Gene/Protein
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Symptom
Drug
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Target Concepts:
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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)
Bacteriophage T4 provides a simple model system in which to examine the mechanism of action of antitumor agents that have been proposed to attack type II DNA topoisomerases. Prior results demonstrated that T4 type II DNA topoisomerase is the target of antitumor agent 4'-(9-acridinylamino)methanesulfon-m-anisidide (
m-AMSA
) in phage-infected Escherichia coli: a point mutation in
topoisomerase
structural gene 39 was shown to confer both
m-AMSA
-resistant phage growth and
m-AMSA
-insensitive
topoisomerase
activity. We report here that a point mutation in T4
topoisomerase
structural gene 52 can also independently render both phage growth and
topoisomerase
activity resistant to
m-AMSA
. The DNA relaxation and DNA cleavage activities of this newly isolated mutant
topoisomerase
were significantly insensitive to
m-AMSA
. The drug-resistance mutation in gene 52, as well as that in gene 39, alters the DNA cleavage site specificity of wild-type T4
topoisomerase
. This finding is consistent with a mechanism of drug action in which both
topoisomerase
and DNA participate in formation of the drug-binding site.
...
PMID:Mutational alteration of the breakage/resealing subunit of bacteriophage T4 DNA topoisomerase confers resistance to antitumor agent m-AMSA. 215 56
Using cultured V79 Chinese hamster cells, we found that novobiocin (or 2,4-dinitrophenol) can abrogate, almost completely, the cytotoxicity due to the
topoisomerase
II inhibitor amsacrine (
mAMSA
). V79 cells were sensitive to
mAMSA
killing at all stages in the cell cycle but mainly in S phase followed by late G1 phase; however, novo rescued cells of all ages. The properties of two kinds of radiation-sensitive Chinese hamster cells were also examined, i.e., the line of V79 cells that can be rescued by caffeine, designated S-10 (H. Utsumi and M.M. Elkind, Radiat. Res., 96: 348-358, 1983); and Chinese hamster ovary cells (P.A. Jeggo and L.M. Kemp, Mutat. Res., 112: 313-327, 1983) which are also sensitive to other DNA-damaging agents. As is the case for exposure to radiation, after
mAMSA
treatment caffeine rescued V79/S-10 cells. Although Jeggo's Chinese hamster ovary cells were more responsive to
mAMSA
, novo still abrogated
mAMSA
toxicity in the mutant cells as well as in the parental Chinese hamster ovary cells 2,4-Dinitrophenol acted similarly to novo with respect to
mAMSA
killing, but neither compound reduced the ATP content of V79 cells. We propose that one reason for the rescue from
mAMSA
killing of at least S-phase cells by novo or 2,4-dinitrophenol is their ability transiently to inhibit replicative DNA synthesis.
...
PMID:Abrogation by novobiocin of cytotoxicity due to the topoisomerase II inhibitor amsacrine in Chinese hamster cells. 215 94
In order to elucidate the mechanism by which the intercalative antineoplastic drug 4'-(9-acridinylamino)methanesulfon-m-anisidide (
m-AMSA
) stabilizes the covalent
topoisomerase
II-DNA cleavage complex, the effect of the drug on the DNA cleavage/religation reaction of the type II enzyme from Drosophila melanogaster was examined. At a concentration of 60 microM,
m-AMSA
enhanced
topoisomerase
II mediated double-stranded DNA breakage approximately 5-fold. Drug-induced stabilization of the enzyme-DNA cleavage complex was readily reversed by the addition of EDTA or salt. When a DNA religation assay was utilized,
m-AMSA
was found to inhibit the
topoisomerase
II mediated rejoining of cleaved DNA approximately 3.5-fold. This result is similar to that previously reported for the effects of etoposide on the activity of the Drosophila enzyme [Osheroff, N. (1989) Biochemistry 28, 6157-6160]. Thus, it appears that structurally disparate classes of
topoisomerase
II targeted antineoplastic drugs stabilize the enzyme's DNA cleavage complex primarily by interfering with the ability of
topoisomerase
II to religate DNA.
...
