Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:P04637 (p53)
77,613 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The authors have assayed the level of expression of several cell-cycle related genes in several populations of circulating myeloid leukemic blast cells. The genes explored included oncogenes such as c-myc, c-myb, p53, and cell-cycle-related genes such as vimentin, calcyclin, ornithine decarboxylase (ODC) and histone H3. Particular attention was given to analysis of the relationship existing between the mRNA levels of the histone H3 gene, which is expressed specifically in the S phase of the cell cycle, and the levels of other genes that are expressed in different stages of the G1 phase. Remarkable differences were observed among the different cases indicating that a differential expression of cell-cycle-related genes characterizes many acute leukemias. This differential expression is reflected in an altered ratio among G1-related genes and the H3 histone gene. The large fraction of leukemic cells which does not express histone H3 and therefore is functionally noncycling, shows a heterogeneous pattern of G1-related gene expression. This reflects the inability of most leukemic cells to progress through the G1 phase into the S phase of the cell cycle. This inability represents an abnormality of the cell cycle. It is concluded that the study of the expression of cell-cycle genes and protooncogenes in in understanding how leukemic cells enter a state of proliferation arrest, which appears to occur in a large fraction of leukemic cells.
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PMID:Expression of oncogenes and cell cycle related genes in acute and chronic leukemias. 319 78

We have investigated the expression of six growth-regulated genes (c-myc, c-myb, p53, 4F1, 2F1, and ornithine decarboxylase) and the S-phase-specific histone H3 gene in acute myeloid and lymphoid leukemic cells. We have purposely chosen three growth-regulated protooncogenes that share similar biological features and three gene sequences that have in common the cell cycle dependence of their expression in cells of different tissue and in different species. The level of expression was determined by measuring the amounts of specific RNA by Northern blot analysis. Levels of expression of the six growth-regulated genes were compared to the level of expression of the S-phase-specific H3 gene and among themselves. This method distinguishes the increased expression of a growth-regulated gene due to a true altered activation from over-expression which simply reflects an increase in the fraction of cycling cells. We have found that six of 14 patients with acute leukemias have markedly high ratios of c-myc/H3, c-myc/p53, and c-myc/c-myb expression. Two patients with altered c-myc expression have also a high ratio p53/H3. Within the group of cell cycle-dependent genes the ratios of expression seem in the overall much more regular with the clear exception of a patient with acute myelogenous leukemia in which the ratios 4F1/H3 and 2F1/H3 are significantly increased. A possible interpretation of these findings is that the fraction of noncycling leukemic cells that often constitute the majority of the entire leukemic population is in some cases in a true resting state, whereas in other cases heterogeneous degrees of growth arrest might occur. The altered expression of c-myc seems the feature most commonly associated with this putative growth arrest of leukemic cells suggesting that this gene may contribute to the impairment of proliferative control that is associated with the leukemic phenotype.
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PMID:Expression of growth-regulated genes in human acute leukemias. 375 69

We have investigated the expression of growth-regulated genes in tsJT60 cells, a temperature-sensitive (ts) mutant of Fischer rat cells, which, on the basis of its kinetic behavior, can be classified as a G0 mutant. It grows normally at 34 degrees C and also at 39.5 degrees C if shifted to the higher temperature during exponential growth. However, if the cell population is first made quiescent by serum deprivation, subsequent stimulation by serum induces the cells to enter S phase at 34 degrees C but not at 39.5 degrees C. A panel of growth-regulated genes was used that included three protooncogenes (c-fos, c-myc, and p53), several genes that are induced in G0 cells stimulated by growth factors (beta-actin, 2A9, 2F1, vimentin, JE-3, KC-1, and ornithine decarboxylase), and an S-phase gene (histone H3). The expression of these growth-regulated genes was studied in both tsJT60 cells and its parental cell line, rat 3Y1 cells. All the genes tested, except histone H3, are similarly induced when quiescent tsJT60 cells are stimulated by serum at either permissive or restrictive temperatures. These results raise intriguing questions on the nature of quiescence and the relationship between G0 and G1 in cells in culture.
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PMID:Expression of growth-regulated genes in tsJT60 cells, a temperature-sensitive mutant of the cell cycle. 380 8

