Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:5.99.1.3 (topoisomerase)
 9,911 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The level of expression of cellular proto-oncogens c-myc and c-fos in rat liver has been studied as a function of protein synthesis rate (cycloheximide dose). Activation of proto-oncogens has been established to be initiated by 50% inhibition of nuclear protein synthesis. This promotes a certain level in chromatin structural rearrangements which is manifested, in particular, in decreasing activity of chromatin cleavage by Ca2+, Mg(2+)-DNAase and increasing degree of chromatin condensation. A role of topoisomerase II in chromatin structural rearrangements during proto-oncogen activation is postulated.
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PMID:[Structural changes of chromatin during proto-oncogene activation by cycloheximide: dose-effect]. 145 95

The epipodophyllotoxin etoposide is an inhibitor of topoisomerase II. The effects of this agent on gene expression, particularly the transcriptional induction of genes implicated in growth control, are unknown. The present results demonstrate that etoposide induces expression of the c-jun protooncogene in HL-60 myeloid leukemia cells. This induction of c-jun expression was maximal at 3 hr and was transient. Similar findings were obtained in the human U-937 myeloid leukemia cell line. Nuclear run-on assays demonstrated that the induction of c-jun expression by etoposide is regulated at the transcriptional level. The results further demonstrate that etoposide-induced c-jun expression occurs in association with the appearance of c-fos transcripts. Moreover, the c-jun gene is induced by etoposide during periods of oligonucleosomal DNA cleavage, which is characteristic of programmed cell death. These findings suggest that transcriptional induction of c-jun expression represents a signaling pathway activated in the cellular response to etoposide-induced DNA damage.
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PMID:Activation of the c-jun protooncogene in human myeloid leukemia cells treated with etoposide. 190 80

We have analyzed 1 kb of cloned human c-fos sequence (-711 to +287) for calf thymus DNA topoisomerase II cleavage sites in vitro. Using the anti-tumor drug VP16 (demethylepipodophyllotoxin-beta-D-glucoside) with purified topoisomerase II, we identify twelve sites. Five sites are clustered around position -306 in a region that possesses enhancer-like properties. A second cluster of three sites is positioned 15 bp upstream of the TATA promoter element. With a HeLa nuclear extract as a source of topoisomerase II, a subset of cleavage sites is conserved within the two clusters. The cleavage sites in the enhancer-like element are conserved in the homologous region of the murine c-fos. These findings raise the possibility that topoisomerase II is involved in mediation of mitogen-induced c-fos expression.
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PMID:DNA topoisomerase II cleaves at specific sites in the 5' flanking region of c-fos proto-oncogenes in vitro. 302 64

The administration of 150 nM etoposide, an inhibitor of DNA topoisomerase II activity, decreased the proliferation and induced the differentiation of U937 human promonocytic cells, as determined by nitroblue tetrazolium reduction, surface accumulation of CD11b/CD18 and CD11c/CD18 integrins, and c-fms protooncogene expression. The expression of these differentiation markers started to be detected at 24 h of treatment. Etoposide caused little cell damage, as determined by trypan blue exclusion and by apoptotic-like DNA degradation, which was slightly initiated at 48 h. The treatment induced a transient increase in c-fos, c-jun, and jun B mRNA levels, with maximum values at 12 h, a transient increase in collagenase mRNA level, with maximum value at 48 h, and a progressive increase in vimentin and lamin A and C mRNAs. These changes were qualitatively similar to those produced by 12-O-tetradecanoylphorbol-13-acetate. Etoposide also caused a transient increase of total AP-1 binding activity, with maximum value at 12 h of treatment, as determined by gel retardation assays. The drug produced an early transient activation (3-6 h) of membrane-bound protein kinase C, followed by the later activation (48 h) of both the membrane and cytosolic enzyme. The protein kinase C inhibitors, sphinganine and 1-(5-isoquinolinylsulfonyl)-2-methylpiperazine (H7), attenuated the induction of differentiation markers by etoposide. These results suggest that protein kinase C and AP-1-dependent gene expression could be involved in myeloid cell differentiation by DNA topoisomerase II inhibitors.
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PMID:Etoposide-induced differentiation of U937 promonocytic cells: AP-1-dependent gene expression and protein kinase C activation. 781 32

