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)

Camptothecin was recently identified as an inhibitor of mammalian topoisomerase I. Similar to inhibitors of topoisomerase II, camptothecin produces DNA single-strand breaks (SSB) and DNA-protein cross-links (DPC) in mammalian cells. However, their one-to-one association, expected for trapped topoisomerase complexes, has not previously been demonstrated. We have studied camptothecin-induced SSB and DPC in Chinese hamster DC3F cells and their isolated nuclei, using the DNA alkaline elution technique. It was found that the SSB and DPC frequencies detected following camptothecin treatment depend upon the conditions used for lysis. When lysis was with sodium dodecyl sulfate, the observed frequencies of SSB and DPC were 2- to 3-fold greater than when sodium dodecyl sarkosinate (Sarkosyl) was used. In either case, the SSB:DPC ratio was close to 1. All of the camptothecin-induced SSB were protein linked, as indicated by the absence of DNA elution under nondeproteinizing conditions. DNA cleavage assays with purified topoisomerase I also indicated that the weaker Sarkosyl detergent fails to trap all of the enzyme-DNA complexes. In contrast, lysis conditions had little effect on levels of SSB or DPC produced by 4'-(9-acridinylamino)-methanesulfon-m-anisidide, suggesting that trapping of topoisomerase II complexes occurs equally well with either detergent. In experiments using isolated nuclei, it was found that the camptothecin-induced SSB, in contrast to trapped topoisomerase II complexes, can form and reverse within minutes at 4 degrees C. The activity of camptothecin at low temperature was also seen with purified topoisomerase I. These results support the hypothesis that the SSB and DPC induced by camptothecin in mammalian cells are due to an action on topoisomerase I.
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PMID:Protein-linked DNA strand breaks induced in mammalian cells by camptothecin, an inhibitor of topoisomerase I. 254 7

Camptothecin is a cytotoxic drug which inhibits cellular nucleic acid synthesis. Associated with this inhibition is the induction of protein-linked DNA strand breaks. Recent studies have demonstrated that camptothecin interferes with the DNA breakage and rejoining activity of the enzyme DNA topoisomerase I and stabilizes a cleavable complex between this enzyme and DNA. Treatment of this complex with a protein denaturant results in DNA strand breaks and the covalent attachment of topoisomerase to the 3'-end of the DNA breaks. In this paper we have mapped the camptothecin-induced DNA breaks on the hsp 70 heat-shock gene in cultured Drosophila cells. Drug-induced breaks are present primarily within the coding region of this gene and occur only when transcription of this gene is activated by heat. Camptothecin (20 microM) was also observed to inhibit heat-induced hsp 70 transcription greater than 70%. The possible role of topoisomerase I in hsp 70 heat-shock gene transcription is discussed.
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PMID:Camptothecin inhibits hsp 70 heat-shock transcription and induces DNA strand breaks in hsp 70 genes in Drosophila. 281 31

I have found that type I and type II topoisomerase inhibitors have pronounced but very different effects on SV40 DNA replication. Type II topoisomerase inhibitors selectively interfere with separation of newly replicated SV40 daughter chromosomes, while the type I topoisomerase inhibitor camptothecin rapidly produces broken replication forks in growing Cairns structures. Camptothecin also produces abnormal SV40 DNAs which appear to be intermediates and end products of sister chromatid exchange.
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PMID:Topoisomerase inhibitors can selectively interfere with different stages of simian virus 40 DNA replication. 281 32

Detergent-soluble DNA is the fraction (2-4%) of DNA that is released into the supernate upon mild detergent lysis. It is nonmitochondrial in origin. It labels efficiently with deoxy[3H]ribonucleosides and the labeling is prevented by inhibitors of polymerase alpha and ribonucleotide reductase. In previous publications we have characterized detergent-soluble DNA from splenocytes of immunologically activated mice. In this publication we show that incorporation of [3H]thymidine into detergent-soluble DNA is prevented by pretreatment with novobiocin, 4'-(9-acridinylamino)methanesulfon-m-anisidide (m-AMSA), and teniposide (VM26), three inhibitors of type II topoisomerases. Camptothecin, an inhibitor of type I topoisomerases, also reduces incorporation of [3H]thymidine but only to 50% of control levels. In addition to affecting incorporation of [3H]thymidine, preincubation with the topoisomerase II inhibitors m-AMSA and VM26 alters the amount of DNA recovered in the detergent-soluble fraction. At low concentrations of m-AMSA the amount of detergent-soluble DNA increases somewhat, whereas at higher drug concentrations a marked decrease is observed. Treatment with VM26 results in diminished amounts of DNA being released into the detergent-soluble fraction as well. However, maximal inhibition of detergent-soluble DNA release by VM26 requires the presence of camptothecin. Therefore, we suggest that topoisomerases play an important role in making a small part of lymphocyte chromatin detergent labile. Furthermore, these results are consistent with recent studies demonstrating a role for topoisomerases in yeast replication. Thus, the newly synthesized portion of detergent-soluble DNA may arise as DNA replication intermediates not yet stabilized into mature chromatin.
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PMID:Role for topoisomerases in the release of DNA into the detergent-soluble fraction of eukaryotic cells. 301 25

