Free Radicals as a Double-Edged Sword: The Cancer Preventive and Therapeutic Roles of Curcumin
Abstract
:1. Introduction
2. Free Radicals as a Double Edge Sword
2.1. Carcinogenesis
2.2. Therapeutic
3. Cancer Preventive Role of Curcumin through Suppression of Free Radicals
3.1. Curcumin Mediates Chemopreventive Effect through Its Antioxidant Property
3.2. Chemopreventive Potential of Curcumin in Combination with Other Compounds
4. Cancer Therapeutic Role of Curcumin through Induction of ROS
4.1. ROS Mediated Anticancer Effect of Curcumin
4.2. Chemosensitizing Effect of Curcumin Mediated through ROS
5. Conclusions
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
References
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Properties | Models | Mechanisms | References |
---|---|---|---|
Anti-carcinogenesis | BP-induced lung tumor in mice | Decreases the levels of LPO, ROS, as well as increases activities of SOD, GST | [51] |
In combination with resveratrol, decreases the LPO level and restores activities of SOD, GR, and GST | [54] | ||
CoCl2-induced hypoxia in HCC | decreased hypoxia-induced HIF-1α protein, suppressed cell proliferation, migration and invasiveness, as well as EMT changes | [55] | |
AOM-DSS-induced colon cancer in mice | Decreases DNA CpG methylation of Tnf | [49] | |
DEN induced HCC in rats | Combats oxidative damage of hepatic cells and inhibits carcinogenesis | [56] | |
Chemopreventive | ddY mice | Increases the activity of antioxidant enzymes GPx, GR, glucose-6-phosphate dehydrogenase and catalase | [57] |
Sprague-Dawley rats. | Increases activity of GST enzyme | [58] | |
Renal epithelial cells | Stimulates the expression of Nrf2, increases in HO-1 | [59] | |
Bovine aortic endothelial cells | Increases the expression of HO-1 mRNA, protein and its activity | [60] | |
Spontaneous ovarian cancer in hen | Reduces tumor sizes and number, inhibits NF-κB and STAT3 signaling pathways, decreases KRAS and HRAS mutations, and induces NRF2/HO-1 antioxidant pathway | [61] | |
Chemoprotective | Hemin-induced cytotoxicity in rat neurons. | Attenuates ROS production, reduces GSH/GSSG ratio, increases GR, GST and SOD enzymes, increases HO-1 level and Nrf2 translocation into the nucleus, and reduces cell death | [62] |
TAA-induced liver inflammation and fibrosis in rats | Reduces oxidative stress, inhibits apoptosis, induced autophagy, decreases fetoprotein AST activity, and increased serum albumin concentration. | [63] | |
Anti-cytotoxic | PhIP-induced cytotoxicity in breast epithelial cells | Decreases ROS production, inhibits DNA adduct formation and DNA double stand breaks, and induces expression of various antioxidant and DNA repair genes | [50] |
Dox-induced cytotoxicity in 3T3 normal cells | With resveratrol and EEAC increases cell antioxidant ability by improving the activity of SOD, prevents intracellular damage, and reduces ROS | [64] | |
MG-induced cell death in human hepatoma G2 cells | Abolishes oxidative stress, prevents apoptotic biochemical changes such as release of cytochrome c, caspase-3 activation, and cleavage of PARP | [52] |
Properties | Models | Mechanism | Reference |
---|---|---|---|
Apoptosis | Myeloid leukemia K562 cells | Releases cytochrome c from mitochondria, PARP and caspase-9 cleavages | [93] |
Melanoma A375 cells | Induces ROS burst, decreases GSH, and wrecks MMP | [94] | |
Gastric cancer BGC-823 cells | Induces ROS, activates ASK1, and phosphorylates JNK protein | [95] | |
