Abstract B203: Mitochondria-targeted superoxide spin-traps for treatment of cancers with high oxidative stress

Many human malignancies such as prostate cancer (CaP) and primary brain tumor (GBM) exhibit high oxidative stress. Developing a successful therapeutic drug to treat advanced metastatic CaP and GBM is a major unmet medical need. It has been demonstrated that in certain chemo- and/or radiation resistant cancer cells with high oxidative stress, cells depend on reactive oxygen species (ROS) for survival and proliferation. Therefore, reducing ROS can be a successful strategy for developing chemotherapeutic drugs for use against chemo- and/or radiation-resistant tumors. The mitochondria are a major source of superoxide and other ROS. We focused on targeting spin-trapping nitroxide analogs at the mitochondrial interstitial space with appropriate linker length in order to remove the superoxide in order to reduce the cellular ROS levels without interfering with the mitochondrial electron transport chain. Our lead compound in this new class of drugs is Mito-tempol-C10. The drug successfully blocked ROS production in human CaP and GBM cell lines as determined by DCF dye oxidation assay. It exhibited marked growth inhibitory effect against androgen-dependent as well as androgen-independent cultured human CaP cells (IC50 < 1 µM) and similar growth inhibitory activity against several human GBM cells lines as well as cultured primary brain tumor stem cells as determined by DNA fluorescence measurement assay. Preliminary pharmacokinetic (PK) study show that the drug has serum half-life of approximately 45 minutes, but is retained by the tumor and other animal tissue for more than 24 hours. The drug is tolerated by ICR white mice, nude mice and NOD-SCID mice at a dose of 15 mg/kg i.p. given once every week for four weeks without any overt systemic toxicity. Preliminary efficacy study at this treatment condition showed marked effect on the growth of intracranially implanted, radiation-resistant U-87 MG human GBM cells in NOD-SCID mice and a small, but significant effect on the growth of androgen-independent PC-3 human prostate cancer cell xenografts growing on the flanks of nude mice. These results confirm that mitochondria-targeted spin-traps that reduce cellular ROS can be therapeutically effective in treatment of advanced, hard-to-treat human tumors with high oxidative stress. Citation Information: Mol Cancer Ther 2009;8(12 Suppl):B203.