Beerkens Anne P M, Boreel Daan F, Nathan James A, Neuzil Jiri, Cheng Gang, Kalyanaraman Balaraman, Hardy Micael, Adema Gosse J, Heskamp Sandra, Span Paul N, Bussink Johan
Radiotherapy & OncoImmunology Laboratory, Department of Radiation Oncology, Radboud University Medical Center, Nijmegen, 6525GA, The Netherlands.
Department of Medical Imaging, Radboud University Medical Center, Nijmegen, 6525GA, The Netherlands.
Cancer Metab. 2024 May 3;12(1):13. doi: 10.1186/s40170-024-00342-6.
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.
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.
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.
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.
缺氧是许多实体瘤的常见特征,并导致放疗和免疫治疗耐药。氧化磷酸化(OXPHOS)的药理学抑制已成为一种减轻缺氧的治疗策略。然而,在临床试验中测试的OXPHOS抑制剂在缓解缺氧方面仅产生中度反应,或者由于剂量限制毒性而终止试验。为了提高治疗效果,美国食品药品监督管理局(FDA)批准的OXPHOS抑制剂(如阿托伐醌)与三苯基膦(TPP)偶联,以优先靶向癌细胞的线粒体。在本研究中,我们使用新开发的用于模拟扩散受限性缺氧的球体模型,评估了几种线粒体靶向的OXPHOS抑制剂的缺氧减轻效果,并将它们与非线粒体靶向的OXPHOS抑制剂进行了比较。
构建表达缺氧诱导因子反应元件(HRE)诱导的绿色荧光蛋白(GFP)且带有氧依赖性降解结构域(HRE-eGFP-ODD)的B16OVA小鼠黑色素瘤细胞和MC38小鼠结肠癌细胞,以评估球体中扩散受限性缺氧动态。用IACS-010759、阿托伐醌、二甲双胍、他莫昔芬或线粒体靶向的阿托伐醌(Mito-ATO)、聚乙二醇化线粒体靶向的阿托伐醌(Mito-PEG-ATO)或线粒体靶向的他莫昔芬(MitoTam)处理球体。使用IncuCyte Zoom活细胞成像系统随时间跟踪并量化缺氧动态。
接种后24小时内,B16OVA.HRE和MC38.HRE球体中出现缺氧核心。用IACS-010759、二甲双胍、阿托伐醌、Mito-PEG-ATO和MitoTam处理后,B16OVA.HRE和MC38.HRE球体中的缺氧均呈剂量依赖性降低。Mito-ATO仅减轻了MC38.HRE球体中的缺氧,而他莫昔芬在任何球体模型中均无法降低缺氧。与非线粒体靶向的OXPHOS抑制剂相比,线粒体靶向的OXPHOS抑制剂表现出更强的抗缺氧作用。
我们成功开发了一种高通量球体模型,其中缺氧动态可随时间进行量化。使用该模型,我们表明线粒体靶向的OXPHOS抑制剂Mito-ATO、Mito-PEG-ATO和MitoTam以剂量依赖性方式降低肿瘤细胞中的缺氧,可能使缺氧肿瘤细胞对放疗敏感。
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