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=={{Bilingual|利用効率|Bioavailability}}== | =={{Bilingual|利用効率|Bioavailability}}== | ||
+ | {| class ="wikitable" | ||
+ | ! Flavonoid || Dose || Observation | ||
+ | |- | ||
+ | | catechin<ref>Das NP (1971) ''Biochem Pharmacol'' 20, 3435-3445</ref> || 5.8 g || 26% was excreted within 24h. ''m''-hydroxyphenyl propionic acid was detected in plasma after 6h | ||
+ | |- | ||
+ | | 3-O-methyl-catechin<ref>Hackett AM, Griffiths LA, Wermeille M (1985) ''Xenobiotica'' 15, 907-914</ref> || 2 g || plasma level 11-18 ug/ml within 2h; 38% was excreted as glucuronides and sulphates in urine within 120h | ||
+ | |- | ||
+ | | quercetin<ref>Hollman PCH et al (1995) ''Am J Clin Nutr'' 62, 1276-1282; Hollman PCH et al (1996) ''Free Rad Biol Med'' 21, 703-707</ref> || 64 mg (as fried onion) || plasma level 1 uM, 2h later | ||
+ | |- | ||
+ | | quercetin<ref>Gugler R, Leshik M, Dengler HV (1975) ''Eur J Clin Pharmacol'' 9, 229-234</ref> || 4 g (as supplement) || undetected in urine or plasma | ||
+ | |- | ||
+ | | decaffeinated green tea<ref>Lee MT et al (1995) ''Cancer Epidemiol Biomarkers Prev'' 41,393-399</ref> || 88 mg EGCG, 82 mg EGC, 33 mg ECG, and 32 mg EC || plasma level 46-268 ng/ml, 82-206 ng/ml, undetected, and 40-80 ng/ml, respectively. | ||
+ | |} | ||
+ | |||
; Isoflavones | ; Isoflavones | ||
Isoflavones are efficiently absorbed from the colon and exhibit the highest bioavailability. (Usually polyphenols absorbed from the colon show very low availability.) Daidzein and genistein are known to form chlorinated products (e.g. 3- and 8-chlorodaidzein), then are conjugated with glucuronides and excreted in bile. | Isoflavones are efficiently absorbed from the colon and exhibit the highest bioavailability. (Usually polyphenols absorbed from the colon show very low availability.) Daidzein and genistein are known to form chlorinated products (e.g. 3- and 8-chlorodaidzein), then are conjugated with glucuronides and excreted in bile. | ||
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During absorption, polyphenols are metabolized to form β-glucuronide and sulfate conjugates (phase II conjugation in the intestinal wall), and catechol units are methylated. C-glycosides such as puerarin remain stable and not conjugated. These metabolized forms show markedly different bioactivities from their aglycones. | During absorption, polyphenols are metabolized to form β-glucuronide and sulfate conjugates (phase II conjugation in the intestinal wall), and catechol units are methylated. C-glycosides such as puerarin remain stable and not conjugated. These metabolized forms show markedly different bioactivities from their aglycones. | ||
+ | |||
+ | <references/> | ||
=={{Bilingual|代表例|Representative Names}}== | =={{Bilingual|代表例|Representative Names}}== |
Revision as of 09:00, 18 September 2010
Flavonoid
Flavonoid Top | Molecule Index | Author Index | Journals | Structure Search | Food | New Input |
Contents |
Class Overview
The word "flavonoid" comes from its Latin origin flavus (yellow) with oid, meaning yellow-ish. It comes from its history as yellow natural dye (quercetin and kaempferol are the most widespread flavone dyes. See flavone).
Chemically speaking, it is a class of plant secondary metabolites that have two benzene rings (each called A-ring and B-ring) connected by a chain of three carbons (Figure 1).
The carbon chain, corresponding to the numbers 2,3,4 in Figure 1, is linked to a hydroxyl group in the A-ring to form the C-ring. The class of flavonoids are usually determined by the modification pattern of the C-ring (Table 1).
