Accumulation of quercetin conjugates in blood plasma after the short-term ingestion of onion by women

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Accumulation of quercetin conjugates in blood plasma after the short-term ingestion of onion by women

Jae-Hak Moon¹, Ritsuko Nakata², Syunji Oshima³, Takahiro Inakuma³, and Junji Terao¹

¹ Department of Nutrition, School of Medicine, The University of Tokushima, Tokushima 770-8503; ² Department of Nursing, School of Medical Sciences, The University of Tokushima, Tokushima 770-8509; and ³ Kagome Research Institute, Kagome Company, Nishinasuno, Tochigi 329-2762, Japan

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Quercetin is a typical flavonoid present mostly as glycosides in plant foods; it has attracted much attention for its potentialbeneficial effects in disease prevention. In this study, we examinedhuman volunteers after the short-term ingestion of onion, a vegetablerich in quercetin glucosides. The subjects were served diets containingonion slices (quercetin equivalent: 67.6-93.6 mg/day) with mealsfor 1 wk. Quercetin was only found in glucuronidase-sulfatase-treatedplasma, and its concentration after 10 h of fasting increasedfrom 0.04 ± 0.04 µM before the trial to 0.63 ± 0.72 µM after the1-wk trial. The quercetin content in low-density lipoprotein (LDL)after glucuronidase-sulfatase treatment corresponded to <1% ofthe $alpha$ -tocopherol content. Human LDL isolated from the plasma afterthe trial showed little improvement of its resistance to copperion-induced oxidation. It is therefore concluded that conjugatedmetabolites of quercetin accumulate exclusively in human bloodplasma in the concentration range of 10⁷ ~ 10⁶ M after the short-term ingestion of vegetables rich in quercetinglucosides, although these metabolites are hardly incorporatedinto plasmaLDL.

quercetin metabolites; quercetin glycosides; low-density lipoprotein oxidation; glucuronidation

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

QUERCETIN IS ONE OF THE ABUNDANT flavonol-type flavonoids, commonly found in vegetables and fruits (12, 15). The averagedaily intake of flavonoids, including three flavonol-type flavonoids(quercetin, myricetin, kaempferol) and two flavone-type flavonoids(luteolin, apigenin), was estimated to be 25 mg/person, with quercetinas the mostly consumed of these five flavonoids (16). Interestin quercetin was increased by the finding that quercetin was mutagenicin the Ames and other short-term tests (2, 36). However,in recent years, quercetin and other flavonoids have attractedrenewed attention for their potential beneficial effects in diseaseprevention (8, 13, 34). In particular, epidemiologicalstudies have demonstrated an inverse relationship between theintake of flavonoids, including quercetin, and coronary heartdisease risk (14, 22). The antioxidant activity of flavonoidshas frequently been mentioned in connection with their physiologicalfunction in the cardiovascular system (24), because oxidativemodification of plasma low-density lipoprotein (LDL) is stronglysuggested to participate in the initial event of atherosclerosisleading to coronary heart disease (35). Considerable studies(6, 11, 26, 33, 43) have shown that quercetin and itsrelated flavonoids can prevent oxidation of LDL by scavengingreactive oxygen radicals (ROS), chelating iron, which is responsiblefor the generation of ROS, or inhibiting lipoxygenase. However,the in vivo function of dietary flavonoids cannot be determinedwithout an understanding of their absorption and metabolicfate.

