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Query: UNIPROT:P04637 (p53)
77,613 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We have generated a series of murine erythroleukemia clones that ectopically express a temperature sensitive mutant p53 allele. In many clones, activation of p53 at low temperature resulted in the accumulation of cells in G1 and in apoptosis. Several cytokines including erythropoietin, IL-3 and the ligand for the Kit receptor blocked p53-dependent apoptosis in p53ts-expressing cells at 32 degrees C. Cytokine-treated cells were reversibly arrested in G1 and resumed growth upon return to 37 degrees C. Certain clones exhibited only a G1 arrest in response to p53 activation at 32 degrees C. One of the these clones secreted erythropoietin and another secreted IL-3. We tested the possibility that autocrine secretion of IL-3 played a role in preventing apoptosis and showed that disruption of the autocrine loop by cell dilution or with neutralizing antibodies to IL-3 restored p53-dependent apoptosis at 32 degrees C. Thus, two properties of p53 protein, namely, its ability to arrest cells in G1 and its ability to promote apoptosis could be uncoupled by cytokines acting as survival factors.
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PMID:p53-mediated cell cycle arrest and apoptosis. 920 79

The AML14.3D10 human myeloid leukemic cell line expresses receptors for granulocyte-macrophage colony stimulating factor (GM-CSF) and interleukin-5 (IL-5), but not IL-3. We have found that this cell line produces GM-CSF in amounts up to 113 pg/ml in culture supernatants. Deprivation of endogenous GM-CSF by addition of neutralizing anti-GM-CSF antibody strongly inhibits proliferation of the cells, suggesting a GM-CSF autocrine growth mechanism. To examine whether endogenously produced GM-CSF activates intracellular GM-CSF/IL-3/IL-5-related signal transduction pathways, we performed antiphosphotyrosine immunoblotting of cell lysates of AML14.3D10 cells before and after deprivation of endogenous GM-CSF. We found constitutive tyrosine-phosphorylation of a number of proteins in AML14.3D10 that could not be detectably increased by the addition of exogenous GM-CSF, IL-3, or IL-5. However, GM-CSF-deprived cells demonstrated a marked increase in phosphorylation of proteins of identical molecular mass following addition of GM-CSF and IL-5, but not IL-3, consistent with the receptor expression of the cells and the known use of the same signaling pathways by the three cytokines. This suggests that AML14.3D10 cells use endogenously produced GM-CSF to activate signal transduction pathways, interfering with activation by exogenous cytokine until the endogenous stimulation is removed. We then assessed the activation of the beta-subunit common to the GM-CSF/IL-3/IL-5 receptors (beta c), JAK2 and p53/56 lyn, known to be involved in the common signaling pathways of the three cytokines. We found that phosphorylation of beta c and JAK2 in response to GM-CSF and IL-5 could be markedly enhanced by depriving cells of endogenous GM-CSF. Constitutive hyperphosphorylation of lyn was found in AML14.3D10 cells, and no further activation of lyn in response to cytokine was demonstrable in GM-CSF-deprived cells, suggesting that lyn is activated in this cell line by a mechanism other than GM-CSF. These studies represent the first demonstration of autocrine activation of intracellular cytokine signaling pathways by malignant hematopoietic cells. Because the addition of anti-GM-CSF to cell cultures improved responsiveness of intracellular signal transducing molecules to exogenous GM-CSF and IL-5, it can be inferred that endogenously produced GM-CSF exerts its effects by secretion and binding to surface GM-CSF receptors, although an intracellular component to signaling cannot be excluded. These observations provide further information regarding an autocrine contribution to leukemic cell growth, and establish a new model for study of these events.
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PMID:Autocrine activation of the IL-3/GM-CSF/IL-5 signaling pathway in leukemic cells. 932 48

Upstream stimulating factor (USF2) is a basic helix-loop-helix leucine zipper transcription factor, which is found in most tissues. A critical role for USF2 in cellular proliferation has been proposed based on its importance in the regulation of various cyclins and P53 and its capability to antagonize c-myc. In this paper we report that IL-3, which is a major growth factor for mast cells, induces USF2 protein synthesis in murine mast cells (MC-9). Surprisingly, it does not significantly affect the level of USF2 mRNA in these cells at any of the time points tested. Using polysomal fractionation and RNA analysis we then demonstrated that this translational regulation is mostly the result of increased USF2 translational efficiency. Moreover, protein kinase C (PKC) inhibitors prevented both the induction of USF2 protein synthesis and the increase in USF2 translational efficiency in IL-3-activated mast cells. Two other hematopoietic cell lines were used to determine whether the translational regulation of USF2 is of a more general nature: mouse lymphosarcoma cells whose proliferation is inhibited by dexamethasone; and mouse erythroleukemia cells that differentiate upon exposure to hexamethylen bisacetamide. In both cell types, USF2 translation was repressed in the non-dividing cells. This strongly implies that USF2 is translationally repressed in quiescent hematopoietic cells. Considering the proposed role of USF in proliferation it seems that translational regulation of USF2 might have an important role in cellular growth.
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PMID:Growth-dependent and PKC-mediated translational regulation of the upstream stimulating factor-2 (USF2) mRNA in hematopoietic cells. 948 40

