Hostname: page-component-586b7cd67f-2brh9 Total loading time: 0 Render date: 2024-11-26T15:56:26.579Z Has data issue: false hasContentIssue false

Comparison of the uptake and secretion of carotene and xanthophyll carotenoids by Caco-2 intestinal cells

Published online by Cambridge University Press:  01 July 2007

Laurie O'Sullivan
Affiliation:
Department of Food and Nutritional Sciences, University College Cork, Ireland
Lisa Ryan
Affiliation:
Department of Food and Nutritional Sciences, University College Cork, Ireland
Nora O'Brien*
Affiliation:
Department of Food and Nutritional Sciences, University College Cork, Ireland
*
*Corresponding author: Professor Nora O'Brien, fax 00353 21 4270244, email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Carotenoids have been shown to have potential beneficial effects on human health which has led to an increasing interest in the study of their bioavailability. A Caco-2 cell model, as previously described, was employed to examine the percentage transfer of the carotenoids α-carotene, β-carotene, lycopene, astaxanthin, β-cryptoxanthin, lutein and zeaxanthin through an intact, highly differentiated Caco-2 cell monolayer at a range of different amounts. Our results show that astaxanthin, a carotenoid with powerful antioxidant capacity, had the highest percentage transfer overall. We examined the cellular uptake and secretion of lutein and zeaxanthin to compare two structurally similar carotenoids. Both were efficiently transported through the monolayer with a range between 5·1 (sem 1·2) % to 20·2 (sem 3·3) % and 5·5 (sem 2·5) % to 13·4 (sem 4) % for lutein and zeaxanthin, respectively. These carotenoids were compared to each other at each added amount and no significant difference was observed between the two xanthophylls. The carotene carotenoids α-carotene, β-carotene and lycopene and the xanthophyll β-cryptoxanthin were also examined and had lower uptake and secretion values when compared to lutein, zeaxanthin and astaxanthin. The xanthophyll β-cryptoxanthin was also not significantly different when compared to the carotene carotenoids. Data generated from this study compares well with in vivo bioavailability studies. Furthermore, the model provides comparative data on the relative absorption and transfer of seven different carotenoids. Our data indicate that lower amounts of carotenoids were absorbed and transferred more efficiently than higher amounts suggesting a saturation effect at higher exposure.

Type
Full Papers
Copyright
Copyright © The Authors 2007

Carotenoids are a class of fat-soluble plant compounds that are responsible for the colouration of fruits and vegetables. Interest in the bioavailability of carotenoids has been encouraged by research, demonstrating an association between the intake of fruits and vegetables and a reduced risk of chronic conditions such as CVD, certain cancers, age-related macular degeneration and cataract formation (Furr & Clark, Reference Furr and Clark1997). Carotenoids can be divided into two main groups based on their structure; carotenes and xanthophylls. β-Carotene, α-carotene and lycopene are the predominant members of the carotene group which includes carotenoids mainly composed of carbon and hydrogen atoms. Xanthophylls contain at least one oxygen atom. Lutein, zeaxanthin, β-cryptoxanthin and astaxanthin are common xanthophylls with hydroxyl and keto groups as structural elements (Stahl & Sies, Reference Stahl and Sies2005). Bioavailability of carotenoids has been investigated using both animal and human studies. Human studies include plasma carotenoid response and intake–excretion balance studies. Animals that have similar metabolism of β-carotene to that of man include the ferret, the preruminant calf and the gerbil, but the specialised care of these animals does not make this method widely accessible (Garrett et al. Reference Garrett, Failla and Sarama1999). More recent approaches using stable isotopes and mass spectral analysis of carotenoids and their metabolites are potential methods of studying human intestinal absorption but they are intricate and expensive (During & Harrison, Reference During and Harrison2004).

An in vitro intestinal cell culture model mimicking the in vivo intestinal absorption of carotenoids was recently reported (During et al. Reference During, Morel and Harrison2002) and is employed in the present study with modifications. The Caco-2 cell model consists of a 3-week-old differentiated Caco-2 cell monolayer grown on a permeable membrane. Caco-2 cells are human colonic adenocarcinoma cells that, when differentiated, exhibit both functional and morphological characteristics similar to enterocytes such as the secretion of brush border enzymes and the presence of microvilli (Sambury et al. Reference Sambury, Ferruzza, Ranaldi and De Angelis2001). The cell monolayer is stimulated to produce chylomicrons according to the method of Luchoomun & Hussain (Reference Luchoomun and Hussein1999). These conditions mimic the in vivo postprandial state. Carotenoids are delivered in a Tween 40 micelle and are incubated for a total of 16 h (During et al. Reference During and Harrison2005). The carotenoids are absorbed by the Caco-2 cells, incorporated into chylomircons and are secreted into the basolateral chamber of the transwell plate. The amounts of carotenoids that were chosen for this study were based on the calculation that During et al. (Reference During, Morel and Harrison2002) reported to be physiologically realistic. These amounts are based on a daily intake of 5 mg β-carotene and the surface absorption, length and diameter of the upper region of the small intestine and are considered representative of the normal range of carotenoids from diet and supplements.

