Cafestol

Cafestol
Names
	IUPAC name 3,18-(Epoxymetheno)-19-nor-5β,8α,9β,10α,13β,16β-kaur-3-ene-16α,17-diol
	Systematic IUPAC name (3bS,5aS,7R,8R,10aR,10bS)-7-(Hydroxymethyl)-10b-methyl-3b,4,5,6,7,8,9,10,10a,10b,11,12-dodecahydro-5a,8-methanocyclohepta[5,6]naphtho[2,1-b]furan-7-ol
Identifiers
CAS Number	469-83-0;
3D model (JSmol)	Interactive image;
ChEBI	CHEBI:3291;
ChemSpider	10289419;
KEGG	C09066;
PubChem CID	108052;
UNII	AC465T6Q6W;
CompTox Dashboard (EPA)	DTXSID3040986 ;
	InChI InChI=1/C20H28O3/c1-18-7-5-16-14(6-9-23-16)15(18)4-8-19-10-13(2-3-17(18)19)20(22,11-19)12-21/h6,9,13,15,17,21-22H,2-5,7-8,10-12H2,1H3/t13?,15-,17+,18-,19+,20+/m1/s1 Key: DNJVYWXIDISQRD-GTATUSGQBK;
	SMILES OC[C@@]5(O)C[C@@]31C[C@@H]5CC[C@H]1[C@]4(C)CCc2occc2[C@H]4CC3;
Properties
Chemical formula	C20H28O3
Molar mass	316.441 g·mol−1
Melting point	158 to 162 °C (316 to 324 °F; 431 to 435 K)
	Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa). Infobox references

Cafestol is a diterpenoid molecule present in coffee beans. It is one of the compounds that may be responsible for proposed biological and pharmacological effects of coffee.^[1]

Sources

A typical bean of Coffea arabica contains about 0.4% to 0.7% cafestol by weight.^[2] Cafestol is present in highest quantity in unfiltered coffee drinks such as French press coffee, Turkish coffee or Greek coffee. In paper-filtered coffee drinks such as drip brewed coffee, it is present in only negligible amounts, as the paper filter in drip filtered coffee retains the diterpenes.^[3]

Research into biological activity

Coffee consumption has been associated with a number of effects on health and cafestol has been proposed to produce these through a number of biological actions.^[4] Studies have shown that regular consumption of boiled coffee increases serum cholesterol whereas filtered coffee does not.^[5] Cafestol may act as an agonist ligand for the nuclear receptor farnesoid X receptor and pregnane X receptor, blocking cholesterol homeostasis. Thus cafestol can increase cholesterol synthesis.^[6]

Cafestol has also shown anticarcinogenic properties in rats.^[7]

Cafestol also has neuroprotective effects in a Drosophila fruit fly model of Parkinson's disease.^[8]^[9]

References

^ Ludwig, I. A.; Clifford, M. N.; Lean, M. E.; Ashihara, H.; Crozier, A. (August 2014). "Coffee: biochemistry and potential impact on health". Food & Function. 5 (8): 1695–1717. doi:10.1039/c4fo00042k. PMID 24671262. S2CID 29389074.
^ Kitzberger, C.; Scholz, M.; Benassi, M. (2014). "Bioactive compounds content in roasted coffee from traditional and modern Coffea arabica cultivars grown under the same edapho-climatic conditions". Food Research International. 61: 61–66. doi:10.1016/j.foodres.2014.04.031.
^ Zhang, C.; Linforth, R.; Fisk, I. D. (2012). "Cafestol extraction yield from different coffee brew mechanisms". Food Research International. 49: 27–31. doi:10.1016/j.foodres.2012.06.032.
^ Higdon, J. V.; Frei, B. (2006). "Coffee and health: a review of recent human research". Critical Reviews in Food Science and Nutrition. 46 (2): 101–123. doi:10.1080/10408390500400009. PMID 16507475.
^ Urgert, R.; Katan, M. B. (1997). "The cholesterol-raising factor from coffee beans". Annual Review of Nutrition. 17: 305–324. doi:10.1146/annurev.nutr.17.1.305. PMC 1295997. PMID 9240930.
^ Ricketts, M. L.; Boekschoten, M. V.; Kreeft, A. J.; Hooiveld, G. J.; Moen, C. J.; Müller, M.; Frants, R. R.; Kasanmoentalib, S.; Post, S. M.; Princen, H. M.; Porter, J. G.; Katan, M. B.; Hofker, M. H.; Moore, D. D. (2007). "The cholesterol-raising factor from coffee beans, cafestol, as an agonist ligand for the farnesoid and pregnane X receptors". Molecular Endocrinology. 21 (7): 1603–1616. doi:10.1210/me.2007-0133. PMID 17456796.
^ National Toxicology Program (October 1999). "Cafestol (CASRN 469-83-0) and Kahweol (CASRN 6894-43-5) — Review of Toxicological Literature" (PDF). Archived from the original (PDF) on November 1, 2004.
^ Trinh, K.; Andrews, L.; Krause, J.; Hanak, T.; Lee, D.; Gelb, M.; Pallanck, L. (April 2010). "Decaffeinated coffee and nicotine-free tobacco provide neuroprotection in Drosophila models of Parkinson's disease through an NRF2-dependent mechanism". The Journal of Neuroscience. 30 (16): 5525–5532. doi:10.1523/JNEUROSCI.4777-09.2010. PMC 3842467. PMID 20410106.
^ Callaway, E. (April 23, 2010). "Parkinson's protection without caffeine or nicotine". New Scientist.

