EC:5.99.1.2 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:5.99.1.2 (topoisomerase)
9,166 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We have isolated a multidrug-resistant derivative of Chinese hamster ovary CHO-K1 cells by exposure to progressively increasing concentrations of Adriamycin. This cell line, designated CHO-Adrr, was 27-fold more resistant than the parental line to Adriamycin and showed similar degrees of cross-resistance to several other topoisomerase II (topo II) inhibitors, including mitoxantrone, daunomycin and etoposide. CHO-Adrr cells showed a lower (4-fold) level of cross-resistance to vincristine and colchicine, drugs associated with the multidrug-resistant phenotype. While CHO-Adrr cells showed no enhanced resistance to several mono- and bi-functional alkylating agents or to UV and ionizing radiation, they were greater than 80-fold resistant to mitomycin C (MMC). There was a 5-fold decreased level of daunomycin accumulation in CHO-Adrr cells compared to CHO-K1 cells and this was associated with increased drug efflux. The resistant cells had amplified multidrug resistance gene (mdr) sequences and overexpressed (mdr) mRNA. Verapamil was able to completely reverse Adriamycin resistance but reversal of MMC resistance was only partial, with residual 23-fold resistance. CHO-Adrr cells expressed a 4-fold reduced level of topo II protein but overexpressed an alpha class (basic) glutathione S-transferase (GST). Analysis of cell hybrids showed that while the level of resistance to Adriamycin dropped by a factor of 3 in CHO-K1/CHO-Adrr hybrids compared to CHO-Adrr/CHO-Adrr hybrids, resistance to MMC dropped 10-fold. Thus, CHO-Adrr cells appear to exhibit simultaneously several different drug resistance mechanisms including MDR and GST overexpression, and topo II reduction.
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PMID:Reduced topoisomerase II and elevated alpha class glutathione S-transferase expression in a multidrug resistant CHO cell line highly cross-resistant to mitomycin C. 131 88

The development of tumor drug resistance is the major obstacle to successful systemic chemotherapy. Therefore, devising methods for reversing drug resistance is a high priority and could lead to significant improvements in cancer treatment. The mechanisms of tumor drug resistance are manifold and are not well understood. The phenomenon of multidrug resistance (MDR) represents the development of resistance to most drugs, regardless of their chemical structure. Several types of MDR are known, for example, the overexpression of a cell membrane glycoprotein (P-170), increased activity of glutathione S-transferase, elevated levels of glutathione (GSH), and alterations in topoisomerase action. A partial reversal of tumor drug resistance has been achieved by the use of competitive inhibitors for the function of glycoprotein P-170, or by the inhibition of GSH synthesis; however, this strategy has not been substantially successful for improving the response of human tumors to clinical therapy. We have recently used electroporation, in conjunction with the cytotoxic drug, cisplatin (cDDP), in an attempt to circumvent drug resistance in cDDP-resistant mouse tumor cells (RIF/Ptr1). Electroporation is the application of a high-voltage electric shock which is known to create transient pores in plasma membranes of cultured cells. Electroporation plus cDDP treatment increased intracellular cDDP concentration and reversed cellular resistance to cDDP-induced cell killing.
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PMID:New approaches to the study of tumor drug resistance. 136 47

In a P-glycoprotein-negative cell line, GLC4-Adr90, a 75-fold acquired Adriamycin (Adr) resistance coincided with a reduced cellular Adr level, an increased detoxifying capacity (glutathione (GSH) and glutathione S-transferase (GST) elevated), and a reduced topoisomerase-II (topo-II) activity compared with the parent cell line GLC4. The effect on Adr resistance of buthionine sulfoximine (BSO, GSH synthesis inhibitor), was studied alone or in combination with verapamil (drug-efflux inhibitor), docosahexaenoic acid (membrane lipid domain affector), ethacrynic acid (GST inhibitor), aphidicolin (DNA-polymerase-alpha inhibitor) or novobiocin (NOV, topo-II inhibitor). Cytotoxicity was tested using a microculture tetrazolium assay. In GLC4-Adr90, BSO and NOV increased Adr-induced cytotoxicity 12.9-fold and 1.8-fold respectively. The combination of BSO plus NOV showed an additive effect, decreasing the Adr resistance factor from 75 to 2.7. Combination of modulators of Adr resistance directed at different resistance mechanisms appears promising in vitro.
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PMID:Combined in vitro modulation of adriamycin resistance. 168 Aug 15