Gugler et al. (10) found that <1% of quercetin was absorbed into the human body after the oral administration of quercetinaglycone. Ueno et al. (41) demonstrated that 20% of quercetinwas absorbed from the digestive tract and detected in bile andurine as glucuronide and sulfate conjugates within 48 h afteroral administration to rats. We previously suggested that theefficiency of intestinal absorption of quercetin in rats is stronglyaffected by its solubility in vehicles (31). Quercetin is mostlypresent in the form of glycosides in vegetables and fruits, anddietary glycosides were believed to be converted to the respectiveaglycones in the large intestine by the glycosidase activity ofintestinal bacteria (37). It was recently reported that thehuman small intestine possesses an ability to liberate the aglyconefrom quercetin glycosides (7). Nevertheless, Paganga and Rice-Evans(29) and Aziz et al. (1) reported that quercetin glucosidesare present in human plasma without metabolic conversion. Hollmanet al. (17, 19) studied the absorption and accumulation ofquercetin glucosides in humans using onion as a dietary sourceof quercetin glycosides, and they claimed that quercetin glucosidesare absorbed more easily than quercetin aglycone. However, Manachet al. (25) suspected that intact quercetin glucosides are presentin blood circulation without metabolic conversion. Their suggestionswere based on a human volunteer study that found that quercetinconjugates, not glucosides, accumulated in the plasma after asingle ingestion of quercetin glucoside-rich food (23).

The aim of the present study was to clarify whether quercetin glucosides accumulate in human plasma after periodic ingestionof vegetables rich in quercetin glucosides. Onion was used asa dietary source rich in quercetin. The accumulation of quercetinin blood plasma and its distribution to plasma LDL were investigatedafter short-term ingestion of onion in female volunteers. By usingHPLC analysis of nonhydrolyzed extracts, we show that quercetinconjugates, not glucosides, accumulated in blood plasma aftershort-term ingestion of quercetin glucosides from thediet.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Chemicals. Quercetin and sulfatase type H-5 (from Helix pomatia, EC 3.1.6.1) were supplied by Sigma Chemical (St. Louis, MO). Quercetin3,4'-di-O- $beta$ -glucoside (Q3,4'G) and quercetin 4'-O- $beta$ -glucoside(Q4'G) were kindly supplied by Dr. T. Tsushida of the NationalFood Research Institute, Japan. Quercetin 3-O- $beta$ -glucoside (Q3G)was purchased from Funakoshi (Tokyo, Japan). Diethylenetriaminepentaaceticacid (DTPA), EDTA, and 3,5-di-tert-butyl-4-hydroxytoluene (BHT)were obtained from Nacalai Tesque (Kyoto, Japan). N,O-bis(trimethylsilyl)acetamidewas purchased from Tokyo Kasei (Tokyo, Japan). All other chemicalsand solvents were of analyticgrade.

Human study. Seven volunteers (women, 20 ~ 21 yr of age) participated in the study. They were healthy, not on any medication, and providedinformed consent. Cooked onion slices were obtained from a localmarket. The subjects were freely served diet containing onionslices three times a day (260 ~ 360 g/day) for 1 wk. Before andafter the trial, blood was collected from each subject after fastingfor 10 h. Plasma was obtained by centrifuging heparinized bloodat 1,600 g for 20 min at 4°C. LDL was isolated from the plasmaby density-gradient ultracentrifugation according to the methoddescribed previously (6). The concentration of cholesterolin plasma lipoproteins was determined enzymatically using CholesterolE Test-Wako (Wako Pure Chemicals, Tokyo,Japan).

Measurement of quercetin glucosides in onion. Twenty grams of onion slices were homogenized with 80 ml of methanol using a Polytron homogenizer at room temperature (41).The homogenate was filtered through no. 2 filter paper (Advantec,Toyo, Tokyo, Japan). The residue retained on the paper was mixedwith 100 ml of 80% methanol and then filtered again. Both filtrateswere poured into a 200-ml volumetric flask and filled to volumewith 80% methanol. Subsequently, the extract was filtered througha 0.45-µm filter (GL Sciences, Tokyo, Japan). Ten millilitersof the filtrate were then injected directly in an HPLC apparatusequipped with an octadecylsilane (ODS) column (TSK gel ODS-80TS,5 µm, 150 × 4.6 mm, TOSOH). Isocratic elution was carried outwith water-methanol-acetic acid (68:30:2, vol/vol/vol) in 50 mMlithium acetate at a flow rate of 1.0 ml/min. The quercetin glucosideseluted from the column were monitored with an amperometric electrochemicaldetector (+800 mV; ICA-5212, TOA Electronics, Tokyo, Japan) andidentified by the coincidence of their retention times with thoseof respective standard compounds. Their concentrations were calculatedusing standard curves for each quercetinglucoside.

