Gingerol
Names | |
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Preferred IUPAC name
(5S)-5-Hydroxy-1-(4-hydroxy-3-methoxyphenyl)decan-3-one | |
Other names
[6]-Gingerol; 6-Gingerol
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Identifiers | |
3D model (JSmol)
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ChEBI | |
ChEMBL | |
ChemSpider | |
ECHA InfoCard | 100.131.126 |
KEGG | |
PubChem CID
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UNII | |
CompTox Dashboard (EPA)
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Properties | |
C17H26O4 | |
Molar mass | 294.38 g/mol |
Melting point | 30 to 32 °C (86 to 90 °F; 303 to 305 K) |
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
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Gingerol | |
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Heat | Very hot (chemical) |
Scoville scale | 60,000 SHU |
Gingerol ([6]-gingerol) is a phenolic phytochemical compound found in fresh ginger that activates heat receptors on the tongue.[1][2] It is normally found as a pungent yellow oil in the ginger rhizome, but can also form a low-melting crystalline solid. This chemical compound is found in all members of the Zingiberaceae family and is high in concentrations in the grains of paradise as well as an African Ginger species.
Cooking ginger transforms gingerol via a reverse aldol reaction into zingerone, which is less pungent and has a spicy-sweet aroma. When ginger is dried or mildly heated, gingerol undergoes a dehydration reaction forming shogaols, which are about twice as pungent as gingerol.[3] This explains why dried ginger is more pungent than fresh ginger.[4]
Ginger also contains [8]-gingerol, [10]-gingerol,[5] and [12]-gingerol,[6] collectively deemed gingerols.
Physiological potential
In a pre-clinical meta-analysis of gingerol compounds anticancer, anti-inflammatory, anti-fungal,[7] antioxidant, neuroprotective[8] and gastroprotective properties were reported, which include studies in-vitro and in-vivo.[9] A few in-vivo studies have proposed that gingerols facilitate healthy glucose regulation for diabetics.[10][11][12] Many studies have been around the effects of gingerols on a wide range of cancers including leukemia,[13] prostate,[14] breast,[15] skin,[16] ovarian,[17] lung,[18] pancreatic[19] and colorectal.[20] There has not been much clinical testing to observe gingerols physiological impacts in humans.[21][22]
While many of the chemical mechanisms associated with the effects of gingerols on cells have been thoroughly studied, few have been in a clinical setting. This is due to the high variability in natural phytochemicals and the lack of efficacy in research.[21][23] Most herbal medicine, which include gingerols, are under the restrictions of the Food and Drug Administration in the United States and experimental methods have not held up to scrutiny which has decreased the value in phytochemical research.[23][21] Herbal medicine is untested for quality assurance, potency and effectiveness in clinical settings due to a lack of funding in eastern medical research.[21] Most research on [6]-Gingerol has been on either mouse subjects (in-vivo) or on cultured human tissue (in-vitro) and may be used in the future to discuss possible applications for multi-target disease control.
An investigation scrutinizing gingerol's anti-fungal capabilities remarked that an African species of ginger tested higher in both gingerol and shogaol compounds than the more commonly cultivated Indonesian relative.[7] When tested for the anti-fungal properties the African ginger combated against 13 human pathogens and was three times more effective than the commercial Indonesian counterpart.[7] It is thought that gingerol compounds work in tandem with the other phytochemicals present including shogaols, paradols and zingerone.[7]
In a meta analysis looking at many different phytochemical effects on prostate cancer, two specific studies using mice observed [6]-gingerol compounds induced apoptosis in cancer cells by interfering with the mitochondrial membrane.[14] There were also observed mechanisms associated with the disruption of G1 phase proteins to stop the reproduction of cancer cells which is also an associated benefit of other relevant anticancer studies.[14][20][17][19] The main mechanism by which gingerol phytochemicals act on cancer cells seems to be protein disruption. The anti-carcinogenic activity of [6]-gingerol and [6]-paradol was analysed in a study observing the cellular mechanisms associated with mouse skin cancer which targeted the activator proteins associated with tumor initiation. Gingerol compounds inhibited the transformation of normal cells into cancer cells by blocking AP-1 proteins and when cancer did develop paradol encouraged apoptosis due to its cytotoxic activity.[16][13] [6]-Gingerol exhibits cell cycle arrest capabilities, apoptotic action and enzyme-coupled cell signaling receptor degradation in cancer cells. Gingerol has been observed to stop proliferation through inhibiting the translation of Cyclin proteins necessary for replication during G1 and G2 phase of cell division.[24] To promote apoptosis in cancer cells Cytochrome C is ejected from the mitochondria which ceases ATP production leaving a dysfunctional mitochondria. The Cytochrome C assembles an apoptosome which activates the Caspase-9 and initiates an executioner Caspase cascade, effectively breaking down DNA into histones and promoting apoptosis. [6]-Gingerol also inhibits the anti-apoptotic Bcl-2 proteins on the surface of mitochondria, which in turn increases the capabilities for the pro-apoptotic Bcl-2 proteins to initiate cell death. Cancer cells exhibit high amounts of growth hormone activator proteins that are expressed through enzyme-coupled signaling pathways. By halting the phosphorylation of PI-3-Kinase the Akt protein cannot bind with its PH domain, effectively deactivating the downstream signal. Successively keeping Bad proteins bound to anti-apoptotic proteins which keeps them from promoting cell growth, consequently, a double negative cellular signaling pathway to promote apoptosis.
