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

It has been more than 60 years since the discovery of the oxygen effect that empirically demonstrates the direct association between cell radiosensitivity and oxygen tension, important parameters in radiotherapy. Yet the mechanisms underlying this principal tenet of radiobiology are poorly understoo...

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Bibliographic Details
Published in:Oncotarget 2016-04, Vol.7 (16), p.21469-21483
Main Authors: Richardson, Richard B, Harper, Mary-Ellen
Format: Article
Language:English
Subjects:
Adenosine Triphosphate - metabolism
Algorithms
Cell Hypoxia
Electron Transport - radiation effects
Eukaryotic Cells - metabolism
Eukaryotic Cells - radiation effects
Humans
Hypoxia
Mitochondria - metabolism
Mitochondria - radiation effects
Mitochondrial Membranes - metabolism
Mitochondrial Membranes - radiation effects
Models, Biological
Neoplasms - metabolism
Neoplasms - radiotherapy
Oxidative Stress
Oxygen - metabolism
Radiation Tolerance
Radiation, Ionizing
Reactive Oxygen Species - metabolism
Research Paper
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Summary:It has been more than 60 years since the discovery of the oxygen effect that empirically demonstrates the direct association between cell radiosensitivity and oxygen tension, important parameters in radiotherapy. Yet the mechanisms underlying this principal tenet of radiobiology are poorly understood. Better understanding of the oxygen effect may explain difficulty in eliminating hypoxic tumor cells, a major cause of regrowth after therapy. Our analysis utilizes the Howard-Flanders and Alper formula, which describes the relationship of radiosensitivity with oxygen tension. Here, we assign and qualitatively assess the relative contributions of two important mechanisms. The first mechanism involves the emission of reactive oxygen species from the mitochondrial electron transport chain, which increases with oxygen tension. The second mechanism is related to an energy and repair deficit, which increases with hypoxia. Following a radiation exposure, the uncoupling of the oxidative phosphorylation system (proton leak) in mitochondria lowers the emission of reactive oxygen species which has implications for fractionated radiotherapy, particularly of hypoxic tumors. Our analysis shows that, in oxygenated tumor and normal cells, mitochondria, rather than the nucleus, are the primary loci of radiotherapy effects, especially for low linear energy transfer radiation. Therefore, the oxygen effect can be explained by radiation-induced effects in mitochondria that generate reactive oxygen species, which in turn indirectly target nuclear DNA.
ISSN:1949-2553
1949-2553
DOI:10.18632/oncotarget.7412