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Target Concepts:
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Query: EC:5.99.1.3 (
topoisomerase
)
9,911
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
After twenty years, understanding the mechanisms of tumor cells kill by anthracyclines still remains an active area of research. Of many mechanisms described for this class of drugs, efforts in the last year have focused on defining the role of free radical formation,
topoisomerase
II-induced DNA breakage, and P-170-dependent cellular accumulation of anthracyclines in tumor cell kill and resistance. First, in a number of tumor cell lines, the formation of free radical species from anthracyclines has been implicated in the cell killing. Modulation of detoxification pathways in a drug-resistant cell line e.g depletion of GSH, a substrate for peroxidase and transferase, enhanced both the formation of oxy-radicals and adriamycin cytotoxicity. It should be noted, however, that these findings are not true for every cell line examined, and free radical-mediated tumor kill may be cell- or tissue-specific. Second, anthracyclines-mediated topo II-dependent DNA cleavage was observed in most cell lines and reduced breaks were found in resistant cells. The decrease in single-strand breaks, however, neither correlated with the degree of resistance nor with differences in the relative topo II activity, which was in most cases only two-fold less in resistant cells than in sensitive cells. Finally, the reduced accumulation of the drug does not appear to be the only contributing factor in multidrug resistant cells and P-170 is not the only protein overexpressed in certain cells, e.g., an 85,000 Da protein may also be linked to adriamycin resistance. Although GST protein is overexpressed in most adriamycin resistant cells along with mdr1 gene, current evidence suggests that this protein may not be directly involved in adriamycin resistance. Taken together, both the mechanism of action and resistance to this class of drug likely vary among cell lines. Clinical studies in the past year have brought about interesting refinements in anthracycline-containing chemotherapy;
ICRF-187
(by itself also cytotoxic) seems to offer protection against cardiac toxicity, while implicating iron in the mediation of cardiac damage. Out of a large number of newer anthracycline derivatives, clinical evidence indicates only a modest increase in therapeutic index with a few analogs, perhaps idarubicin and epirubicin. It is not yet clear that being able to receive more milligrams (or more cycles) of anthracycline eventually translates into a significantly better response rate or in a survival advantage. Much less clear is whether patients refractory to adriamycin may derive any benefit from newer anthracyclines.(ABSTRACT TRUNCATED AT 400 WORDS)
...
PMID:Anthracyclines. 222 2
A series of twelve structurally related bisdioxopiperazines that included
ICRF-187
(dexrazoxane), ICRF-159 (razoxane), ICRF-193, and ICRF-154 were examined both for their ability to inhibit the growth of Chinese hamster ovary (CHO) cells and their ability to inhibit the catalytic activity of mammalian
DNA topoisomerase II
. The bisdioxopiperazines exhibited a wide range in both growth inhibitory effects (30,000-fold), and in their ability to inhibit the catalytic activity of
topoisomerase
II (150-fold). The cytotoxicity of the bisdioxopiperazines toward CHO cells was highly correlated (correlation coefficient r = 0.86, P = 0.0003) with their inhibition of the catalytic activity of
DNA topoisomerase II
. This result strongly suggests that
DNA topoisomerase II
is the functional target of the bisdioxopiperazines. The stereoisomers (+)-
ICRF-187
and (-)-ICRF-186 were observed to be equally cytotoxic and equally inhibitory toward
DNA topoisomerase II
. This result indicates that the bisdioxopiperazine binding site on
DNA topoisomerase II
is large enough or flexible enough to accommodate either form of the drug. The strongly metal-ion binding fully rings-opened hydrolysis product of
ICRF-187
, ADR-925, demonstrated no measurable inhibitory activity toward
DNA topoisomerase II
or cytotoxicity toward CHO cells.
...
