Differential Expression Of C-myc Research Articles

Epigenetic mechanisms regulate placental c-myc and hTERT in normal and pathological pregnancies; c-myc as a novel fetal DNA epigenetic marker for pre-eclampsia.

Placental development is known for its resemblance with tumor development, such as in the expression of oncogenes (c-myc) and telomerase (hTERT). The expression of c-myc and hTERT is up-regulated during early pregnancy and gestational trophoblastic diseases (GTDs). To determine the role of DNA methylation [via methylation-sensitive high resolution melting (MS-HRM)] and histone modifications [via chromatin immunoprecipitation (ChIP assay)] in regulating the differential expression of c-myc and hTERT during normal gestation and their dysregulation during placental disorders, we obtained placental samples from 135 pregnant women, in five groups: normal first, second and third trimester (n = 30 each), pre-eclamptic pregnancy (n = 30) and molar pregnancy (n = 15). Two placental cell lines (JEG-3 and HTR-8/SVneo) and isolated first-trimester cytotrophoblasts were also studied. Quantitative RT-PCR revealed decreased mRNA expression levels of c-myc and hTERT, which were associated with a higher level of H3K9me3 (1.5-fold, P < 0.05) and H3K27me3 (1.9-fold, P < 0.05), respectively, in third-trimester placental villi versus first-trimester villi. A significantly lower level of H3K27me3 in molar placenta was associated with a higher mRNA expression of c-myc and hTERT. The development of pre-eclampsia (PE) was associated with increased methylation (P < 0.001) and H3K27me3 (P < 0.01) at the c-myc promoter and reduced H3K9me3 (P < 0.01) and H3K27me3 (P < 0.05) at the hTERT promoter. Further, mRNA expression of c-myc and hTERT was strongly correlated in molar villi (r = 0.88, P < 0.01) and JEG-3 cells (r = 0.99, P < 0.02). Moreover, on the basis of methylation data, we demonstrate the potential of c-myc as a fetal DNA epigenetic marker for pre-eclamptic pregnancies. Thus we suggest a role for epigenetic mechanisms in regulating differential expression of c-myc and hTERT during placental development and use of the c-myc promoter region as a potential fetal DNA marker in the case of PE.

Oncosecretomics coupled to bioenergetics identifies α-amino adipic acid, isoleucine and GABA as potential biomarkers of cancer: Differential expression of c-Myc, Oct1 and KLF4 coordinates metabolic changes

Bioenergetic profiling of tumors is a new challenge of cancer research and medicine as therapies are currently being developed. Meanwhile, methodological means must be proposed to gather information on tumor metabolism in order to adapt these potential therapies to the bioenergetic specificities of tumors. Studies performed on tumors and cancer cell lines have shown that cancer cells bioenergetics is highly variable. This profile changes with microenvironmental conditions (eg. substrate availability), the oncogenes activated (and the tumor suppressors inactivated) and the interaction with the stroma (i.e. reverse Warburg effect). Here, we assessed the power of metabolic footprinting (MFP) to unravel the bioenergetics and associated anabolic changes induced by three oncogenes, c-Myc, KLF4 and Oct1. The MFP approach provides a quantitative analysis of the metabolites secreted and consumed by cancer cells. We used ultra performance liquid chromatography for quantifying the amino acid uptake and secretion. To investigate the potential oncogene-mediated alterations in mitochondrial metabolism, we measured oxygen consumption rate and ATP production as well as the glucose uptake and lactate release. Our findings show that c-Myc deficiency initiates the Warburg effect along with a reduction of mitochondrial respiration. KLF4 deficiency also stimulated glycolysis, albeit without cellular respiration impairment. In contrast, Oct1 deficiency reduced glycolysis and enhanced oxidative phosphorylation efficiency. MFP revealed that c-Myc, KLF4 and Oct1 altered amino acid metabolism with specific patterns. We identified isoleucine, α-aminoadipic acid and GABA (γ-aminoisobutyric acid) as biomarkers related. Our findings establish the impact of Oct1, KLF4 and c-Myc on cancer bioenergetics and evidence a link between oncosecretomics and cellular bioenergetics profile.

