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)

1. The solid tumour has various properties which tend to minimize the effects of a cytotoxic agent; the low vascular density of tumours, in particular, limits the diffusion of many anti-tumour drugs. 2. This applies particularly to two general classes of anti-cancer drugs which already play an important role in chemotherapy: mitotic poisons and topoisomerase poisons. Such compounds bind strongly to proteins and/or DNA, and their diffusion from the bloodstream into solid tumours is slow, as is their clearance from tumour tissue. 3. The specific questions posed here is whether anti-cancer compounds of these types are more cytotoxic when administered at a low concentration for a long time (mimicking conditions in solid tumours) than at a correspondingly high concentration for a short time (mimicking conditions in host tissue). Two possible principles may be involved, the first based on cytokinetic considerations and then second on self-inhibition of drug cytotoxicity. 4. Using cultured human cancer cells we have shown that taxol, which acts on mitotic cells and camptothecin, which acts on S-phase cells, are examples of the first principle. Exposures to high drug concentrations for short times are much less cytotoxic than exposure to correspondingly lower drug concentrations for a longer time (with the same concentration x time of exposure). We also show that the drug DACA (N-[2-(dimethylamino)ethyl]acridine-4-carboxamide) developed in this laboratory and currently undergoing clinical trial, achieves the same result through the principle of self-inhibition of cytotoxicity. 5. Matching of the cytokinetic or self-inhibitory profile of a drugs' action with the pharmacokinetics of drug in tumours may provide new drugs with increased anti-tumour effects.
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PMID:Pharmacokinetic/cytokinetic principles in the chemotherapy of solid tumours. 859 37

The mechanism of action of the antitumor drug amsacrine involves intercalation of the acridine chromophore into DNA and inhibition of topoisomerase II. The substituent at position 1' on the aniline is believed to be essential to the formation of the topoisomerase II/DNA cleavable complex and therefore to the cytotoxicity of the drug. To further delineate the role of the 1'-substituent, we investigated the effects on topoisomerase II activities of three anilinoacridine derivatives that differ only by the nature of the substituent at position 1'. The results of the cytotoxicity assays performed with cells sensitive (DC-3F) and resistant [DC-3F/9-hydroxy-ellipticine (9-OH-E)] to topoisomerase inhibitors are correlated with the effects of the drugs on topoisomerase II-mediated DNA cleavage in vitro. The influence of topoisomerase II alpha on the mechanism of action of the drugs was examined using resistant DC-3F/9-OH-E cells transfected with a plasmid carrying a wild-type human topoisomerase II alpha cDNA. Depending on the nature of the 1'-substituent of the drugs, the restoration of normal topoisomerase II alpha catalytic activity in human topoisomerase II alpha cDNA-transfected DC-3F/9-OH-E cells either does not modify the susceptibility of the cells to the drug or partially reverses the resistance phenotype. The molecular and cellular studies reveal that topoisomerase II alpha is implicated in the cytotoxicity of amsacrine and confirm that the substituent at position 1' on the anilino ring of amsacrine governs the interaction with topoisomerase II.
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PMID:The 1'-substituent on the anilino ring of the antitumor drug amsacrine is a critical element for topoisomerase II inhibition and cytotoxicity. 863 68

A series of novel C11-substituted derivatives of azaelliptitoxin (azatoxin) have been synthesized and tested for their inhibitory activity against human DNA topoisomerase II. Incorporation of a C11 polyamine or amine resulted in an increase in the intercalation properties of the drug and a decrease of topoisomerase II activity. The structure-activity relationship (SAR) profile of the nonintercalating C11 anilino azatoxin class follows the SAR of the (anilino)acridine family. 11-(4-Cyanoanilino)azatoxin (14) was found to be the most active analog in this series, exhibiting approximately 10-fold higher activity than azatoxin 12 and etoposide.
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PMID:Inhibition of DNA topoisomerase II by azaelliptitoxins functionalized in the variable substituent domain. 866 62

A number of acridine derivatives, including the clinical antileukaemia agent amsacrine and the experimental agent DACA (N-[2-(dimethylamino)ethyl]acridine-4-carboxamide), target the enzyme topoisomerase II. We demonstrate here that DACA induces DNA cleavage in the presence of topoisomerase I as well as of topoisomerase II. We also investigate a series of acridine derivatives which link amsacrine to DACA in terms of DNA binding, topoisomerase poisoning and biological activity. The presence of an acridine 4-linked N-2-(dimethylamino)ethyl group provides both a pronounced G-C preference for DNA binding and activity towards topoisomerase I. The removal of the anilino side chain of amsacrine, in combination with the presence of the N-2-(dimethylamino)ethyl group, provides in vitro biological activity against "atypical" multidrug resistant leukaemia lines with low topoisomerase II activity. Among these compounds, suppression of the ionisation of the acridine nitrogen to produce the compound DACA is associated with experimental activity against solid tumours. The addition of an acridine 2-chloro substituent to DACA suppresses the stimulation of topoisomerase II-dependent DNA cleavage but increases stimulation of topoisomerase I cleavage. 2-Substitution also increases activity against the "atypical" multidrug resistant cell lines. Overall, the results suggest that augmentation of topoisomerase I-dependent activity in this series by appropriate chemical substitution in this series leads to circumvention of topoisomerase II-mediated multidrug resistance.
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PMID:From amsacrine to DACA (N-[2-(dimethylamino)ethyl]acridine-4-carboxamide): selectivity for topoisomerases I and II among acridine derivatives. 869 77