The main objective of this study was to examine the percentage transport of various carotenes and xanthophylls through a differentiated Caco-2 cell monolayer cultured on a 0·4 μm pore size membrane and to compare the differences in absorption of individual carotenoids at varying amounts. The carotenoids studied, β-carotene, α-carotene, lycopene, lutein, zeaxanthin, β-cryptoxanthin and astaxanthin, were delivered to the cells in an emulsion. This model, when used in conjunction with an in vitro digestion procedure, provides an approach to assess the relative availability of carotenoids from food sources and synthetic formulations.

Materials and methods

Materials

β-Cryptoxanthin was obtained from LGC Prochem (Middlesex, UK). α-Carotene was obtained from Carbon 14 Centralen (Hoersholm, Denmark). Lutein and zeaxanthin were purchased from Fluka (Buchs SG, Switzerland). Foetal bovine serum was purchased from GIBCO BRL Technologies Ltd. (Paisley, Scotland). All other chemical reagents were purchased from Sigma Aldrich Ireland Ltd (Dublin, Ireland) unless otherwise stated. Tissue culture plastics were supplied by Greiner Bio-One (Kremsmunster, Austria). Transwell plates were purchased from Costar (New York, USA). All solvents employed were of HPLC grade.

Preparation of carotenoids

All carotenoid analysis was performed under amber light to avoid photo-oxidation of carotenoids. The carotenoids α-carotene, β-carotene, β-cryptoxanthin, lutein, lycopene, zeaxanthin and astaxanthin were prepared using the ‘Tween 40’ method as described by O'Sullivan et al. (Reference O'Sullivan, Woods and O'Brien2004). Briefly, the amounts (0·5 μg, 1·0 μg, 1·5 μg, 2·0 μg, 2·5 μg) of each carotenoid were determined spectrophotometrically using the published extinction coefficients, in either hexane, ethanol or methylethylketone. Each preparation was dried down under N2. The carotenoids were reconstituted in 50 μl Tween 40 (200 ml acetone/l). These solutions were again dried down under N2. Residues were reconstituted in 2 ml serum free media containing 0·5 mm taurocholate, 1·6 mm oleic acid and 45 mm glycerol for the stimulation and secretion of chylomicrons. Carotenoid enriched media was passed through a surfactant-free cellulose acetate filter (0·2 μm; Millipore, Bedford, MA, USA). before addition to cells (at final concentration of carotenoids ranging from approximately 0·5 to 2·3 μm).

Cell Culture

Caco-2 cells (without 15, 15′ dioxygenase activity) were purchased from the European Collection of Animal Cell Cultures (Salisbury, Wilts., UK). Cells were maintained in Dulbecco's Modified Eagle's Medium supplemented with 10 % foetal bovine serum and 1 % non-essential amino acids. Cells were grown at 37°C and 5 % CO2 in a humidified incubator, in the absence of antibiotics. For experiments, cells were seeded at a density of 1·25 × 105 cells/ml on transwell plates (6-well plate, 24 mm diameter, 0·4 μm pore size membrane). Cells were grown for 21–25 d to obtain a differentiated cell monolayer. Trans-epithelial electrical resistance (TEERS) measurements were taken twice weekly by a TEERS voltohometer to ensure the monolayer was intact. Diffusion of phenol red was also performed to ensure that cell monolayers were undamaged (results not shown). Differentiation was confirmed by measuring the activity of the brush border enzymes alkaline phosphatase and amino peptidase, which have higher activity in enterocytes compared with undifferentiated Caco-2 cells (results not shown). At the beginning of each experiment, the apical side of the transwell plate received 2 ml carotenoid enriched media (containing chylomicron stimulating compounds). The basolateral chamber received 2 ml serum free media. The incubation time for all experiments was 16 h which is optimised for chylomicron production. After the incubation time, media from each side of the membrane were removed, the monolayer was washed twice with Hanks Balanced Salt Solution (HBSS) and cells were scraped into 1 ml HBSS. Cell samples were sonicated for 30 s on ice. Samples were stored at − 80°C for further analysis.