Determination of quercetin metabolites in human plasma. Fifty microliters of human plasma were mixed with 50 µl of sulfatase type H-5 (25 units, from H. pomatia) solution in 0.1M sodium acetate buffer (pH 5.0) (5). The mixture was incubatedat 37°C in a shaking water bath for 50 min to liberate quercetinaglycone from its conjugates. Then the mixture was added to 900µl of methanol-acetic acid (100:5, vol/vol) followed by sonicationfor 30 s. The mixture was vortexed for 30 s and then centrifuged(5,000 g) for 5 min at 4°C. The supernatant was concentrated byevaporation with nitrogen gas and dissolved in methanol. A portionof the resulting solution was injected onto the HPLC column (TSKgel ODS-80TS, 5 µm, 150 × 4.6 mm, TOSOH). The mobile phase wascomposed of water-methanol-acetic acid (57:41:2, vol/vol/vol)containing 50 mM lithium acetate. The flow rate was 1.0 ml/min.Elution was monitored with an amperometric detector (ICA-5212,TOA) with a working potential of +800 mV. Experiments with quercetin-spikedplasma showed that this procedure ensured a nearly 95% recovery.Determination of quercetin was performed using an external standardcurve. The detection limit for quercetin was 1 nM with lineardetector response up to 20 µM.

Isolation of quercetin from plasma and gas chromatography-mass spectrometry analysis. Plasma (1.0 ml) obtained from seven volunteers after the trial was subjected to enzymatic hydrolysis using sulfatase H-5,and the resultant methanolic extract was injected onto the HPLCcolumn as described above. A fraction corresponding to quercetinwas obtained and applied to a Sep-Pak C₁₈ cartridge (Millipore,Waters, MA) for the elimination of lithium acetate from the HPLCmobile phase. After the cartridge was washed with methanol (10ml) and water (10 ml), an aqueous solution of the isolated compoundwas used to charge the cartridge, which was then eluted with water(10 ml) followed by methanol (10 ml). The methanol eluate wasevaporated to dryness, and the residue was trimethylsilyated usingN,O-bis(trimethylsilyl)acetamide for gas chromatography-mass spectrometryanalysis. A QP-5050 mass spectrometer (Shimadzu, Kyoto, Japan)equipped with an SPD-1-fused silica capillary column (0.25 mmID × 30 m, 10-µm film thickness; Supelco) in the electron impactmode (70 electron volt) was used. The carrier gas, helium, wasapplied at a flow rate of 1.0 ml/min. The column oven temperaturewas held at 120°C for 5 min before being elevated to 290°C at20°C/min and then kept constant for 10min.

Isolation of LDL from human plasma and its copper ion-induced lipid oxidation. The LDL fraction was isolated from heparinized plasma of volunteers before and after trials by differential density-gradientultracentrifugation according to the method described previously(6). The isolated LDL solution was used immediately for experimentsor was stored at 4°C for a maximum of 1 wk under a nitrogen atmosphereuntil used. The oxidation of the LDL solution [0.2 mg protein/mlPBS buffer (pH 7.4)] was initiated by the addition of cupric sulfate(final concentration of 5 µM). Cholesteryl ester hydroperoxides(CE-OOH) were determined by reversed-phase HPLC with ultravioletdetection at 235 nm as described previously (27). The concentrationof CE-OOH was tentatively calculated from the standard curve ofthe hydroperoxy derivative of cholesteryllinoleate.