Flavonoid is utilized in many industrial processes from pigments to food additives. Often heard names include anthocyanin, catechin, flavan, and isoflavone.
Biosynthesis
Flavonoid is synthesized through both the phenylpropanoid-acetate pathway and the acetate-malonate pathway in all higher plants (but not algae). Most plants contain the 7 major subgroups (chalcones, flavanones, flavones, flavonols, flavans, anthocyanidins, and anthycyanins), but aurones or isoflavonoids are not ubiquitous.
4-coumaroyl CoA + malonyl CoA | ||||||||||||||||
CHS | ||||||||||||||||
CHALCONES, AURONES |
chalconaringenin |
FLAVONES | ||||||||||||||
CHI (isomerase) | FS (oxygenase) | |||||||||||||||
IFS |
naringenin FLAVANONE |
kaempferol |
FLAVONOLS |
quercetin |
myricetin | |||||||||||
ISO-FLAVONES |
F3H (hydroxylase) | FLS (oxygenase) | FLS | FLS | ||||||||||||
DIHYDRO FLAVONOLS |
dihydro-kaempferol |
F3'H +OH in B-ring |
dihydro-quercetin |
F3'5'H +OH in B-ring |
dihydro-myricetin | |||||||||||
DFR (reductase) | DFR | DFR | ||||||||||||||
flavan diol LEUCOANTHO-CYANIDINS |
leuco-pelargonidin |
|
leuco-cyanidin |
LAR | leuco-delphinidin |
LAR | ||||||||||
LDOX (oxygenase) | PROANTHO- CYANIDINS * | LDOX | PROANTHO- CYANIDINS * | LDOX | *...polymers of flavanols | |||||||||||
ANTHO-CYANIDINS |
pelargonidin |
ANR | cyanidin |
ANR | delphinidin |
ANR | ||||||||||
UF3GT (+sugar) | epi-afzelechin |
UF3GT | epi-catechin |
UF3GT | epigallo-catechin |
FLAVAN 3-OLS | ||||||||||
ANTHO-CYANINS |
pelargonidin 3-glucoside |
cyanidin 3-glucoside |
delphinidin 3-glucoside | |||||||||||||
|
|
|
Information for the Above Abbreviated Gene Names | |||
---|---|---|---|
Six Structural Genes | |||
Abbrev. | Name | Origin | Information |
CHS | chalcone synthase | Bacterial polyketide synthases, particularly those in fatty acid synthesis (Verwoert et al. 1992) | Early response against light [1] [2] |
CHI | chalcone-flavanone isomerase | Unclear and unique to plants.[3]
Eubacterium ramulus has the CHI activity. [4] |
Early response against light. |
F3H | flavanone 3-hydroxylase | 2-oxoglutarate-dependent dioxygenase family [5] | Early response in Arabidopsis but late in Antirrhinum [6] |
FLS | flavonol synthase | 2-oxoglutarate-dependent dioxygenase family [7] | Early response against light. In Arabidopsis, all structural genes are single-copy except for this one, to which six genes exist and two of them are not expressed. |
DFR | dihydroflavonol 4-reductase | NADPH-dependent reductase associated with steroid metabolism [8] | Later response |
ANS/LDOX | anthocyanidin synthase or leucoanthocyanidin dioxygenase | 2-oxoglutarate-dependent dioxygenase family | Later response |
Auxiliary Genes | |||
F3'H | flavonoid 3'-hydroxylase | cytochrome P450 hydroxylase family [9] | |
F3'5'H | flavonoid 3',5'-hydroxylase | cytochrome P450 hydroxylase family [10] | Not reported in mosses or liverworts. The transformation of the F3'5'H and the cytochrome b5 gene of petunia into carnation changed its flower color deep purple.[11][12] |
FSI | flavone synthase | Dioxygenase in parsley (FSI) and P450 monooxygenase in snapdragon (FSII). | |
LAR (or LCR) | leucoanthocyanidin reductase | ||
UF3GT | UDP flavonoid glucosyltransferase | ||
