Nobiletin and Derivatives: Functional Compounds from Citrus Fruit Peel for Colon Cancer Chemoprevention
Abstract
:1. Introduction
2. Research Methodology
3. Nobiletin and Its Derivatives
4. Pathogenesis of Colorectal Cancer
5. Chemopreventive Effects of Nobiletin, 5-DMN and NOB-Metabolites
5.1. Cell Cycle Arrest
5.1.1. Action of NOB and Its Metabolites Inducing Cell Arrest
5.1.2. Action of 5-DMN Inducing Cell Cycle Arrest
5.2. Programmed Cell Death
Action of NOB and Metabolites Inducing Programmed Cell Death
5.3. Anti-Inflammation
Anti-Inflammation Effect of NOB and Its Metabolites
5.4. Anti-Angiogenesis
Anti-Angiogenesis Effect of NOB
6. Pharmacokinetics, Bioavailability and Delivery Systems of NOB
7. Toxicity
8. Commercial Uses
9. Future Directions
10. Conclusions
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
References
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Compounds | Activities | Cell lines | Treatment/Assay (Treatment Duration) | Assays/Results/Mechanisms | References |
---|---|---|---|---|---|
NOB | Anti-proliferative | HT-29 | H-thymidine uptake assay | - IC50 of NOB = 4.7 μM | [70] |
- IC90 of NOB = 13.9 μM | |||||
5-DMN | - IC50 of 5-DMN = 8.5 μM | ||||
- IC90 of 5-DMN = 171 μM | |||||
NOB | Cytotoxicity | COLO320, SW480 and Caco-2 | MTS viability assay (48 h) | - IC50 for COLO320 = 40.4 ± 9.1 μM | [79] |
- IC50 for SW480 = 245 ± 9.1 μΜ | |||||
- IC50 for Caco-2 = 305.6 ± 41.9 μΜ | |||||
Apoptosis-inducing | Apoptosis assays—DNA fragmentation | - DNA ladder pattern | |||
200 μΜ—2-fold increase DNA fragmentation in COLO320 | |||||
- gel electrophoresis (48 h) | |||||
Anti-proliferative | BrdU labelling index | - 34.7 ± 4.7% BrdU-binding cells at 100 μΜ | |||
- 44.4 ± 6.4% BrdU-binding cells at 40 μΜ | |||||
NOB | Anti-metastasis | HT-29 | ELISA | [77] | |
- proMMP-7 expression | - At 100 μM, no detection of proMMP-7 in media, ~280 pg/mL proMMP-7 in media | ||||
qPCR and Western blot | - >25 μM, reduced RNA and protein (both intracellular and supernatant) expression of proMMP-7 | ||||
AP-1 binding activity | - Inhibited binding activity of AP-1 (transcription factor for MMP-7 gene) | ||||
NOB | Anti-proliferative | HT-29 | Cell counting assay | - IC50 of NOB ≈ 50 μM | [14] |
- Inhibited cell proliferation in a time- and dose-dependent manner | |||||
Cell cycle arrest | |||||
Cell cycle analysis | - Induced G1 phase cell cycle arrest (60 and 200 μM) | ||||
- Propidium iodide staining | |||||
Apoptosis-inducing | Apoptosis assay | - No significant apoptosis detected at 60 and 100 μM | |||
Resumption of proliferation | - Resumed proliferation within 24 h of removal of NOB and achieve the same stage of growth as compared to control after four days of removal of NOB | ||||
NOB 5-DMN | Cytotoxicity | HCT116, HT-29 | MTT viability assay (48 h) | - IC50 of NOB on HCT116 = 37 μM | [63] |
- IC50 of 5-DMN on HCT116 = 8.7 μM | |||||
- IC50 of NOB on HT-29 = 46.2 μM | |||||
- IC50 of 5-DMN on HT-29 = 22 μM | |||||
Cell cycle arrest | Cell cycle analysis - Propidium iodide staining (24 h) Western blot | - At 8 μM, 5-DMN induced G2/M phase arrest in HCT116 | |||
- At 36 μM, 5-DMN induced G2/M phase arrest in HT-29 | |||||
- At 16 μM, NOB reduced CDK-2 expression | |||||
- At 4 μM and 8 μM, 5-DMN increased p21 and Rb, while decreased CDK-2 and p-Rb. | |||||
Apoptosis-inducing | Apoptosis assay | - At 8 μM, 5-DMN increased early apoptosis by 2.2-fold in HCT116 | |||
Annexin-V/PI (48 h) | - At 36 μM, 5-DMN increased early apoptosis by ~2-fold in HT-29 | ||||
