Dietary Natural Products for Prevention and Treatment of Liver Cancer
Abstract
:1. Introduction
2. Fruits
2.1. Grape
2.2. Black Currant
2.3. Plum
2.4. Other Fruits
3. Vegetables
3.1. Cruciferous Vegetables
3.2. French Bean
3.3. Tomato
3.4. Asparagus
3.5. Other Vegetables
4. Spices
4.1. Garlic
4.2. Turmeric
4.3. Pepper
4.4. Ginger
4.5. Other Spices
5. Soy
6. Cereals
7. Edible Macro-Fungi
8. Effects of Combination of Dietary Natural Products with Anticancer Treatments
9. Conclusions
Acknowledgments
Author Contributions
Conflicts of Interest
References
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Natural Products | Bioactive Components | Study Type | Bioactivities and Potential Mechanisms | References |
---|---|---|---|---|
Fruits | ||||
Grape | procyanidins | in vitro | selective cytotoxicity to cancer cells | [13] |
in vivo | inhibiting tumor angiogenesis; promoting doxorubicin induced apoptosis | [19,144] | ||
Flavan-3-ol | in vitro | inducing apoptosis, DNA damage and Suppressing expression of oncoprotein Her-2 | [20] | |
Black currant | anthocyanins | in vivo | protecting against diethylnitrosamine induced hepatocarcinogenesis by inducting apoptosis and suppressing oxidative stress and inflammation | [10] |
Plum | polyphenols | in vitro | inducing extrinsic apoptosis and inhibiting migration | [11,25] |
in vivo | protecting against B(α)P liver damage through regulating enzymes involved detoxification | [26] | ||
Pomegranate | polyphenols | in vivo | protecting against diethylnitrosamine induced hepatocarcinogenesis by suppressing oxidative stress and inflammatory responses | [27,28] |
Apple | polyphenols | in vitro | inducing apoptosis, G2/M cell cycle arrest and inhibiting DNA topoisomerase II in cancer cells | [31] |
Sweetsop | annonaceous acetogenins | in vitro and in vivo | exerting cytotoxicity against HepG2 cells and inhibiting tumor growth in hepatoma bearing mice | [32] |
Sea buckthorn | isorhamnetin | in vitro | promoting apoptosis of human hepatoma cells | [34] |
Gac fruit | a water soluble protein | in vitro | inducing S phase arrest in cancer cells | [35] |
Mangosteen | γ-mangostin | in vitro | inducing apoptosis in cancer cells | [36] |
Citrus fruit | auraptene | in vivo | suppressing tumor progression in N,N-diethylnitrosamine challenged rats by negative selection for cancer cells with β-catenin mutation | [38] |
Mango | lupeol | in vivo | ameliorating DMBA insult induced alterations in liver | [39] |
Vegetables | ||||
Radish | Glucoraphasa-tin, isothiocyanate | in vitro | upregulating hepatic phase II detoxification enzymes involved in the metabolism of chemical carcinogens | [45] |
Broccoli | sulforaphane | in vitro | upregulating CYP1A1 and quinone reductase | [46,47] |
Rutabaga | NA | in vitro | exerting selective antiproliferative and pro-apoptotic effects in cancer cells | [50] |
French bean | triterpenoids, flavonoids | in vitro | exhibiting antiproliferative activities against cancer cells | [52] |
lectins | in vitro | exerting selectively cytotoxicity to cancer cells via promoting apoptosis, necrosis, NO production and release of proinflammatory cytokines | [54] | |
Tomato | lycopene | in vivo | protecting against chemical induced liver carcinogenesis through inducing apoptosis | [59,60] |
tomatine | in vivo | inducing antigen-specific cellular immunity and direct destructing cancer cell membranes | [61] | |
Asparagus | polysaccharides | in vitro and in vivo | selectively inhibiting cancer cell proliferation and enhancing the tumoricidal activities of mitomycin | [62] |
in vivo | serving as a good embolic candidate in transcatheter arterial chemoembolization | [63] | ||
asparanin A | in vitro | inducing G2/M cell cycle arrest and apoptosis | [65] | |
Mung bean sprouts | NA | in vitro | increasing apoptosis, anti-tumor cytokines (TNF-α and IFN-β), IFN-γ production and upregulating cell-mediated immunity | [66] |
Bitter gourd | lectin | in vitro | inducing G2/M phase arrest, apoptosis, autophagy and enhancing the anti-tumor effects of Sorafenib | [67] |
MAP30 | in vitro and in vivo | inducing apoptosis and S phase cell cycle arrest | [68] | |
Purple perilla | Isoegomake-tone | in vitro and in vivo | inhibiting cell growth and xenograft tumor formation probably through blocking the PI3K/Akt signaling pathway | [70] |
Potato | glycoalkaloids | in vitro | selectively inhibiting cancer cell growth | [72] |
Celery | pigenin, linamarose, Vitamins A/C | in vivo | dose dependently suppressing chemically induced hepatocarcinogenesis | [73] |
Spices | ||||
Garlic | Organo-sulphur compounds | in vitro | inhibiting chemical induced DNA damage | [77] |
sodium 2-propenyl thiosulfate | in vitro | upregulating quinone reductase | [78] | |
allicin | in vitro | inducing apoptosis through overproduction of ROS | [80] | |
S-allylcysteine | in vitro and in vivo | inducing apoptosis and S phase arrest, inhibiting cancer cell migration and invasion | [78] | |
aged garlic extract | in vivo | inhibiting diethylnitrosamine induced preneoplastic lesions in liver | [81] | |