I have found that antineoplastic drugs which are known to be inhibitors of mammalian DNA topoisomerases have pronounced and selective effects on simian virus 40 DNA replication. Ellipticine, 4'-(9-acridinylamino)methanesulfon-m-aniside, and Adriamycin blocked decatenation of newly replicated simian virus 40 daughter chromosomes in vivo. The arrested decatenation intermediates produced by these drugs contained single-strand DNA breaks. Ellipticine in particular produced these catenated dimers rapidly and efficiently. Removal of the drug resulted in rapid reversal of the block and completion of decatenation. The demonstration that these drugs interfere with decatenation suggests that they may exert their cytotoxic and antineoplastic effects by preventing the separation of newly replicated cellular chromosomes. Camptothecin rapidly breaks replication forks in growing Cairns structures. It is likely that the target of camptothecin is the "swivel" topoisomerase required for DNA replication and that it is located at or very near the replication fork in vivo. Evidence is presented that many of the broken Cairns structures are in fact half-completed sister chromatid exchanges. One pathway for the resolution of these structures is completion of the sister chromatid exchange to produce a circular head-to-tail dimer.
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PMID:Topoisomerase inhibitors can selectively interfere with different stages of simian virus 40 DNA replication. 302 45

Results of filter elution assays of lesions produced in the DNA of cultured L1210 cells by the antineoplastic alkaloid camptothecin support the notion that topoisomerase I is an intracellular target of this drug. One to 10 microM camptothecin induced DNA single-strand, but not double-strand, breaks when incubated with intact cells or with their isolated nuclei. Approximately one half of the strand breakage was protein concealed, as judged by filter elution. Camptothecin-induced, protein-concealed DNA strand breaks disappeared rapidly after drug removal. DNA-protein cross-links were generated by camptothecin with frequencies approximately equal to those of protein-concealed DNA strand breaks. It is likely that camptothecin can inhibit topoisomerase I in intact cells in a manner similar to that in which other antineoplastic agents such as amsacrine or teniposide inhibit topoisomerase II. DNA-breaking lesions other than those resulting from trapped topoisomerase I-DNA complexes may also be generated by camptothecin. The yields of DNA strand breaks induced by camptothecin, amsacrine, or teniposide were approximately doubled when cells were incubated for 16 h with 3-aminobenzamide, an inhibitor of poly(ADP ribosylation) of proteins, prior to 1-h exposure to the antineoplastic compounds. 3-Aminobenzamide also enhanced the cytotoxic action of camptothecin, amsacrine, and teniposide. These results suggest that protein-concealed strand breaks can be lethal lesions and that intracellular topoisomerase I and II activity may be regulated coordinately through poly(ADP ribosylation).
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PMID:Relationship between the intracellular effects of camptothecin and the inhibition of DNA topoisomerase I in cultured L1210 cells. 302 14

The fraction DE-B obtained by fractionating an extract from rat mammary adenocarcinoma cells on a DEAE-Sephadex column was used for transcribing linear and supercoiled rRNA gene (rDNA). This fraction, which is known to contain RNA polymerase I and essential transcription factors, also contains DNA topoisomerase I activity. Inhibition of this topoisomerase activity by the selective inhibitor camptothecin markedly diminished transcription of supercoiled rDNA, and at a concentration of 150 microM, camptothecin almost completely inhibited DNA topoisomerase I activity and supercoiled rDNA transcription. Addition of exogenous calf thymus DNA topoisomerase I to the sample containing the drug restored the ability of the extract to transcribe supercoiled rDNA. Camptothecin, even at a concentration of 500 microM, had no significant effect on the transcription of linear rDNA. These studies show that relaxation of supercoiled rDNA by DNA topoisomerase I is essential for its transcription. The preferential inhibition of rRNA synthesis in vivo following treatment with camptothecin is probably due to selective camptothecin inhibition of DNA topoisomerase I activity.
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PMID:Role of DNA topoisomerase I in the transcription of supercoiled rRNA gene. 303 39