PMID:A QSAR study comparing the cytotoxicity and DNA topoisomerase II inhibitory effects of bisdioxopiperazine analogs of ICRF-187 (dexrazoxane). 757 79
The epipodophyllotoxins etoposide and teniposide are probably the most important drugs in the treatment of small cell lung cancer. The drugs are used in maximally tolerated doses, and the toxicity of the drugs precludes significant dose increments. The cellular target is the nuclear enzyme
topoisomerase
II which, in the presence of these drugs, causes an extensive fragmentation of DNA. The cell kill can be antagonized by distinct drug types. We have demonstrated previously that the intercalating drug aclarubicin and the cardioprotecting agent
ICRF-187
antagonize the cytotoxicity of etoposide in vitro. We have studied possible ways of using this antagonism as a means of differentially protecting normal tissue. Here we demonstrate that the intercalating agent chloroquine prevents the introduction of
topoisomerase
II-mediated DNA breaks and thereby antagonizes the cytotoxicity of etoposide. This interaction depends on the extracellular pH. Chloroquine, in contrast to etoposide, is a weak base and therefore does not enter the cell if the extracellular fluid is acidic, as is the case in most solid tumors. We propose that such a pH-dependent drug interaction may be useful in directing
topoisomerase
II drug effects toward solid tumors. Thus, by lowering the extracellular pH (pHe) from neutral (pHe = 7.4) to acidic (pHe = 6.0), [3H]chloroquine accumulation was decreased 5-fold in a human small cell lung cancer cell line, OC-NYH, and in murine leukemia L1210 cells. In parallel, the antagonism exhibited by chloroquine on etoposide cytotoxicity was pHe dependent. Thus, no protection by chloroquine was observed at pHe = 6.5, whereas at pHe = 7.4, etoposide cytotoxicity was almost completely antagonized with a 460-fold protection or more than eight doublings of the cell population. This exploitation of antagonist extracellular trapping by acidic pH is a novel model for regulation of anticancer drug effects.
...
PMID:Targeting the cytotoxicity of topoisomerase II-directed epipodophyllotoxins to tumor cells in acidic environments. 818 81
Certain bis(2,6-dioxopiperazine) derivatives, which include
ICRF-187
[(+)-1,2-bis(3,5-dioxopiperazinyl-1-yl]propane; ADR-529) and its racemic compound ICRF 159 (Razoxane), have been investigated as antineoplastic agents. In addition,
ICRF-187
is currently under intense study as an agent to ameliorate the cardiac toxicity of anthracycline therapy. These agents have recently been identified as inhibitors of
topoisomerase
II. We studied the effects of
ICRF-187
and ICRF-159 on the progression of cultured epithelial cells through M phase. Beginning approximately 1.5 h after drug addition, chromosome condensation was significantly inhibited. Cells entered and progressed through M phase at near normal rates, but the lack of complete chromosome separation during anaphase resulted in catastrophic effects on normal chromosome distribution. Immunolabeling with Crest autoimmune sera, which recognizes centromere proteins, and with MPM-2 monoclonal antibody, which recognizes mitotic phosphoproteins, indicated that the centromeres of the chromosomes assembled a normal metaphase array in the presence of
ICRF-187
and ICRF-159. Centromere separation in anaphase was initiated normally but was not completed because the chromatid arms failed to disengage from each other. Massive chromosome bridges were formed, and the chromatin mass became trapped in the cleavage furrow leading to its unequal distribution to the daughter cells. In many cases, all the chromatin was pushed into one of the two dividing cells. It is likely that previous studies, based on flow cytometry, indicating that bis(2,6-dioxypiperazine) derivatives cause an accumulation of cells with a 4N DNA content, reflect the incomplete segregation of chromosomes in mitosis rather than a block in G2 of the cell cycle as had been proposed.
...
