Understanding the metabolic basis of drug resistance: Therapeutic induction of the Warburg effect kills cancer cells

Ubaldo E. Martinez-Outschoorn, Zhao Lin, Ying Hui Ko, Allison F. Goldberg, Neal Flomenberg, Chenguang Wang, Stephanos Pavlides, Richard G. Pestell, Anthony Howell, Federica Sotgia, Michael P. Lisanti

    Research output: Contribution to journalArticlepeer-review

    Abstract

    Previously, we identified a form of epithelial-stromal metabolic coupling, in which cancer cells induce aerobic glycolysis in adjacent stromal fibroblasts, via oxidative stress, driving autophagy and mitophagy. In turn, these cancer-associated fibroblasts provide recycled nutrients to epithelial cancer cells, "fueling" oxidative mitochondrial metabolism and anabolic growth. An additional consequence is that these glycolytic fibroblasts protect cancer cells against apoptosis, by providing a steady nutrient stream to mitochondria in cancer cells. Here, we investigated whether these interactions might be the basis of tamoxifen-resistance in ER(+) breast cancer cells. We show that MCF7 cells alone are Tamoxifen-sensitive, but become resistant when co-cultured with hTE RT-immortalized human fibroblasts. Next, we searched for a drug combination (Tamoxifen + Dasatinib) that could over-come fibroblast-induced Tamoxifen-resistance. Importantly, we show that this drug combination acutely induces the Warburg effect (aerobic glycolysis) in MCF7 cancer cells, abruptly cutting off their ability to use their fuel supply, effectively killing these cancer cells. Thus, we believe that the Warburg effect in tumor cells is not the "root cause" of cancer, but rather it may provide the necessary clues to preventing chemoresistance in cancer cells. Finally, we observed that this drug combination (Tamoxifen + Dasatinib) also had a generalized anti-oxidant effect, on both co-cultured fibroblasts and cancer cells alike, potentially reducing tumor-stroma co-evolution. Our results are consistent with the idea that chemo-resistance may be both a metabolic and stromal phenomenon that can be overcome by targeting mitochondrial function in epithelial cancer cells. Thus, simultaneously targeting both (1) the tumor stroma and (2) the epithelial cancer cells, with combination therapies, may be the most successful approach to anti-cancer therapy. This general strategy of combination therapy for overcoming drug resistance could be applicable to many different types of cancer. © 2011 Landes Bioscience.
    Original languageEnglish
    Pages (from-to)2521-2528
    Number of pages7
    JournalCell Cycle
    Volume10
    Issue number15
    DOIs
    Publication statusPublished - 1 Aug 2011

    Keywords

    • Aerobic glycolysis
    • Cancer-associated fibroblasts
    • Dasatinib
    • Drug resistance
    • Glucose uptake
    • Microenvironment
    • Mitochondrial oxidative phosphorylation
    • Oxidative stress
    • Reactive oxygen species (ROD)
    • Tamoxifen
    • Tumor stroma
    • Warburg effect

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