Etoposide (VP-16) is one of several DNA-damaging agents that induce subcellular structural changes associated with apoptosis. VP-16 exerts its DNA-damaging and cytotoxic effects subsequent to interference with DNA topoisomerase II activity. VP-16 also stimulates c-jun and c-fos mRNA expression in some cell lines, including human leukemia K562 and HL-60 cells. To compare the temporal relationship between drug-induced c-jun expression and apoptosis, we examined cell morphology, cell viability, DNA integrity, and c-jun induction during VP-16 treatment of K562 and HL-60 cells. VP-16 (10 microM)-induced internucleosomal DNA damage and nuclear fragmentation were readily apparent within 6 hr in HL-60 cells but were absent in K562 cells treated for up to 24 hr. Some internucleosomal DNA damage was observed in K562 cells but only after treatment with 100 microM VP-16 for 24 hr. In contrast, VP-16-induced DNA single-strand breaks, VP-16-induced topoisomerase II/DNA covalent complex formation, and VP-16-mediated growth inhibition were similar in K562 and HL-60 cells. Also, the time course of VP-16-induced c-jun mRNA expression was comparable for both K562 and HL-60 cell lines. Western blot analysis of whole-cell lysates showed that Bcl-2 protein levels were 13-fold greater in HL-60 cells than in K562 cells. Thus, the resistance of VP-16-treated K562 cells to apoptosis was not attributable to protection by Bcl-2. Furthermore, the relatively high levels of Bcl-2 in HL-60 cells were not sufficient to protect these cells against apoptosis. Together, our results indicate that the temporal coupling of VP-16-induced DNA damage, c-jun expression, and apoptosis is cell type specific and suggest that different signaling pathways for apoptosis are operating in these two human leukemia cell lines.
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PMID:Differential induction of etoposide-mediated apoptosis in human leukemia HL-60 and K562 cells. 796 39

Although the DNA topoisomerases are critical intracellular targets of a number of clinically important anticancer drugs, the mechanism(s) by which inhibition of these enzymes causes cell death are poorly understood. We found that treatment of human leukemic lymphoblasts (CCRF-CEM) with teniposide (VM-26), under conditions that stabilize DNA-topoisomerase II complexes, caused the formation of internucleosomal DNA ladders. However, it appeared unlikely that the VM-26-stabilized DNA-topoisomerase II-cleavable complexes directly produce these internucleosomal DNA ladders, since similar nucleosomal DNA ladders were observed following either continuous or a short (1 h) exposure of cells to VM-26. Under continuous exposure to VM-26, the internucleosomal DNA ladders were associated with the transient induction of c-jun mRNA in a dose-dependent fashion, reaching maximum expression at 6 h after treatment with VM-26 and being down-regulated to basal levels by 12 h. The induction of c-jun mRNA by VM-26 apparently preceded DNA ladder formation. However, in CEM sublines selected for resistance to VM-26 (CEM/VM-1 and CEM/VM-1-5; approximately 50- and 140-fold resistant, respectively) and which display the phenotype of multidrug resistance associated with altered DNA topoisomerase II (at-MDR), we found that the induction of c-jun mRNA by VM-26 and subsequent DNA ladder formation were progressively attenuated in proportion to the resistance of the cells, apparently due in part to decreased stabilization of DNA-topoisomerase II-cleavable complexes. Further, the attenuated induction of c-jun in the at-MDR cells was found to be associated with a decreased rate of c-jun transcription and an increase in the instability of its mRNA following VM-26 treatment. The attenuation of c-jun mRNA induction was also reflected in decreased production of c-Jun protein in the at-MDR cells. Of interest was the fact that no significant induction of c-fos mRNA by VM-26 was observed in either CEM or at-MDR cells. Furthermore, the induction of c-jun was related to the activation of AP-1 DNA-binding activity in a time- and dose-dependent manner in CEM cells, whereas the activation of AP-1 binding was attenuated in at-MDR cells in proportion to their resistance to VM-26. Using Jun and Fos family member antibody inhibition experiments in gel-mobility shift assays, we found that AP-1-binding activity appeared to be preferentially mediated by c-Jun/Fra-1 heterodimers in both CEM and at-MDR cells.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Differences between drug-sensitive and -resistant human leukemic CEM cells in c-jun expression, AP-1 DNA-binding activity, and formation of Jun/Fos family dimers, and their association with internucleosomal DNA ladders after treatment with VM-26. 806 63

Sublines of K562 human leukemia cells were selected for resistance (30- to 80-fold) to etoposide by continuous exposure to 0.5 microM VP-16. Two etoposide-resistant cell lines, K/VP.5 and K/VP.5-1, showed a 5-fold reduction in levels of topoisomerase II alpha protein compared with K562 cells. Northern analysis indicated a 2.5-fold reduction in topoisomerase II alpha mRNA in etoposide-resistant cell lines, due in part to a 1.7-fold decrease in topoisomerase II mRNA stability with no change in transcription rate. Immunoblotting assays of electrophoresed cell lysates from VP-16-treated cells revealed less drug-induced covalent topoisomerase II/DNA adducts in resistant than in sensitive cells, suggesting a functional alteration in resistant cell topoisomerase II. Recent reports of specific topoisomerase II DNA binding sites near the promoter sites of growth response genes and alterations of gene expression in cells treated with topoisomerase II inhibitory drugs led to experiments to determine if the apparent functional alterations of topoisomerase II were accompanied by changes in the regulation of these genes. Therefore, the expression of several growth response genes was compared by northern analysis in parental K562 and both VP-16-resistant cell lines. Basal levels of c-myc were comparable for all three cell lines, but levels of c-jun and c-fos were elevated 2- to 4-fold in VP-16-resistant cell lines. Increased levels of c-fos and c-jun were not a result of altered rates of transcription, as determined by nuclear run-off assays. Exposure of both sensitive and resistant cells to 200 microM VP-16 for 5 hr resulted in no further changes in topoisomerase II mRNA levels but caused an additional 2- to 3-fold elevation in the level of c-jun mRNA, indicating that altered basal levels of this gene were not due to deregulation of this gene. Acquired VP-16 resistance in K/VP.5 and K/VP.5-1 cells was accompanied by reduced levels and altered activities of DNA topoisomerase II as well as changes affecting the expression of genes important for growth and differentiation.
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PMID:Altered gene expression in human leukemia K562 cells selected for resistance to etoposide. 826 50