Cytotoxicity of several classes of antitumor DNA intercalators is thought to result from disturbance of DNA metabolism following trapping of the nuclear enzyme DNA topoisomerase II as a covalent complex on DNA. Here, molecular interactions of the potent antitumor drug amsacrine (m-AMSA), an inhibitor of topoisomerase II, within living K562 cancer cells have been studied using surface-enhanced Raman (SER) spectroscopy. The work is based on data of the previously performed model SER experiments dealing with amsacrine/DNA, drug/topoisomerase II and drug/DNA/topoisomerase II complexes in aqueous buffer solutions. The SER data indicated two kinds of amsacrine interactions in the model complexes with topoisomerase II alone or within ternary complex: non-specific (via the acridine moiety) and specific to the enzyme conformation (via the side chain of the drug). These two types of interactions have been both revealed by the micro-SER spectra of amsacrine within living K562 cancer cells. Our data suppose the specific interactions of amsacrine with topoisomerase II via the side chain of the drug (particular feature of the drug/topoisomerase II and ternary complexes) to be crucial for its inhibitory activity.
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PMID:Intracellular molecular interactions of antitumor drug amsacrine (m-AMSA) as revealed by surface-enhanced Raman spectroscopy. 894 14

The mixed topoisomerase I/II inhibitor N-[2-(dimethylamino)ethyl]acridine-4-carboxamide (DACA) is currently in clinical trial as an anticancer drug. A series of acridine-substituted analogues were prepared, using a new synthetic route to substituted acridine-4-carboxylic acids (conversion of substituted diphenylamine diacid monoesters to the corresponding aldehydes and mild acid-catalyzed ring closure to form the acridines directly). The analogues were evaluated in a panel of cell lines which included wild-type (JLC) and mutant (JLA and JLD) forms of the human Jurkat leukemia line. The latter mutant lines are resistant to topoisomerase II targeted agents due to lower levels of the enzyme. Structure-activity studies suggest that the electronic properties of the substituents do not markedly affect cytotoxicity, but steric bulk is important, with larger groups leading to loss of activity. The compounds fell broadly into two categories. The majority had cytotoxicities similar to (or lower than) that of DACA itself and were equitoxic in all the Jurkat lines, suggesting a relatively greater effect on topoisomerase I compared with topoisomerase II. Most of the 5-substituted derivatives and the 7-Ph compound were more cytotoxic than DACA, but were less effective against JLA and JLD cell lines than in the wild-type JLC, suggesting a mode of cytotoxicity largely mediated by effects on topoisomerase II. Both DACA and selected acridine-substituted analogues were active in the relatively refractory subcutaneous colon 38 tumor model in vivo.
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PMID:Structure-activity relationships for acridine-substituted analogues of the mixed topoisomerase I/II inhibitor N-[2-(dimethylamino)ethyl]acridine-4-carboxamide. 919 70

Members of the class of 9-anilinoacridine topoisomerase II inhibitors bearing lipophilic electron-donating 1'-anilino substituents are active against both the promastigote and amastigote forms of the parasite Leishmania major. A series of analogues of the known 1'-NHhexyl lead compound were prepared and evaluated against L. major in macrophage culture to further develop structure-activity relationships (SAR). Toxicity toward mammalian cells was measured in a human leukemia cell line, and the ratio of the two IC50 values (IC50(J)/IC50(L)) was used as a measure of the in vitro therapeutic index (IVTI). A 3,6-diNMe2 substitution pattern on the acridine greatly increased toxicity to L. major without altering mammalian toxicity, increasing IVTIs over that of the lead compound. The 2-OMe, 6-Cl acridine substitution pattern used in the antimalarial drug mepacrine also resulted in potent antileishmanial activity and high IVTIs. Earlier suggestions of the utility of 2'-OR groups in lowering mammalian cytotoxicity were not borne out in this wider study. A series of very lipophilic 1'-NRR (symmetric dialkylamino)-substituted analogues showed relatively high antileishmanial potency, but no clear trend was apparent across the series, and none were superior to the 1'-NH(CH2)5Me subclass. Subsets of the most active 1'-N(R)(CH2)5Me- and 1'-N(alkyl)2-substituted compounds against L. major were also evaluated against Leishmania donovani, Trypanosoma cruzi, and Trypanosoma brucei, but no consistent SAR could be discerned in these physiologically diverse test systems. The present study has confirmed earlier conclusions that lipophilic electron-donating groups at the 1'-position of 9-anilinoacridines provide high activity against L. major, but the SAR patterns observed do not carry over to the other parasites studied.
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PMID:Structure-activity relationships for the antileishmanial and antitrypanosomal activities of 1'-substituted 9-anilinoacridines. 925 70

