Antiangiogenic agents increase breast cancer stem cells via the generation of tumor hypoxia
Antiangiogenic therapy has been thought to hold significant potential for the treatment of cancer. However, the efficacy of such treatments, especially in breast cancer patients, has been called into question, as recent clinical trials reveal only limited effectiveness of antiangiogenic agents in prolonging patient survival. New research using preclinical models further suggests that antiangiogenic agents actually increase invasive and metastatic properties of breast cancer cells. We demonstrate that by generating intratumoral hypoxia in human breast cancer xenografts, the antiangiogenic agents sunitinib and bevacizumab increase the population of cancer stem cells. In vitro studies revealed that hypoxia-driven stem/progenitor cell enrichment is primarily mediated by hypoxia-inducible factor 1α. We further show that the Akt/β-catenin cancer stem cell regulatory pathway is activated in breast cancer cells under hypoxic conditions in vitro and in sunitinib-treated mouse xenografts. These studies demonstrate that hypoxia-driven cancer stem cell stimulation limits the effectiveness of antiangiogenic agents, and suggest that to improve patient outcome, these agents might have to be combined with cancer stem cell-targeting drugs.antiangiogenesis | HIF-1α
Although breast cancer stem cells (BCSCs) display plasticity transitioning between quiescent mesenchymal-like (M) and proliferative epithelial-like (E) states, how this plasticity is regulated by metabolic or oxidative stress remains poorly understood. Here, we show that M- and E-BCSCs rely on distinct metabolic pathways and display markedly different sensitivities to inhibitors of glycolysis and redox metabolism. Metabolic or oxidative stress generated by 2DG, HO, or hypoxia promotes the transition of ROS M-BCSCs to a ROS E-state. This transition is reversed by N-acetylcysteine and mediated by activation of the AMPK-HIF1α axis. Moreover, E-BCSCs exhibit robust NRF2-mediated antioxidant responses, rendering them vulnerable to ROS-induced differentiation and cytotoxicity following suppression of NRF2 or downstream thioredoxin (TXN) and glutathione (GSH) antioxidant pathways. Co-inhibition of glycolysis and TXN and GSH pathways suppresses tumor growth, tumor-initiating potential, and metastasis by eliminating both M- and E-BCSCs. Exploiting metabolic vulnerabilities of distinct BCSC states provides a novel therapeutic approach targeting this critical tumor cell population.
Cancer stem cells (CSCs) drive tumor growth as well as mediating metastasis and treatment resistance. In breast cancer (BC), CSCs exist in alternative mesenchymal (EMT) and epithelial (MET)-like states characterized by the expression of CD44+CD24- and aldehyde dehydrogenase (ALDH) respectively. BCSCs display phenotypic plasticity allowing them to transition between EMT and MET states in a process regulated by the tumor microenvironment. The plasticity of BCSCs suggests that it may be necessary to simultaneously target alternative BCSC states to achieve maximal eradication of these cell populations. In order to develop strategies to target these BCSC states, we measured the cellular bioenergetics of EMT and MET BCSCs compared to non-stem bulk tumor cells as well as the sensitivity of distinct BCSC states to inhibitors of glucose and hydroperoxide metabolism. Using a Seahorse XCF instrument, we found that both MET and EMT BCSCs display higher glycolytic potential than bulk tumor cells. Increased glycolysis correlated with elevated expression of hexokinase 2, a rate limiting glycolytic enzyme in cancer. Interestingly, the glycolytic inhibitor, 2-deoxyglucose (2DG), specifically inhibited EMT BCSCs in a dose dependent fashion; however, MET BCSCs were completely refractory to this treatment. Proteomic and RNA-seq analyses revealed that two important arms of hydroperoxide metabolism, the thioredoxin- and glutathione-mediated antioxidant pathways, were robustly up-regulated in MET BCSCs, suggesting that these cells are rendered resistant to glycolysis inhibition via an enhanced anti-oxidant defense. Pharmacologic inhibition of this antioxidant defense by Auranofin (an inhibitor of thioredoxin reductase) is sufficient to deplete MET BCSCs in SUM149 BC cells which were rescued by NAC, a ROS scavenger, or catalase, a specific enzyme capable of degrading intracellular H2O2. Finally, administration of 2DG together with Auranofin and BSO (an inhibitor of glutathione metabolism) synergistically suppressed tumor growth in a patient derived xenograft (PDX) model by suppressing both EMT and MET BCSCs. This study suggests that utilizing metabolic inhibition to simultaneously target EMT and MET BCSCs is a viable therapeutic strategy with important clinical implications. Citation Format: Ming Luo, April Davis, Sean McDermott, Evelyn Jiagge, Michael Brooks, Elizabeth Gheordunescu, Tahra Luther, Shawn G. Clouthier, Sarah Conley, Douglas R. Spitz, Max S. Wicha. Targeting EMT and MET breast cancer stem cell states through simultaneous inhibition of glycolytic and antioxidant pathways. [abstract]. In: Proceedings of the 106th Annual Meeting of the American Association for Cancer Research; 2015 Apr 18-22; Philadelphia, PA. Philadelphia (PA): AACR; Cancer Res 2015;75(15 Suppl):Abstract nr 2311. doi:10.1158/1538-7445.AM2015-2311
Cancer stem cells (CSCs) exhibit lower intracellular reactive oxygen species (ROS) levels than non-CSCs, which may be due to the increased expression of free radical scavenging systems. Exogenous agents may be useful to increase ROS and selectively kill CSCs by oxidative stress. Here we tested a combination approach to increase ROS as an effective strategy to eradicate breast CSCs and metastases. Buthionine sulfoximine (BSO) and auranofin (AU) were used to deplete glutathione (GSH) and inhibit thioredoxin reductase (TR), respectively, while mitochondrial-targeted decyltriphenylphosphonium (dTPP) was used to elevate ROS levels. In vitro clonogenicity assays using SUM159 cells showed that treatment with dTPP alone resulted in <30% survival, while AU+BSO, BSO+dTPP and AU+BSO+dTPP all resulted in <1% survival. These effects were reversible with N-acetylcysteine pre-treatment. The Aldefluor+ (CSC) population was also measured following drug treatment in vitro. dTPP or AU treatment alone resulted in <50% of CSCs remaining, while BSO+AU or BSO+dTPP resulted in <25% of CSCs remaining, and treatment with all three compounds resulted in <1% of CSCs remaining. In a preclinical model of breast cancer metastasis, long-term adjuvant treatment with each individual compound significantly reduced the amount of metastases and increased survival, with dTPP treatment alone resulting in 100% survival rate. Interestingly, the combination of all three compounds resulted in increased metastases compared to the single agents. This may potentially be a stress-induced effect resulting from drug toxicity. In conclusion, the approach of increasing ROS in breast cancer cells may be an effective way to target CSCs and useful for adjuvant therapy to reduce metastases in patients. Citation Format: Sarah J. Conley, Trenton Baker, Rebecca Theisen, Elizabeth Gheordunescu, Yueming Zhu, Nukhet Aykin-Burns, Melissa Fath, Douglas Spitz, Max Wicha. Targeting breast cancer stem cells via oxidative stress with inhibitors of hydroperoxide metabolism and decyl-triphenylphosphonium. [abstract]. In: Proceedings of the 104th Annual Meeting of the American Association for Cancer Research; 2013 Apr 6-10; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2013;73(8 Suppl):Abstract nr 3729. doi:10.1158/1538-7445.AM2013-3729
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