Western blot | - At 16 μM, NOB did not increase apoptotic cell population in HCT116/HT-29 | ||||
- At 4 μM and 8 μM, 5-DMN increased expressions of cleaved caspase 8, cleaved caspase 3 and cleaved PARP. | |||||
5-DMN | Apoptosis-inducing | HCT116 (p53 +/+) and HCT116 (p53 −/−); HCT116 (Bax +/−) and HCT116 (Bax −/−); HCT116 (p21 −/−) | Apoptosis assay Annexin-V/PI | - At 15 μM, 5-DMN increased late apoptotic/necrotic cell in HCT116 (p53 −/−) > HCT115 (p53 +/+), suggesting the apoptotic inducing action is independent of p53 | [80] |
- At 15 μM, 5-DMN increased early apoptotic cell in HCT116 (Bax +/−), but not in HCT116 (Bax −/−) | |||||
Cell cycle arrest | Cell cycle analysis - Propidium iodide staining | - At 15 μM, 5-DMN arrested cells at G2/M and G0/G1 phases in HCT116 (p53 +/+) cells, but only caused G2/M phase arrest in HCT116 (p53 −/−) cells | |||
- G0/G1 is p53 dependent and G2/M is p53-independent | |||||
NOB; 3′-DMN; 4′-DMN; 3′,4′-DMN | Cytotoxicity | HCT116, HT-29 | MTT viability assay | - At 2.03 μM and 3.28 μM, NOB and 3′-DMN, respectively showed no significant cytotoxicity against HCT116 and HT-29 | [54] |
- At 24.13 μM, 4′-DMN inhibited growth of HCT-116 by 45% and HT-29 by 33% | |||||
- At 12.03 μM, 3’,4’-DMN inhibited growth of HCT116 by 30% and HT-29 by 9% | |||||
- combination of all three NOB-metabolites inhibited growth of HCT116 by 64% and HT-29 by 62% (no significant difference to three NOB-metabolites + NOB) | |||||
Cell cycle arrest | Cell cycle analysis - Propidium iodide staining (24 h) | - NOB (40 μM) arrested cells at G0/G1 phase in both HCT-116 and HT-29 | |||
- 3′-DMN (40 μM) arrested cells at both S phase and G2/M phase in HCT-116; while arrested cells at both G0/G1 and G2/M phase in HT-29 | |||||
- 4′-DMN (40 μM) induced a stronger effect than NOB in arresting cells at G0/G1 phase in HCT-116 and HT-29 | |||||
- 3′,4′-DMN (20 μM) arrested cells at both S phase and G2/M phase in HCT-116; while arrested cells at both G0/G1 and G2/M phase in HT-29 | |||||
Apoptosis inducing | Western blot | - NOB and all three NOB-metabolites cause profound increase in expression of p21Cip1/Waf1 | |||
Annexin-V/PI (48 h) | - NOB (40 μM) increased early apoptotic cell population by 3.3-fold, increased late apoptotic cell population by 4.2-fold in HCT116 | ||||
- 3′-DMN (40 μM) increased early apoptotic cell population by 5.0-fold, increased late apoptotic cell population by 3.5-fold in HCT116 | |||||
- 4′-DMN (40 μM) increased early apoptotic cell population by 4.9-fold, increased late apoptotic cell population by 7.1-fold in HCT116 | |||||
- 3′,4′-DMN (20 μM) increased early apoptotic cell population by 7.6-fold, increase late apoptotic cell population by 4.5-fold in HCT116 | |||||
-3′-DMN (40 μM) and 4’-DMN (40 μM) did not cause significant apoptosis in HT-29 | |||||
- 3′,4′-DMN (20 μM) exhibits stronger apoptosis effect than NOB (40 μM) in HT-29 | |||||
Western blot | - NOB (40 μM) only increased activation of caspase-9 and did not affect caspase-3 or PARP levels in HCT116 | ||||
- NOB-metabolites increased activation of caspase-3, caspase-9 and other downstream proteins like PARP in HCT116 | |||||
NOB-Met (2.03 μM NOB: 3.28 μM 3′-DMN: 24.13 μM 4′-DMN: 12.03 μM 3′,4′-DMN | Anti-inflammatory | RAW264.7 | Western Blot | - At 0.5× concentration of NOB-Met, supressed LPS-induced iNOS expression by 56.4% | [76] |
- At 1× and 2× concentration of NOB-Met, completely abrogated LPS-induced iNOS expression | |||||
- At ×0.5, increased expression of NQO1 by 21% as compared to LPS-treated cells | |||||