The acridine derivative m-AMCA (methyl-N-[4-(9-acridinylamino)-2-methoxyphenyl]carbamate hydrochloride), a carbamate analogue of the topoisomerase II poison amsacrine, is distinguished by its high cytotoxicity against non-cycling tumour cells. We compared the response of cultured Lewis lung carcinoma cells to m-AMCA, amsacrine and the topoisomerase I poison camptothecin. The DNA polymerase inhibitor aphidicolin reversed the cytotoxicity of camptothecin fully, that of amsacrine partially, and that of m-AMCA minimally. The ability of m-AMCA to induce the enzyme poly(ADP-ribose)polymerase (PARP) was markedly lower than that of camptothecin or amsacrine. Cell cycle responses to m-AMCA and amsacrine were similar, with slowing of progress through S-phase and arrest in G2-phase. These cell cycle changes were also observed when plateau phase cultures were exposed to drug for 1 h, washed free of drug and cultured in fresh medium, with m-AMCA having a more pronounced effect than amsacrine and camptothecin having no effect. We also examined the role of p53 protein in the response using cultured human H460 cells. Both m-AMCA and amsacrine induced p53 protein expression in proliferating but not in non-proliferating H460 cells, and induced p21WAF1 regardless of proliferation status. Both induced G1-phase cell cycle arrest. It is suggested that two cytotoxicity mechanisms can be distinguished using these drugs. The first is specific for S-phase cells, is reversed by aphidicolin and induces PARP activity. The second is cell cycle non-specific, does not induce PARP and is unaffected by aphidicolin. Camptothecin activates only the first, m-AMCA primarily the second and amsacrine activates both.
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PMID:Cellular responses to methyl-N-[4-9-acridinylamino)-2-methoxyphenyl] carbamate hydrochloride, an analogue of amsacrine active against non-proliferating cells. 938 32

Pyrazoloacridine (PA), an acridine congener with an unknown mechanism of action, has shown selective activity against solid tumor cells, cytotoxicity in noncycling and hypoxic cells, and promising antitumor activity in Phase I clinical trials. In the present study, the effect of PA on topoisomerase (topo) activity was evaluated using yeast strains lacking functional topo I or II, mammalian cell nuclear extracts, purified samples of mammalian topo I and topo II, and intact mammalian tissue culture cells. Clonogenic assays revealed that PA cytotoxicity in yeast strains was unaffected by selective loss of topo I or topo II activity. On the other hand, enzyme assays revealed that 2-4 microM PA abolished the catalytic activity of both topo I and topo II in vitro. In contrast to topotecan and etoposide, PA did not stabilize covalent topo-DNA complexes. Instead, PA inhibited topotecan-induced stabilization of covalent topo I-DNA complexes and etoposide-induced stabilization of topo II-DNA complexes in vitro and in intact cells. Consistent with these results, colony-forming assays indicated that short-term PA exposure inhibited the cytotoxicity of topotecan and etoposide, whereas prolonged PA exposure was itself toxic to these cells. Accumulation studies revealed that PA was concentrated as much as 250-fold in drug-treated cells, resulting in intranuclear concentrations that far exceeded those required to inhibit topo I and topo II. Collectively, these results not only suggest that PA can target both topo I and topo II at clinically achievable concentrations but also indicate that its mechanism is distinct from topo I and topo II poisons presently licensed for clinical use.
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PMID:Effect of pyrazoloacridine (NSC 366140) on DNA topoisomerases I and II. 953 38

The effects of acridine derivatives (proflavine and 2,7-dialkyl derivatives, diacridines and triacridines, 9-aminoacridine carboxamides, and 9-anilinoacridine, amsacrine and its congeners) on overall RNA synthesis in vitro, on synthesis of initiating oligonucleotides and the binding of the enzyme to DNA were studied. The primary mechanism of action is related to inhibition of the enzyme binding to DNA. The acridines (intercalating or non-intercalating and bis-intercalating ligands) assayed here differ in the properties of their complexes with DNA. Correlation is generally observed between inhibition of RNA synthesis in vitro and cytotoxicity in cell cultures for di- and triacridines and 9-aminoacridine carboxamide derivatives. No relationship was found between the effect on RNA polymerase system and biological effects for amsacrine and its derivatives in contrast to the other series of acridines studied here. The aniline ring seems to decrease the inhibitory potency of a ligand. The discrepancy between the biological effect and RNA synthesis inhibition may be due to a different mechanism of cytotoxicity action of amsacrine which is a potent topoisomerase II poison.
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PMID:Inhibition of RNA synthesis in vitro by acridines--relation between structure and activity. 967 27


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