Lipoprotein fractionation

Lipoprotein fractions which include large chylomicrons, small chylomicrons and VLDL were isolated from the basolateral medium by sequential density gradient ultracentrifugation according to the methods of Luchoomun & Hussain (Reference Luchoomun and Hussein1999). Briefly, 2 ml basolateral chamber medium was mixed with 0·287 g KBr and then overlaid with 900 μl 1·063 g/ml density solution, 900 μl 1·019 g/ml density solution and of 900 μl 1·006 g/ml density solution. The samples were then subjected to three successive centrifugations (NVT90 rotor, Beckman Instruments Inc., CA, USA): first at 40 000 rpm for 12 min, then 40 000 rpm for 77 min followed by 60 000 rpm for 169 min. After each centrifugation, 1 ml supernatant was collected and each sample was replenished with 1·006 g/ml density solution prior to the next centrifugation. The supernatants were pooled and stored at − 80°C.

Carotenoid extraction and analysis

Apical, basolateral and cell samples were allowed to thaw and were briefly vortexed. A recovery standard consisting of 25 mm α-tocopherol acetate was added to all samples. These samples were extracted twice with hexane–ethanol–acetone (50:25:25, by volume) (Olives Barba et al. Reference Olives Barba, Hutado, Sanchez Mata, Fernadez Ruiz and Lopez Saenz de Tejada2006). Samples were centrifuged (Sorvall TC6, H400 rotor, DuPont Instruments, Herts, UK) at 3000 rpm for 5 min and the supernatant layers were removed, pooled and dried down under N2. The residues were reconstituted in 200 μl mobile phase and the carotenoid content of the samples was analysed by reverse phase HPLC. The HPLC system (Shimadzu, Kyoto, Japan) consisted of a LC10-AD pump connected to a SIL-10A auto-injector, a SPD-6AV system controller, SPD-6AV UV-visible detector and SPD-10AV UV-visible detector. The column system consisted of a Spherisorb ODS-2 C18 5 μm PEEK guard column (Alltech Associate Applied Science Ltd; supplied by Ocon Chemicals Ltd, Cork, Ireland) connected to a Vydac 201TP54 (250 × 4·6 mm) reverse phase C18 column (Separations Group; supplied by AGB Scientific Ltd, Dublin, Ireland). Column temperature was maintained at 25°C using a column water jacket (Alltech Associates Applied Science Ltd.) with a thermostatically controlled water bath (Lauda RM6 T; Lauda-Königshofen, Germany). The injection volume was 50 μl; samples were eluted using isocratic mobile phase composed of acetonitrile–methanol–dichloromethane (75:20:5, by volume) containing 10 mm-ammonium acetate, 4·5 mm-butylated hydroxytoluene and 3·6 mm triethylamine at a flow rate of 1·5 ml/min. Carotenoids were detected at 450 nm on a visible detector and tocopherols at 292 nm on a UV detector. The mobile phase was filtered through a 0·5 μm organic filter and degassed using ultrasonic agitation. Results were collected and analysed using Millenium software (Waters Corporation, Milford, MA, USA). β-Carotene, α-carotene, lycopene, lutein, zeaxanthin, β-cryptoxanthin and astaxanthin recovered from media and cell samples were extrapolated from pure carotenoid standard curves, after correction for extraction efficiency based on recovery of α-tocopherol acetate.

Statistical analyses

Results are representative of three or more independent experiments. Errors are expressed as standard errors of the means. Carotenoids were compared at various concentrations by one-way ANOVA followed by Tukey's test. Carotenoids were compared to each other at differing concentrations by an unpaired t test.

Results

The uptake and secretion of carotene carotenoids

The carotene carotenoids examined in this study were α-carotene, β-carotene and lycopene. These were added to Caco-2 cells at amounts of 0·5 μg, 1·0 μg, 1·5 μg, 2·0 μg, 2·5 μg. The basolateral chamber value is the amount of carotenoid that was taken up by the Caco-2 cell, packaged into chylomicrons, transported through the monolayer and secreted into the basolateral chamber of the transwell plate. This value is expressed as a percentage of the original starting amount that was added to the well. Large chylomicrons, small chylomicrons and VLDL lipoprotein fractions were isolated from the basolateral medium and the carotenoid contents of these fractions were combined and compared to the total amount of carotenoid in the basolateral chamber (data not shown). There was no difference in the carotenoid content when the lipoprotein fractions were combined and compared to the total content in the basolateral chamber. Therefore, lipoprotein fractions were no longer prepared and the entire basolateral chamber medium was analysed for carotenoid content. The percentage α-carotene that was recovered from the basolateral chamber ranged from 0·6 (sem 0·1) to 3·8 (sem 2·1) % (Fig. 1). This is lower than that of β-carotene where values ranged between 1·3 (sem 0·1) and 4·2 (sem 0·8) % (Fig. 1) and when the two carotenoids were compared, the percentage transfer values differed significantly at the 1·0 μg, 1·5 μg and 2·0 μg concentrations (P < 0·05). Lycopene transfer was similar to that of α-carotene as there was no significant difference between the two carotenoids. The percentage carotene that remained in cells (Table 1) was combined with basolateral values (Fig. 1) and was expressed as total uptake and secretion (Fig. 2). When the percentage total uptake and secretion of α-carotene, β-carotene and lycopene were compared to each other there was no significant difference at any amount except at 2 μg where lycopene was significantly different from α-carotene and β-carotene (P < 0·05). There were also significant differences between the 1·0 μg and the 2·0 μg lycopene amounts (P < 0·05).