- At ×1, increased expression of HO-1 by 10%, increased expression of NQO1 by 34% as compared to LPS-treated cells | |||||
- At ×2, increased expression of HO-1 by 37%, increased expression of NQO1 by 50% as compared to LPS-treated cells | |||||
- Induced translocation of Nrf2 | |||||
Cell cycle arrest | HCT116 | Cell cycle analysis - Propidium iodide staining Western blot | - At 1×, induced G0/G1 phase arrest; while at 2×, induced G0/G1 and G2/M phases arrest | ||
- Reduced expressions of CDK-2, CDK-4, CDK-6 and cyclin D, while increased expressions of p53 and p27 | |||||
NOB, 5-DMN | Cytotoxicity | HCT116, HT-29, COLO205 | MTT viability assay | - At 40 μM, NOB significantly reduced viability of HCT116, HT-29 and COLO205 by ~20–30% | [49] |
- At >5 μM, 5-DMN significantly reduced viability of HCT116, HT-29 and COLO205 | |||||
Apoptosis inducing | Cell cycle analysis - SubG1 quantification Western | - At 20 μM, 5-DMN increased apoptosis ratio by ~26%, while no increased in subG1 population in NOB-treated COLO205 | |||
- At 10 and 20 μM, significantly increased expression of cleaved PARP in COLO205 | |||||
NOB | Anti-inflammatory | Human synovial fibroblast, mouse macrophage J774A.1 | ELISA | - At >4 μM, NOB inhibited PGE2 induced by IL-1α in human synovial fibroblast | [81] |
Western blot and qPCR | - At >16 μM, NOB reduced mRNA of COX-2 induced by IL-1α in human synovial fibroblast | ||||
- At 64 μM, NOB inhibited COX-2 protein expression induced by IL-1α in human synovial fibroblast | |||||
qPCR | - At 32 μM, NOB reduced mRNA of IL-1α, IL-1β, IL-6, TNF-α induced by LPS in J774A.1 | ||||
Western blot | - At >16 μM, NOB reduced proMMP-1 and proMMP-3 induced by IL-1α in human synovial fibroblast | ||||
- At >16 μM, NOB enhanced TIMP-1 expression in response to IL-1α in human synovial fibroblast | |||||
NOB | Anti-inflammatory | Mouse adipocyte 3T3-L1 | ELISA | - At 50 and 100 μM, NOB suppressed MCP-1 secretion induced by TNF-α IN 3T3-L1 adipocytes | [82] |
Western blot | - At 50 and 100 μM, NOB reduced ERK phosphorylation in 3T3-L1 adipocytes treated with TNF-α |
Animal Models | Treatment/Dosage | Mechanisms | Detailed Results | References |
---|---|---|---|---|
Colitis-associated colon carcinogenesis model
| AIN93G diet containing 0.05% wt NOB (20 weeks) | Cell cycle arrest | Protein expression in colonic mucosa by Western blot - Reduced levels of CDK-2, CDK-4, CDK-6, cyclin D and cyclin E - Increased levels of p21, p27 and p53 | [76] |
Anti-inflammatory effects | Immunohistochemical analysis - Reduced expression of iNOS reduced by 35% when compared to the positive control Protein expression in colonic mucosa by Western blot - Increased level of HO-1 - Increased level of NQO1 - Induced translocation of level of Nrf2 transcription factor (Nuclear fraction < Cytoplasmic fraction) | |||
Colitis-associated colon carcinogenesis model
| AIN93G diet containing 0.05% wt NOB (20 weeks) | Inhibit AOM/DSS-induced colon carcinogenesis | - Prevented shortening of colon length, reduced the increased colon weight/length ratio - Reduced tumor incidence by 40% and tumor multiplicity by 71% - Maintained histological characteristic of normal mucosa | [54] |
Anti-proliferative effect | - Reduced PCNA-positive colonocytes by 69% in mucosal crypts | |||
Apoptosis-inducing effect | - Increased cleaved caspase-3 positive cells by 2.3-fold in colonic tumor | |||
Anti-inflammatory effects | - Reduced levels of proinflammatory cytokines - ELISA showed reduction of TNF-α by 51%, IL-1ß by 92% and IL-6 by 69% compared - qRT-PCR analysis showed reduction of TNF-α by 65%, IL-1ß by 69% and IL-6 by 45% | |||
