gel electrophoresis. Bcl-XL, an inhibitor of apoptosis, and Bax, which can accelerate apoptosis, are expressed at maximal levels 24 h after initial isolation of the cells and again after day 25 in heavily mineralized bone tissue nodules. Bcl-2 is expressed in a reciprocal manner to its related gene product Bcl-XL with the highest levels observed during the early post-proliferative stages of osteoblast maturation. Expression of p53, c-fos, and the interferon regulatory factors IRF-1 and IRF-2, but not cdc2 or cdk, were also induced in mineralized bone nodules. The upregulation of Msx-2 in association with apoptosis is consistent with its in vivo expression during embryogenesis in areas that will undergo programmed cell death. We propose that cell death by apoptosis is a fundamental component of osteoblast differentiation that contributes to maintaining tissue organization.
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PMID:Apoptosis during bone-like tissue development in vitro. 940 12

The tumor suppressor proteins IRF-1 and p53 are involved in response pathways after DNA damage. In different cell types, IRF-1 and p53 can cooperate to produce cell cycle arrest (embryo fibroblasts) or can independently trigger apoptosis (lymphoid cells). p53 may also regulate DNA repair, but there is no information on IRF-1 and repair. The cell lineage dependency of these effects precludes extrapolation of findings to other tissues of relevance to human cancer. Here, we report the consequences of IRF-1 deficiency for apoptosis, cell cycle arrest, and DNA repair in primary hepatocytes after DNA damage and extend previous work on the role of p53 in hepatocytes. IRF-1-deficient hepatocytes showed reduced DNA repair activity compared with wild-type, as assessed by unscheduled DNA synthesis after UV irradiation (10J/m2) and by host reactivation of a UV-damaged reporter construct. p53-deficient hepatocytes also showed reduced unscheduled DNA synthesis after UV, but there was no impairment of specific repair in host reactivation assays. IRF-1 deficiency did not affect the p53-dependent G1/S arrest after UV irradiation. Hepatocyte apoptosis after UV treatment, previously reported to be independent of p53, was also independent of IRF-1. However, IRF-1 deficiency produced dysregulation of p53, manifested as increased transactivation of a p53-reporter plasmid in undamaged hepatocytes, and accelerated p53 stabilization after DNA damage. Hence, in hepatocytes, IRF-1 is not required for growth arrest or apoptosis after DNA damage, but the results suggest for the first time a role in DNA repair regulation.
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PMID:Altered DNA repair and dysregulation of p53 in IRF-1 null hepatocytes. 947 83

p53 is a tumor suppressor which exerts its function through the regulation of genes mediating cell cycle arrest and the induction of apoptosis. Cellular survival and proliferation can be positively regulated through the action of cytokines. These signals act through the activation of cell surface receptors, and the phosphorylation of intracellular signaling components, e.g. members of the Stat family (signal transducers and activators of transcription). The signaling effects of p53 and the cytokine receptors on the cellular phenotype are counteracting. We investigated the influence of p53 on the transactivation potential of Stat5. p53 repressed the prolactin induction of the Stat5 mediated transcription of the beta-casein promoter-luciferase reporter gene, but did not affect IFN-gamma induced, Stat1 dependent transcription of the IRF-1 promoter. The inhibition was not due to a decrease in the cellular concentration of Stat5 or to interference with its specific DNA binding activity. No repression of the basal transcriptional activity of the beta-casein promoter was observed. p53 mutants defective in their DNA binding or oligomerization functions had only weak inhibitory effects, but a mutant of p53 in the transactivation domain, efficiently repressed Stat5 dependent induction. The repressive function of p53 on Stat5 activity is independent of the amino-terminal transactivation domain, but requires a functional DNA binding domain and the carboxyl-terminal domain. Our experiments show that p53 counteracts Stat5 mediated cytokine induction of gene transcription. The effect is specific for Stat5 and independent of p53 induced apoptosis.
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PMID:p53 suppresses cytokine induced, Stat5 mediated activation of transcription. 980 59

This paper reviews the functions of and connections between the presumed DNA damage sensors: poly(ADP-ribose) polymerase (PARP), DNA-dependent protein kinase (DNA-PK), the protein product of the ataxia telangiectasia mutated (ATM) gene, and the tumor suppressor, p53. Recognition of DNA damage is associated with the generation of alarm signals. The possible alarm signals include synthesis of poly(ADP-ribose) polymers and initiation of phosphorylation cascades by kinases complexed with the DNA damage sensors, DNA-PK and ATM; the role of other factors is discussed, among them BRCA1 and 2, IRF-1 and RB (retinoblastoma). Alarm signal molecules generated in the cytoplasm or plasma membrane are reactive oxygen species and ceramide. Some of the signal pathways are discussed. The p53 protein, which is poised in the central junction of the postirradiation signaling, as well as p53-independent signaling pathways form an intricate network that executes concerted and partly overlapping functions in the cellular response to ionizing radiation. These functions comprise activation of specific groups of genes, control of progression through the cell cycle checkpoints, inhibition of replication and transcription, induction of apoptosis, or an adaptive response; these features of the cellular response to radiation are discussed. They affect the fate of the irradiated mammalian cell as markedly as the DNA repair efficiency. This is shown in examples of the effect of inhibition of signaling on the adaptive response of human lymphocytes and on survival of tumor cells.
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PMID:Monitoring and signaling of radiation-induced damage in mammalian cells. 980 12

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