Deregulation of the S-phase promoting E2F-1 transcription factor has been shown to cooperate with p53 to induce apoptosis. BaF3 cells undergo rapid, p53-dependent apoptosis when irradiated in the absence of IL-3. Rapid apoptosis induced by ionizing radiation (IR) coincides with attenuated p21(WAF1/Cip1) induction. Failure to adequately induce p21 could result in inappropriate release of E2F from Rb which may then cooperate with p53 to induce apoptosis in cells deprived of growth factor. We engineered BaF3 cells to express exogenous p21 and tested whether overexpressing p21 in cells irradiated in the absence of IL-3 protects from IR-induced apoptosis. Enforced p21 expression resulted in a consistent, but partial, protection of cells from undergoing IR-induced apoptosis. However, deregulating E2F activity through expression of HPV E7 failed to sensitize cells to IR-induced apoptosis in the presence of IL-3. Together, these data strongly suggest that the IL-3-responsive factors which modulate p53-mediated apoptosis in BaF3 cells are largely independent of G1 cell cycle checkpoint control mediated by p21.
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PMID:Small contribution of G1 checkpoint control manipulation to modulation of p53-mediated apoptosis. 951 69

Overexpression of wild-type p53 in M1 myeloid leukemia cells induces apoptotic cell death that was suppressed by the calcium ionophore A23187 and the calcium ATPase inhibitor thapsigargin (TG). This suppression of apoptosis by A23187 or TG was associated with suppression of caspase activation but not with suppression of wild-type-p53-induced expression of WAF-1, mdm-2, or FAS. In contrast to suppression of apoptosis by the cytokines interleukin 6 (IL-6) and interferon gamma, a protease inhibitor, or an antioxidant, suppression of apoptosis by A23187 or TG required extracellular Ca2+ and was specifically abolished by the calcineurin inhibitor cyclosporin A. IL-6 induced immediate early activation of junB and zif/268 (Egr-1) but A23187 and TG did not. A23187 and TG also suppressed induction of apoptosis by doxorubicin or vincristine in M1 cells that did not express p53 by a cyclosporin A-sensitive mechanism. Suppression of apoptosis by A23187 or TG was not associated with autocrine production of IL-6. Apoptosis induced in IL-6-primed M1 cells after IL-6 withdrawal was not suppressed by A23187 or TG but was suppressed by the cytokines IL-6, IL-3, or interferon gamma. The results indicate that these Ca2+-mobilizing compounds can suppress some pathways of apoptosis suppressed by cytokines but do so by a different mechanism.
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PMID:Different mechanisms for suppression of apoptosis by cytokines and calcium mobilizing compounds. 953 84

Adenovirus infection of CD34+ hematopoietic stem/progenitor cells is dependent on the multiplicity of infection (MOI), time of incubation, the volume in which the co-incubation occurs and the presence or absence of growth factors. Studies revealed that a brief co-incubation (1-8 hours), resulted in low levels of transgene expression, suggesting that adenovirus infection of CD34+ cells occurs slowly, and optimal transduction requires a 24 hour exposure to adenovirus. Infection by Ad/beta-gal or Ad/p53 at a MOI of 500:1 provided a high transduction efficiency but inhibited hematopoietic function. However, treatment at a MOI of 50-100 resulted in efficient transduction (10.7-15.7% positive) without detectable toxicity. Secondary proof of adenovirus transgene expression was demonstrated by detection of mRNA for p53 in Ad/p53 infected stem cells. We conclude that a 24 hour exposure to recombinant adenovirus encoding p53 or beta-gal, at a MOI of 50-100 is optimal for in vitro gene transfer to BM cells and has no significant effect on hematopoietic function. Adenovirus-mediated transduction of BM cells can also be modulated by growth factors (IL-3, GM-CSF and G-CSF) with improved gene delivery and maintenance of hematopoietic function. In summary, adenovirus vectors can be used to transiently transduce stem cells, and conditions have been defined to maximize expression and limit inhibitory effects on CD34+ cells. These data support continued investigation of this vector for local cytokine delivery and purging of stem cell products.
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PMID:Enhancement of adenovirus-mediated gene transfer to human bone marrow cells. 964 58