Fig. 1 The percentage transfer of carotenoids to the basolateral chamber. Data are means representative of three of more independent experiments with their standard errors represented by vertical bars. (A) ■, α-carotene; □, β-carotene; , lycopene. (B) , lutein; , zeaxanthin. (C) , β-cryptoxanthin; , astaxanthin. a,b,c,d,e,f Mean values were significantly different for the following comparisons: av. all other β-carotene amounts (P < 0·01); bv. α-carotene at same amount (P < 0·05); cv. lycopene at same amount (P < 0·05); dv. 0·5 μg zeaxanthin (P < 0·05); ev. all other lutein amounts (P < 0·01); fv. astaxanthin at same amount (P < 0·05).

Table 1 The percentage carotene and xanthophyll carotenoids recovered from Caco-2 cells after 16 h incubation. Values are expressed as a percentage of the original quantities added to the cells and data are means representative of three or more independent experiments with their standard errors

a,b,c,d,e,f,g,h Mean values were significantly different for the following comparisons: av. all other lycopene amounts (P < 0·01), bv. lycopene at same amount (P < 0·05), cv. α-carotene at same amount (P < 0·05), dv. 0·5 μg lutein (P < 0·01), ev. 1·0 μg lutein (P < 0·05), fv. zeaxanthin at same amount (P < 0·05), gv. β-cryptoxanthin at same amount (P < 0·05), hv. 0·5 μg astaxanthin (P < 0·05).

Fig. 2 The percentage total uptake and secretion of carotenoids through the Caco-2 model. Data are means representative of three of more independent experiments with their standard errors represented by vertical bars. (A) ■, α-carotene; □, β-carotene; , lycopene. (B) , lutein; , zeaxanthin. (C) , β-cryptoxanthin; , astaxanthin. a,b,c,d,e,f Mean values were significantly different for the following comparisons: av. 0·5 μg lycopene (P < 0·05); bv. lycopene at same amount (P < 0·05); cv. 0·5 μg zeaxanthin (P < 0·05); dv. all other lutein amounts (P < 0·01); ev. 0·5 μg astaxanthin (P < 0·05); fv. β-cryptoxanthin at the same amount (P < 0·05).

Uptake and secretion of the xanthophyll carotenoids lutein and zeaxanthin

Lutein and zeaxanthin are isomers of each other differing only in the location of a double bond on the hydroxyl end of the molecule. The percentage transfer of lutein to the basolateral chamber ranged from 2·3 (sem 1·4) to 10·5 (sem 2·4) % (Fig. 1). When the percentage transfer to the basolateral chamber of lutein was compared at all amounts added the 0·5 μg amount differed significantly from all others (P < 0·01; Fig. 1). The percentage transfer of zeaxanthin to the basolateral chamber ranged from 4·5 (sem 2·3) to 11·8 (sem 3·9) % (Fig. 1). The 2·5 μg amount differed significantly from the 0·5 μg zeaxanthin (P < 0·05). When the percentage transfer of lutein was compared to that of zeaxanthin at each amount, there was no significant difference between the isomers (Fig. 1). For lutein the total uptake and secretion ranged from 5·1 (sem 1·2) to 20·2 (sem 3·3) % and this was very similar to zeaxanthin, which ranged from 5·5 (sem 2·5) to 13·4 (sem 4) % (Fig. 2). These carotenoids were compared to each other at each amount and no significant difference was observed between the two xanthophylls.

Uptake and secretion of the xanthophylls β-cryptoxanthin and astaxanthin

Although astaxanthin is considered a xanthophyll carotenoid, it differs from the other xanthophyll carotenoids in this study, as it has a ketone group on the molecule. We compared the uptake and secretion of a xanthophyll carotenoid β-cryptoxanthin with the keto-xanthophyll astaxanthin in Caco-2 cells (Fig. 2). After a 16 h incubation, the percentage transfer to the basolateral chamber of β-cryptoxanthin and astaxanthin varied from 1·1 (sem 0·1) to 3·4 (sem 1·2) % and 2·2 (sem 0·6) to 6·7 (sem 0·51) % respectively (Fig. 1). The transfer of β-cryptoxanthin to the basolateral chamber was lower than that of astaxanthin (Fig. 1) and differed statistically at 0·5 μg and 1·0 μg (P < 0·05). There was a significant difference (P < 0·05) at all amounts when the percentage β-cryptoxanthin in cells was compared to that of astaxanthin (Table 1). The same trend was observed in the percentage total uptake and secretion of β-cryptoxanthin at every amount (Fig. 2). The 0·5 μg quantity of astaxanthin was significantly different (P < 0·05) to all other astaxanthin amounts (Fig. 2). When both xanthophylls were compared against each other at each quantity the percentage uptake and secretion of astaxanthin was significantly higher (P < 0·05) than that of β-cryptoxanthin (Fig. 2).