PMID:Cell cycle progression and chromosome segregation in mammalian cells cultured in the presence of the topoisomerase II inhibitors ICRF-187 [(+)-1,2-bis(3,5-dioxopiperazinyl-1-yl)propane; ADR-529] and ICRF-159 (Razoxane). 831 60
The effect of the bisdioxopiperazine cardioprotector
ICRF-187
(ADR-529, dexrazoxan) on drug-induced DNA damage and cytotoxicity was studied. Using alkaline elution assays,
ICRF-187
in a dose-dependent manner inhibited the formation of DNA single strand breaks (SSBs) as well as DNA-protein cross-links induced by drugs such as VP-16 (etoposide), m-AMSA [4'-(9-acridinylamino)-methanesulfon-m-anisidide], daunorubicin and doxorubicin (Adriamycin) which are known to stimulate DNA-
topoisomerase
II cleavable complex formation. Thus, 50% inhibition of DNA SSBs induced by 5 microM doxorubicin occurred already at equimolar
ICRF-187
. In contrast,
ICRF-187
did not affect DNA SSBs induced by H2O2. In clonogenic assay,
ICRF-187
in non-toxic doses antagonized both VP-16 and daunorubicin cytotoxicity in a dose-dependent manner. Our results indicate that the previously described acute in vivo protection by
ICRF-187
against anthracycline toxicity may be due to inhibition of
topoisomerase
II activity. The antagonistic effect of
ICRF-187
on daunorubicin cytotoxicity should be taken into consideration when planning clinical trials.
...
PMID:Antagonistic effect of the cardioprotector (+)-1,2-bis(3,5-dioxopiperazinyl-1-yl)propane (ICRF-187) on DNA breaks and cytotoxicity induced by the topoisomerase II directed drugs daunorubicin and etoposide (VP-16). 839 80
The catalytic cycle of
topoisomerase
II is the target of some of the most successful antitumor agents used today, e.g. etoposide (VP-16), in the treatment of testicular cancer and small-cell lung cancer. The cell kill mediated by
topoisomerase
II poisons can be antagonized by distinct drug types. Thus, we have demonstrated etoposide antagonism with the type-II anthracycline aclarubicin, the antimalarial drug chloroquine, and the cardioprotective agent
ICRF-187
. In other setups, combinations of agonist and antagonists have led to high-dose regimens for counteracting drug resistance. Thus, the exploitation of folinic acid rescue for methotrexate toxicity and the use of mesna to protect against cyclophosphamide toxicity have enabled the use of high-dose methotrexate and cyclophosphamide protocols. Using a similar approach, we have studied possible ways to apply antagonists to
topoisomerase
II poisons. NDF1-hybrid female mice were treated with the various drugs and drug combinations. Lethality (LD10 and LD50 values) was computed by use of the maximum-likelihood method, and the antitumor effect of the drugs was compared in mice inoculated i.p. with either L1210 cells or Ehrlich ascites tumor cells. In addition, the compounds were tested on L1210 cells inoculated intracranially. The toxicity of the various drugs was evaluated by weight and leukocyte counts.
ICRF-187
rescues healthy mice from lethal doses of
topoisomerase
II poisons. In mice the
ICRF-187
LD10 was 500 mg/kg. Within a wide non-toxic dose range (50-250 mg/kg) of
ICRF-187
we found protection against m-AMSA and etoposide lethality. Thus, the LD10 of etoposide increased from 34 mg/kg for the single agent to 122 mg/kg for its combination with
ICRF-187
, corresponding to a 3.6-fold etoposide dose escalation. In contrast,
ICRF-187
did not protect against lethal doses of the non-
topoisomerase
II-directed drug paclitaxel. We further investigated the anti-tumor effect of equitoxic schedules in mice inoculated i.p. with L1210 or Ehrlich ascites tumor cells. The L1210-bearing mice appeared to obtain a larger increase in life span from the etoposide and
ICRF-187
combination as compared with etoposide alone, whereas this was not the case in mice inoculated with Ehrlich ascites tumor cells. As the hydrophilic
ICRF-187
is not expected to cross the blood-brain barrier, in contrast to the lipophilic etoposide, we investigated the effect of the drug combination in mice inoculated intracranially with L1210 cells. We obtained a significant increase in life span in mice treated with
ICRF-187
+ etoposide as compared with mice treated with an equitoxic dose of etoposide alone. Thus, there appear to be potential routes by which one can benefit from this antagonism.