PMID:Stabilization of the topoisomerase II-DNA cleavage complex by antineoplastic drugs: inhibition of enzyme-mediated DNA religation by 4'-(9-acridinylamino)methanesulfon-m-anisidide. 215 23
The effect of combinations of the anthracycline aclarubicin and the
topoisomerase
II targeting drugs 4'-demethylepipodophyllotoxin-9-(4,6-O-ethylidene-beta-D-glucopyra noside) (VP-16) and 4'-(9-acridinylamino)methanesulfon-m-anisidide (
m-AMSA
) was investigated in a clonogenic assay. The cytotoxicity of VP-16 was almost completely antagonized by preincubating cells with nontoxic concentrations of aclarubicin. The inhibition of cytotoxicity was not seen when the cells were exposed to aclarubicin after exposure to VP-16. The inhibition was significant over a wide range of aclarubicin concentrations (3 nM to 0.4 microM), above which the toxicity of aclarubicin became apparent. A similar effect was seen on the toxicity of
m-AMSA
. In contrast to aclarubicin, preincubation with Adriamycin did not antagonize the effect of VP-16. With purified
topoisomerase
II and naked DNA, aclarubicin did not stimulate the formation of cleavable complexes between
topoisomerase
II and DNA. Aclarubicin concentrations above 1 microM inhibited the baseline formation of cleavable complexes elicited with the enzyme alone. Low (1 to 10 nM) aclarubicin concentrations increased the formation of cleavable complexes obtained with VP-16 and
m-AMSA
; however, at aclarubicin concentrations above 1 microM an antagonistic effect was obtained. In cells, the
m-AMSA
- and VP-16-induced, protein-concealed DNA strand breaks were completely inhibitable by aclarubicin preincubation with no synergic dose levels. Our results suggest that aclarubicin inhibits
topoisomerase
II-mediated DNA cleavage. This inhibition could represent the mechanism of action of the drug and explain the lack of cross-resistance to the classical anthracyclines. The observed antagonism could have consequences for scheduling of aclarubicin with
topoisomerase
II-active anticancer drugs.
...
PMID:Antagonistic effect of aclarubicin on the cytotoxicity of etoposide and 4'-(9-acridinylamino)methanesulfon-m-anisidide in human small cell lung cancer cell lines and on topoisomerase II-mediated DNA cleavage. 215 80
The intercalating agent,
m-AMSA
, and the epipodophyllotoxin, VP-16, both
topoisomerase
II-reactive anticancer agents, are also embryotoxic agents in rat embryos cultured in vitro. Quantifying the embryotoxic effects of these drugs revealed that the no observed adverse effect level (NOAEL) for
m-AMSA
is 10 nM, the embryotoxic concentration range is 50-500 nM, and complete lethality is observed at 1 microM. In contrast, the NOAEL for o-AMSA, an inactive isomer of
m-AMSA
, is 1.0 microM, the embryotoxic concentration range is 10-100 microM, and complete lethality occurs at 200 microM. Based upon the concentrations of drugs required to produce 50% embryotoxicity or 50% malformed embryos,
m-AMSA
exhibits a 200-500-fold-higher embryotoxicity compared to o-AMSA. VP-16 exhibits a NOAEL of 1.0 microM, an embryotoxic concentration range of 2-5 microM, and complete lethality at 10 microM. Compared to
m-AMSA
, VP-16 is approximately 10-fold less embryotoxic. At appropriate concentrations, all three drugs were dysmorphogenic resulting in embryos that were characterized by hypoplasia of the prosencephalon with associated microopthalmia and dilation of the rhombencephalon. and dilation of the rhombencephalon. As a prelude to future studies focusing on the mechanism of drug-induced embryotoxicity, we have used established biochemical and immunologic methods to identify and quantify
topoisomerase
II in rat embryos. In addition, we have demonstrated that the embryo
topoisomerase
II can be inhibited by both
m-AMSA
and VP-16. Finally, we have used a human cDNA probe to detect
topoisomerase
II mRNA in the rat embryo. Thus, the combination of the in vitro whole embryo culture and these biochemical/molecular assays should allow us to explore the role of a specific nuclear target, i.e.,
topoisomerase
II, in the teratogenic effects of some commonly employed chemotherapeutic agents.
...
