Correlation between Oxidative Stress, Nutrition, and Cancer Initiation
Abstract
:1. Introduction
2. Correlation between Nutrition and Oxidative Stress
2.1. Nutrition Induces Oxidative Stress during Early Human Development
2.2. Nutrition Triggers Oxidative Stress at the Cellular Level
2.3. Nutrition Increases Oxidative Stress during Tissue Metabolism
2.3.1. Liver
2.3.2. Adipose Tissue
2.3.3. Pancreas
2.3.4. Skeletal Muscle
2.4. Nutrition Induces Oxidative Homeostasis
3. The Relationship between Nutrition and Oxidative Stress Following Carcinogenesis
3.1. Alcohol
3.2. Carbohydrates
3.3. Fatty acids (FAs)
3.4. Fiber
3.5. Flavonoids
3.6. Proteins
3.7. Vitamins
4. The Association between Oxidative Stress and Cancer Progression
5. Conclusions
Acknowledgments
Author Contributions
Conflicts of Interest
Abbreviations
8-OHdG | 8-OH deoxyguanosine |
AGE | advanced glycation end product |
ATP | adenosine triphosphate |
BMI | body mass index |
COX-2 | cyclooxygenase 2 |
CPT-1 | carnitine palmitoyltransferase-1 |
CRP | C-reactive protein |
CSC | cancer stem cells |
CVD | cardiovascular disease |
DAG | diacylglycerols |
DHA | docosahexaenoic acid |
EFA | Essential fatty acids |
EPA | eicosapentaenoic acid |
EPIC | European Prospective Investigation into Cancer and Nutrition |
ER: | endoplasmic reticulum |
ERK | extracellular signal-regulated kinase |
ETC: | electron transport chain |
FFA | free fatty acids |
FoxO1 | Forkhead box protein O1 |
GI | glycemic indexes |
GLUT4 | glucose transporter type 4 |
GPX | glutathione peroxidase |
GR | glutathione reductase |
GRXo | glutaredoxin (oxidized) |
GRXr | glutaredoxin (reduced) |
GSHr | glutathione (reduced) |
HDL | high-density lipoproteins |
IARC | International Agency for Research on Cancer |
IGT | impaired glucose tolerance |
IKKα | IκB kinase α |
IKKβ | IκB kinase β |
IL- 6 | Interleukin 6 |
IκBα | inhibitor κBα |
JNK | c-Jun N-terminal kinase |
MAPK | mitogen-activated protein kinase |
MCP-1 | Monocyte chemoattractant protein-1 |
MDA | malondialdehyde |
Mito-ETC | mitochondrial electron transport chain |
MNC | mononuclear cells |
NADPH | nicotinamide adenine dinucleotide phosphate |
NF-κB | nuclear factor κB |
NO | nitric oxide |
NOX4 | NADPH oxidase 4 |
NRF2 | nuclear factor erythroid 2-related factor 2 |
PAI-1 | plasminogen activator inhibitor-1 |
PCOS | polycystic ovarian syndrome |
PKC | protein kinase C |
PMNL | polymorphonuclear leukocytes |
PTEN | phosphatase and tensin homolog |
PTP | protein tyrosine phosphatase |
ROS | reactive oxygen species |
SOD | superoxide dismutase |
TAG | triacylglycerol |
TLR4: | Toll-like receptor 4 |
TRXo | thioredoxin (oxidized) |
TRXr | thioredoxin (reduced) |
VLDL | very low-density lipoproteins |
WCRF | World Cancer Research Fund |
WHI | Women’s Health Initiative |
WHO | World Health Organization |
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No. | Dietary Components | Role in Oxidative Stress | Role in Carcinogenesis |
---|---|---|---|
1 | Alcohol | ▪ Promotes ROS production while lowering cellular antioxidant levels, thereby altering homeostasis between pro- and anti-oxidants leading to oxidative stress in multiple tissues [123]. ▪ Increases ROS production and oxidative stress, and results in the accumulation of acetaldehyde [124]. ▪ alters mitochondrial function resulting in cellular death [125]. | ▪ Prominent carcinogen linked with several cancers [95]. ▪ Higher risk for esophageal cancer [95]. ▪ Highly associated with risks for breast tumors [115]. ▪ Alcohol intake and the genes involved in alcohol metabolism and their interaction increase the risk of breast cancer in post-menopausal women [126]. ▪ Chronic alcohol abuse can cause folate deficiency, which is a well-documented risk factor for breast cancer [127]. |
2 | Carbohydrates | ▪ Lead to increased oxidative stress, which has been associated with increased risk for atherosclerosis and related disorders [128]. ▪ High-carbohydrate meal may evoke a greater postprandial oxidative stress response [129]. | ▪ Could affect breast cancer influencing plasma levels of glucose and insulin, and insulin resistance [130]. ▪ Consuming foods with high insulinogenic content may increase the risk of breast cancer [131]. |