Colon carcinogenesis model
| Diet containing 100 ppm NOB (0.1% wt) (10 weeks) | Inhibit AOM induced colon carcinogenesis | - Reduced frequency of preneoplastic lesions (colonic aberrant crypt foci (ACF) and β-catenin-accumulated crypts (BCAC)) - Reduced incidence of ACF by 68-91% and BCAC by 64–71% - Reduced PCNA-labeling index in ACF by 21% and BCAC by 19% | [83] |
Colon carcinogenesis model
| Diet containing 100 ppm NOB (0.1% wt) (for 17 weeks) | Inhibit AOM/DSS-induced colon carcinogenesis | - Suppressed incidence of neoplasms (adenoma and adenocarcinoma), lowered multiplicity of tumor | [84] |
Inhibit leptin-induced colon carcinogenesis | ||||
- Suppressed serum levels of leptin by 75–84% | ||||
Colon carcinogenesis model
| Diet containing NOB (0.01% wt and 0.05% wt) (34 weeks) | Inhibit AOM induced colon carcinogenesis | - Reduced incidence and multiplicity of colonic adenocarcinoma | [74] |
Anti-proliferative effect | ||||
- Increased apoptosis index of adenocarcinoma | ||||
Anti-inflammatory effect | ||||
- Reduced level of PGE2 in colonic adenocarcinoma and surrounding mucosa | ||||
Colon carcinogenesis model
| Diet containing NOB (0.01% wt and 0.05% wt) (5 weeks) | Inhibit AOM-induced colon carcinogenesis | - Reduced the frequency of colonic aberrant crypt foci formation - Reduced number of ACF in proximal, middle and distal colon | [41] |
Anti-proliferative effect | ||||
- Reduced MIB-5 labeling index of ACF but not of normal colonic crypts | ||||
Anti-inflammatory effect | ||||
- Reduced level of PGE2 in colonic mucosa | ||||
Colon carcinogenesis model
| Diet containing NOB (0.05% wt.) (50 weeks) | Inhibit PhIP-induced ACF in transverse colon | - Reduced the total colonic ACF indices in transverse colon | [75] |
Colorectal cancer xenograft mouse model
| NOB 100 mg/kg i.p. daily for 3 weeks 5-DMN 50 mg/kg and 100 mg/kg i.p. daily for 3 weeks | Anti-tumor effect | - NOB reduced tumor size and weight but not significant as compared to control - 5-DMN reduced tumor size and weight significantly as compared to control | [49] |
Autophagy induction | - 5-DMN increased LC3 expression | |||
Anti-inflammatory effect | ||||
- 5-DMN increased p53 expression - 5-DMN reduced COX-2 expression | ||||
Anti-angiogenesis | ||||
- 5-DMN reduced VEGF expression |
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Goh, J.X.H.; Tan, L.T.-H.; Goh, J.K.; Chan, K.G.; Pusparajah, P.; Lee, L.-H.; Goh, B.-H. Nobiletin and Derivatives: Functional Compounds from Citrus Fruit Peel for Colon Cancer Chemoprevention. Cancers 2019, 11, 867. https://doi.org/10.3390/cancers11060867
Goh JXH, Tan LT-H, Goh JK, Chan KG, Pusparajah P, Lee L-H, Goh B-H. Nobiletin and Derivatives: Functional Compounds from Citrus Fruit Peel for Colon Cancer Chemoprevention. Cancers. 2019; 11(6):867. https://doi.org/10.3390/cancers11060867
Chicago/Turabian StyleGoh, Joanna Xuan Hui, Loh Teng-Hern Tan, Joo Kheng Goh, Kok Gan Chan, Priyia Pusparajah, Learn-Han Lee, and Bey-Hing Goh. 2019. "Nobiletin and Derivatives: Functional Compounds from Citrus Fruit Peel for Colon Cancer Chemoprevention" Cancers 11, no. 6: 867. https://doi.org/10.3390/cancers11060867
APA StyleGoh, J. X. H., Tan, L. T. -H., Goh, J. K., Chan, K. G., Pusparajah, P., Lee, L. -H., & Goh, B. -H. (2019). Nobiletin and Derivatives: Functional Compounds from Citrus Fruit Peel for Colon Cancer Chemoprevention. Cancers, 11(6), 867. https://doi.org/10.3390/cancers11060867