Cultured human breast cancer cells were subjected to various concentrations of [6]-gingerol to determine the impacts on live cells. These concentration dependent results concluded that there was no impact at 5 μM but a reduction of 16% occurred at 10 μM.[15] [6]-gingerol targeted three specific proteins in breast cancer cells that promote metastasis and while adhesion remained relatively unchanged, [6]-gingerol inhibited the cancer cells from invading and increasing in size.[15] This study suggests the mechanism by which cancer cell growth was impacted was due to a reduction in specific mRNA that transcribes for extracellular degrading enzymes called matrix metalloproteinases (MMP's).[15] An examination using human cells in-vitro displayed gingerols capabilities in combating oxidative stress. The results concluded that gingerol had anti-inflammatory effects though shogaol showed the most promising effects combating free radicals.[22] There was an inverted dose- concentration response and as dosage concentration increased the amount of free radicals in cells decreased.[22]
Cisplatin is a chemotherapy drug that if used in high dosages causes renal failure which is considered a limiting factor for this life saving drug. By using [6]-gingerol it prevented the occurrence of renal failure in rats.[25] [6]-gingerol improved glutathione production in dose-dependent results which suggested that the higher a dosage the more of an effect [6]-gingerol had.[25]
Gingerol compounds are thought to help in diabetic patients because of increases in glutathione, a cellular toxin regulatory factor.[11] Anti-hyperglycaemic effects were studied in diabetic and severely obese mice. Gingerol compounds increased glucose uptake in cells without the need of a synthetic insulin activator, while also decreasing fasting glucose and increasing glucose tolerance.[10] In a different study the exact metabolic mechanisms associated with the physiological benefits of gingerol phytochemicals concluded that there was increased enzyme activity (CAT) and glutathione production while decreasing lipoprotein cholesterol and improving glucose tolerance in mice.[11] Cardio-arrhythmia is a common side effect of diabetic patients and the anti-inflammatory effects of gingerol suppressed the risks by lowering blood glucose levels in-vivo.[12]
The anti-oxidant properties of [6]-gingerol has been considered as a defense against Alzheimer’s. A study observed the molecular mechanisms responsible for the protection against DNA fragmentation and mitochondrial membrane potential deterioration of cells which suggests a neuroprotective support of gingerol.[8] This study indicates that ginger up-regulates glutathione production in cells, including nerve cells, through anti-oxidative properties which decreases the risk of Alzheimer's in human neuroblastoma cells and mouse hippocampal cells.[8]
While many studies suggest the low risk of using ginger phytochemicals to combat oxidation damage to cells, there are a few studies that suggest potential genotoxic effects. In one study too high of a dose to human hepatoma cells resulted in DNA fragmentation, chromosomal damage and organelle membrane instability which could result in apoptotic behavior.[26] There are some pro-oxidant behaviors to gingerol compounds when the concentration reaches high levels although also considered, in normal conditions these phytochemicals observed have anti-inflammatory and anti-oxidant qualities.[26] In another study [6]-Gingerol notably inhibited the metabolic rate of rats when given an intraperitoneal injection which induced a hypothermic reaction though, when consumed orally in excess there were no changes in body temperature.[27]
Biosynthesis
Both ginger (Zingiber officinale) and turmeric (Curcuma longa) had been suspected to utilize phenylpropanoid pathway and produce putative type III polyketide synthase products based on the research of 6-gingerol biosynthesis by Denniff and Whiting in 1976 [28] and by Schröder's research in 1997.[29] 6-Gingerol is the major gingerol in ginger rhizomes and it possesses some interesting pharmacological activities like analgesic effect. While the biosynthesis of 6-gingerol is not fully elucidated, plausible pathways are presented here.