Contents of quercetin, $alpha$ -tocopherol, and $alpha$ -/ $beta$ -carotene in LDL. To determine the quercetin content in LDL, the LDL solution was diluted with 0.1 M sodium acetate buffer (pH 5.0) to adjustit to the desired concentration of protein (mg protein LDL/ml),and the diluted solution (100 µl) was mixed with sulfatase typeH-5 (25 units, 50 µl) solution in 0.1 M sodium acetate buffer(pH 5.0). The mixture was incubated at 37°C in a shaking waterbath for 50 min. After the addition of 0.9 ml of methanol, themixture was sonicated for 30 s and subjected to centrifugationat 4°C (5,000 g, 5 min). The supernatant was evaporated undera stream of nitrogen gas, and the residue was dissolved in methanol.The resulting solution was subjected to HPLC analysis for quercetindetermination. The HPLC conditions were the same as those describedabove.

To determine $alpha$ -tocopherol and $alpha$ -/ $beta$ -carotene contents, the LDL solution was diluted with 10 mM Tris · HCl buffer (25 µg protein/100µl of final volume, pH 7.4) containing 0.5 mM DTPA. Ten microlitersof water containing 1 mM EDTA were added to the LDL solution. $delta$ -Tocopherol (0.5 nmol) and $beta$ -apo-8'-carotenal (50 pmol) wereadded as internal standards for the determination of $alpha$ -tocopheroland carotenes, respectively. The resulting LDL solution was mixedvigorously with 500 µl of ethanol and 500 µl of n-hexane. Boththe ethanol and n-hexane contained 1 mM BHT. After 1 min of sonicationfollowed by centrifugation (3,000 g, 5 min, 4°C), the upper layerwas collected and the solvent was subsequently evaporated undera stream of nitrogen gas and the residue was dissolved in chloroform.Portions of the chloroform solution were analyzed by HPLC fordetermination of $alpha$ -tocopherol and $alpha$ -/ $beta$ -carotene, respectively. $alpha$ -Tocopherol was analyzed by HPLC on a TSK gel Octyl-80TS column(5 µm, 4.6 × 150 mm, TOSOH) using 93% methanol as the elutingsolvent at a flow rate of 1.0 ml/min. The eluate was monitoredby fluorescence (excitation 295 nm; emission 325 nm). HPLC analysisof $alpha$ - and $beta$ -carotene was carried out with a TSK gel ODS-80TS column(5 µm, 4.6 × 250 mm, TOSOH) with a mobile phase of methanol-acetonitrile-dichloromethane-water(7:7:2:0.16, vol/vol/vol/vol) at a flow rate of 1.0 ml/min. $alpha$ -and $beta$ -Carotene were detected by measuring the absorbance at 450nm.

Statistical analysis. Reported values were presented as means ± SD. Statistical analysis was evaluated by Wilcoxon signed-ranks test to identifysignificant differences using StatView J-4.5 (Abacus Concepts,Berkeley, CA) with Macintosh software. The level of significancewas set at P < 0.05.

	RESULTS

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Content of quercetin glucosides in onion slices. Onion slices used in this trial contained two major glucosides (Q3,4'G and Q4'G) and one minor glucoside (Q3G). The contentsof Q3,4'G, Q4'G, and Q3G were 40.5, 9.7, and 0.3 mg/100 g, respectively,on a fresh weight basis. The quercetin equivalent ingested bythe subjects was 67.6 ~ 93.6 mg · day¹ · person¹ in the experiment. Quercetin in the free form was not detectedin thispreparation.

Plasma and lipoprotein cholesterol levels before and after short-term ingestion of onion slices. The cholesterol levels before and after short-term ingestion of onion slices were as follows: total plasma cholesterol, 169.3± 19.4 (before trial) and 161.6 ± 19.6 mg/dl (after trial); high-densitylipoprotein (HDL) cholesterol, 58.7 ± 9.4 (before trial) and 59.4± 9.2 mg/dl (after trial); LDL cholesterol, 98.6 ± 12.6 (beforetrial) and 91.6 ± 13.4 mg/dl (after trial). The plasma and HDLcholesterol levels after the trial did not differ significantlyfrom the respective levels before the trial. However, the LDLcholesterol level after the trial was significantly lower thanthat before the trial (P < 0.05).