Colorectal cancer affect the 15% of general population in developed countries. Cancer is a multistep process in which multiple genetic alterations must usually occur in several years. The premalignant step consists of one or multiple aberrant crypts due to hyperproliferation of cells and its shift from the deep third of the crypt to its surface. It has been suggested that abnormality in the APC gene is responsible for this. Furthermore, there exists DNA hypometilation, activation of the gene K-ras and ornithine decarboxylase activity. There is also a loss of MCC gene, that seems to interact with the APC gene. Entire alterations described make possible the Class I adenoma formation. This adenoma, needs the loss of the DCC gene (late stage in the carcinogenesis process), to become a Class II adenoma. The following alteration is deleted and mutation of the p53 gene. There is also an activation of the c-myc oncogene. These two genes are important mechanisms for the conversion of a benign adenoma to a malignant one, adenoma with in situ carcinoma or Class III adenoma. This type of adenoma becomes carcinoma and metastatic stage, throughout inactivation of several tumor suppressor genes. Besides the hereditary APC alteration and other acquired genetic changes as described above there are other associated genetics, antigenics, and enzymes that have an important role in the adenoma-carcinoma sequence. Several carcinogenic factors have been described which also contribute in the adenoma and carcinoma formation: ulcerative colitis, acromegaly, familial history of colonic neoplasia, certain professions, smoking and drinking, consumption of red or processed meat, etc.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:[Etiology of colorectal cancer]. 755 83

Proteasomes are large, unique protein complexes catalyzing energy- and ubiquitin-dependent proteolysis. Recent studies have revealed that these complexes are involved in two important cellular functions. One is to make antigen fragments for major histo-compatibility complex (MHC) class I-restricted antigen presentation and the other is to regulate the cell cycle by proteolysis. Here we review only the latter function of proteasomes. Proteasomes are widely distributed in eukaryotic cells, but their levels have been shown to be particularly high in various immature cells, such as cancerous, fetal and lymphoblastic cells, and agents including cell differentiation were found to suppress their expression. These conditions also regulate the expression of ubiquitin genes in a similar way, suggesting that proteasomes act ubiquitin-dependently in their 26S form in immature cells. High levels of proteasomes were found immunochemically in the nuclei of rapidly growing cells, indicating that proteasomes are important for eukaryotic cell growth. Indeed, gene disruptions of most subunits of proteasomes in yeast resulted in total suppression of cell growth and cell death. Short-lived regulatory factors of the cell cycle, such as Fos, p53, Mos, and cyclins are degraded by the proteasome-ubiquitin pathway under phosphorylated or dephosphorylated conditions. Ornithine decarboxylase, which is also a short-lived enzyme and is involved in the early phase of cell growth, is quickly degraded by proteasomes with antizyme, but without ubiquitination. Recently, we found that one of the regulatory factors of 26S proteasomes, p31, is a homologue of Nin1p, whose mutation caused inhibition of the cell cycle in yeast. These results indicate that proteasomes play important roles in regulation of the cell cycle in eukaryotes.
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PMID:Roles of proteasomes in cell growth. 756 64

The c-myc oncogene c-Myc is commonly activated in cancer and transactivates gene expression by binding to CACGTG DNA sequences as a heterodimeric complex with Max. The ornithine decarboxylase (ODC), p53, prothymosin alpha and ECA39 promoters are transactivated by c-Myc, and are considered direct targets, as activation is mediated by CACGTG sequences. Interestingly, the c-Myc-responsive CACGTG sequences in the p53, prothymosin alpha, ECA39 and murine ODC genes are all downstream of the RNA CAP site, suggesting that downstream sequences are preferred c-Myc targets. Using a series of heterologous reporter constructs, we have tested the effects of position and orientation of c-Myc-responsive CACGTG sequences on c-Myc's ability to activate transcription. A single binding site conferred c-Myc-responsiveness independent of position and orientation, and over distances of 1.7 kbp. The extent of transactivation was not significantly influenced by position of the responsive elements. By contrast, the extent of transactivation was dependent upon the number of c-Myc binding sites. The results demonstrate that c-Myc activates transcription independent of position and orientation and that considerable flexibility exists in the interaction of c-Myc transactivation domains with the general transcription machinery.
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PMID:Position and orientation independent transactivation by c-Myc. 778 88