In the proposed biosynthetic pathway, Scheme 1, L-Phe (1) is used as the starting material. It is converted into Cinnamic acid (2) via phenylalanine ammonia lyase (PAL). Then it is turned into p-Coumaric acid (3) with use of cinnamate 4-hydroxylase (C4H). 4-coumarate:CoA ligase (4CL) is then used to get p-Coumaroyl-CoA (5). P-Coumaroyl shikimate transferase (CST) is the enzyme that is responsible for the bonding of shikimic acid and p-Coumaroyl-CoA. The complexed (5) is then selectively oxidized at C3 by p-coumaroyl 5-O-shikimate 3'-hydroxylase (CS3'H) to alcohol. With another action of CST, shikimate is broken off from this intermediate, thereby yielding Caffeoyl-CoA (7). In order to get desired substitution pattern on the aromatic ring, caffeoyl-CoA O-methyltransferase (CCOMT) converts the hydroxyl group at C3 into methoxy as seen in Feruloyl-CoA (8). Up until this step, according to Ramirez-Ahumada et al., the enzyme activities are very active.[30] It is speculated that some polyketide synthases (PKS) and reductases are involved in final synthesis of 6-Gingerol (10).
Because it is unclear whether the methoxy group addition is performed before or after the condensation step of the polyketide synthase, alternative pathway is shown in Scheme 2, where methoxy group is introduced after PKS activity. In this alternative pathway, the enzymes involved are likely to be cytochrome p450 hydroxylases, and S-adenosyl-L-methionine-dependent O-methyltransferases (OMT).[30] There are three possibilities for the reduction step by Reductase: directly after PKS activity, after PKS and Hydroxylase activity, or in the end after PKS, Hydroxylase, and OMT activity.
References
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- ^ Yin, et al. (17 June 2019). "Structural mechanisms underlying activation of TRPV1 channels by pungent compounds in gingers". British Journal of Pharmacology. 176 (17): 3364–3377. doi:10.1111/bph.14766. PMC 6692589. PMID 31207668.
- ^ NSF International Determination of Gingerols and Shogaols in Zingiber officinale rhizome and powdered extract by High-Performance Liquid Chromatography [full citation needed]
- ^ McGee, Harold (2004). "A survey of tropical spices". McGee on Food and Cooking. Hodder and Stoughton. p. 426. ISBN 0-340-83149-9.
- ^ Zick SM, Djuric Z, Ruffin MT, Litzinger AJ, Normolle DP, Alrawi S, et al. (August 2008). "Pharmacokinetics of 6-gingerol, 8-gingerol, 10-gingerol, and 6-shogaol and conjugate metabolites in healthy human subjects". Cancer Epidemiology, Biomarkers & Prevention. 17 (8): 1930–6. doi:10.1158/1055-9965.EPI-07-2934. PMC 2676573. PMID 18708382.
- ^ Park M, Bae J, Lee DS (November 2008). "Antibacterial activity of [10]-gingerol and [12]-gingerol isolated from ginger rhizome against periodontal bacteria". Phytotherapy Research. 22 (11): 1446–9. doi:10.1002/ptr.2473. PMID 18814211. S2CID 31384218.
- ^ a b c d Ficker C, Smith ML, Akpagana K, Gbeassor M, Zhang J, Durst T, et al. (September 2003). "Bioassay-guided isolation and identification of antifungal compounds from ginger". Phytotherapy Research. 17 (8): 897–902. doi:10.1002/ptr.1335. PMID 13680820. S2CID 4141252.
- ^ a b c Lee C, Park GH, Kim CY, Jang JH (June 2011). "[6]-Gingerol attenuates β-amyloid-induced oxidative cell death via fortifying cellular antioxidant defense system". Food and Chemical Toxicology. 49 (6): 1261–9. doi:10.1016/j.fct.2011.03.005. PMID 21396424.
- ^ Baliga MS, Haniadka R, Pereira MM, D'Souza JJ, Pallaty PL, Bhat HP, Popuri S (July 2011). "Update on the chemopreventive effects of ginger and its phytochemicals". Critical Reviews in Food Science and Nutrition. 51 (6): 499–523. doi:10.1080/10408391003698669. PMID 21929329. S2CID 45531427.
- ^ a b Son MJ, Miura Y, Yagasaki K (August 2015). "Mechanisms for antidiabetic effect of gingerol in cultured cells and obese diabetic model mice". Cytotechnology. 67 (4): 641–52. doi:10.1007/s10616-014-9730-3. PMC 4474985. PMID 24794903.
- ^ a b c Tamrakar AK, Singh AB, Srivastava AK (February 2009). "db/+ Mice as an alternate model in antidiabetic drug discovery research". Archives of Medical Research. 40 (2): 73–8. doi:10.1016/j.arcmed.2008.12.001. PMID 19237015.
- ^ a b El-Bassossy HM, Elberry AA, Ghareib SA, Azhar A, Banjar ZM, Watson ML (September 2016). "Cardioprotection by 6-gingerol in diabetic rats". Biochemical and Biophysical Research Communications. 477 (4): 908–914. doi:10.1016/j.bbrc.2016.06.157. PMID 27378426. S2CID 205946473.