Cisplatin (CDDP) resistance mechanisms were studied in a model of three germ cell tumour and three colon carcinoma cell lines representing intrinsically CDDP-sensitive and -resistant tumours respectively. The CDDP sensitivity of the cell lines mimicked the clinical situation. The glutathione levels of the cell lines correlated with CDDP concentrations inhibiting cell survival by 50% (IC50); total cellular sulphydryl content (TSH) was unexpectedly inversely correlated with IC50. IC50 correlated neither with glutathione S-transferase (GST) nor with GST pi expression, topoisomerase I or II activity. Immediately after 4 h incubation with CDDP, platinum (Pt) accumulation and Pt bound to DNA were not correlated, but after another 24 h drug-free culture, Pt binding to DNA in germ cell tumour but not in colon carcinoma cell lines correlated with IC50. With the exception of in vitro sensitivity and TSH, none of the parameters studied discriminated between the two groups of cell lines. Correction of CDDP sensitivity parameters for phenotypical differences did not influence statistical correlations. Analysis of variance revealed a correlation between IC50 and the combination of glutathione, GST activity and Pt bound to DNA. But at other CDDP cytotoxicity levels sensitivity was also correlated with Pt accumulation, topoisomerase II activity and TSH in various combinations. This model of intrinsic CDDP resistance showed that multiple parameters ought to be studied to explain CDDP resistance, but did not elucidate the cause of the unique sensitivity of germ cell carcinoma, although the unexpected values of TSH deserve further attention.
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PMID:Cellular basis for differential sensitivity to cisplatin in human germ cell tumour and colon carcinoma cell lines. 771 Sep 29

Resistance to antineoplastic drugs has often been associated with P-glycoprotein overexpression, this certainly being not the sole mechanism. In order to characterize resistance to doxorubicin and cisplatin, we have analysed P-glycoprotein expression, topoisomerase II activity, glutathione and related enzymes in murine leukemic cells (doxorubicin or cisplatin-resistant). The doxorubicin-resistant cells contained P-glycoprotein, showed lower activities of glutathione S-transferase well as of glutathione reductase and topoisomerase II. The modifications observed in the most cisplatin-resistant cell line were a higher activity of glutathione S-transferase isoenzyme pi and topoisomerase II. These results suggest that drug uptake, glutathione metabolism as well as topoisomerase II activity are all characteristic of multidrug resistance.
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PMID:Chemoresistance to doxorubicin and cisplatin in a murine cell line. Analysis of P-glycoprotein, topoisomerase II activity, glutathione and related enzymes. 791 9

The activity of several proteins involved in the development of antitumor drug resistance is regulated by protein phosphorylation. These proteins include the mdr-1-encoded P-glycoprotein (Pgp) and topoisomerase II (topo II). The corresponding evidence is reviewed and attempts to modulate multidrug resistance (MDR) by protein kinase C inhibitors are described. The expression of several proteins which are essential in drug resistance is regulated at the transcriptional level, involving protein phosphorylation by members of the protein kinase C (PKC) family, casein kinase II (CKII), and others. These proteins include mdr-1-encoded P-glycoprotein, metallothionein, glutathione S-transferase (GST), dTMP synthase, and the proteins Fos and Jun. The corresponding genes are under positive regulation of ras, which in turn requires the activation of a protein kinase cascade for its function. Protein kinases are therefore potentially useful targets in reducing the expression of proteins involved in the development of multifactorial drug resistance caused by the expression of transforming ras-genes. Attempts to inhibit the ras-induced fos expression by an inhibitor of protein kinase C (ilmofosine) are described. Protein kinase inhibitors are also able to synergistically enhance the cytotoxicity of cis-platinum, which is discussed as resulting from a reduction of PKC-dependent fos expression.
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PMID:Role of protein kinases in antitumor drug resistance. 806 Nov 7

In order to clarify the mechanism of drug resistance in human myeloma cells, we investigated the expressions of DNA topoisomerase I and topoisomerase II gene and the genes possibly related to drug resistance; multi-drug resistant gene 1 (MDR-1), glutathione S-transferase class pi gene (GST-pi), by Northern blotting. Myeloma cells in eight of 15 cases prior to chemotherapy expressed topoisomerase I mRNA considerably, while the expression of topoisomerase II mRNA was detected weakly in only one of 16 myeloma patients. There was not any correlation between expression of topoisomerase I mRNA and clinical drug resistance. Significant expression of MDR-1 mRNA and P-glycoprotein was not detected in 25 cases of multiple myeloma prior to chemotherapy and even after several courses of VAD (vincristine, adriamycin and dexamethasone) therapy by Northern blotting and immunostaining using monoclonal anti-P-glycoprotein antibody (MRK-16), respectively. On the other hand, 16 of 21 myeloma cases showed significant expression of GST-pi protein and GST-pi mRNA with the various strengths, but there was no apparent correlation between GST-pi mRNA expression and clinical response. Therefore these data suggest that expression of the genes we tested may not determine the level of drug resistance in multiple myeloma, but lower or no significant expression of topoisomerase II mRNA in most myeloma cells indicates the possibility that topoisomerase II inhibitors such as VP-16 and topoisomerase II-mediated cytotoxic drugs such as adriamycin, are not so effective for the treatment of multiple myeloma.
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PMID:Expressions of DNA topoisomerase I and II gene and the genes possibly related to drug resistance in human myeloma cells. 809 26