Discussion

Uptake and transport of the carotene carotenoids

The aim of this study was to examine individual carotenoid uptake and transport in the Caco-2 cell model. The Caco-2 cell model has previously been used to mimic the intestinal absorption of carotenoids (Garrett et al. Reference Garrett, Failla and Sarama1999, Reference Garrett, Failla and Sarama2000; Ferruzzi et al. Reference Ferruzzi, Failla and Schwartz2001; During et al. Reference During, Morel and Harrison2002; Chitchumroonchokchai et al. Reference Chitchumroonchokchai, Schwartz and Failla2004; Liu et al. Reference Liu, Glahn and Liu2004; During & Harrison, Reference During and Harrison2005; Reboul et al. Reference Reboul, Abou, Mikail, Ghiringhelli, André, Potugal, Jourdheuil-Rahmani, Amiot, Lairon and Borel2005; Chitchumroonchokchai & Fallia, Reference Chitchumroonchokchai and Failla2006; Ferruzzi et al. Reference Ferruzzi, Lumpkin, Schwartz and Failla2006). There are some reports on uptake and transport kinetics of β-carotene through Caco-2 cell monolayers (During et al. Reference During, Morel and Harrison2002, Reference During, Morel and Harrison2005); data on α-carotene, zeaxanthin, β-cryptoxanthin and astaxanthin transport, however, are limited. The amounts of carotenoids added to cells (0·5–2·5 μg) in this study are similar to the amounts that have been demonstrated to produce an anti-proliferative effect on human prostate carcinoma cells in vitro (Levy et al. Reference Levy, Bosin, Feldman, Giat, Münster, Danilenko and Sharoni1995; Pastori et al. Reference Pastori, Pfander, Boscoboinik and Azzi1998) and these concentrations are also reported to be physiologically realistic (Pastori et al. Reference Pastori, Pfander, Boscoboinik and Azzi1998).

Data from this study indicates a 1 % difference in the percentage transport of α-carotene and β-carotene which is in line with the observations made by During et al. (Reference During, Morel and Harrison2002) and suggests that the uptake and secretion of both carotenoids is similar. These findings are also consistent with a human study conducted by Edwards et al. (Reference Edwards, Nguyen, You, Swanson, Emenhiser and Parker2002) which reported similar absorption of α- and β-carotene. However, for both α- and β-carotene the percentage transport to the basolateral chamber reported by During et al. (Reference During, Morel and Harrison2002) was higher and differed from the results obtained in the present study by approximately 10 %. The discrepancy between the findings may be related to the differences in pore size of the membrane on the transwell plate. Differentiated Caco-2 monolayers grown on transwell plates are a well- established method for studying drug transport in vitro (Artursson & Karlsson, Reference Artursson and Karlsson1991). More recent studies investigating lipophilic drug transport in the Caco-2 cell model use transwell membranes having pores with a 0·4 μm diameter in order to avoid cell migration from the apical to the basolateral side (Seeballuck et al. Reference Seeballuck, Ashford and O'Driscoll2003, Reference Seeballuck, Lawless, Ashford and O'Driscoll2004). In the present study, 0·4 μm pore size membranes were also employed on the transwell plates and this contrasts with the study by During et al. (Reference During, Morel and Harrison2002)where a 3 μm pore size membrane was employed. Our data agree with the work of Edwards et al. (Reference Edwards, Nguyen, You, Swanson, Emenhiser and Parker2002) who, in a human study, reported an absorption value of about 1·2–3·5 % for α-carotene after ingestion of a known concentration of this carotenoid from a carrot puree. Using a similar Caco-2 cell model, Ferruzzi et al. (Reference Ferruzzi, Lumpkin, Schwartz and Failla2006) examined the uptake of β-carotene from a test meal following in vitro digestion and reported that the micelles generated contained 22 139 pmol β-carotene of which 916 pmol (about 4 %) was taken up by the cells. Our results support this observation as we found the percentage of β-carotene remaining in cells ranged from about 3·7 to 5·2 % after the 16 h incubation period. These data also compare well with the results of the human study reported by Edwards et al. (Reference Edwards, Nguyen, You, Swanson, Emenhiser and Parker2002) where between 0·9 and 2·4 % of a known ingested amount of β-carotene was absorbed from a test meal determined using an extrinsic reference method. A human study conducted by O'Neill & Thurnham (Reference O'Neill and Thurnham1998) investigated the intestinal absorption of β-carotene, lycopene and lutein and concluded that the absorption of β-carotene is a saturable process as only small amounts (about 3·5 %) of a 40 mg dose were detected in the TAG-rich lipoprotein fraction. Data from the present study are also in agreement with isotopic tracer studies conducted by Edwards et al. (Reference Edwards, You, Swanson and Parker2001) and Lin et al. (Reference Lin, Durker, Burri, Neidlinger and Clifford2000) who reported bioavailability values for β-carotene ranging from 3 to 16 % from a test meal and pure β-carotene sources, respectively. In a human study using intrinsically labelled tomatoes, Tang et al. (Reference Tang, Ferreria, Grusak, Qin, Dolnikowski, Russell and Krinsky2005) examined the bioavailability of lycopene and reported that approximately 1·2 % of the administered dose was absorbed. This is similar to the results we obtained for the percentage of lycopene that was secreted into the basolateral chamber which ranged from 0·9 (sem 0·2) to 2·6 (sem 0·9) %. These data also agree with the work of O'Neill & Thurnham (Reference O'Neill and Thurnham1998) who found that about 1 mg lycopene was absorbed from a 38 mg dose administered in capsules (approximately 2·6 %) and that there was no significant difference between the absorption of β-carotene and lycopene.