- ^ a b Wei QY, Ma JP, Cai YJ, Yang L, Liu ZL (November 2005). "Cytotoxic and apoptotic activities of diarylheptanoids and gingerol-related compounds from the rhizome of Chinese ginger". Journal of Ethnopharmacology. 102 (2): 177–84. doi:10.1016/j.jep.2005.05.043. PMID 16024193.
- ^ a b c Salehi B, Fokou PV, Yamthe LR, Tali BT, Adetunji CO, Rahavian A, et al. (June 2019). "Phytochemicals in Prostate Cancer: From Bioactive Molecules to Upcoming Therapeutic Agents". Nutrients. 11 (7): 1483. doi:10.3390/nu11071483. PMC 6683070. PMID 31261861.
- ^ a b c d Lee HS, Seo EY, Kang NE, Kim WK (May 2008). "[6]-Gingerol inhibits metastasis of MDA-MB-231 human breast cancer cells". The Journal of Nutritional Biochemistry. 19 (5): 313–9. doi:10.1016/j.jnutbio.2007.05.008. PMID 17683926.
- ^ a b Bode AM, Ma WY, Surh YJ, Dong Z (February 2001). "Inhibition of epidermal growth factor-induced cell transformation and activator protein 1 activation by [6]-gingerol". Cancer Research. 61 (3): 850–3. PMID 11221868.
- ^ a b Rhode J, Fogoros S, Zick S, Wahl H, Griffith KA, Huang J, Liu JR (December 2007). "Ginger inhibits cell growth and modulates angiogenic factors in ovarian cancer cells". BMC Complementary and Alternative Medicine. 7 (1): 44. doi:10.1186/1472-6882-7-44. PMC 2241638. PMID 18096028.
- ^ Semwal RB, Semwal DK, Combrinck S, Viljoen AM (September 2015). "Gingerols and shogaols: Important nutraceutical principles from ginger". Phytochemistry. 117: 554–568. doi:10.1016/j.phytochem.2015.07.012. PMID 26228533.
- ^ a b Park YJ, Wen J, Bang S, Park SW, Song SY (October 2006). "[6]-Gingerol induces cell cycle arrest and cell death of mutant p53-expressing pancreatic cancer cells". Yonsei Medical Journal. 47 (5): 688–97. doi:10.3349/ymj.2006.47.5.688. PMC 2687755. PMID 17066513.
- ^ a b Lee SH, Cekanova M, Baek SJ (March 2008). "Multiple mechanisms are involved in 6-gingerol-induced cell growth arrest and apoptosis in human colorectal cancer cells". Molecular Carcinogenesis. 47 (3): 197–208. doi:10.1002/mc.20374. PMC 2430145. PMID 18058799.
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- ^ a b c Dugasani S, Pichika MR, Nadarajah VD, Balijepalli MK, Tandra S, Korlakunta JN (February 2010). "Comparative antioxidant and anti-inflammatory effects of [6]-gingerol, [8]-gingerol, [10]-gingerol and [6]-shogaol". Journal of Ethnopharmacology. 127 (2): 515–20. doi:10.1016/j.jep.2009.10.004. PMID 19833188.
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- ^ Mao, Qian-Qian; Xu, Xiao-Yu; Cao, Shi-Yu; Gan, Ren-You; Corke, Harold; Beta, Trust; Li, Hua-Bin (June 2019). "Bioactive Compounds and Bioactivities of Ginger (Zingiber officinale Roscoe)". Foods. 8 (6): 185. doi:10.3390/foods8060185. PMC 6616534. PMID 31151279.
- ^ a b Kuhad A, Tirkey N, Pilkhwal S, Chopra K (2006). "6-Gingerol prevents cisplatin-induced acute renal failure in rats". BioFactors. 26 (3): 189–200. doi:10.1002/biof.5520260304. PMID 16971750. S2CID 21531335.
- ^ a b Yang G, Zhong L, Jiang L, Geng C, Cao J, Sun X, Ma Y (April 2010). "Genotoxic effect of 6-gingerol on human hepatoma G2 cells". Chemico-Biological Interactions. 185 (1): 12–7. doi:10.1016/j.cbi.2010.02.017. PMID 20167213.
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- ^ Denniff, Phillip; Whiting, Donald A. (1976). "Biosynthesis of [6]-gingerol, pungent principle of Zingiber officinale". Journal of the Chemical Society, Chemical Communications (18): 711. doi:10.1039/C39760000711.
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- ^ a b Ramirez-Ahumada M, Timmermann BN, Gang DR (September 2006). "Biosynthesis of curcuminoids and gingerols in turmeric (Curcuma longa) and ginger (Zingiber officinale): identification of curcuminoid synthase and hydroxycinnamoyl-CoA thioesterases". Phytochemistry. 67 (18): 2017–29. doi:10.1016/j.phytochem.2006.06.028. PMID 16890967.
External links
Notes
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