[PMID24671262-1] Ludwig, I. A.; Clifford, M. N.; Lean, M. E.; Ashihara, H.; Crozier, A. (August 2014). "Coffee: biochemistry and potential impact on health". Food & Function. 5 (8): 1695–1717. doi:10.1039/c4fo00042k. PMID 24671262. S2CID 29389074.

[2] Kitzberger, C.; Scholz, M.; Benassi, M. (2014). "Bioactive compounds content in roasted coffee from traditional and modern Coffea arabica cultivars grown under the same edapho-climatic conditions". Food Research International. 61: 61–66. doi:10.1016/j.foodres.2014.04.031.

[3] Zhang, C.; Linforth, R.; Fisk, I. D. (2012). "Cafestol extraction yield from different coffee brew mechanisms". Food Research International. 49: 27–31. doi:10.1016/j.foodres.2012.06.032.

[4] Higdon, J. V.; Frei, B. (2006). "Coffee and health: a review of recent human research". Critical Reviews in Food Science and Nutrition. 46 (2): 101–123. doi:10.1080/10408390500400009. PMID 16507475.

[5] Urgert, R.; Katan, M. B. (1997). "The cholesterol-raising factor from coffee beans". Annual Review of Nutrition. 17: 305–324. doi:10.1146/annurev.nutr.17.1.305. PMC 1295997. PMID 9240930.

[pmid17456796-6] Ricketts, M. L.; Boekschoten, M. V.; Kreeft, A. J.; Hooiveld, G. J.; Moen, C. J.; Müller, M.; Frants, R. R.; Kasanmoentalib, S.; Post, S. M.; Princen, H. M.; Porter, J. G.; Katan, M. B.; Hofker, M. H.; Moore, D. D. (2007). "The cholesterol-raising factor from coffee beans, cafestol, as an agonist ligand for the farnesoid and pregnane X receptors". Molecular Endocrinology. 21 (7): 1603–1616. doi:10.1210/me.2007-0133. PMID 17456796.

[ntp-7] National Toxicology Program (October 1999). "Cafestol (CASRN 469-83-0) and Kahweol (CASRN 6894-43-5) — Review of Toxicological Literature" (PDF). Archived from the original (PDF) on November 1, 2004.

[pmid20410106-8] Trinh, K.; Andrews, L.; Krause, J.; Hanak, T.; Lee, D.; Gelb, M.; Pallanck, L. (April 2010). "Decaffeinated coffee and nicotine-free tobacco provide neuroprotection in Drosophila models of Parkinson's disease through an NRF2-dependent mechanism". The Journal of Neuroscience. 30 (16): 5525–5532. doi:10.1523/JNEUROSCI.4777-09.2010. PMC 3842467. PMID 20410106.

[9] Callaway, E. (April 23, 2010). "Parkinson's protection without caffeine or nicotine". New Scientist.