PMID:Embryotoxicity of the intercalating agents m-AMSA and o-AMSA and the epipodophyllotoxin VP-16 in postimplantation rat embryos in vitro. 216 85
CEM leukemia cells selected for resistance to VM-26 (CEM/VM-1) are cross-resistant to various other DNA topoisomerase II inhibitors but not to Vinca alkaloids. Since DNA topoisomerase II is a major protein of the nuclear matrix, we asked if alterations in nuclear matrix
topoisomerase
II might be important in this form of multidrug resistance. Pretreatment of drug-sensitive CEM cells for 2 h with either 5 microM VM-26 or 3 microM
m-AMSA
reduced the specific activity of newly replicated DNA on the nuclear matrix by 75 and 50%, respectively, relative to that of the bulk DNA. However, neither VM-26 nor
m-AMSA
affected the relative specific activity of nascent DNA isolated from the nuclear matrices of drug-resistant CEM/VM-1 cells. The decatenating and unknotting activities of DNA topoisomerase II were 6- and 7-fold lower, respectively, in the nuclear matrix preparations from the CEM/VM-1 cells compared to parental CEM cells. Western blot analysis revealed that the amount of immunoreactive
topoisomerase
II in the nuclear matrices of the CEM/VM-1 cells was decreased 3.2-fold relative to that in CEM cells, but there was no significant difference in the amount of enzyme present in the nonmatrix (1.5 M salt soluble) fractions of nuclei from these cell lines. Increasing the NaCl concentration used in the matrix isolation procedure from 0.2 to 1.8 M resulted in a progressive decrease in the specific activity of
topoisomerase
II in matrices of CEM/VM-1 but not CEM cells, which suggested that the association of the enzyme with the matrix is altered in the resistant cells.(ABSTRACT TRUNCATED AT 250 WORDS)
...
PMID:Decreased nuclear matrix DNA topoisomerase II in human leukemia cells resistant to VM-26 and m-AMSA. 216 74
The cytotoxic actions of several classes of antitumor DNA intercalators are thought to result from some disturbance to DNA metabolism following trapping of the nuclear enzyme DNA topoisomerase II as a covalent complex on DNA. Here we have studied
topoisomerase
II trapping and DNA synthesis patterns in relation to the acute cytotoxic actions of 4'-(9-acridinylamino)methanesulfon-m-anisidide (
mAMSA
) or mitoxantrone on SV40 transformed human fibroblasts. These two DNA intercalators differed significantly in their cytotoxic potential, mitoxantrone being 24-fold more toxic than
mAMSA
when assayed by the inhibition of clonogenicity. Although both drugs induced G2 delay at cytotoxic concentrations,
mAMSA
-treated cells recovered normal cell cycle phase distributions within 24 h of removal of drug, while mitoxantrone-treated cells continued to accumulate in G2 up to 48 h following drug treatment with evidence of complete inhibition of entry into mitosis. Compared with
mAMSA
, mitoxantrone showed a similar capacity to induce cleavable complexes in cellular DNA, and only a 2-fold greater ability to inhibit DNA synthesis. Within a 4-h posttreatment period,
mAMSA
-treated cells recovered normal rates of DNA synthesis, whereas a continued depression of DNA synthesis was observed in mitoxantrone-treated cells. The recovery patterns of DNA synthesis correlated with the rapid disappearance of
mAMSA
-induced complexes (less than 27% lesions remaining 2 h after drug removal) and the persistence of mitoxantrone-induced complexes during a 4-h posttreatment period. This difference in complex longevity was observed in other human transformed fibroblast cell lines irrespective of differences in the absolute levels of complexes induced by either agent. We suggest that the results provide evidence that DNA intercalators may differ in the forms of complexes induced and that the comparatively high cytotoxicity of mitoxantrone relates to the ability of the drug to trap
topoisomerase
II complexes in a form which effects a long-term inhibition of DNA replication and G2 traverse.
...
PMID:Long-term inhibition of DNA synthesis and the persistence of trapped topoisomerase II complexes in determining the toxicity of the antitumor DNA intercalators mAMSA and mitoxantrone. 216 81
Four drugs known to interact with
topoisomerase
II were assessed for their ability to enhance the cytotoxicity of cis-diamminedichloroplatinum(II) (CDDP) in Chinese hamster ovary (CHO) cell lines sensitive and resistant to VM-26. The combination treatments were analyzed by isobologram methodology. On 24 h exposure, there was no significant difference in the cytotoxicity of novobiocin or ciprofloxacin toward either cell line. The resistant cells were approximately 9-fold more resistant to 4'-(9-acridinylamino)methanesulfon-m-anisidide (
m-AMSA
) and approximately 170-fold more resistant to etoposide after a 24-h exposure. The combination of novobiocin and cisplatin produced greater than additive cell kill over the entire dose range of cisplatin tested in both cell lines.
m-AMSA
and CDDP produced cell kill that fell within the envelope of additivity. Etoposide and CDDP resulted in cytotoxicity that was slightly greater than additive at low CDDP concentrations and additive at the highest concentration of CDDP tested in the parental cell line and was slightly greater than additive in the resistant cell line. Ciprofloxacin and CDDP, like novobiocin, resulted in greater than additive cell kill in both cell lines. The enhancement of CDDP cytotoxicity by novobiocin that was seen in exponentially growing cells was lost in stationary-phase cultures. In these studies, novobiocin and, to a lesser degree, ciprofloxacin produced greater than additive cell kill in combination with CDDP in parental and epipodophyllotoxin-resistant CHO cells.