Uptake and transport of the xanthophyll carotenoids lutein and zeaxanthin

We examined the cellular uptake and secretion of lutein and zeaxanthin to compare two structurally similar carotenoids. It is important to note that we looked at these carotenoids independently of each other and therefore we were not observing preferential uptake of one carotenoid over another as a number of studies have reported (Böhm & Bitsch, Reference Böhm and Bitsch1999; Garrett et al. Reference Garrett, Failla and Sarama1999; Kostic et al. 1995; van Hof et al. Reference van Hof, Brouwer, West, Haddeman and van Dusseldorp1999; Tyssandier et al. Reference Tyssandier, Cardinault, Caris-Veyrat, Amiot, Grloier, Bouteloup, Azias-Braesco and Borel2002). Findings from the present study are supported by the work of Chitchumroonchokchai et al. (Reference Chitchumroonchokchai, Schwartz and Failla2004) who found that about 6·3 % of lutein that was retained by cells was transported to the basolateral chamber after the addition of lutein containing micelles generated from in vitro digestion of spinach.

To date, little work has been conducted on the absorption and transport of zeaxanthin through Caco-2 cell monolayers. Chitchumroonchokchai & Failla (Reference Chitchumroonchokchai and Failla2006) investigated the hydrolysis of zeaxanthin esters during an in vitro digestion procedure and found that about 4·5 % of zeaxanthin that was taken up by cells was transported to the basolateral chamber. This was slightly lower than results obtained from this study.

Uptake and transport of the xanthophyll carotenoids β-cryptoxanthin and astaxanthin

Coral-Hinostroza et al. (Reference Coral-Hinostroza, Ytrestoyl, Ruyter and Bjerkeng2004) conducted a study to investigate the appearance of astaxanthin isomers in men given a mixed dose of astaxanthin diester isomers. They reported that about 6 % of the administered dose appeared in plasma after supplementation with 100 mg carotenoid. This compares well with our data, which reports a 6·7 (sem 0·5) % transfer of astaxanthin to the basolateral chamber. When the transfer of astaxanthin was compared to β-cryptoxanthin, it was significantly higher at all amounts studied (Fig. 1). Overall, astaxanthin had the highest percentage total uptake and secretion, which ranged from 13·8 (sem 3·9) to 26·9 (sem 2·4) % (Fig. 2).

In conclusion, we demonstrate that the Caco-2 cell model is a useful tool to study the absorption and transport of carotenoids through a cell monolayer representative of the intestinal epithelia in vivo. Statistical analysis of data concludes that the xanthophyll carotenoids astaxanthin and lutein were transported more efficiently than the carotene carotenoids and that overall, astaxanthin was the most efficiently absorbed. This is the first study to compare a range of carotene and xanthophyll carotenoids using the Caco-2 in vitro model. Our results correlate with in vivo data (Kostic et al. Reference Kostic, White and Olson1995; Gartner et al. Reference Gartner, Stahl and Sies1996; van Hof et al. Reference van Hof, Gärtner, Wiersma, Tijburg and Weststrate1999) that have also shown higher percentage absorption of xanthophyll carotenoids compared to carotenes thus providing validation of this model as an approach to assess carotenoid availability. Additionally, our findings indicate that lower amounts of carotenoids were absorbed and transferred more efficiently than higher amounts suggesting a saturation effect. Our study adds to the increasing body of literature demonstrating the usefulness of the Caco-2 in vitro model for obtaining information about the intestinal absorption of carotenoids. In the future we will couple the Caco-2 cell model with an in vitro digestion procedure to look at the availability of carotenoids from foods and supplements.

