Antitumor activity of S 16020-2 in two orthotopic models of lung cancer.

S 16020-2, a new olivacine derivative selected on the basis of its cytotoxicity in vitro and antitumor activity in vivo, was evaluated against the human A549 and the murine Lewis lung tumor models implanted s.c. and i.v. Against Lewis lung carcinoma implanted s.c., S 16020-2 was found to be curative, with an activity and therapeutic index (Ti = 4) similar to that of cyclophosphamide. S 16020-2 administered weekly demonstrated a high therapeutic efficacy against A549 non-small cell lung carcinoma implanted s.c. in nude mice and induced tumor regression at 80 mg/kg. When A549 tumor cells were injected i.v. in SCID mice, experimental metastases rapidly developed and the progressive invasion of the lung tissue by tumor preceded the death of animals. In this model, S 16020-2 administered at 40 mg/kg i.v. following an early (days 8, 18 and 28) or delayed (days 20, 30 and 40) treatment schedule prolonged the survival of tumor-bearing mice with T/C values of 150 and 145%, respectively. Against the i.v. Lewis lung carcinoma, S 16020-2 was also highly active since when administered at 60 mg/kg on days 5, 9 and 13 it totally inhibited tumor growth and cured up to 89% of mice. When administered on days 11, 15 and 19 to animals with established tumors, S 16020-2 was still active but not curative. In the presented studies, S 16020-2 antitumor activity was superior to that of adriamycin and comparable or superior to cyclophosphamide (used as reference compounds). Our results demonstrate the efficacy of S 16020-2 against these highly aggressive and chemoresistant tumor models.

Experimental antitumour activity of S 16020-2 in a panel of human tumours.

The antitumour activity of S 16020-2, a new topoisomerase II inhibitor, was evaluated in comparison with doxorubicin against 13 human tumours, including colon (HT-29, Colo320DM), breast (MCF7, MDAMB-231), ovary (SK-OV-3, A2780, NIH:OVCAR-3), non-small cell lung (NCI-H460, A549, Calu-6, NCI-H125) and small-cell lung (NCI-H69, SCLC6) cancers. S 16020-2 was administered weekly intravenous within a dose range of 20-90 mg/kg for 3 weeks. Antitumour responses were obtained in all the tumour types tested except in the two colon cancers. S 16020-2 produced significant growth delays in nine tumour models and induced regressions of all A549 lung tumours. The antitumour activity of S 16020-2 was superior to that of doxorubicin against the NCI-H460, A549, NCI-H69, SCLC6 and NIH:OVCAR-3 xenografts. These results demonstrate the broad spectrum of antitumour activity of S 16020-2 in a large panel of in vivo experimental models and confirm its interest as a potential agent in the treatment of malignant disease.

In vivo antitumor activity of S 16020-2, a new olivacine derivative.

The antitumor activity of S 16020-2, a new olivacine derivative, was investigated in vivo and compared with that of Adriamycin and elliptinium acetate in a panel of murine (P388 leukemia, M5076 sarcoma, Lewis lung carcinoma, and B16 melanoma) and human (NCI-H460 non-small-cell lung and MCF7 breast carcinomas) tumor models. S 16020-2 given i.v. was active against P388 leukemia implanted i.p., s.c., or intracerebrally. The therapeutic effect of an intermittent schedule (administration on days 1, 5, 9) was superior to that of single-dose treatment, allowing the i.v. administration of high total doses of S 16020-2 and resulting in the cure of 60% of mice in the i.p. P388 model. In this model, S 16020-2 was more active than elliptinium acetate and showed a better therapeutic index than Adriamycin: > or = 8 versus 2. A good therapeutic effect of S 16020-2 was also observed in three P388 leukemia sublines displaying the classic multidrug-resistance phenotype, namely, P388/VCR, P388/VCR-20, and P388/MDRC.04, the latter being totally insensitive to vincristine and Adriamycin. However, S 16020-2 was not active against the P388/ADR leukemia, a model highly resistant to adriamycin in vivo. S 16020-2 was both more active than Adriamycin and curative in the M5076 sarcoma and Lewis lung carcinoma implanted s.c. In the B16 melanoma implanted i.p. or s.c., S 16020-2 was less active than Adriamycin. Against the NCI-H460 human tumor xenograft, S 16020-2 demonstrated activity superior to that of Adriamycin (T/C = 20% versus 43% on day 21). Against the MCF7 breast cancer xenograft, S 16020-2 was active, but less so than Adriamycin (T/C = 23% versus 9% on day 21), whereas elliptinium acetate was marginally active (T/C = 49% on day 24). The hematological toxicity of S 16020-2 given to B6D2F1 mice at pharmacological dose appeared to be less severe than that of Adriamycin, particularly in bone-marrow stem cells. These results demonstrate that S 16020-2 is a highly active antitumor drug in various experimental tumor models and is markedly more efficient than elliptinium acetate. Because of its pharmacological profile, which is globally different from that of Adriamycin, S 16020-2 is considered an interesting candidate for clinical trials.

Studies of the potency of protein kinase inhibitors on ATPase activities.

Tyrosine as well as serine/threonine protein kinase inhibitors have potentially two sites of interaction with their targets: the protein-substrate binding site and the ATP binding site. The latter could be modelized by measuring the capacity of protein kinase inhibitors to inhibit ATPase activities. In order to do so, we assess a novel, highly sensitive HPLC method based on hydrophilic separation of [gamma-32P]ATP and [32P]Pi. The novel assay is presented. Furthermore, the potency of 13 protein kinase inhibitors was tested on two types of ATPase, namely: apyrase and partially purified liver mitochondria F1-ATPase. The method described for the assay of ATPase can be used with almost any type of enzyme catalyzing this activity. Only cibacron blue and suramin show interesting capacities in inhibiting these ATPase activities pointing out that several widely used protein kinase inhibitors are at least somewhat specific in that they do not inhibit these two ATPases.