Mitochondrial stress controls the radiosensitivity of the oxygen effect: Implications for radiotherapy

Richardson, Richard B.; Harper, Mary‐Ellen

doi:10.18632/oncotarget.7412

Cited by 74 publications

(66 citation statements)

References 68 publications

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“…Interestingly, Lall et al (61) described an HIF1-dependent metabolic adaptation at 5% O 2 to the adaptive response that involves the induction of a glycolytic program at later time points (12 h). We believe that this adaptation may be attributed to changes in the radiation oxygen effect, in which greater cell death is observed at higher O 2 tension, as previously described by Richardson and Harper (3). Our system differs from that of Lall et al .…”

Section: Discussionsupporting

confidence: 73%

“…Additionaly, although failing to reach statistical significance, OPA1-KO cells also generally had less γH2AX following IR. This last finding may be related to the oxygen effect, which posits that cells that are less reliant on mitochondria for ATP production are radioresistant because there is less secondary IR damage due in part to lowered induction of mitochondrial ROS (3). Taken together, our data suggest that functional mitochondrial remodeling is required for certain aspects of the biologic responses to IR.…”

Section: Resultsmentioning

confidence: 99%

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Mitochondrial adaptation in human mesenchymal stem cells following ionizing radiation

et al. 2019

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Mitochondria are highly dynamic organelles that respond rapidly to a number of stressors to regulate energy transduction, cell death signaling, and reactive oxygen species generation. We hypothesized that mitochondrial remodeling, comprising both structural and functional alterations, following ionizing radiation (IR) may underlie some of the tenets of radiobiology. Mesenchymal stem cells (MSCs) are precursors of bone marrow stroma and are altered in acute myeloid leukemia and by radiation and chemotherapy. Here, we report on changes in mitochondrial remodeling in human MSCs following X‐ray IR. Mitochondrial function was significantly increased in MSCs 4 h after IR as measured by mitochondrial oxygen consumption. Consistent with this elevated functional effect, electron transport chain supercomplexes were also increased in irradiated samples. In addition, mitochondria were significantly, albeit modestly, elongated, as measured by high‐throughput automated confocal imaging coupled with automated mitochondrial morphometric analyses. We also demonstrate in fibroblasts that mitochondrial remodeling is required for the adaptation of cells to IR. To determine novel mechanisms involved in mitochondrial remodeling, we performed quantitative proteomics on isolated mitochondria from cells following IR. Label‐free quantitative mitochondrial proteomics revealed notable changes in proteins in irradiated samples and identified prosaposin, and potentially its daughter protein saposin‐B, as a potential candidate for regulating mitochondrial function following IR. Whereas research into the biologic effects of cellular irradiation has long focused on nuclear DNA effects, our experimental work, along with that of others, is finding that mitochondrial effects may have broader implications in the field of stress adaptation and cell death in cancer (including leukemia) and other disease states.—Patten, D. A., Ouellet, M., Allan, D. S., Germain, M., Baird, S. D., Harper, M.‐E., Richardson, R. B. Mitochondrial adaptation in human mesenchymal stem cells following ionizing radiation. FASEB J. 33, 9263–9278 (2019). http://www.fasebj.org

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Section: Discussionsupporting

confidence: 73%

Section: Resultsmentioning

confidence: 99%

Mitochondrial adaptation in human mesenchymal stem cells following ionizing radiation

et al. 2019

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“…All these mechanisms are consistent with data implying that the mitochondrial location of anti-oxidative enzymes is more cell protective than the cytosolic one, in particular in case of manganese superoxide dismutase (MnSOD) which dismutates superoxide to the less toxic hydrogen peroxide (H 2 O 2 ) [65]. According to Richardson and Harper [66], the mtROS and mtRNS produced through IR could fully account for the majority of nDNA damage and most of the observed RT effects.…”

Section: The Physics and Biology Of Radiotherapy Against Cancersupporting

confidence: 82%

“…Ionization clusters are also predicted to occur within mitochondria [64], which seems to have much higher relevance for RT outcomes than realized in the past [65,66]. Mitochondrial DNA (mtDNA) is more vulnerable to ionizing radiation than nDNA, due to a lack of histone protection and less efficient repair mechanisms [67,68].…”

Section: The Physics and Biology Of Radiotherapy Against Cancermentioning

confidence: 99%

“…Recently, Richardson and Harper [66] proposed a 2-component model for the oxygen effect. In their explanation, as oxygen levels rise, damage from increasing levels of mtROS constitutes the main component which is more and more counteracted by more efficient DNA repair due to increasing ATP production.…”

Section: Combining Ketogenic Metabolic Therapy With Radiotherapy To Ementioning

confidence: 99%

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Fasting, Fats, and Physics: Combining Ketogenic and Radiation Therapy against Cancer

Klement¹

2017

Complement Med Res

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Radiotherapy (RT) is a mainstay in the treatment of solid tumors and works by physicochemical reactions inducing oxidative stress in cells. Because in practice the efficacy of RT is limited by its toxicity to normal tissues, any strategy that selectively increases the radiosensitivity of tumor cells or boosts the radioresistance of normal cells is a valuable adjunct to RT. In this review, I summarize preclinical and clinical data supporting the hypothesis that ketogenic therapy through fasting and/or ketogenic diets can be utilized as such an adjunct in order to improve the outcome after RT, in terms of both higher tumor control and lower normal-tissue complication probability. The first effect relates to the metabolic shift from glycolysis towards mitochondrial metabolism, which selectively increases reactive oxygen species (ROS) production and impairs adenoside triphosphate (ATP) production in tumor cells. The second effect is based on the differential stress resistance phenomenon describing the reprogramming of normal cells, but not tumor cells, from proliferation towards maintenance and stress resistance when glucose and growth factor levels are decreased and ketone body levels are elevated. Underlying both effects are metabolic differences between normal and tumor cells. Ketogenic therapy is a non-toxic and cost-effective complementary treatment option that exploits these differences and deserves further clinical investigation.

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Ion Transport and Radioresistance

Roth¹,

Huber²

2020

Reviews of Physiology, Biochemistry and Pharmacology

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Mitochondrial stress controls the radiosensitivity of the oxygen effect: Implications for radiotherapy

Cited by 74 publications

References 68 publications

Mitochondrial adaptation in human mesenchymal stem cells following ionizing radiation

Mitochondrial adaptation in human mesenchymal stem cells following ionizing radiation

Fasting, Fats, and Physics: Combining Ketogenic and Radiation Therapy against Cancer

Ion Transport and Radioresistance

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