Drugs that interact with DNA topoisomerases I and II hold great promise for the treatment of cancer, however, like many other anti-cancer agents, they are a double-edged sword and may themselves cause mutation and cancer. In vitro studies show that clinically effective agents, such as etoposide, doxorubicin and others, stabilize a ternary complex where topoisomerase II is covalently linked to DNA. This complex represents an intermediate in the topoisomerase-II catalyzed DNA supercoil relaxation reaction. Camptothecin and its analogues stabilize a similar ternary complex, in vitro, consisting of topoisomerase I covalently linked to DNA at single-strand breaks. Short-term tests of genotoxicity confirm that topoisomerase-interactive agents are mutagenic and suggest common mechanisms by which they induce mutation and selectively kill tumor cells. These agents induce sister-chromatid exchange, chromosomal aberrations and mutations in specific mammalian genes. Their propensity to induce small colonies in the L5178/TK+/(-)-3.7.2C assay implies that topoisomerase-interactive agents induce large DNA rearrangements and deletions. These may result from topoisomerase-subunit exchange at drug-stabilized ternary complexes or from attempts by the cell to bypass the replication block caused by stabilized ternary complexes. Studies in bacterial mutation assays suggest that topoisomerase-interactive agents may also induce mutations, albeit at a lower rate, through simple DNA intercalation or via generation of oxygen free radicals. Second malignancies observed in patients previously treated with topoisomerase II interactive agents suggest these may be an important clinical consequence of their capacity to induce mutation. In particular, a unique form of acute myelogenous leukemia is observed at strikingly high frequencies after treatment with relatively high doses of the epipodophyllotoxins etoposide and teniposide. This form of AML has been reported after the uses of other classes of topoisomerase-interactive agents as well. Cancer induction is therefore a toxic consequence predicted by short-term tests of genotoxicity and should be weighed against the potential therapeutic benefits of topoisomerase-interactive agents.
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PMID:International Commission for Protection Against Environmental Mutagens and Carcinogens. Mutagenicity and carcinogenicity of topoisomerase-interactive agents. 751 27

DNA topoisomerases are enzymes governing the multitude of conformational changes DNA undergoes during the cell cycle. Several compounds are likely to interfere with specific steps of the catalytic cycle of these enzymes. Camptothecin arrests the activity of DNA topoisomerase I by provoking the formation of a single-stranded DNA break with the enzyme molecule covalently attached to the DNA. Exposure to m-AMSA arrests DNA topoisomerase II by the formation of a ternary complex involving the drug, the enzyme, and DNA carrying a double-stranded break. Netropsin, distamycin A, and berenil inhibit DNA topoisomerase-mediated relaxation of supercoiled DNA by an as-yet unknown mechanism. Here, we analyze the cell cycle kinetic effects of exposure to camptothecin, m-AMSA, netropsin, distamycin A, and berenil by using continuous bromodeoxyuridine labeling followed by bivariate Hoechst 33258/ethidium bromide flow cytometry. Camptothecin elicits an accumulation of cells in all compartments of the cell cycle, while exposure to m-AMSA leads mainly to retention of cells in the G0/G1 compartment and to accumulation in the G2 phase. Neither camptothecin nor m-AMSA shows a synergism with bromodeoxyuridine incorporation into the DNA. These results point toward distinct functions of the two DNA topoisomerases in the process of cell cycle traverse. The compounds binding to the minor groove of DNA interfere with all phases of the cell cycle, but with a relative emphasis on the G2 phase. Neither camptothecin nor m-AMSA exhibits a synergistic effect in combination with berenil. Hence, at the level of perturbed cell cycle kinetics a distinction can be made between compounds provoking an abortive inhibition of the catalytic cycle of DNA topoisomerases (e.g., camptothecin, m-AMSA) and those interfering with the activity of the enzyme by a distinct mechanism.
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PMID:Distinct patterns of cell cycle disturbance elicited by compounds interfering with DNA topoisomerase I and II activity. 753 96

An impediment to the investigation of mammalian spermatogenic meiosis has been the lack of an appropriate system for experimental manipulation of meiotic prophase cells. We report here the use of a simple system for the short-term culture of pachytene spermatocytes. We have assayed parameters of cell function pertinent to meiotic prophase, namely chromosome pairing and synapsis. During the culture period of 24-48 hr, cells maintained typical pachytene morphology, chromatin condensation patterns, and chromosome pairing, as assessed by light and electron microscopy. Uridine incorporation, monitored by autoradiography, reflected the chromosomal distribution found in vivo in that the autosomal chromosomes were transcriptionally active, while the sex chromosomes were not. Thus features of chromosome pairing and sex chromatin inactivation are maintained in these cultures. We have conducted experiments to demonstrate that cultured pachytene spermatocytes can be useful for the analysis of agents, some of which may be suspected mutagens, that might affect chromosome structure and function during meiosis. Treatment of cells with actinomycin D revealed a differential effect on chromatin condensation in the autosomes versus the sex chromosomes. Camptothecin, a topoisomerase inhibitor, induced desynapsis of paired chromosomes. Okadaic acid, a phosphatase inhibitor, induced premature metaphase-I condensation of pachytene chromosomes. This last experiment suggests that these cultured cells may be useful for analysis of meiotic cell cycle controls. Taken together, these results demonstrate a culture system that can be useful for analysis of meiotic events as well as in screening for potential mutagenic agents that might affect meiotic chromosome structure and function.
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PMID:Culture of pachytene spermatocytes for analysis of meiosis. 773 63

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