Detection of quercetin in human plasma before and after short-term ingestion of onion slices. We performed HPLC analysis of methanol extracts of the plasma to know whether quercetin in the free form was present in humanplasma before and after short-term ingestion of onion (Fig. 1,A and B). No obvious peak corresponding to free quercetin appearedin the chromatogram from either plasma extract as shown in Fig.1, A and B. However, after sulfatase H-5 treatment, a prominentpeak emerged with a retention time of 19.7 min in the extractof human plasma after short-term ingestion of onion slices (Fig.1C). This peak was isolated and subjected to GC-MS after trimethylsilylation.Molecular ion (M⁺) was observed at mass-to-charge ratio (m/z; relative intensity)662 (1.5%). Other ions were formed in the fragmentation [M-CH₃⁺] and [M-OSiMe₃⁺] at m/z 647 (100%) and 573 (1.4%), respectively. This spectrumwas in good agreement with that obtained from the trimethylsilylatedderivative of standard quercetin. Consequently, the isolated compoundwas identified as quercetin. These results strongly indicate thatquercetin was present exclusively as the conjugated form in humanplasma; after short-term ingestion of onion, the quercetin aglyconewas liberated by the action of sulfatase H-5. Sulfatase H-5 possessesboth glucuronidase activity and sulfatase activity (31). However,this enzyme preparation can also react with quercetin glucosidesliberating quercetin, similar to the reaction with the conjugatesof the blood extracts. Therefore, to confirm the presence or absenceof quercetin glucosides in blood plasma, HPLC was carried outfor the detection of glucosides using the eluting solvent withhigher polarity without sulfatase H-5 treatment. Figure 2 showsa representative chromatogram of a methanol extract of human bloodplasma after short-term ingestion of onion (Fig. 2B) and of cochromatographyof this extract with the quercetin glucosides present in onionslices (Fig. 2A). Two peaks (retention time 12.1 and 23.9 min)were observed in the HPLC chromatogram (Fig. 2B) of the plasmaextract after onion ingestion. However, these peaks did not correspondto Q3,4'G, Q3G, or Q4'G. The detection limits for quercetin glucosideswere 20, 2, and 10 nM for Q3,4'G, Q3G, and Q4'G, respectively.It is therefore suggested that the level of quercetin glucosideaccumulation in the plasma is at least <20 nM.

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Fig. 1. HPLC chromatograms of methanol extracts of human plasma before and after short-term ingestion of onion slices. A: extract of human plasma before the trial; B: extract of human plasma after the trial; C: extract of human plasma after the trial after treatment with sulfatase H-5 (from Helix pomatia). The eluting solvent for the HPLC analysis was composed of methanol-water-acetic acid (41:57:2, vol/vol/vol) containing 50 mM lithium acetate. Other analytic conditions were the same as those described in MATERIALS AND METHODS.

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Fig. 2. HPLC chromatograms of methanol extracts of human plasma after short-term ingestion of onion slices. A: cochromatography of extract of human plasma after ingestion of onion and standard compounds of quercetin glucosides: quercetin 3,4'-di-O- $beta$ -glucoside (Q3,4'G); quercetin 3-O- $beta$ -glucoside (Q3G); quercetin 4'-O- $beta$ -glucoside (Q4'G); B: extract of human plasma after ingestion of onion;. The eluting solvent for the HPLC analysis was composed of methanol-water-acetic acid (30:68:2, vol/vol/vol) containing 50 mM lithium acetate. Other analytic conditions were the same as those described in MATERIALS AND METHODS.