C-Myc Mediated Regulation of Multidrug Resistance Genes in Chronic Myeloid Leukaemia Cd34+ Cell Progenitors.

Abstract 3252Poster Board III-1A better understanding of the mechanisms which regulate drug resistance is critical for improving therapy for patients at risk of poor response. Even for CML patients the long-term benefits of the treatment are limited by the emergence of resistance, although the therapy has been dramatically improved by Imatinib Mesylate, which inhibits Bcr-Abl activity. One of the most important mechanisms of resistance is the disregulation of various members of the highly conserved family of transmembrane proteins characterized by an ATP-binding cassette domain, called ABC superfamily of transporters (Dean et al., Genome Res 2001). In CML cells an aberrant expression of ABC transporter genes has been described to be mediated by specific transcription factors, which are in turn affected by an aberrant activity of Bcr-Abl. It has been shown that Bcr-Abl can indirectly activate c-Myc via the JAK2 pathway, which increases a translation of c-Myc mRNA. In addition, in a subgroup of CML patients a chromosome 8 trysomy, has been observed, which can be associated with c-Myc amplification.In this study we have investigated whether c-Myc can regulate transcription of ABC tranporter genes in CML. Initially, ABC transporter gene expression has been monitored in HL60, a human promyelocytic cell line in which c-MYC is overexpressed. We have examined the expression level of all 48 human ABCs transporters as a function of c-MYC silencing. Our results have demonstrated that c-Myc regulates the transcription of several ABC genes, such as ABCA2, ABCB9, ABCB10, ABCC1, ABCC4, ABCE1, ABCF1, ABCF2, a majority of which has been found implicated in drug resistance. Furthermore, by performing chromatin immunoprecipitation (ChIP) we have shown a direct binding of c-Myc to the promoters of those ABC transporter genes in HL60 cell line. In addition, by ChIP we have demonstrated that c-MYC is physically bound to the promoter of tested ABC genes in CML cell lines KG-1a and K562.Based on those findings we have investigated the expression level of c-Myc in CD34+ progenitor cells derived from CML patients. Also, we have evaluated the effects of highly expressed c-Myc on ABC transporters. Our results have shown in a group of 20 newly diagnosed chronic phase (CP)-CML patients an increased expression of c-Myc in CD34+ cell fraction, when compared to the expression level of c-Myc in the entire population of mononuclear cells from which CD34+ cell fraction has been purified. In those cells we have identified in association with an increased level of c-Myc an increased expression of the same subset of ABC genes, which we have observed in cell lines. Furthermore, we have evaluated whether a differential expression of c-Myc and ABC transporter genes is associated with low Sokal risk and high Sokal risk patients. This analysis has been performed on CD34+ cells purified from 19 CML patients of whom 12 were scored as low Sokal risk and 7 as high Sokal risk. Our results have shown that expression of c-Myc and ABCC4 is different in those two patients population (p<0.05). Overall, our results highlight a novel aspect of the Bcr-Abl/c-Myc crosstalk with important implications on ABC genes upregulation in CML cells. These data suggest that inhibitors of Bcr-Abl, as exemplified by Gleevec may affect pathways involved in the regulation of drug resistance. To our knowledge this is the first identification of a small set of genes which reflect Sokal risk dichotomization, a key determinant of optimal and suboptimal response in CML patients. Supported by Novartis Oncology, Clinical Development, TOPS Correlative Studies Network Disclosures:No relevant conflicts of interest to declare.

Regulation of adrenomedullin gene transcription and degradation by the c-myc gene.

Adrenomedullin, a vasodilatory peptide originally isolated from pheochromocytoma, is known to regulate cell growth, apoptosis, and migration. Overexpression of the c-myc oncogene has been shown to suppress the mouse adrenomedullin gene via the initiator element. We investigated whether c-myc regulates rat and human adrenomedullin genes because there appears to be no initiator elements in their promoter regions. Transactivation of the human adrenomedullin gene by c-myc was demonstrated using a luciferase reporter construct containing an upstream sequence. Using a panel of isogenic rat fibroblast cell lines with differential c-myc expression obtained by targeted homologous recombination, we found markedly elevated adrenomedullin transcript levels in cells stably overexpressing c-myc but a minimal decrease in two independent cell lines containing a homozygous null deletion of c-myc. Degradation of adrenomedullin mRNA was enhanced by a c-myc transgene, resulting in a relatively reserved increase in cellular secretion of adrenomedullin-like immunoreactivity. These results indicate that c-myc transactivates rat and human adrenomedullin genes and accelerates the degradation rate of adrenomedullin mRNA. However, c-myc is not essential for basal expression of the adrenomedullin gene.