Immunohistological methods did not elucidate the etiology and pathogenesis of Hodgkin's disease. In "classical" cases the immunophenotype is based on evidence of three markers: CD30+, CD15+, CD20-. Despite the use of more recent methodical approaches a considerable percentage of Hodgkin and RS cells with CD15 antibody is negative. The Epstein-Barr virus (EBV) plays an important part in the development of malignant disease and at the same time a number of nuclear antigens can be detected: EBNA-1, EBNA-2, EBNA-3a,-3b,-3c,LP. Also latent membrane proteins LMP-1, -2a, -2b and two small ribonucleic acids described as EBER-1, EBER-2. Bcl-2 protein was detected in the majority of malignant lymphomas which reduces its value in differential diagnostic reflections. In Hodgkin and RS cells its positivity is not due to translocation or other disorders of the cell genoma. In these cells the expression of mRNA for bcl-2 is much more constant. Most probably there is no cooperation of bcl-2 and p53. Co-expression of the two genes was found only in a small percentage of patients with m.Hodgkin. The varied morphological picture in particular in the mixed type of m. Hodgkin is most probably associated with the formation and release of cytokines, factors which stimulate cell colonies (IL-3, GM-CSF, G-CSF, M-CSF). Non-tumourous cells chemotactically attracted to sites of tumour cells release further cytokines e.g. TGF-beta, IL-1, Il-2, which participate in the overall morphological appearance of the lesion.
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PMID:[Molecular biology aspects of Hodgkin's disease]. 982 63

The wild-type human MDM2 protooncogene was tested for its ability to modulate apoptotic activity of the de novo expressed p53 tumor suppressor gene in K562 cells. We also studied the role of some cytokines in this phenomenon. K562, a human myeloid leukemia cell line, does not express p53 at the mRNA or protein level. In this study, we stably transfected K562 with eukaryotic vectors containing either normal p53 cDNA (pC53-SN3) or mutated p53 (143Val-->Ala) cDNA (pC53-SCX3). Transfectants expressing WT p53 or those expressing mutant p53 are called K562 SN and K562 SM respectively. Many leukemic cell lines undergo apoptosis when de novo WT p53 is expressed alone. In contrast, while the resulting clones (K562 SN and K562 SM) expressed p53, they did not undergo apoptosis. However, when treated with MDM2 mRNA antisense (MDM2 AS) oligodeoxynucleotides (ODNs), K562 SN demonstrated apoptotic features at both molecular and morphological levels. No change was observed when the other clones (K562 and K562 SM) were treated with MDM2 AS. Apoptosis induced in this manner was associated with a relatively small increase in intracellular calcium [Ca2+]i. Cells cultured in medium previously supplemented with recombinant human (rh) interleukin (IL)-3 and rh-erythropoietin (Epo) did not undergo apoptosis. Moreover, K562 SN cells were induced to differentiate. This differentiation was evaluated by measuring hemoglobin (Hb) level in cellular extracted proteins and by analyzing erythroid colony number and morphology. High Hb synthesis was obtained when K562 SN cells were cultured with cytokines (IL-3 + Epo) combined with MDM2 AS. Our results are consistent with the hypothesis that the function of the proto-oncogene MDM2 is to provide a 'feedback' mechanism for the p53-dependent pathway of apoptosis that could be shunted toward differentiation.
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PMID:Rescue of K562 cells from MDM2-modulated p53-dependent apoptosis by growth factor-induced differentiation. 1008 38