By manipulating the circulating blood level of androgen, it is possible to induce either the programmed death (apoptosis) or proliferation of prostatic glandular cells. To examine the role of differential gene regulation in these two procedure, the expression of the mRNA of a series of genes was quantitated on a per cell basis during the androgen ablation-induced programmed death of rat prostatic glandular cells. These results were then compared to quantitative analysis of the mRNA expression of these same series of genes during the proliferative regrowth of prostatic glandular cells induced in rats castrated for 1 week before being treated with exogenous androgen replacement. These comparisons demonstrated that androgen ablation-induced programmed death of prostatic glandular cells share several (i.e. c-myc, H-ras, and tissue transglutaminase), but not most, of the epigenetic changes associated with androgen-stimulated proliferation of these cells. No enhancement of the mRNA expression of several genes required for entrance of prostatic glandular cells into the S-phase of the proliferative cycle (i.e. histone-H4, c-fos, p53, and ornithine decarboxylase) occurred during androgen ablation-induced programmed death of these cells. These results demonstrated that neither entrance into the S-phase nor progression through a defective proliferative cell cycle is involved in androgen ablation-induced programmed death of prostatic glandular cells. This was further supported by the observation that there is a set of genes (i.e. TRPM-2, transforming growth factor-beta 1, alpha-prothymosin, and calmodulin) in which mRNA expression is only enhanced during programmed cell death and not during proliferation of prostatic glandular cells induced by androgen replacement. These results demonstrate that prostatic programmed cell death is a distinct pathway from cell proliferation involving differential gene regulation.
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PMID:Differential gene regulation during programmed death (apoptosis) versus proliferation of prostatic glandular cells induced by androgen manipulation. 824 89

Juvenile polyps (JP) are the most common colonic tumor in children. Although considered benign, malignant transformation has been reported in JP. Ornithine decarboxylase (ODC) and tyrosine kinase (TyK) enzymes are markers for a rapid cell proliferation index. DNA aneuploidy score and p53 gene expression are late malignant changes seen in patients with colon cancer. In this study, we investigated ODC and TyK activities as well as DNA aneuploidy score and p53 expression in juvenile polyps compared with the adjacent normal colonic mucosa. Results showed that ODC was significantly increased in JP compared with the adjacent normal colonic mucosa. TyK activity was increased in 3/5 polyps and decreased in 2/5 polyps compared with the mucosa. Mean TyK activity was higher in JP compared with normal mucosa but did not reach significance (707 and 632 pmol/mg pmol, respectively). Moreover, changes in phosphorylization of TyK proteins was also observed in JP but not in normal mucosa. JP had a normal DNA aneuploidy score and showed no expression of p53 gene. We conclude that JP do not express p53 gene and aneuploidy but had higher activity of ODC and TyK enzymes, suggesting a higher stage of cell proliferation.
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PMID:Ornithine decarboxylase and tyrosine kinase activity in juvenile polyps of childhood. 855 12

Degradation provides one means for controlling the cellular level of the p53 tumor suppressor. Here we have determined a structural element of p53 required for degradation. To create a substrate amenable to in vitro analysis of proteolysis, we appended to p53 the N terminus of antizyme, a protein that binds to and induces degradation of mammalian ornithine decarboxylase (ODC). We found using deletion analysis that an element within amino acids 100-150 is required for degradation of the fusion protein. A monoclonal antibody (PAb246) that binds close to this region prevents the degradation induced by human papillomavirus 16 E6 protein. Furthermore, we found that amino acids 100-150 of p53 can function as an independent domain to induce Trypanosoma brucei ODC, a stable protein, to be degraded in vivo or, by cooperating with an antizyme binding domain of ODC, to confer polyamine-dependent regulation.
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PMID:Identification of a region of p53 that confers lability. 862 97

Ultraviolet radiation activates the expression of a wide variety of genes, by pathways which differ between the short non-solar ultraviolet C (UVC) wavelengths, which are strongly absorbed by nucleic acids, and the long solar ultraviolet A (UVA, 320-380 nm) wavelengths, which generate active oxygen intermediates. Intermediate solar ultraviolet (UV) wavelengths in the UVB (290-320 nm) range also contain an oxidative component, but more closely resemble UVC in their gene activating properties. Short wavelength UV, in common with other extracellular stimuli including growth factors, activates signal transduction events that involve both stress- and mitogen-activated protein kinase cascades. The extrapolation of the complex modulation of gene expression that ensues to the consequences of natural UV exposure requires careful attention to the details of doses and wavelength employed in the model experiments. Nevertheless, there is evidence that UVB irradiation of skin can activate the expression of proteins including immunomodulating cytokines, ornithine decarboxylase and, to a limited extent, nuclear oncogene products, as well as lead to stabilisation of p53. Non-cytotoxic doses of UVA radiation also lead to the strong activation of several genes which would be expected to have functional relevance in vivo.
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PMID:Activation of mammalian gene expression by the UV component of sunlight--from models to reality. 885 Oct 47


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