ICRF-187
is a powerful nontoxic protector against the lethality of the
topoisomerase
II-directed drugs etoposide and m-AMSA in vivo. A brain tumor model demonstrates the superiority of high-dose etoposide treatment with
ICRF-187
protection as compared with etoposide treatment alone. This implies that tumors in the brain can be reached by cytotoxic drug doses and that normal tissues can be protected due to differences in drug transport across the blood-brain barrier.
ICRF-187
is therefore a promising lead compound for the development of schedules using high-dose
topoisomerase
II poisons in the treatment of brain tumors and metastases.
...
PMID:ICRF-187 rescue in etoposide treatment in vivo. A model targeting high-dose topoisomerase II poisons to CNS tumors. 864 93
The complex catalytic cycle of
topoisomerase
II is the target of important antitumor agents. Topoisomerase II poisons, such as etoposide and daunorubicin, inhibit the resealing of DNA breaks created by the enzyme. This enzyme-coupled cell kill is susceptible to pharmacological regulation by drugs interfering with other steps in the enzyme's catalytic cycle (i.e. so-called catalytic inhibitors). From in vitro studies, is appears that there are 2 distinct sites in the cycle at which a complete antagonism of the toxicity of
topoisomerase
II poisons can be obtained. The first is the inhibition of the enzyme's binding to its DNA substrate as seen with intercalating drugs such as chloroquine and aclarubicin; a second, more specific, interaction is elicited by bisdioxopiperazines, which are thought to lock the homodimeric
topoisomerase
II in the form of a closed bracelet surrounding the DNA at the postreligation step. To investigate these in vitro findings in the more complex whole cell system, we studied enzyme-DNA binding in Western blots of 0.35 M NaCL nuclear extracts from human small cell lung cancer OC-NYH cells incubated with the bisdioxopiperazine
ICRF-187
and aclarubicin. With
ICRF-187
, we found a reversible ATP dependent decrease in the extractable levels of both the alpha and the beta isoforms of
topoisomerase
II. In contrast to
ICRF-187
, aclarubicin increased the amount of extractable enzyme from cells. Further, when using the terpenoid clerocidin, which differs from conventional
topoisomerase
II poisons by forming a salt-and heat-stable inhibition of DNA resealing, no antagonism was found by
ICRF-187
on formation of DNA strand breaks and cytotoxicity. However, aclarubicin, which interferes early in the
topoisomerase
II catalytic cycle, was able to antagonize DNA breaks and cytotoxicity caused by clerocidin. The results indicate 4 different steps in the
topoisomerase
II cycle that can be uncoupled in the cell by different drug types: etoposide and clerocidin cause reversible and irreversible inhibition of DNA resealing, respectively, and DNA intercalating agents, such as aclarubicin, inhibit binding of
topoisomerase
II enzyme to its DNA substrate. Finally, bisdioxopiperazines as
ICRF-187
partake in an energy dependent inappropriate binding of
topoisomerase
II to DNA after the resealing step. This knowledge may enable the design of rational combinations of
topoisomerase
II poisons and catalytic inhibitors to enhance the efficacy of anticancer therapy.
...