In the MCF-7 human breast tumor cell line, the aminoacridine, m-AMSA, induces protein-associated DNA strand breaks consistent with inhibition of topoisomerase II. However, neither single-strand nor double-strand breaks in DNA, determined using conventional assays, show a consistent relationship with m-AMSA-induced inhibition of growth. In contrast, when DNA strand breaks are determined by alkaline unwinding under the high salt conditions of the alkaline unwinding/Southern blotting (AU/SB) assay, developed by our laboratories, damage to DNA corresponds closely with growth inhibition. The AU/SB assay, which is capable of assessing breaks within large-scale domains (upwards of 1 megabase) surrounding genes of interest, was further utilized to explore the capacity of m-AMSA to induce damage within specific genomic regions that may regulate cell growth. Regions encompassing the transcriptionally active oncogenes, c-myc and c-fos, were found to be more susceptible to m-AMSA-induced strand breaks than the region encompassing the non-transcribed alpha-satellite DNA or the genome as a whole (bulk DNA). These findings demonstrate that m-AMSA may produce more pronounced damage within specific genomic regions than in bulk DNA, m-AMSA also preferentially altered expression of the c-myc oncogene; at an m-AMSA concentration where growth was inhibited by between 70 and 80%, steady-state c-myc mRNA levels declined to approximately 10-15% of control levels within 2-3 hr; furthermore, concentration-dependent reductions in c-myc expression appeared to coincide with growth inhibition. In addition, inhibition of [3H]thymidine incorporation after 2 hr directly paralleled inhibition of growth, suggesting an early effect at the level of DNA biosynthesis, possibly related to the down-regulation of c-myc expression. It is proposed that specific lesions, e.g., in regions surrounding the c-myc gene, as well as generalized lesions in DNA may lead to growth inhibition mediated by down-regulation of the expression of select growth regulatory genes, such as c-myc.
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PMID:Influence of amsacrine (m-AMSA) on bulk and gene-specific DNA damage and c-myc expression in MCF-7 breast tumor cells. 830 76

In order to establish what role members of the activating protein-1 (AP-1) gene families, i.e., c-fos, c-jun, junB, and junD, play in thymic apoptosis, we have analyzed changes in their expression in response to three different agents: a glucocorticoid analog dexamethasone, an inhibitor of topoisomerase II teniposide VM26, and gamma radiation. All three agents induced thymic death at a similar rate and with the same morphological and biochemical features. There was a rapid and transient increase in the steady-state mRNA level of junB and c-fos genes in all treatments, including control cultures, reminiscent rather of cellular stress response to the environmental changes than to the apoptotic stimuli. On the other hand, treatments with the DNA-damaging agents, VM26 and gamma radiation, resulted in superinduction of the c-jun mRNA and in the activation of the stress response signaling pathway of c-Jun N-terminal kinase. Gene transcription ceased completely in cells with fragmented DNA and the down-regulation of genes such as junD and tubulin was reflective of the thymocytes' commitment to apoptosis. The DNA-binding activities of the serum response factors, cyclic AMP response element binding proteins, and AP-1 factors, indicative of their transcriptional competence, were compromised shortly after induction of apoptosis regardless of the agent employed, consistent with previously reported enhancement in cellular proteolysis which is an essential component of the apoptotic cell death.
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PMID:Jun and JNK kinase are activated in thymocytes in response to VM26 and radiation but not glucocorticoids. 902 81

Chemotherapeutic drug resistance is a major clinical problem and cause for failure in the therapy of human cancer. One of the goals of molecular oncology is to identify the underlying mechanisms, with the hope that more effective therapies can be developed. Several mechanisms have been suggested to contribute to chemoresistance: 1) amplification or overexpression of the P-glycoprotein family of membrane transporters (eg, MDR1, MRP, LRP) which decrease the intracellular accumulation of chemotherapy; 2) changes in cellular proteins involved in detoxification (eg, glutathione S-transferase pi, metallothioneins, human MutT homologue, bleomycin hydrolase, dihydrofolate reductase) or activation of the chemotherapeutic drugs (DT-diaphorase, nicotinamide adenine dinucleotide phosphate:cytochrome P-450 reductase); 3) changes in molecules involved in DNA repair (eg, O6-methylguanine-DNA methyltransferase, DNA topoisomerase II, hMLH1, p21WAF1/CIP1; 4) activation of oncogenes such as Her-2/neu, bcl-2, bcl-XL, c-myc, ras, c-jun, c-fos, MDM2, p210 BCR-abl, or mutant p53. An overview of these resistance mechanisms is presented, with a particular focus on the role of oncogenes. Some current strategies attempting to reverse their effects are discussed.
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PMID:Role of oncogenes in resistance and killing by cancer therapeutic agents. 909 Apr 98


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