Hypoxia is a common feature of solid tumors and is associated with a poor response to anticancer therapies. Hypoxia also induces metabolic changes, such as a switch to glycolysis. This glycolytic swit Show more
Hypoxia is a common feature of solid tumors and is associated with a poor response to anticancer therapies. Hypoxia also induces metabolic changes, such as a switch to glycolysis. This glycolytic switch causes acidification of the tumor microenvironment (TME), thereby attenuating the anticancer immune response. A promising therapeutic strategy to reduce hypoxia and thereby sensitize tumors to irradiation and/or antitumor immune responses is pharmacological inhibition of oxidative phosphorylation (OXPHOS). Several OXPHOS inhibitors (OXPHOSi) have been tested in clinical trials. However, moderate responses and/or substantial toxicity have hampered clinical implementation. OXPHOSi tested in clinical trials inhibit the oxidative metabolism in tumor cells as well as healthy cells. Therefore, new strategies are needed to improve the efficacy of OXPHOSi while minimizing side effects. To enhance the therapeutic window, available OXPHOSi have, for instance, been conjugated to triphenylphosphonium to preferentially target the mitochondria of cancer cells, resulting in increased tumor uptake compared with healthy cells, as cancer cells have a higher mitochondrial membrane potential. However, OXPHOS inhibition also induces reactive oxygen species and subsequent antioxidant responses, which may influence the efficacy of therapies, such as platinum-based chemotherapy and radiotherapy. Here, we review the limitations of the clinically tested OXPHOSi metformin, atovaquone, tamoxifen, BAY 87-2243, and IACS-010759 and the potential of mitochondria-targeted OXPHOSi and their influence on reactive oxygen species production. Furthermore, the effect of the mitochondria-targeting moiety triphenylphosphonium on mitochondria is discussed as it affects mitochondrial bioenergetics. Show less
Background Hypoxia is a common feature of many solid tumors and causes radiotherapy and immunotherapy resistance. Pharmacological inhibition of oxidative phosphorylation (OXPHOS) has emerged as a the Show more
Background Hypoxia is a common feature of many solid tumors and causes radiotherapy and immunotherapy resistance. Pharmacological inhibition of oxidative phosphorylation (OXPHOS) has emerged as a therapeutic strategy to reduce hypoxia. However, the OXPHOS inhibitors tested in clinical trials caused only moderate responses in hypoxia alleviation or trials were terminated due to dose-limiting toxicities. To improve the therapeutic benefit, FDA approved OXPHOS inhibitors (e.g. atovaquone) were conjugated to triphenylphosphonium (TPP + ) to preferentially target cancer cell’s mitochondria. In this study, we evaluated the hypoxia reducing effects of several mitochondria-targeted OXPHOS inhibitors and compared them to non-mitochondria-targeted OXPHOS inhibitors using newly developed spheroid models for diffusion-limited hypoxia. Methods B16OVA murine melanoma cells and MC38 murine colon cancer cells expressing a HIF-Responsive Element (HRE)-induced Green Fluorescent Protein (GFP) with an oxygen-dependent degradation domain (HRE-eGFP-ODD) were generated to assess diffusion-limited hypoxia dynamics in spheroids. Spheroids were treated with IACS-010759, atovaquone, metformin, tamoxifen or with mitochondria-targeted atovaquone (Mito-ATO), PEGylated mitochondria-targeted atovaquone (Mito-PEG-ATO) or mitochondria-targeted tamoxifen (MitoTam). Hypoxia dynamics were followed and quantified over time using the IncuCyte Zoom Live Cell-Imaging system. Results Hypoxic cores developed in B16OVA.HRE and MC38.HRE spheroids within 24 h hours after seeding. Treatment with IACS-010759, metformin, atovaquone, Mito-PEG-ATO and MitoTam showed a dose-dependent reduction of hypoxia in both B16OVA.HRE and MC38.HRE spheroids. Mito-ATO only alleviated hypoxia in MC38.HRE spheroids while tamoxifen was not able to reduce hypoxia in any of the spheroid models. The mitochondria-targeted OXPHOS inhibitors demonstrated stronger anti-hypoxic effects compared to the non-mito-targeted OXPHOS inhibitors. Conclusions We successfully developed a high-throughput spheroid model in which hypoxia dynamics can be quantified over time. Using this model, we showed that the mitochondria-targeted OXPHOS inhibitors Mito-ATO, Mito-PEG-ATO and MitoTam reduce hypoxia in tumor cells in a dose-dependent manner, potentially sensitizing hypoxic tumor cells for radiotherapy. Supplementary Information The online version contains supplementary material available at 10.1186/s40170-024-00342-6. Show less