Quantitative change of quercetin in human plasma by short-term ingestion of onion slices. Table 1 shows the concentrations of quercetin in human plasma from seven volunteers before and after short-term ingestionof onion slices. Here, quercetin was quantified in methanol extractsafter hydrolysis with sulfatase H-5. The average concentrationsof quercetin in human plasma before and after short-term ingestionof onion were 0.04 ± 0.04 and 0.69 ± 0.72 µM, respectively. Althoughthe concentration of quercetin in human plasma varied widely (0.08~ 1.88 µM), after the trial, every volunteer showed elevationof the concentration of quercetin after short-term ingestion ofonion slices.

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Table 1. Concentration of quercetin in human plasma from 7 volunteers before and after trial

Content of quercetin, $alpha$ -tocopherol, and carotene in LDL isolated from human plasma. Table 2 shows the contents of quercetin, $alpha$ -tocopherol, and $alpha$ -/ $beta$ -carotene in LDL isolated from human plasma before and aftershort-term ingestion of onion slices. Quercetin was analyzed afterhydrolysis with sulfatase H-5. The $alpha$ - and $beta$ -carotene levels werenot changed by the trials. The $alpha$ -tocopherol level in human plasmaafter onion ingestion (16.6 ± 2.6 nmol/mg protein LDL) was significantlyhigher than that before onion ingestion (12.6 ± 1.7 nmol/mg proteinLDL). Quercetin was not detected in human plasma LDL before onioningestion. Quercetin at the level of 0.03 nmol/mg protein LDLwas found in plasma LDL after short-term ingestion of onion. Thisconcentration is quite low compared with the $alpha$ -tocopherol andcarotene levels in human plasma LDL. The quercetin content inLDL (0.03 nmol/mg protein) corresponded to 1.8 ng/1.0 ml plasma,because the LDL concentration in plasma was 0.2 mg protein/ml.The average concentration of quercetin in human plasma after thetrial (0.7 µM) was estimated to be 210 ng/ml. It is thereforeestimated that the quercetin in LDL represents <1% of the quercetinpresent in human plasma after onion ingestion.

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Table 2. Contents of quercetin, $alpha$ -tocopherol, and $alpha$ -/ $beta$ -carotenes in LDL isolated from human plasma before and after short-term ingestion of onion slices

Effect of short-term onion ingestion on copper ion-induced oxidation of LDL isolated from human plasma. The LDL isolated from the plasma of the volunteers before and after onion ingestion was oxidized with copper ion at 37°C.Lipid peroxidation was monitored by the increase of CE-OOH concentration(Fig. 3). CE-OOH levels produced by 0.5, 1, and 2 h of oxidationdid not differ significantly before and after onion ingestion.Thus short-term ingestion of onion had no influence on the susceptibilityof isolated LDL to copper ion-induced oxidation.

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Fig. 3. Accumulation of cholesterylester hypdoperoxides (CE-OOH) in copper ion-induced lipid peroxidation of low-density lipoprotein (LDL) isolated from human plasma LDL. Oxidation of the LDL suspension (0.2 mg protein/ml) was initiated by the addition of cupric sulfate (final concentration 5 µM) dissolved in PBS buffer (pH 7.4). Open bars and filled bars show average CE-OOH concentrations before and after trials, respectively. Initial concentrations of quercetin and $alpha$ -tocopherol in the LDL suspension before and after short-term ingestion of onion are shown in Table 1.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

The aim of this study was to determine whether quercetin accumulates in human plasma after short-term ingestion of quercetin-richvegetables. We used onion as the dietary source of quercetin.Onion samples contained only quercetin glucosides and no quercetinaglycone. Therefore, we tried to measure the plasma concentrationof quercetin glucosides as well as quercetin in free form. Itis apparent from the analysis with sulfatase H-5 treatment thatthe quercetin content in blood plasma after 10 h of fasting wasincreased by the short-term ingestion of onion for 1 wk (Table1). However, quercetin in the free form was not detected in theplasma of volunteers before or after the trial (Fig. 1). Moreover,the quercetin glucosides present in the onion samples, Q4'G, Q3,4'G,and Q3G, were scarcely detectable in the plasma after the trial(Fig. 2). Therefore, two conclusions can be derived from theseresults. One is that periodic short-term ingestion of quercetin-richvegetables elevates the concentration of quercetin in human plasmaeven after fasting. The other conclusion is that conjugated metabolitesof quercetin accumulate exclusively in human plasma after quercetinglucosides are supplied in thediet.

