Abstract 949: Identification of OXPHOS inhibitors which selectively kill tumors with specific metabolic vulnerabilities

Abstract

Abstract Inhibition of mitochondria complex I in tumors that are metabolically dependent on oxidative phosphorylation (OXPHOS) for their survival offers unique synthetic lethal opportunities. Examples of dependent contexts are AML and DLBCL, where OXPHOS is highly active and subpopulations of glioblastoma and neuroblastoma that possess genetic alterations which make them glycolysis deficient. In addition, several lines of evidence indicate that after treatment with chemo or targeted therapy, residual tumor cells become reliant on OXPHOS for their continued survival. In each of these cellular states, excessive dependence on OXPHOS renders tumor cells vulnerable to therapeutic targeting strategies that exploit this addiction. We have generated a series of novel, highly potent complex I inhibitors, which in vitro inhibit complex I with IC50 values < 10 nM. When tested in cultured cell systems (cell lines and spheroids) these compounds inhibit oxygen consumption, eliminate hypoxia, and strongly inhibit the proliferation cells grown in galactose medium with EC50 values between 1-10 nM. Lead compounds specifically induce apoptosis with EC50 values between 1-10 nM in OXPHOS dependent cancer models such as AML and DLBCL cell lines and in glycolysis deficient cancer cell lines. Of note, apoptosis is induced in primary AML cells but not in normal patient-derived CD34+ cells. These compounds are orally bioavailable with excellent pharmacokinetics properties in preclinical species making them appropriate tools for proof-of-concept studies in vivo. In agreement with data in cell culture, we have shown that daily oral treatment with as low as 5 -10 mg/kg of our OXPHOS inhibitors is well tolerated and induce strong regression of NB-1 (glycolysis-deficient cells) subcutaneous and intracranial xenografts. We have also demonstrated that sustained pharmacological inhibition of OXPHOS induce regression of DLBCL subcutaneous models and dramatically increase mice survival in an OCI-AML3 orthotopic xenograft model. In addition to synthetic lethality in monotherapy, we are exploring whether OXPHOS inhibition can overcome resistance to radiotherapy, chemotherapy and specific targeted therapies. Taken together, these data strongly support the notion that inhibiting OXPHOS in hypersensitive populations could be a novel, innovative therapeutic approach and justifies evaluation of OXPHOS inhibitors in a clinical setting. Citation Format: Joseph R. Marszalek, Madhavi Bandi, Jennifer Bardenhagen, Christopher Bristow, Christopher Carroll, Edward Chang, Ninping Feng, Barbara Czako, Jason Gay, Mary Geck Do, Jennifer Greer, Ryan M. Johnson, Marina Konopleva, Zhijun Kang, Gang Liu, Timothy Lofton, Timothy McAfoos, Marina Protopopova, Alessia Petrocchi, Florian Muller, Jay Theroff, Yuanqing Wu, Lynda Chin, Giulio Draetta, Philip Jones, Carlo Toniatti, Emilia Di Francesco. Identification of OXPHOS inhibitors which selectively kill tumors with specific metabolic vulnerabilities. [abstract]. In: Proceedings of the 105th Annual Meeting of the American Association for Cancer Research; 2014 Apr 5-9; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2014;74(19 Suppl):Abstract nr 949. doi:10.1158/1538-7445.AM2014-949