Chromophore-modified antitumor anthracenediones: synthesis, DNA binding and cytotoxic activity of 1,4-bis[(aminoalkil)amino]benzo [g]phthalazine-5,10-diones

As part of a program aimed at exploring the effect of the introduction of heteroatoms into the anthracene-9,lO-dione chromophore, we have synthesized novel 1,4-bis[(aminoalkyl)aminolbenzo[ glphthalazine-5,l0-diones (BPDs) 1 which are related to the antitumor agents ametantrone and mitoxantrone. Derivatives 1 were prepared by chromic acid oxidation of acylated benzo[glphthalazines 5 followed by acid hydrolysis or by silylation-amination of 5,lOdihydroxybenzo[ glphthalazine-1,4-dione( 8). The l-[(aminoalkyl)aminol-4-amincoo ngeners 2 were isolated in low yields as byproducts from the oxidation of 5. Against a panel of human tumor cell lines, the benzo~lphthalazine-5,l0-dione1s and 2 exhibited cytotoxic activity comparable or even superior to that of mitoxantrone. In compounds 1, structure-activity relationships different than those operative in the carbocyclic series appeared to emerge. DNAbinding studies with the ametantrone-like compound IC and its single-armed congener 2c indicated that the introduction of a 2,3-diaza subunit into the anthracene-9,lO-dione chromophore reduces the affinity of the drug for DNA in comparison with ametantrone. On the other hand, the number of side-chain groups does not affect binding to a great extent. These findings seem to suggest mechanisms of cell death other than those induced by simple interaction of the 1,4-BPDs 1 and 2 with DNA

A novel 7-modified camptothecin analog overcomes breast cancer resistance protein-associated resistance in a mitoxantrone-selected colon carcinoma cell line

We selected a mitoxantrone-resistant HT29 colon carcinoma cell line (HT29/MIT) that exhibited a very high degree of resistance to the selecting agent and marked resistance to topotecan and SN38, but limited resistance to doxorubicin. The development of drug resistance was independent of expression of P-glycoprotein or multidrug resistance-associated protein but was associated with high up-regulation of the breast carcinoma resistance protein (BCRP) as shown by Western blot analysis. BCRP overexpression was associated with a reduced intracellular accumulation of topotecan, a known substrate for BCRP. Conversely, a lipophilic 7-modified camptothecin analogue (ST1481) displayed a complete lack of cross-resistance in HT29/MIT cells, suggesting that the drug was not a substrate for BCRP because no defects in intracellular accumulation were found. This conclusion is consistent with the antitumor efficacy of ST1481 against a BCRP-expressing tumor. These results may have therapeutic implications because the antitumor efficacy of ST1481 is in part related to a good bioavailability after oral administration, and the drug is currently under Phase I clinical evaluation

A novel 9-aza-anthrapyrazole effective against human prostatic carcinoma xenografts

Objectives: Systematic investigation of a novel series of intercalating agents, 9-aza-anthrapyrazoles, has led to the identification of a promising analogue, BBR 3438. This study describes the antitumour efficacy of the novel compound in human prostate carcinoma models and the molecular/cellular basis of its activity. Methods and Results: The novel 9-aza-anthrapyrazole BBR 3438 was significantly more effective than doxorubicin and losoxantrone (DuP-941) in two of the three tested prostate carcinoma models. The superior activity was more evident in PC3 tumour, since BBR 3438 produced an appreciable rate of complete tumour regressions. Under these conditions, the drug-induced antiproliferative activity paralleled delayed apoptosis. Tumour response to in vivo drug treatment was associated with an early down-regulation of Bcl-2, which was somewhat more marked for the aza compound. In fact, the 9-aza-anthrapyrazole induced DNA cleavage in vitro with isolated DNA topoisomerase II (isoform \ub7) and DNA strand breaks in prostatic carcinoma cells. Although the molecular effects of losoxantrone and the 9-aza analogue on the enzyme target were comparable, the cytotoxic effects of BBR 3438 could be enhanced by long-term exposure as a consequence of favourable cellular accumulation and prominent DNA-binding affinity. In addition, a lower reduction potential of the 9-aza-anthrapyrazole in comparison with classical anthrapyrazoles suggests an increased ability of the drug to induce oxidative stress following free radical production, which may be a contributing factor in determining the long-term response (i.e. delayed cell death) to genotoxic damage. Conclusions: BBR 3438 exhibited a unique profile of preclinical activity with a superior efficacy against prostatic carcinoma models compared to reference compounds (doxorubicin and losoxantrone). The antitumour efficacy of BBR 3438 against prostatic carcinoma could be the result of a combination of favourable events, including enhanced intracellular accumulation and an increased DNA-binding affinity favouring the accumulation of multiple sublethal or lethal damage. In spite of its enhanced cytotoxic potency, the 9-aza compound was better tolerated in vivo than losoxantrone, thus improving the therapeutic index. The preclinical profile of efficacy against prostatic carcinoma, a tumour resistant to conventional antitumour drugs, makes the novel 9-aza-anthrapyrazole BBR 3438 a promising candidate for clinical evaluation

A novel 9-aza-anthrapyrazole effective against human prostatic carcinoma xenografts.

Systematic investigation of a novel series of intercalating agents, 9-aza-anthrapyrazoles, has led to the identification of a promising analogue, BBR 3438. This study describes the antitumour efficacy of the novel compound in human prostate carcinoma models and the molecular/cellular basis of its activity.The novel 9-aza-anthrapyrazole BBR 3438 was significantly more effective than doxorubicin and losoxantrone (DuP-941) in two of the three tested prostate carcinoma models. The superior activity was more evident in PC3 tumour, since BBR 3438 produced an appreciable rate of complete tumour regressions. Under these conditions, the drug-induced antiproliferative activity paralleled delayed apoptosis. Tumour response to in vivo drug treatment was associated with an early down-regulation of Bcl-2, which was somewhat more marked for the aza compound. In fact, the 9-aza-anthrapyrazole induced DNA cleavage in vitro with isolated DNA topoisomerase II (isoform alpha) and DNA strand breaks in prostatic carcinoma cells. Although the molecular effects of losoxantrone and the 9-aza analogue on the enzyme target were comparable, the cytotoxic effects of BBR 3438 could be enhanced by long-term exposure as a consequence of favourable cellular accumulation and prominent DNA-binding affinity. In addition, a lower reduction potential of the 9-aza-anthrapyrazole in comparison with classical anthrapyrazoles suggests an increased ability of the drug to induce oxidative stress following free radical production, which may be a contributing factor in determining the long-term response (i.e. delayed cell death) to genotoxic damage.BBR 3438 exhibited a unique profile of preclinical activity with a superior efficacy against prostatic carcinoma models compared to reference compounds (doxorubicin and losoxantrone). The antitumour efficacy of BBR 3438 against prostatic carcinoma could be the result of a combination of favourable events, including enhanced intracellular accumulation and an increased DNA-binding affinity favouring the accumulation of multiple sublethal or lethal damage. In spite of its enhanced cytotoxic potency, the 9-aza compound was better tolerated in vivo than losoxantrone, thus improving the therapeutic index. The preclinical profile of efficacy against prostatic carcinoma, a tumour resistant to conventional antitumour drugs, makes the novel 9-aza-anthrapyrazole BBR 3438 a promising candidate for clinical evaluation