GST | glutathione-S-transferase | Transport of flavonoids from cytoplasm to vacuole or cell walls requires both GST and the glutathione pump in ATP-binding cassette family.[13][14] | |
AOMT | anthocyanin O-methyl transferase | ||
|
Bioactivity
Tea Related
- Tea category 茶の種類
- Tea consumption 茶の消費量
- Tea and health 茶と健康
General Flavonoid
- All flavonoids
Not only anthocyanins but even simple structures such as chalcone can absorb UV wavelengths strongly. The ability of photoprotection is derived from its anti-oxidative activity. For example, quercetin is a more effective photoprotectant and anti-oxidant than kaempferol. [1] [2]
- ↑ Ryan KG, Swinny EE, Markham KR, Winefield C (2002) "Flavonoid gene expression and UV photoprotection in transgenic and mutant Penunia leaves" Phytochem 59:23-32 PMID 11754940
- ↑ Li J, Ou-Lee T-M, Raba R, Amundson RG, Last RL (1993) "Arabidopsis flavonoid mutants are hypersensitive to UV-B irradiation" Plant Cell 5: 171-179 PMID 12271060
Flavanols
Quercetin in onions and flavanols in cocoa are said to reduce blood pressure in hypertensive animals [1], but their effect or mechanism is not clinically conclusive.
- ↑ Hooper L, Kroon PA, Rimm EB, et al. (2008) "Flavonoids, flavonoid-rich foods, and cardiovascular risk: a meta-analysis of randomized controlled trials" Am J Clin Nutr 88:38–50 PMID 18614722
Tannins (proanthocyanidins) anti-bacteria, anti-fungi
Bioavailability
Flavonoid | Dose | Observation |
---|---|---|
catechin[1] | 5.8 g | 26% was excreted within 24h. m-hydroxyphenyl propionic acid was detected in plasma after 6h |
3-O-methyl-catechin[2] | 2 g | plasma level 11-18 ug/ml within 2h; 38% was excreted as glucuronides and sulphates in urine within 120h |
quercetin[3] | 64 mg (as fried onion) | plasma level 1 uM, 2h later |
quercetin[4] | 4 g (as supplement) | undetected in urine or plasma |
decaffeinated green tea[5] | 88 mg EGCG, 82 mg EGC, 33 mg ECG, and 32 mg EC | plasma level 46-268 ng/ml, 82-206 ng/ml, undetected, and 40-80 ng/ml, respectively. |
- Isoflavones
Isoflavones are efficiently absorbed from the colon and exhibit the highest bioavailability. (Usually polyphenols absorbed from the colon show very low availability.) Daidzein and genistein are known to form chlorinated products (e.g. 3- and 8-chlorodaidzein), then are conjugated with glucuronides and excreted in bile.
- Anthocyanins
Although anthocyanins comprise ca. 50% of total polyphenols, they are poorly available (less than 1% of intake in urinary levels). Anthocyanins are absorbed from the stomach, and their glycosides appear in plasma soon after the intake. In blood, only anthocyanins exist in a non-conjugated form.
- Flavan
Flavan 3-ols and phenolic acids are efficiently abosrbed from the small instestine, a few hours after intake.
- Others
Non-absorbed flavonoids are transported to the colon, and subjected to metabolism by microbiota. These flavonoids are therefore absorbed much less compared to flavan 3-ols and phenolic acids. Esterification of phenolic acids (e.g. chlorogenic acid), however, reduces absorption.
During absorption, polyphenols are metabolized to form β-glucuronide and sulfate conjugates (phase II conjugation in the intestinal wall), and catechol units are methylated. C-glycosides such as puerarin remain stable and not conjugated. These metabolized forms show markedly different bioactivities from their aglycones.