Acknowledgements

This work was funded by Science Foundation Ireland.

References

Artursson, P & Karlsson, J (1991) Correlation between oral drug transport in humans and apparent drug permeability coefficients in human intestinal epithelial (Caco-2) cells. Biochem Biophys Res Commun 175, 880885.CrossRefGoogle ScholarPubMed
Böhm, V & Bitsch, R (1999) Intestinal absorption of lycopene from different matrices and interactions to other carotenoids, the lipid status, and the antioxidant capacity of human plasma. Eur J Nutr 38, 118125.Google ScholarPubMed
Chitchumroonchokchai, C & Failla, M (2006) Hydrolysis of zeaxanthin esters by carboxyl ester lipase during simulated digestion facilitates micellarization and uptake by Caco-2 human intestinal cells. J Nutr 136, 3, 588594.CrossRefGoogle ScholarPubMed
Chitchumroonchokchai, C, Schwartz, S & Failla, M (2004) Assessment of lutein bioavailability from meals and a supplement using simulated digestion and Caco-2 human intestinal cells. J Nutr 134, 22802286.CrossRefGoogle Scholar
Coral-Hinostroza, G, Ytrestoyl, T, Ruyter, B & Bjerkeng, B (2004) Plasma appearance of un-esterified astaxanthin geometrical E/Z and optical R/S isomers in men given single doses of a mixture of optical 3 and 3′R/S isomers of astaxanthin fatty acyl diesters. Comp Biochem Physiol C Toxicol Pharmacol 139, 99110.CrossRefGoogle Scholar
During, A & Harrison, E (2004) Intestinal absorption and metabolism of carotenoids: insights from cell culture. Arch Biochem Biophys 430, 7788.CrossRefGoogle ScholarPubMed
During, A & Harrison, E (2005) An in vitro model to study the intestinal absorption of carotenoids. Food Research International 38, 10011008.CrossRefGoogle Scholar
During, A, Morel, D & Harrison, E (2002) Carotenoid uptake and secretion by Caco-2 cells. β -carotene isomer selectivity and carotenoid interactions. J Lipid Res 43, 10861095.CrossRefGoogle ScholarPubMed
During, A, Morel, D & Harrison, E (2005) Carotenoid transport is decreased and expression of the lipid transporters SR-BI, NPC1L1 and ABCA1 is down-regulated in Caco-2 cells treated with Ezetimibe. J Nutr 135, 23052312.CrossRefGoogle Scholar
Edwards, A, Nguyen, C, You, C, Swanson, J, Emenhiser, C & Parker, R (2002) α and β-carotene from a commercial carrot puree are more bioavailable to humans than from boiled-mashed carrots, as determined using an extrinsic stable isotope reference method. J Nutr 132, 159167.CrossRefGoogle ScholarPubMed
Edwards, A, You, C, Swanson, J & Parker, R (2001) A novel extrinsic reference method for assessing the vitamin A value of plant foods. Am J Clin Nutr 74, 348355.CrossRefGoogle ScholarPubMed
Ferruzzi, M, Failla, M & Schwartz, S (2001) Assessment of degradation and intestinal cell uptake of carotenoids and chlorophyll derivatives from spinach puree using an in vitro digestion and Caco-2 human cell model. J Agric Food Chem 49, 20822089.CrossRefGoogle Scholar
Ferruzzi, M, Lumpkin, J, Schwartz, S & Failla, M (2006) Digestive stability, micellarization and uptake of β-carotene isomers by Caco-2 intestinal cells. J Agric Food Chem 54, 7, 27802785.CrossRefGoogle Scholar
Furr, H & Clark, M (1997) Intestinal absorption and tissue distribution of carotenoids. J Nutr Biochem 8, 364377.CrossRefGoogle Scholar
Garrett, D, Failla, M & Sarama, R (1999) Development of an in vitro digestion method to assess carotenoid bioavailability from meals. J Agric Food Chem 47, 43014309.CrossRefGoogle Scholar
Garrett, D, Failla, M & Sarama, R (2000) Estimation of carotenoid bioavailability from fresh and stir-fried vegetables using an in vitro digestion/Caco-2 cell culture model. J Nutr Biochem 11, 574580.CrossRefGoogle ScholarPubMed
Gartner, C, Stahl, W & Sies, H (1996) Preferential increase in chylomicron levels of the xanthophylls lutein and zeaxanthin compared to β-carotene in the human. Int J Vitam Nutr Res 66, 119125.Google ScholarPubMed