PMID:Mapping of DNA topoisomerase II poisons (etoposide, clerocidin) and catalytic inhibitors (aclarubicin, ICRF-187) to four distinct steps in the topoisomerase II catalytic cycle. 865 36
Etoposide (VP-16)-resistant K562 cells (K/VP.5) were 26-fold resistant to VP-16, due in part to a reduction in
DNA topoisomerase II
(
topoisomerase
II) protein levels. Compared with parental K562 cells, VP-16-resistant K/VP.5 cells were found to be 3.4-fold more sensitive to the effects of dexrazoxane (
ICRF-187
), a
topoisomerase
II inhibitor that does not stabilize
topoisomerase
II-DNA covalent complexes. In contrast, K/VP.5 cells were 4.0-fold cross-resistant to merbarone and showed no cross-resistance to fostriecin, two other
topoisomerase
II inhibitors that do not stabilize
topoisomerase
II-DNA covalent complexes. Preincubation with
ICRF-187
resulted in greater inhibition of subsequent VP-16-induced
topoisomerase
II-DNA covalent complexes in K/VP.5 cells than in K562 cells. Conversely, preincubation with merbarone resulted in less inhibition of VP-16-induced
topoisomerase
II-DNA covalent complexes in K/VP.5 cells than in parental K562 cells. Preincubation with forstriecin had little effect on VP-16-induced
topoisomerase
II-DNA covalent complex formation in either cell line. The onset rates for
ICRF-187
inhibition of VP-16-induced
topoisomerase
II-DNA complex formation were similar in sensitive and resistant cells. In addition,
ICRF-187
had a comparable concentration-dependent inhibitory effect on the
topoisomerase
II catalytic activities of K562 and K/VP.5 cells. Together, our results indicate that collateral sensitivity to
ICRF-187
in K/VP.5 cells is due to decreased
topoisomerase
II protein levels rather than to an alteration in
topoisomerase
II activity. Furthermore, results suggest that
ICRF-187
, merbarone, and fostriecin have different mechanisms of action that can be studied effectively in K/VP.5 and K562 cells.
...
PMID:Collateral sensitivity to the bisdioxopiperazine dexrazoxane (ICRF-187) in etoposide (VP-16)-resistant human leukemia K562 cells. 875 37
DNA topoisomerase II
(topo II) is required at mitosis in yeast for high chromosome condensation and for chromosome segregation. Recent studies on intact mammalian cells using topo II inhibitors that do not stabilize cleavable complexes also suggest a requirement for topo II for complete chromosome condensation and perhaps also for entry into mitosis. We have investigated the effects of merbarone,
ICRF-187
, and aclarubicin, three topo II inhibitors that do not stabilize the cleavable complex, on entry into mitosis and on chromosome condensation in BHK and in tsBN2 cells. We have compared their effects with those of etoposide, a topo II inhibitor that stabilizes the cleavable complex. All inhibitors induced a concentration-dependent G2 delay or arrest that could be overcome with fostriecin or okadaic acid or by inactivation of RCC1 in tsBN2 cells. Mitotic chromosomes from cells treated with etoposide were extensively fragmented, whereas mitotic chromosomes from cells treated with merbarone,
ICRF-187
, or aclarubicin were intact but elongated and tangled. These results provide strong evidence that topo II activity is required in chromosome condensation for final coiling of the chromatids. Our results also indicate that protein phosphatases and RCC1 play a role in G2 delay induced by all inhibitors, whether they do or do not stabilize the cleavable complex.
...
PMID:Topoisomerase II inhibitors affect entry into mitosis and chromosome condensation in BHK cells. 878 36
Dexrazoxane (
ICRF-187
) is clinically used to reduce doxorubicin-induced cardiotoxicity. Because dexrazoxane, doxorubicin and daunorubicin all act on
DNA topoisomerase II
, a study was undertaken to see what effect dexrazoxane had on the growth inhibitory effects of doxorubicin and daunorubicin towards Chinese hamster ovary cells. Dexrazoxane exhibited significant antagonism of doxorubicin- and daunorubicin-mediated growth inhibition when the cells were preincubated with dexrazoxane before the anthracycline was added. Continuous exposure of cells to either anthracycline and low concentrations of dexrazoxane resulted in additive growth inhibitory effects at low anthracycline concentrations, and no effect at higher anthracycline concentrations.
...
PMID:The effect of dexrazoxane (ICRF-187) on doxorubicin- and daunorubicin-mediated growth inhibition of Chinese hamster ovary cells. 886 24
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