Differential c-myc expression profiles in normal human bronchial epithelial cells following treatment with benzo[a]pyrene, benzo[a]pyrene-4,5 epoxide, and benzo[a]pyrene-7,8-9,10 diol epoxide.

Bronchial epithelial cells are often exposed to airborne mutagens that have the potential to induce genetic changes involved in the development of lung cancer. Although lung tumors often display alterations in the expression of oncogenes and/or tumor suppressor genes, the role of specific chemicals and/or metabolites in causing these alterations is not well defined. The polycyclic aromatic hydrocarbon (PAH) benzo[a]pyrene (B[a]P), a by-product of combustion, is a prevalent airborne environmental mutagen and a constituent of cigarette smoke. The primary objective of this study was to compare the effect of B[a]P and two of its reactive metabolites, benzo[a]pyrene diol epoxide (BPDE or bay region epoxide) and benzo[a]pyrene-4,5-dihydroepoxide (BPE or K-region epoxide), on expression of the proto-oncogene c-myc in normal human bronchial epithelial (NHBE) cells using a quantitative reverse transcriptase-polymerase chain reaction (RT-PCR) method. Changes in c-myc gene expression were compared with DNA adduct formation, growth inhibition, and cell-cycle progression as determined by (32)P-postlabelling, neutral red (NR), and flow cytometric analyses, respectively. None of the three test compounds altered the levels of 18S ribosomal RNA or beta-actin at the concentrations evaluated for c-myc expression, indicating that nonspecific changes in gene expression induced by cytotoxicity, for example, were not present at the concentrations evaluated. Cells exposed to B[a]P exhibited a dose-dependent increase in c-myc expression; conversely, a dose-dependent decrease in c-myc expression was observed following BPDE exposure. A marginal but concentration-dependent increase in c-myc mRNA levels was observed following exposure to the K-region epoxide. Our results demonstrated that, although B[a]P and its metabolites alter c-myc expression, the parent compound and its metabolites produce unequal and contrasting effects on the expression of this gene.

Endothelin-1 is a potent survival factor for c-Myc-dependent apoptosis.

Many vertebrate cells are resistant to apoptotic stimuli, whose variety and the mechanisms involved are not fully understood. Endothelin-1 is an endothelium-derived vasoactive peptide that mediates many physiological functions, such as vasoconstriction and cell proliferation. Deregulated expression of c-Myc induces apoptosis in serum-deprived fibroblasts. Using a panel of isogenic fibroblast cell lines with differential c-myc expression levels, we demonstrate that low doses of endothelin-1 protect fibroblasts against serum deprivation-induced apoptosis, which occurs through a c-Myc-dependent process. The endothelin-1-induced cell survival was mediated by the ET(A) receptor and was not linked to the ability of endothelin-1 to induce cell proliferation. The survival function of endothelin-1 was abrogated by inhibiting the mitogen-activated protein kinase pathway. These results demonstrate a hitherto unappreciated role of endothelin-1 as a potent survival factor for c-Myc-dependent apoptosis, a process mediated by the ET(A) receptor and the mitogen-activated protein kinase pathway.