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Components	Cafestol Caffeic acid Caffeine Coffee bean Furan-2-ylmethanethiol Kahweol
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v t e FXRTooltip Farnesoid X receptor and LXRTooltip liver X receptor modulators
FXRTooltip Farnesoid X receptor	Agonists: Bile acids Cafestol Chenodeoxycholic acid Cilofexor Fexaramine GW-4064 Ivermectin Nidufexor Obeticholic acid Tropifexor Antagonists: Guggulsterone
LXRTooltip Liver X receptor	Agonists: 22R-Hydroxycholesterol 24S-Hydroxycholesterol 27-Hydroxycholesterol Abequolixron Cholestenoic acid DMHCA GW-3965 Hypocholamide T-0901317 Antagonists: Efavirenz Larsucosterol
See also Receptor/signaling modulators

v t e Xenobiotic-sensing receptor modulators
CARTooltip Constitutive androstane receptor	Agonists: 6,7-Dimethylesculetin Amiodarone Artemisinin Benfuracarb Carbamazepine Carvedilol Chlorpromazine Chrysin CITCO Clotrimazole Cyclophosphamide Cypermethrin DHEA (prasterone) Efavirenz Ellagic acid Griseofulvin Methoxychlor Mifepristone Nefazodone Nevirapine Nicardipine Octicizer Permethrin Phenobarbital Phenytoin Pregnanedione (5β-dihydroprogesterone) Reserpine TCPOBOP Telmisartan Tolnaftate Troglitazone Valproic acid Antagonists: 3,17β-Estradiol 3α-Androstanol 3α-Androstenol 3β-Androstanol 17-Androstanol AITC Ethinylestradiol Meclizine Nigramide J Okadaic acid PK-11195 S-07662 T-0901317
PXRTooltip Pregnane X receptor	Agonists: 17α-Hydroxypregnenolone 17α-Hydroxyprogesterone Δ⁴-Androstenedione Δ⁵-Androstenediol Δ⁵-Androstenedione AA-861 Allopregnanediol Allopregnanedione (5α-dihydroprogesterone) Allopregnanolone (brexanolone) Alpha-Lipoic acid Ambrisentan AMI-193 Amlodipine besylate Antimycotics Artemisinin Aurothioglucose Bile acids Bithionol Bosentan Bumecaine Cafestol Cephaloridine Cephradine Chlorpromazine Ciglitazone Clindamycin Clofenvinfos Chloroxine Clotrimazole Colforsin Corticosterone Cyclophosphamide Cyproterone acetate Demecolcine Dexamethasone DHEA (prasterone) DHEA-S (prasterone sulfate) Dibunate sodium Diclazuril Dicloxacillin Dimercaprol Dinaline Docetaxel Docusate calcium Dodecylbenzenesulfonic acid Dronabinol Droxidopa Eburnamonine Ecopipam Enzacamene Epothilone B Erythromycin Famprofazone Febantel Felodipine Fenbendazole Fentanyl Flucloxacillin Fluorometholone Griseofulvin Guggulsterone Haloprogin Hetacillin potassium Hyperforin Hypericum perforatum (St John's wort) Indinavir sulfate Lasalocid sodium Levothyroxine Linolenic acid: α-Linolenic acid and γ-linolenic acid LOE-908 Loratadine Lovastatin Meclizine Metacycline Methylprednisolone Metyrapone Mevastatin Mifepristone Nafcillin Nicardipine Nicotine Nifedipine Nilvadipine Nisoldipine Norelgestromin Omeprazole Orlistat Oxatomide Paclitaxel Phenobarbital Piperine Plicamycin Prednisolone Pregnanediol Pregnanedione (5β-dihydroprogesterone) Pregnanolone Pregnenolone Pregnenolone 16α-carbonitrile Proadifen Progesterone Quingestrone Reserpine Reverse triiodothyronine Rifampicin Rifaximin Rimexolone Riodipine Ritonavir Simvastatin Sirolimus Spironolactone Spiroxatrine SR-12813 Suberoylanilide Sulfisoxazole Suramin Tacrolimus Tenylidone Terconazole Testosterone isocaproate Tetracycline Thiamylal sodium Thiothixene Thonzonium bromide Tianeptine Troglitazone Troleandomycin Tropanyl 3,5-dimethulbenzoate Zafirlukast Zeranol Antagonists: Ketoconazole Sesamin
See also Receptor/signaling modulators

Sources

Research into biological activity

See also

References