We investigated the mechanism of resistance in murine L1210 leukaemia cells selected after treatment with FCE 23762 methoxymorpholinyl doxorubicin: (MMRDX), a methoxymorpholinyl derivative of doxorubicin active in vitro and in vivo on multidrug-resistant (mdr) cells, currently undergoing phase I clinical trials. The resistant subline obtained after repeated in vitro treatments, L1210/MMRDX, is resistant in vitro and in vivo to all tested methoxymorpholinyl derivatives and to cyanomorpholinyl doxorubicin, but shows resistance to morpholinyl derivatives only in vivo or following their activation with rat S9-liver fractions in vitro. L1210/MMRDX cells are sensitive to classic mdr- and altered topoisomerase (AT)-mdr-associated drugs. These cells do not appear to overexpress the mdr1 gene, nor do they exhibit impaired intracellular drug accumulation and efflux or altered levels of glutathione and glutathione S-transferase. The extent of DNA single-strand break formation and, after microsomal activation, of DNA interstrand cross-links after treatment with MMRDX was similar in the parent and the resistant subline. The mechanism of resistance in L1210/MMRDX cells remains to be identified but may prove a novel one, highly specific for this class of mdr-active anthracyclines.
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PMID:L1210 cells selected for resistance to methoxymorpholinyl doxorubicin appear specifically resistant to this class of morpholinyl derivatives. 829 27

Subclones of the two well-characterized myeloid cell lines HL-60 and KG1a were selected for doxorubicin resistance by systematic exposure to increased concentrations of the drug in vitro. Both subclones demonstrated a threefold increased resistance to the drug as evident from cell growth in liquid culture and clonogenicity in a semisolid matrix. Both resistant subclones displayed a similar degree of reduced total and nuclear doxorubicin levels. The HL-60 and the KG1a cells differed qualitatively and quantitatively with respect to glutathione (GSH) levels during culture, with markedly elevated concentrations in the resistant HL-60 subclone during 1 week of culture. Total GSH pools in resistant and sensitive KG1a cells were similar, but maximum GSH levels were reached earlier in the resistant KG1a clones than in the parental cells. Northern blot analysis suggests that resistance was accompanied by increased mdr1 expression in the KG1a but not in the HL-60 cells, whereas alterations in the glutathione S-transferase P1-1 and topoisomerase II message was evident in the latter. The results demonstrate the complex, multifactorial mechanisms behind the in vitro induction of even moderate resistance in anthracyclines.
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PMID:Qualitatively different mechanisms of resistance to doxorubicin, both involving altered glutathione pools, in two myeloid cell lines in vitro. 858 98

Poxviral DNA topoisomerases are sequence-specific enzymes whose activities are thought to influence such diverse processes as transcription, DNA replication, and genetic recombination. To obtain further insights into the relatedness of these enzymes, and their influence on virus-mediated recombination, we have determined the target-specificity and other catalytic properties of the Shope fibroma virus (SFV) topoisomerase. SFV topoisomerase was expressed in Escherichia coli and purified as a glutathione S-transferase (GST) or (his)6-tagged fusion protein. The recombinant Leporipox-virus (SFV) enzyme displayed catalytic properties very similar to vaccinia topoisomerase. In particular SFV topoisomerase recognizes the same pentanucleotide motif [5'-(C/T)CCTT-3'] and promotes the same DNA relaxation, strand transfer, and strand cleavage reactions catalyzed by the Orthopoxviral (vaccinia) enzyme. The SFV enzyme can also efficiently cleave DNA 3' of the variant site 5'-CCCTG-3' in certain sequence contexts. These studies identified several sites where SFV topoisomerases interact with a recombinational substrate and permitted a comparison of recombination frequencies across intervals which did, or did not, span these sites. We failed to detect any effect of topoisomerase-recognition sites on recombination frequencies, except for a small (< 2-fold) stimulation seen when the substrates encoded a nearby poxviral promoter. This and other work shows that poxviral topoisomerases from several genera share common target specificities, but other enzymatic systems probably catalyze the high-frequency recombination seen in poxvirus-infected cells.
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PMID:SFV topoisomerase: sequence specificity in a genetically mapped interval. 866 46

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