Biphasic Regulation of the Preproendothelin-1 Gene by c-myc*

Endothelin-1 (ET-1), a potent vasoconstrictive/mitogenic peptide originally isolated from vascular endothelium, stimulates the expression of immediate early response genes such as c-myc. The c-myc protooncogene participates in regulating the cascade of events that follow mitogenic stimulation of quiescent cells. Using a panel of isogenic fibroblast cell lines with differential c-myc expression levels (obtained by disrupting one c-myc gene copy with targeted homologous recombination and subsequently stably transfecting the heterozygous cells with an exogenous c-myc transgene), we demonstrate that c-Myc protein regulates ET-1 gene transcription in a biphasic fashion: as an activator at low concentrations and as a repressor at high concentrations. Using rat endothelial cells treated with antisense c-myc oligodeoxynucleotides, we also show that c-myc regulates ET-1 synthesis and secretion in a biphasic manner. The present report, therefore, demonstrates the existence of a signal transduction pathway that regulates the synthesis and secretion of ET-1 via the immediate early transcription factor, c-Myc.

Apoptosis of L1210 Leukemia Cells Induced by 3-Deazaadenosine Analogs: Differential Expression of c-myc, NF-Kappa B and Molecular Events.

A new class of potent apogens (apoptosis-inducing agents) has been identified, consisting of 3-deazaadenosine (DZA), 3-deaza-(+/-)aristeromycin (DZAri) and 1-beta-D-arabinofuranosyl-1H-imidazo[4,5-&cumacr;]pyridine (ara-3-deazaadenine; DZAra-A). They are inhibitors of S-adenosylhomocysteine hydrolase and indirect inhibitors of methylation. Furthermore, they have also been found to form 3-deaza-nucleotide analogs. The DZA analogs, DZA, DZAri, and DZAra-A, induced DNA fragmentation in a dose- and time-dependent manner, reaching a maximum at 250 &mgr;M after 72 h. Cycloheximide at 0.5 &mgr;g/ml completely blocked the DNA fragmentation induced by 250 &mgr;M of each of the analogs. Interestingly, exogenous 100 &mgr;M L-homocysteine thiolactone abrogated the DNA fragmentation caused by DZAri and DZAra-A, but not by DZA. Flow cytometric analysis showed that DZA arrested the cells in the G(2)/M phase, whereas the S phase was arrested by DZAri. Correlated with the effect of DZA was a rapid decrease in the expression of c-myc, whereas nur77 and GAPDH were unaffected. In comparison, there was an elevated expression of IFN-gamma mRNA without apparent change in bax, p53 or GAPDH mRNA after 24 h. After treatment with DZA, there was an elevated expression of NF-kappaB DNA binding activity, which became more pronounced at 24 h. Simultaneously, there was an apparent disappearance of AP-1 activity. Thus, DZA most likely inhibited the RNA synthesis of c-myc, a reduction of which could trigger a cascade of gene transcription leading to apoptosis in L1210 cells. Copyright 1997 S. Karger AG, Basel

Apoptosis of L1210 Leukemia Cells Induced by 3-Deazaadenosine Analogs: Differential Expression of c-myc, NF-Kappa B and Molecular Events

Apoptosis of L1210 Leukemia Cells Induced by 3-Deazaadenosine Analogs: Differential Expression of c-myc, NF-Kappa B and Molecular Events

Differential expression of c-myc, max and mxi1 in human myeloid leukemia cells during retrodifferentiation and cell death

Previous studies in human myeloid leukemia cells (HL-60, U-937, THP-1) suggested an involvement of the c-myc gene in the control of mutually exclusive pathways, such as retrodifferentiation and cell death. Treatment of U-937 cells with 12- O-tetradecanoyl phorbol-13-acetate (TPA) which is associated with the induction of a monocytic differentiation program and growth arrest, revealed an initial up-regulation of c-myc, c-max, and mxi1 mRNAs after 1–6 h. Thereafter, expression of these genes significantly declined to barely detectable levels when the cells ceased to grow after 12–24 h of TPA treatment. Between 7 and 11 days of TPA-induced G 0/G 1 cell cycle arrest, expression of the c-max and mxi1 genes continuously increased up to 8-fold until 32 days and declined to control levels when the cells regained proliferative capacity by 36 days. In contrast, c-myc mRNAs remained down-regulated during periods of growth arrest and increased only during re-entry into the cell cycle after 36 days. This effect is consistent with a retrodifferentiation process, whereby previously differentiated cells revert back to the undifferentiated phenotype and re-enter the cell cycle. Different results were obtained during serum starvation-induced cell death of U-937 cells. After 48–72 h of serum-starvation, expression of the c-myc and c-max genes were significantly down-regulated by 4-fold and 3-fold, respectively, while there was little, if any, change in mxi1 mRNA levels. Analysis of cell death in serum-starved U-937 cells demonstrated progressively increasing DNA fragmentation reaching 45.4% ± 0.9% after 72 h. Synchronization of proliferating U-937 cells throughout distinct phases of the cell cycle exhibited little, if any, change in c-myc, c-max and mxi1 mRNAs. Furthermore, like c-myc, c-max and mxi1 mRNA transcripts appeared to be regulated primarily by post-transcriptional mechanisms, and c-max and mxi1 half-lives exceeded 4 h in contrast to < 60 min for the c-myc gene. Taken together, these findings suggested differential regulation and inverse expression levels of c-myc compared to c-max and mxi1 during differentiation, retrodifferentiation and cell death.