Leukemic Jurkat and K562 cells | Downregulates IAPs, pAkt, c-Myc, and cyclin D1 | [96] | |
Breast cancer MCF-7, MDAMB, HepG2 cells | Generates ROS | [97] | |
Cell cycle arrest | Breast cancer MCF-7 cells | Downregulates cyclin B1, Cdc2 and NF-κB by decreasing the interaction of pIκB-NF-κB | [98] |
Cell cycle arrest and apoptosis | HT-29 colon cancer cells | Induced ROS generation, DNA fragmentation, chromatin condensation, and nuclear shrinkage | [99] |
K562 cells and xenograft mouse | Derivative PGV-1 induces prometaphase arrest in the M phase and induces cell senescence and death by increasing ROS. | [100] | |
Prostate carcinoma PC-3 and DU145 and xenograft mice | Analogue Ca 37 induces ROS production | [101] | |
Prostate cancer RM-1 and DU145 cell lines and xenograft mice | Analog WZ35 induces ROS overproduction, intracellular calcium surge, and mitochondrial disruption | [102] | |
NCI-H460 cells | Analogues hexamethoxy-diarylpentadienones (1 and 2) upregulate p53 and p21 and downregulate Cdc25C, cyclin B1/Cdk1 in a Michael acceptor- and ROS-dependent fashion | [103] | |
NSCLC A549 and SPC-A1 cell lines | Causes ROS production, DNA damage, endoplasmic reticulum stress and mitochondrial instability. | [92] | |
Chemosensitization | Glioblastoma | DMC synergistically increases TMZ-induced apoptosis by increasing ROS production, inactivating JAK/STAT3 signaling pathway and caspase-3 cleavage | [104] |
Anti-tumorigenesis | CML-derived K562 cells, xenograft mouse | Derivatives upregulate ROS levels, compete with co-enzymes to bind to the respective ROS metabolic enzymes and inhibit their activities | [105] |
Anti-angiogenesis | HUVECs, CAMs | Analog A2 induces NADH/NADPH oxidase-derived ROS | [106] |
Tumor re-incidence and metastasis inhibition | B16F10 cells, syngeneic mice | Nanoformulation increases intracellular curcumin accumulation and ROS formation | [107] |
Anti-tumorigenesis | Gastric cancer BGC-823 cells, xenograft mice | Enhances oxidative stress, decreases mtDNA content and DNA polymerase γ | [91] |
Leukemic K562 cells, xenograft mice | Induces ROS level | [108] | |
Autophagy and apoptosis | lymphoma HuT-78 cells | Produces ROS, inhibits c-FLIP, Bcl-xL, cIAP, XIAP, disrupts the integrity of IKK and beclin-1 by degrading Hsp90, inhibits NF-κB, accumulates autophagy marker LC3-I | [109] |
Autophagy | Colon cancer HCT116 cells | Generates ROS, converts autophagic marker LC3-I to LC3-II and degrades sequestome-1 | [110] |
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Gupta, N.; Verma, K.; Nalla, S.; Kulshreshtha, A.; Lall, R.; Prasad, S. Free Radicals as a Double-Edged Sword: The Cancer Preventive and Therapeutic Roles of Curcumin. Molecules 2020, 25, 5390. https://doi.org/10.3390/molecules25225390
Gupta N, Verma K, Nalla S, Kulshreshtha A, Lall R, Prasad S. Free Radicals as a Double-Edged Sword: The Cancer Preventive and Therapeutic Roles of Curcumin. Molecules. 2020; 25(22):5390. https://doi.org/10.3390/molecules25225390
Chicago/Turabian StyleGupta, Nehal, Kshitij Verma, Sarath Nalla, Alok Kulshreshtha, Rajiv Lall, and Sahdeo Prasad. 2020. "Free Radicals as a Double-Edged Sword: The Cancer Preventive and Therapeutic Roles of Curcumin" Molecules 25, no. 22: 5390. https://doi.org/10.3390/molecules25225390
APA StyleGupta, N., Verma, K., Nalla, S., Kulshreshtha, A., Lall, R., & Prasad, S. (2020). Free Radicals as a Double-Edged Sword: The Cancer Preventive and Therapeutic Roles of Curcumin. Molecules, 25(22), 5390. https://doi.org/10.3390/molecules25225390