...
PMID:Ability of four potential topoisomerase II inhibitors to enhance the cytotoxicity of cis-diamminedichloroplatinum (II) in Chinese hamster ovary cells and in an epipodophyllotoxin-resistant subline. 217 96
Numerous antitumor and antibacterial agents inhibit type II DNA topoisomerases, yielding, in each case, a complex of enzyme covalently bound to cleaved DNA. We are investigating the mechanism of inhibitor action by using the type II DNA topoisomerase of bacteriophage T4 as a model. The T4
topoisomerase
is the target of antitumor agent 4'-(9-acridinylamino)-methanesulfon-m-anisidide (
m-AMSA
) in T4-infected Escherichia coli. Two
m-AMSA
-resistant phage strains were previously isolated, one with a point mutation in
topoisomerase
subunit gene 39 and the other with a point mutation in
topoisomerase
subunit gene 52. We report here that the wild-type T4
topoisomerase
is inhibited by six additional antitumor agents that also inhibit the mammalian type II
topoisomerase
: ellipticine, 9-OH-ellipticine, 2-me-9-OH-ellipticinium acetate, mitoxantrone diacetate, teniposide, and etoposide. Further, one or both of the
m-AMSA
-resistance mutations alters the enzyme sensitivity to each of these agents, conferring either cross-resistance or enhanced sensitivity. Finally, the gene 39 mutation confers on T4
topoisomerase
a DNA gyrase-like sensitivity to the gyrase inhibitor oxolinic acid, thus establishing a direct link between the mechanism of action of the anti-bacterial quinolones and that of the antitumor agents. These results strongly suggest that diverse inhibitors of type II topoisomerases share a common binding site and a common mechanism of action, both of which are apparently conserved in the evolution of the type II DNA topoisomerases. Alterations in DNA cleavage site specificity caused by either the inhibitors or the
m-AMSA
-resistance mutations favor the proposal that the inhibitor binding site is composed of both protein and DNA.
...
PMID:Evidence for a common mechanism of action for antitumor and antibacterial agents that inhibit type II DNA topoisomerases. 217 9
The present study was designed to determine and compare the clastogenicity of
m-AMSA
and camptothecin (CAMP) in vivo in mouse bone marrow and peripheral blood lymphocytes (PBLs), and in vitro in mouse lymphoma L5178Y cells.
m-AMSA
interferes with
topoisomerase
II to induce double-strand DNA breaks. CAMP interferes with topoisomerase I to induce single-strand DNA breaks. Thus, we expected the two drugs to induce different types of chromosomal aberrations (CAs). However, both drugs produced quantitatively and qualitatively similar numbers and types of aberrations under similar experimental conditions. In mouse bone marrow exposed over and 18-h period, both drugs (3 mg/kg) induced approximately 30 damaged cells, with an average of 0.4 chromatid breaks per cell (in 100 cells analyzed/mouse). In addition, both drugs induced only chromatid-type aberrations in mouse bone marrow in vivo when exposure occurred during G2. Cell cycle specificity was indicated by the absence of CAs when exposure to the drugs occurred in vivo in mouse PBLs during G0. In L5178Y cells,
m-AMSA
was considerably more potent for the induction of mutations and somewhat more potent for the induction of CAs than CAMP was. In contrast to the in vivo bone marrow results, the drugs induced high levels of both chromatid- and chromosome-type aberrations in vitro. The ultimate types of chromosomal damage induced by
m-AMSA
and CAMP result from a complex interaction of (i) cell cycle specific variations in
topoisomerase
enzyme levels, (ii) the abilities of these drugs to interfere with the orderly DNA breakage/reunion associated with
topoisomerase
activity, and (iii) the processing of the damage resulting from these interactions.
...
PMID:Genotoxicity of inhibitors of DNA topoisomerases I (camptothecin) and II (m-AMSA) in vivo and in vitro. 217 33
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