Differential Expression of c-myc and N-myc during Oral Organogenesis of the Mouse Embryo.

The expressions of the c- and N-myc proto-oncogenes during oral development of midgestational mouse embryos were examined by in situ hybridization in order to analyze their roles. In the mandibular rudiment, c-myc RNA was strongly expressed in the mesenchymal condensation around the ossification center in which high-level expression of 2 ar (osteopontin) was detected. In tooth germs, c-myc was strongly expressed in the epithelia at the bud stage, and its expression gradually became restricted to the inner enamel epithelia from the cap to bell stages. In contrast, N-myc expression was detected in the undifferentiated mesenchymal cells of the dental papilla. Incorporation of BrdU was examined immunohistochemically to study the relationship between the expressions of c- and N-myc and cell proliferation. Unexpectedly, the distribution of BrdU labelled regions was not coincident with the expressions of c- and N-myc. These results suggest that the level of myc expression is not necessarily related to cell proliferation.

Differential expression of c-myc and the transferrin receptor in G1 synchronized M1 myeloid leukemia cells.

We have studied the transcriptional activity, steady-state mRNA levels, and steady-state protein levels of the c-myc and transferrin receptor (TfR) genes in murine M1 myeloid leukemia cells arrested in G1 phase of the cell cycle by different methods. When cells are growth-arrested by density inhibition, a technique that places the majority of cells in early G1, c-myc protein, as detected by Western analysis, is expressed at 80% of the level seen in proliferating cells. Steady-state mRNA levels and, to a lesser extent, transcriptional activity of the c-myc gene, parallel the protein findings. Under these conditions, TfR gene expression is much lower than in normally cycling cells. We have previously demonstrated that density-inhibited M1 cells, released from density inhibition and treated with the DNA polymerase alpha inhibitor aphidicolin, remain in G1, but at a point temporally closer to S phase. Cells treated in this manner demonstrate reduced transcriptional activity and expression of the c-myc gene, but TfR gene expression approximates the level found in proliferating cells. These data suggest that neither c-myc nor TfR gene expression is constant throughout the G1 phase of the cell cycle in M1 cells. c-myc gene expression is highest in early G1 and falls to low levels by late G1, while the reverse is true for TfR gene expression.

Study of the levels of expression of two oncogenes, c-myc and c-myb, in acute and chronic leukemias of both lymphoid and myeloid lineage

Total cellular RNA from a series of leukemic cell populations, both myeloid and lymphoid, as well as from normal circulating lymphocytes was analysed for the expression of two cellular oncogenes, c-myc and c-myb, by Northern blot hybridization assay. Expression of c-myc but not of c-myb was observed in unstimulated normal lymphocytes. Stimulation by PHA was shown to activate the expression of both genes. Remarkably different levels of expression of c-myc were observed in ALL, whereas in CLL the expression of c-myc was uniformly low or absent. Differential expression of c-myc was detected in AML as well as in CML, c-myb was differentially expressed in AML and ALL, and absent in CLL and CML. Other single cases of hemopoietic disorders were studied, but the expression of the two oncogenes was low or absent. Neither evident genome amplification nor genome rearrangements were detected in the cell DNAs digested with restriction endonucleases.