clinical trial | enhancing natural-killer cell activities | [83] | ||
Turmeric | NA | in vivo | protecting against HBV-related liver cancer | [84] |
curcumin | in vitro and in vivo | demonstrating anti-tumor activity against chemical induced hepatocarcinogenesis | [85] | |
Sesquiterpe-noids | in vitro and in vivo | alleviating concanavalin A induced oxidative stress and inflammation, inhibiting cancer cell growth | [88] | |
aromatic tumerone | in vitro | inducing apoptotic cell death via ROS-mediated ERK and JNK kinases activation | [89] | |
Pepper | NA | in vitro | selective cytotoxicity against rat hepatoma cells through intracellular accumulation of ROS | [90] |
glycoprotein | in vivo | preventing chemical induced liver carcinogenesis by immunomodulation and promotion of apoptosis | [91] | |
NA | in vitro | inducing G2/M cell cycle arrest and apoptosis, inhibiting cell metastasis, invasion via down-regulating MMP-2/-9 and up-regulating TIMP-1/-2 | [92,93,94] | |
geranyl acetate, citronella, sabinene | in vitro and in vivo | increasing apoptotic cell death through ROS production | [95] | |
Ginger | NA | in vivo | inhibiting inflammation and promoting apoptosis | [100] |
geraniol, pinostrobin, clavatol | in vitro | inhibiting cancer cell proliferation though ROS-mediated apoptotic death | [101] | |
6-shogaol, 6-gingerol | in vitro | suppressing metastasis via down-regulation of MMP-9, urokinase-type plasminogen and up-regulation of TIMP-1 | [102] | |
Star anise | NA | in vivo | ameliorating tumor burden, oxidative stress and upregulating phase II detoxifying enzymes | [104] |
Saffron | NA | in vitro and in vivo | inducing apoptosis and decreasing tumor burden, oxidative damage and inflammatory responses | [105,106] |
Galangal | galagin | in vitro | promoting mitochondrial apoptotic death | [107] |
Cinnamon | Isoobtusilac-tone A | in vitro | inducing apoptotic cancer cell death through overproduction of ROS | [109,110] |
Basil | NA | in vitro and in vivo | inhibiting sulfotransferase induced procarcinogenesis by suppressing DNA adducts formation | [111] |
Rosemary | carnosic acid | in vitro | protecting against aflatoxin B1 through reduced oxidative stress | [112] |
Soy | trypsin inhibitor | in vitro | inhibiting cancer cell growth | [115,116] |
Cereals | ||||
Rice bran | peptide hydrolysates, phytic acid | in vitro | inhibiting cancer cell growth | [118,120] |
Pigmented rice | anthocyanin | in vitro | synergistically promoting the cytotoxicity of vinblastine through a mitochondrial apoptosis pathway | [122] |
Corn silk | polysaccharides | in vivo | enhancing immune function and extending survival time | [123] |
Semen coicis | NA | in vitro | dose-dependently promoting apoptotic death of cancer cells through upregulation of capase-8 | [124] |
Edible macro-fungi | ||||
Agaricus blazei | NA | in vitro | sensitizing doxorubicin induced apoptotic death of cancer cells; decreasing formation of abnormal collagen fiber | [128,146] |
β-glucan | in vitro | protecting against B(α)P induced DNA damage by binding to the carcinogen, scavenging free radicals and probably modulating cell metabolism | [130] | |
blazeispirols A and C | in vitro | displaying potent antiproliferative activities against Hep3B cells and HepG2 cells | [131] | |
Pleurotus pulmonarius | NA | in vitro and in vivo | reducing the incidence and size of tumor; inhibiting invasion and drug-resistance of hepatoma cells; enhancing cytotoxicity of cisplatin | [133,134] |
Lentinula edodes | polysaccharide | in vitro | selectively killing HepG2 cells through the capase-3/-8 mediated extrinsic apoptosis pathway | [137] |
Agrocybe aegerita | lectin | in vitro | binding to the surface of liver cancer cells, resulting apoptotic cell death | [138] |
Flammulina velutipes | FVE (glycoprotein) | in vivo | prolonging survival time and reduced tumor size through inducing cytotoxic immune response | [140] |
Suillus luteus | iso-suillin | in vitro | selectively inducing G1 cell cycle arrest and apoptotic death in cancer cells | [141] |
Grifola frondosa | O-orsellinaldehyde | in vitro | exhibiting selective potent cytotoxicity against Hep3B cells | [142] |
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Zhou, Y.; Li, Y.; Zhou, T.; Zheng, J.; Li, S.; Li, H.-B. Dietary Natural Products for Prevention and Treatment of Liver Cancer. Nutrients 2016, 8, 156. https://doi.org/10.3390/nu8030156
Zhou Y, Li Y, Zhou T, Zheng J, Li S, Li H-B. Dietary Natural Products for Prevention and Treatment of Liver Cancer. Nutrients. 2016; 8(3):156. https://doi.org/10.3390/nu8030156
Chicago/Turabian StyleZhou, Yue, Ya Li, Tong Zhou, Jie Zheng, Sha Li, and Hua-Bin Li. 2016. "Dietary Natural Products for Prevention and Treatment of Liver Cancer" Nutrients 8, no. 3: 156. https://doi.org/10.3390/nu8030156
APA StyleZhou, Y., Li, Y., Zhou, T., Zheng, J., Li, S., & Li, H. -B. (2016). Dietary Natural Products for Prevention and Treatment of Liver Cancer. Nutrients, 8(3), 156. https://doi.org/10.3390/nu8030156