We studied the role of DNA topoisomerase II in the biological actions of a series of novel alkylaminoanthraquinones, including N-oxide derivatives designed as prodrugs liable to bioreductive activation in hypoxic tumour cells. Drug structures were based upon the DNA-binding anticancer topoisomerase II poison mitoxantrone with modifications to the alkylamino side chains. The agents included AQ4, 1,4-bis{[2-(dimethylamino)ethyl] amino}5,8-dihydroxy-anthracene-9,10-dione, and AQ6, 1{[2-dimethylamino)-ethyl]amino}4-{[2[(hydroxyethyl)amino]ethyl]- amino}5,8-dihydroxy-anthracene-9,10-dione, together with the corresponding mono-N-oxide (AQ6NO) and di-N-oxide (AQ4NO). The R3N(+)-O- modification renders the terminal nitrogen group electrically neutral and was found to reduce AQ6NO or effectively abolish AQ4NO-DNA binding. Comparative studies were carried out using two SV40-transformed fibroblast cell lines, MRC5-V1 and AT5BIVA, the latter being a relative overproducer of DNA topoisomerase II alpha. The inhibition of DNA topoisomerase II decatenation activity ranked according to DNA-binding capacity. A similar ranking was found for drug-induced DNA-protein cross-linking in intact cells, depending upon topoisomerase II availability. Inhibition of DNA synthesis in S-phase synchronized cultures ranked in the order of AQ6 > mitoxantrone > > AQ6NO and was independent of topoisomerase II availability. Cytotoxicity of acute 1-h exposures for all agents except the inactive AQ4NO was enhanced in the topoisomerase II-overproducing cell line. The results indicate an important role for enzyme targeting in anthraquinone action. However, DNA synthesis inhibition and cytotoxicity were greater than expected for AQ6, given its topoisomerase- and DNA-interaction properties, and parallel studies have provided evidence of an additional role for enhanced subcellular accumulation and nuclear targeting. The inactivity of AQ4NO and the retention of only partial activity of AQ6NO, allied with the effective topoisomerase II-targeting and high cytotoxic potential of their presumed metabolites, favour their use as prodrugs in tumour cells with enhanced bioreductive potential.
Flow cytometry and laser-scanning confocal fluorescence microscopy have been used in the study of the pharmacodynamics, in single intact cells, of two novel alkylaminoanthraquinones (AQ4 and AQ6), structurally based upon the mid-red excitable but very weakly fluorescent anticancer agent mitoxantrone, together with their respective N-oxide derivatives (AQ4NO and AQ6NO). The drug design rationale was that N-oxide modifications generates prodrug forms suitable for selective bioreductive-activation in hypoxic tumor cells. DNA-binding ranked in the order of mitoxantrone > AQ6 > AQ4 > AQ6NO >> AQ4NO. Using both cytometric methods a similar ranking was found for whole cell and nuclear location in human transformed fibroblasts. However, AQ6 showed enhanced nuclear uptake compared with mitoxantrone, in keeping with its greater capacity to inhibit DNA synthesis. Partial charge neutralisation by N-oxide derivatization resulted in loss of DNA synthesis inhibition but retention of the ability to accumulate in the cytosol, an important property for prodrug development. We conclude that both flow cytometry and confocal imaging revealed biologically significant differences between analogues for subcellular distribution and retention properties. The study demonstrates the potential for these complementary 647-nm krypton laser line-based fluorometric methods to provide relevant structure-activity information in anthraquinone drug-design programmes.
Flow cytometry and laser‐scanning confocal fluorescence microscopy have been used in the study of the pharmacodynamics, in single intact cells, of two novel alkylaminoanthraquinones (AQ4 and AQ6), structurally based upon the mid‐red excitable but very weakly fluorescent anticancer agent mitoxantrone, together with their respective N‐oxide derivatives (AQ4NO and AQ6NO). The drug design rationale was that N‐oxide modifications generates prodrug forms suitable for selective bioreductive‐activation in hypoxic tumor cells. DNA‐binding ranked in the order of mitoxantrone > AQ6 > AQ4 > AQ6NO >> AQ4NO. Using both cytometric methods a similar ranking was found for whole cell and nuclear location in human transformed fibroblasts. However, AQ6 showed enhanced nuclear uptake compared with mitoxantrone, in keeping with its greater capacity to inhibit DNA synthesis. Partial charge neutralisation by N‐oxide derivatization resulted in loss of DNA synthesis inhibition but retention of the ability to accumulate in the cytosol, an important property for prodrug development. We conclude that both flow cytometry and confocal imaging revealed biologically significant differences between analogues for subcellular distribution and retention properties. The study demonstrates the potential for these complementary 647‐nm krypton laser line‐based fluorometric methods to provide relevant structure‐activity information in anthraquinone drug‐design programmes. Cytometry 27:43–53, 1997. © 1997 Wiley‐Liss, Inc.
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