- ↑ Das NP (1971) Biochem Pharmacol 20, 3435-3445
- ↑ Hackett AM, Griffiths LA, Wermeille M (1985) Xenobiotica 15, 907-914
- ↑ Hollman PCH et al (1995) Am J Clin Nutr 62, 1276-1282; Hollman PCH et al (1996) Free Rad Biol Med 21, 703-707
- ↑ Gugler R, Leshik M, Dengler HV (1975) Eur J Clin Pharmacol 9, 229-234
- ↑ Lee MT et al (1995) Cancer Epidemiol Biomarkers Prev 41,393-399
Representative Names
- isoflavonoid in beans (豆のイソフラボン)
- anthocyanin in berries (ベリーのアントシアニン)
- catechin in tea (お茶のカテキン)
- rutin in buckwheat (ソバのルチン)
- hesperidin in orange (ミカンのヘスペリジン)
- naringenin chalcone in tomato (トマトのナリンゲニンカルコン)
Database statistics/ranking
This database collects original references that report identification of flavonoid in various plant species. The database consists of three major namespaces: (flavonoid) compounds, plant species, and references. Currently, 6961 flavonoid structures, 3961 plant species, and 5215 references describing total 19861 metabolite-species relationships are registered.
class | FL1 (chalcones) |
FL2 (flavanones) |
FL3 (flavones) |
FL4 (dihydroflavonols) |
FL5 (flavonols) |
FL6 (flavans) |
FL7 (anthocyanidins) |
FLI (isoflavonoids) |
FLN (neoflavonoids) |
Total |
---|---|---|---|---|---|---|---|---|---|---|
#data | 690 | 705 | 1479 | 272 | 1943 | 291 | 574 | 916 | 96 | 6961 |
Flavonoid content in food
The daily intake of polyphenols from plant foods is considered about 1000 mg/day.
Category | Flavonol | Flavone | Flavan | Flavanone |
---|---|---|---|---|
Names | quercetin, kampferol, myricetin, isorhamnetin | apigenin, luteolin | catechin, epicatechin | |
broccoli ブロッコリ | Δ | |||
celery セロリ | ΔΔ | |||
fava そら豆 | ΔΔ | |||
hot pepper とうがらし | ΔΔ | |||
onion たまねぎ | ΔΔ (Δ) | |||
parsley パセリ | ΔΔΔ | |||
peppermint ペパーミント | ΔΔ | |||
spinach ほうれん草 | Δ | |||
thyme タイム | ΔΔΔ | |||
watercress クレソン | Δ | |||
dill, fennel ディル, フェンネル | ΔΔΔ |
Δ 5 to <10 mg/100 g; ΔΔ 10 to <50 mg/100 g; ΔΔΔ 50< mg/100 g
The following vegetables and herbs have flavonoid contents less than 5 mg/100 g: beets, kidney beans, snap beans, cabbage, carrot, cauliflower, cucumber, endive, gourd, leek, lettuce, green peas, sweet pepper, potato, radish, tomato, oregano, perrilla, rosemary
Design of Flavonoid ID numbers
12-DIGIT
F | L | x | x | y | y | z | z | w | c | c | c |
- x ... backbone structure (母核構造)
FL1 aurone and chalcone; FL2 flavanone; FL3 flavone; FL4 Dihydroflavonol; FL5 Flavonol; FL6 Flavan; FL7 Anthocyanin; FLI Isoflavonoid; FLN Neoflavonoid
- y ... hydroxylation pattern in A and B ring (水酸基パターン)
Click above categories to see details. General description is here.
- z ... glycosylation pattern (糖修飾パターン)
Click above categories to see details. General description is here.
- w ... halogenation etc. (ハロゲン等)
Currently unused.
- c ... serial number (通し番号)
For Users of Flavonoid Viewer
The flavonoid IDs used in this site is the same as those in Flavonoid Viewer in metabolome.jp except for the following FL7 category.
Anthocyanin glycosylated with other than glucose and galactose | ||
---|---|---|
Flavonoid Viewer FL7A..GS |
→ | This site FL7A..GO |
Subcategories
This category has the following 10 subcategories, out of 10 total.