Fatty Acids Metabolism: The Bridge Between Ferroptosis and Ionizing Radiation

Yuan, Zhuhui; Liu, Tong; Wang, Hao; Xue, Lixiang; Wang, Junjie

doi:10.3389/fcell.2021.675617

Cited by 30 publications

(22 citation statements)

References 129 publications

(151 reference statements)

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“…As lipids are one of the major components for cellular and mitochondrial membranes, increased lipid oxidation by HG, RAD and RG supports the theory of cellular and mitochondrial membrane damage after stress [ 64 ]. Anabolic and catabolic changes in lipid and fatty acid metabolism also enhance the possibility of ferroptosis mediated cell death and mitochondrial membrane damage [ 65 , 66 ]. Glycosphingolipids are another vital component for cell and mitochondrial membranes [ 67 ], which are protected by T2E after stressed conditions.…”

Section: Discussionmentioning

confidence: 99%

MnTE-2-PyP protects fibroblast mitochondria from hyperglycemia and radiation exposure

et al. 2022

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Section: Discussionmentioning

confidence: 99%

MnTE-2-PyP protects fibroblast mitochondria from hyperglycemia and radiation exposure

et al. 2022

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“…This illustrates that fatty acids regulate each part of the cancer lifecycle and suggests that therapeutic intervention targeting lipid and fatty acid metabolism signaling pathways by MGF holds promise for colorectal cancer treatment ( Kadochi et al, 2017 ; Nakamura et al, 2018 ; Li et al, 2021 ). Fatty acid catabolism and anabolism pathway crosstalk are pivotal in cell fate decision during redox regulated ferroptosis cancer therapy and maybe strongly context dependent ( Hassannia et al, 2018 ; Kumar et al, 2021 ; Yuan et al, 2021 ). In clinical trials, MGF treatment was already found to improve metabolic health (diabetes, hyperlipidemia, insulin resistance) by optimization of mitochondrial bioenergetic pathways (fuel switching between fatty acid and carbohydrates) via sirtuin (SIRT) and PPAR (in)dependent metabolic mechanisms ( Guo et al, 2011 ; Niu et al, 2012 ; Apontes et al, 2014 ; Na et al, 2015 ; Singh et al, 2018b ; Li et al, 2018 ; Liu et al, 2018 ; Zhang et al, 2019 ).…”

Section: Discussionmentioning

confidence: 99%

Antiproliferative, Antiangiogenic, and Antimetastatic Therapy Response by Mangiferin in a Syngeneic Immunocompetent Colorectal Cancer Mouse Model Involves Changes in Mitochondrial Energy Metabolism

et al. 2021

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In spite of the current advances and achievements in cancer treatments, colorectal cancer (CRC) persists as one of the most prevalent and deadly tumor types in both men and women worldwide. Drug resistance, adverse side effects and high rate of angiogenesis, metastasis and tumor relapse remain one of the greatest challenges in long-term management of CRC and urges need for new leads of anticancer drugs. We demonstrate that CRC treatment with the phytopharmaceutical mangiferin (MGF), a glucosylxanthone present in Mango tree stem bark and leaves (Mangifera Indica L.), induces dose-dependent tumor regression and decreases lung metastasis in a syngeneic immunocompetent allograft mouse model of murine CT26 colon carcinoma, which increases overall survival of mice. Antimetastatic and antiangiogenic MGF effects could be further validated in a wound healing in vitro model in human HT29 cells and in a matrigel plug implant mouse model. Interestingly, transcriptome pathway enrichment analysis demonstrates that MGF inhibits tumor growth, metastasis and angiogenesis by multi-targeting of mitochondrial oxidoreductase and fatty acid β-oxidation metabolism, PPAR, SIRT, NFκB, Stat3, HIF, Wnt and GP6 signaling pathways. MGF effects on fatty acid β-oxidation metabolism and carnitine palmitoyltransferase 1 (CPT1) protein expression could be further confirmed in vitro in human HT29 colon cells. In conclusion, antitumor, antiangiogenic and antimetastatic effects of MGF treatment hold promise to reduce adverse toxicity and to mitigate therapeutic outcome of colorectal cancer treatment by targeting mitochondrial energy metabolism in the tumor microenvironment.

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“…Then, these PUFA-PLs are oxidized by another enzyme named ALOX15 into PL-PUFA-OOHs. Since PL-PUFA-OOHs can trigger ferroptotic cell death, the activity of the abovementioned enzymes contributes to the promotion of ferroptosis ( 38 ). Surprisingly, although ALOX15 and ACSL4 facilitate the ferroptosis process, recent studies showed that higher expression of these molecules was associated with increased cancer malignant features.…”

Section: Ferroptosis Regulators In Lung Cancermentioning

confidence: 99%

Ferroptosis in Lung Cancer: From Molecular Mechanisms to Prognostic and Therapeutic Opportunities

2021

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Lung cancer is the second commonly diagnosed malignancy worldwide and has the highest mortality rate among all cancers. Tremendous efforts have been made to develop novel strategies against lung cancer; however, the overall survival of patients still is low. Uncovering underlying molecular mechanisms of this disease can open up new horizons for its treatment. Ferroptosis is a newly discovered type of programmed cell death that, in an iron-dependent manner, peroxidizes unsaturated phospholipids and results in the accumulation of radical oxygen species. Subsequent oxidative damage caused by ferroptosis contributes to cell death in tumor cells. Therefore, understanding its molecular mechanisms in lung cancer appears as a promising strategy to induce ferroptosis selectively. According to evidence published up to now, significant numbers of research have been done to identify ferroptosis regulators in lung cancer. Therefore, this review aims to provide a comprehensive standpoint of molecular mechanisms of ferroptosis in lung cancer and address these molecules’ prognostic and therapeutic values, hoping that the road for future studies in this field will be paved more efficiently.

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Fatty Acids Metabolism: The Bridge Between Ferroptosis and Ionizing Radiation

Cited by 30 publications

References 129 publications

MnTE-2-PyP protects fibroblast mitochondria from hyperglycemia and radiation exposure

MnTE-2-PyP protects fibroblast mitochondria from hyperglycemia and radiation exposure

Antiproliferative, Antiangiogenic, and Antimetastatic Therapy Response by Mangiferin in a Syngeneic Immunocompetent Colorectal Cancer Mouse Model Involves Changes in Mitochondrial Energy Metabolism

Ferroptosis in Lung Cancer: From Molecular Mechanisms to Prognostic and Therapeutic Opportunities

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