We have come to understand apoptosis as not merely a single form of cell death, but as a fundamental theme in cell biology that has far-reaching implications in the fields of physiology and pathology. At the present time, however, the mechanism of apoptosis is not clearly understood, as research into apoptosis is still at the initial stages. Nevertheless, the links between apoptosis and a variety of pathological conditions are gradually becoming clearer. In this article, we will provide a simple explanation of apoptosis and its mechanism as a novel concept of cell death and discuss the way in which apoptosis has been linked to a variety of pathological conditions. WHAT IS APOPTOSIS?: In normal tissue, cells that are no longer needed are rapidly eliminated without affecting the overall function of the tissue. In this process cells undergo an active and spontaneous suicide called programmed cell death. In fact, the majority of physiological cell deaths take the form of apoptosis. The word apoptosis is used, in contrast to necrosis, to describe the situation in which a cell actively pursues a course toward death upon receiving certain stimuli [1]. The morphological changes of apoptosis found in most cell types first involve contraction in cell volume and condensation of the nucleus. When this happens the intracellular organelles such as the mitochondria retain their normal morphology. As apoptosis proceeds, blebbing of the plasma membrane occurs, and the nucleus becomes fragmented. Finally, the cell itself fragments to form apoptotic bodies that are engulfed by nearby phagocytes. With respect to biochemical changes, it is known that the chromosomes become fragmented into nucleosome units, and DNA forms characteristic ladder patterns when subjected to agarose gel electrophoresis. MECHANISM OF APOPTOSIS: It has been reported that apoptosis is induced in various cells by many kinds of irritations, but the precise mechanism is still unclear. Cell injuries that induce apoptosis include those that cause DNA damage such as radiation and anticancer drugs, those that are mediated by the TNF receptor and Fas receptor (the so-called "death signal receptors"), and the deprivation of cytokines that supply survival signals such as IL-3 and erythropoietin. The tumor suppressor gene p53 plays a very important role in apoptosis induced by damage to DNA. This has been demonstrated by studying resistance to apoptosis of cells derived from p53 knockout mice [2]. Other than the irritations that induce apoptosis, molecules that have been strongly implicated as major players in the drama of apoptosis include the Bcl-2 family proteins and the IL-1 converting enzyme (ICE) and its homolog proteases (caspase family). Both groups of proteins show homology with proteins that affect cell death in nematodes. It is believed that molecules that contribute to cell death have been well conserved in multicellular organisms all the way from the relatively primitive nematodes to mammals including humans. It was discovered that Bcl-2 suppressed apoptosis induced in IL-3 dependent cells by deprivation of IL-3 [3]. It has since become the gene around which apoptosis research revolves. Recently, it has become clear that cell death involving the Bcl-2 protein is under the control of similar proteins from the same family [4]. It is interesting that the phenomenon of cell death may be regulated by the balance of the molecules involved in it. APOPTOSIS ABNORMALITIES AND DISEASE: Physiological cell death plays a major role in the growth and permanent maintenance of the human body [5]. In the process of forming the nervous system, neurons that do not form proper connections die. Physiological cell death also accompanies the removal of virus-infected cells by cytotoxic T cells, the elimination of autoreactive immune cells, the formation of the gut, the reconstitution of cartilage and bone, etc. When physiological cell death that normally should occur is inhibited, inappropriate physiological cell death may occur that is harmful to the body and forms the basis of disease. For example, in patients with neural degenerative disorders such as Alzheimer's disease and Parkinson's disease, we can find premature cell death in a particular subset of neurons. The death of T cells in AIDS patients is also a form of physiological cell death. Inhibition of cell death in the immune system enables the survival of autoreactive B cells and T cells, and is therefore a cause of autoimmune disorders. Apoptosis has been particularly linked to cancer. Normal cells are programmed for death if they are subjected to many types of non-physiological stress such as anticancer drugs or radiation, if they become isolated from surrounding cells and are unable to receive their tissue-specific survival signals [6], or if oncogenes are expressed haphazardly [7]. On the other hand, it is believed that the ability to survive is enhanced in transformed cancer cells because they are more resistant to apoptosis, they exhibit resistance to anticancer drugs, they are no longer dependent on survival signals, and they can metastasize. Therefore, the cancer progresses as the cancer cells maintain the proliferative superiority they acquire from their oncogenes. In other words, when cancer cells become resistant to apoptosis, they become resistant to treatment, metastasize, and proliferate destructively. The concept that the malignancy of cancer is due to its resistance to apoptosis is a relatively new one and is worthy of further study.
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PMID:Physician Education: Apoptosis. 1038 21

A thymic stromal cell line, TFGD, was established from a thymic tumor mass developed spontaneously in p53 knock out mouse, and was found to produce cytokines that could induce bone marrow hematopoietic stem cells (HSCs) to differentiate into macrophages. The cytokines produced by the TFGD line were assessed by immunoassays. High level of macrophage-colony stimulating factor (M-CSF) and interleukin (IL)-6 was detected in the TFGD-culture supernatant, whereas granulocyte/macrophage-colony stimulating factor (GM-CSF), IL-3, IL-4, IL-5, IL-13, or interferon (IFN)-gamma was undetectable. Blocking experiments showed that anti-M-CSF monoclonal antibody could neutralize the differentiation-inducing activity shown by the TFGD-culture supernatant. Dot blot analysis of the total RNA isolated from the cultured fetal thymic stromal cells showed that M-CSF transcripts were expressed in the normal thymus. These observations, together with the earlier finding that M-CSF plus IL-6 is the optimal combination of cytokines for the induction of macrophage differentiation from HSCs in vitro, may indicate that thymic macrophages could be generated within the thymus by cytokines involving M-CSF.
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PMID:A mouse thymic stromal cell line producing macrophage-colony stimulating factor and interleukin-6. 1089 58

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