Hollman et al. (17) demonstrated by single ingestion experiments that the quercetin glucosides from onion are absorbed intohuman plasma and eliminated slowly throughout the day. Thus itis rational to assume that the plasma quercetin level is maintainedby the periodic ingestion of quercetin-rich vegetables with meals.Our results strongly suggest that the plasma quercetin level canbe maintained in the range of 10⁷ ~ 10⁶ M by the periodic ingestion of 100 ~ 200 g of onion/day, althoughthe level of quercetin in the plasma may be transiently elevateda few hours after the intake. This study provides the first evidencethat quercetin accumulates in human plasma after the periodicingestion of quercetin-rich vegetables. Hollman et al. (18)also suggested that quercetin glucosides are absorbed more easilythan other glycosides or aglycones. However, they did not distinguishbetween quercetin aglycone and its conjugates present in humanplasma, because they measured the quercetin content after thehydrolysis of blood plasma by acid catalysis. Manach et al. (23)showed by single ingestion experiments that quercetin as conjugatedmetabolite forms, including sulfates and glucuronides, exclusivelyaccumulated in human plasma after the intake of complex mealscontaining onion and other quercetin-rich foods. However, Pagangaand Rice-Evans (29) demonstrated the presence of quercetin glucosidesin human plasma using nonsupplemented diets. Aziz et al. (1)also reported the presence of Q4'G and isorhamnetin 4'-O- $beta$ -glucosidein human plasma 1.5 h after consuming onion. Therefore, the absorptionand accumulation of quercetin glucosides in human plasma is stilla subject of controversy in terms of the bioavailability of dietaryflavonoids. Our results demonstrated at least that quercetin glucosidesdo not accumulate in human plasma in an intact form, and theyare mostly subject to metabolic conversion beforecirculation.

It is generally accepted that water-soluble quercetin glucosides seem to be poorly absorbed because of their poor solubilityin bile acid micelles in the intestinal tract (38). However,in the large intestine, glycosides are hydrolyzed to release theaglycone by the action of $beta$ -glycosidase in anaerobic enterobacteria(37). This improves the lipophylicity of quercetin, resultingin high solubility in bile acid micelles. We recently reportedthat rat intestinal mucosal homogenates easily hydrolyze Q4'Gto liberate quercetin aglycone (21). Furthermore, Day et al.(7) demonstrated that the human small intestine possesses cytosolic $beta$ -glucosidase activity with broad specificity. Therefore, mostquercetin glucosides from onion seem to be hydrolyzed during intestinalabsorption by $beta$ -glucosidase activity from enterobacteria and/orintestinal mucosa. We previously found that the activity of uridine-5'-diphosphoglucuronosyltransferase (UDP-GT), a typical glucuronidation enzyme, was thestrongest in the preparation from the intestine among rat tissues(30). Glucuronidation of quercetin in Caco-2 cells, which havebeen used as a model for the small intestinal epithelial cells,was also found by our research group (20). The presence of UDP-GTin human intestinal mucosa was also recently reported by Radominska-Pandyaet al. (32). On the other hand, the participation of the glucosetransport system in the cellular uptake of quercetin glucosidesfrom the diet has been reported (9, 28), and this may supportthe idea that quercetin glucosides are absorbed into the intestinaltract and present in human plasma in an intact form. However,Walgren et al. (42) claimed, on the basis of studies using Caco-2cells, that an active transport process for quercetin glucosidesis doubtful. It is therefore likely that quercetin glucosidesfrom onion are converted mostly to glucuronyl conjugates in intestinalepithelial cells by hydrolysis with $beta$ -glucosidase and conjugationby UDP-GT.