3 | Fatty acids (FAs) | ▪ Omega-3 FAs reduce oxidative stress [132]. ▪ FAs shorten in chain length and decrease unsaturation and peroxidation, while the 1-carbon cycle shifts from the methylation to the transsulfuration pathway [133]. | ▪ Established mechanism is an association between inflammatory pathways and the function of omega-3 and omega-6 FAs on the action of cyclooxygenase-2 (COX-2) in prostate cancer [134,135,136]. ▪ n-3 FAs, especially the long-chain polyunsaturated FAs, eicosapentaenoic acid and docosahexaenoic acid, present in fatty fish and fish oils inhibit carcinogenesis [137]. |
4 | Fiber | ▪ Could protect from oxidative stress [138]. ▪ Reduced levels of oxidative stress [139]. ▪ Elicited modest improvements in indices of oxidative stress and inflammation [140]. ▪ Dietary fiber supplementation, rather than energy intake and dietary restriction, appears to be the main process regarding oxidative stress in the cardiac tissue [141]. | ▪ An 11% decrease in breast cancer risk in individuals consuming a fiber-rich diet versus that in individuals consuming the lowest amount of fiber [142]. ▪ With up to a 25% reduction in cancer risk when ingesting around 12.6–33.1 g/day of fiber, or 17% reduction for consuming fiber 3 times a day [143,144]. ▪ It reduces the risk of developing some types of cancer [145]. |
5 | Flavonoids | ▪ Prevent disuse muscle atrophy by attenuating oxidative stress derived from mitochondrial dysfunction [146]. ▪ Have potential antioxidant actions by reacting with and inactivating O2−, oxygen lipid peroxide radicals, and/or stabilizing free radicals involved in the oxidative process by hydrogenation or complexing with oxidant species [147]. ▪ Have both a cytoprotective effect owing to ROS scavenging and cytotoxic effect caused by H2O2 generation [148]. | ▪ Isoflavones are the most well-known compounds that possess well-characterized anti-estrogenic activity; functions in intracellular steroid metabolism; and anti-angiogenic, anti-proliferative, and pro-apoptotic activities in various tumor cells [149,150,151]. ▪ Isoflavones consumption of 20 mg/day can decrease breast cancer risk by 29% compared to that by consumption of 5 mg/day [152]. ▪ Flavonoids are potent regulators of cyclin B and p21 required for cell cycle progression, which may play some roles in the prevention of carcinogenesis [153]. ▪ Flavonoids have emerged as potential chemopreventive candidates for cancer treatment, especially, by their ability to induce apoptosis [154]. |
6 | Proteins | ▪ Long-term intake of high protein diets did not increase variables of oxidative stress [155]. ▪ Become activated by oxidation and help bacteria to respond to oxidative stress [156]. | ▪ Protein-rich food (especially animal protein) could be associated with a higher risk of cancer [157]. ▪ Colorectal cancer progression occurs upon satisfactory consumption of animal protein [158]. |
7 | Vitamins | ▪ Vitamin A is rapidly oxidized in the presence of oxygen, transient metals, and light [159]. ▪ Vitamin E plays an important protective antioxidant role in elderly, particularly in conditions where oxidative stress and free radicals are potentiated [160]. | ▪ Numerous vitamins, including vitamin A, B, C, D, and E, have been implicated in the risk of cancer occurrence [161,162,163,164,165]. ▪ Intake or synthesis of vitamin D is associated with reduced incidence and death rates of colon, breast, prostate, and ovarian cancers [166]. |
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Saha, S.K.; Lee, S.B.; Won, J.; Choi, H.Y.; Kim, K.; Yang, G.-M.; Dayem, A.A.; Cho, S.-g. Correlation between Oxidative Stress, Nutrition, and Cancer Initiation. Int. J. Mol. Sci. 2017, 18, 1544. https://doi.org/10.3390/ijms18071544
Saha SK, Lee SB, Won J, Choi HY, Kim K, Yang G-M, Dayem AA, Cho S-g. Correlation between Oxidative Stress, Nutrition, and Cancer Initiation. International Journal of Molecular Sciences. 2017; 18(7):1544. https://doi.org/10.3390/ijms18071544
Chicago/Turabian StyleSaha, Subbroto Kumar, Soo Bin Lee, Jihye Won, Hye Yeon Choi, Kyeongseok Kim, Gwang-Mo Yang, Ahmed Abdal Dayem, and Ssang-goo Cho. 2017. "Correlation between Oxidative Stress, Nutrition, and Cancer Initiation" International Journal of Molecular Sciences 18, no. 7: 1544. https://doi.org/10.3390/ijms18071544
APA StyleSaha, S. K., Lee, S. B., Won, J., Choi, H. Y., Kim, K., Yang, G. -M., Dayem, A. A., & Cho, S. -g. (2017). Correlation between Oxidative Stress, Nutrition, and Cancer Initiation. International Journal of Molecular Sciences, 18(7), 1544. https://doi.org/10.3390/ijms18071544