Our results clearly show that quercetin is scarcely incorporated within the LDL particles after short-term ingestion of quercetin-richvegetables (Table 2). The level of quercetin in LDL was foundto be <1% of the $alpha$ -tocopherol level, indicating that the participationof quercetin in an antioxidant capacity in isolated LDL is notlikely. The results of LDL oxidation with copper ion (Fig. 3)demonstrated that short-term ingestion of quercetin-rich vegetablesdoes not improve the resistance of isolated LDL to oxidation.Blostein-Fujii et al. (3) showed that citrus flavonoid supplementationdoes not necessarily alter LDL susceptibility to oxidation assessedin vitro. We have assumed that flavonoids are efficient antioxidantsat the interface between the lipid and water phases (39). Itis unlikely that quercetin conjugates enter into LDL particlesbecause of a rather high water solubility, although they may possessan affinity to outer phospholipid membranes in LDL particles.Quercetin is known to bind extensively to human serum albumin(4). However, no information is available on the interactionof quercetin conjugates with serum albumin. Thus, for the assessmentof the antioxidant activity of quercetin conjugates in the circulation,further studies are required to demonstrate whether these conjugatesare present free in the water phase or bound to specificproteins.

In conclusion, our volunteer study clarified that conjugated metabolites of quercetin accumulate in human plasma in the concentrationrange of 10⁷ ~ 10⁶ M after the periodic ingestion of onions with meals for 1 wk.This level corresponds to the concentrations of carotenoids andubiquinol, well-known plasma antioxidants, in human plasma. Althoughthe susceptibility of LDL to oxidation is not altered by the ingestionof onion because of scant incorporation into isolated LDL particles,quercetin metabolites in the plasma may contribute to the antioxidantdefense in thecirculation.

Perspectives

Quercetin glycosides are obtained by the daily intake of vegetables, fruits, and beverages. This study clearly indicates thatthey are accumulated as glucuronide and/or sulfate conjugatesin circulation. Therefore, antiatherosclerotic and other vascularfunction of quercetin is undoubtedly originated from its conjugatedmetabolites. Although the conjugation with glucuronide and sulfateis a step in the detoxification to lose the physicochemical property,intermediate products should retain their activity and exert biologicalfunction. Then, localization of quercetin conjugates in the vascularsystem should be clarified to assess their efficacy as plasmaantioxidants. Their diphenylpropane moiety may facilitate theirlocalization near the surface of lipoproteins because of the interactionbetween this planar structure and outer phospholipid layers. Itis unlikely that quercetin conjugates penetrate into cytosol throughcellular membranes and exert their activity on redox regulationin vascular cells. However, they can modulate the redox stateof cellular membranes by interacting with phospholipid bilayers.Physicochemical reaction of the metabolites toward biomembranesshould be clarified to understand antiatherosclerotic and otherphysiological function of dietary flavonoids in the vascularsystem.

	ACKNOWLEDGEMENTS

The authors thank the volunteers for their participation and Dr. T. Tsushida of National Food Research Institute, Japan, fordonating standard Q4'G and Q3,4'G.

	FOOTNOTES

This work was supported partly by the Special Coordination Funds for Promoting Science Technology of the Science TechnologyAgency of the Japanese Government and Program for Promotion ofBasic Research Activities for InnovativeBiosciences.

Address for reprint requests and other correspondence: J. Terao, Dept. of Nutrition, School of Medicine, The Univ. of Tokushima,Kuramoto-cho 3, Tokushima 770-8503, Japan (E-mail: terao{at}nutr.med.tokushima-u.ac.jp).

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.§1734 solely to indicate thisfact.

Received 18 October 1999; accepted in final form 7 March 2000.

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