Kostic, D, White, W & Olson, J (1995) Intestinal absorption, serum clearance, and interactions between lutein and β-carotene when administered to human adults in separate or combined oral doses. Am J Clin Nutr 62, 604610.CrossRefGoogle ScholarPubMed
Levy, J, Bosin, E, Feldman, B, Giat, Y, Münster, A, Danilenko, M & Sharoni, Y (1995) Lycopene is a more potent inhibitor of human cancer cell proliferation than either alpha-carotene or beta-carotene. Nutr Cancer 24, 257266.CrossRefGoogle ScholarPubMed
Lin, Y, Durker, S, Burri, B, Neidlinger, T & Clifford, A (2000) Variability of the conversion of β-carotene to vitamin A in women measured by using a double-tracer study design. Am J Clin Nutr 71, 15451554.CrossRefGoogle ScholarPubMed
Liu, C, Glahn, R & Liu, R (2004) Assessment of carotenoid bioavailability of whole foods using a Caco-2 cell culture model coupled with an in vitro digestion. J Agric Food Chem 52, 43304337.CrossRefGoogle ScholarPubMed
Luchoomun, J & Hussein, M (1999) Assembly and secretion of chylomicrons by differentiated Caco-2 cells. J Biol Chem 274(28), 1956519572.CrossRefGoogle ScholarPubMed
Olives Barba, A, Hutado, M, Sanchez Mata, M, Fernadez Ruiz, V & Lopez Saenz de Tejada, M (2006) Application of a UV-vis detection-HPLC method for a rapid determination of lycopene and β-carotene in vegetables. Food Chemistry 95, 328336.CrossRefGoogle Scholar
O'Neill, M & Thurnham, D (1998) Intestinal absorption of β-carotene, lycopene and lutein in men and women following a standard meal: Response curves in the triacylglycerol-rich lipoprotein fraction. Br J Nutr 79, 149159.CrossRefGoogle ScholarPubMed
O'Sullivan, S, Woods, J & O'Brien, N (2004) Use of tween 40 and tween 80 to deliver a mixture of phytochemicals to human colonic adenocarcinoma cell (Caco-2) monolayers. Br J Nutr 91, 757764.CrossRefGoogle ScholarPubMed
Pastori, M, Pfander, H, Boscoboinik, D & Azzi, A (1998) Lycopene in association with α-tocopherol inhibits at physiological concentrations proliferation of prostate carcinoma cells. Biochem Biophys Res Commun 250, 582585.CrossRefGoogle ScholarPubMed
Reboul, E, Abou, L, Mikail, C, Ghiringhelli, O, André, M, Potugal, H, Jourdheuil-Rahmani, D, Amiot, M, Lairon, D & Borel, P (2005) Lutein transport by Caco-2 TC-7 cells occurs partly by a facilitated process involving the scavenger receptor class B type 1 (SR-BI). Biochem J 387, 455461.CrossRefGoogle Scholar
Sambury, Y, Ferruzza, S, Ranaldi, G & De Angelis, I (2001) Intestinal cell culture models. Cell Biol Toxicol 17, 301317.CrossRefGoogle Scholar
Seeballuck, F, Ashford, M & O'Driscoll, C (2003) The effects of Pluronic® block copolymers and Cremophor® EL on intestinal lipoprotein processing and the potential link with P-glycoprotein in Caco-2 cells. Pharm Res 20, 10851092.CrossRefGoogle ScholarPubMed
Seeballuck, F, Lawless, E, Ashford, M & O'Driscoll, C (2004) Stimulation of triglyceride rich lipoprotein secretion by polysorbate 80: In vitro and in vivo correlation using Caco-2 cells and a cannulated rat intestinal lymphatic model. Pharm Res 21, 23202326.CrossRefGoogle Scholar
Stahl, W & Sies, H (2005) Bioactivity and protective effects of natural carotenoids. Biochim Biophys Acta 1740, 101107.CrossRefGoogle ScholarPubMed
Tang, G, Ferreria, A, Grusak, M, Qin, J, Dolnikowski, G, Russell, R & Krinsky, N (2005) Bioavailability of synthetic and biosynthetic deuterated lycopene in humans. J Nutr Biochem 16, 229235.CrossRefGoogle ScholarPubMed
Tyssandier, V, Cardinault, N, Caris-Veyrat, , Amiot, M, Grloier, P, Bouteloup, C, Azias-Braesco, V & Borel, P (2002) Vegetable borne lutein, lycopene and β-carotene compete for incorporation into chylomicrons, with no adverse effects on the medium-term (3-wk) plasma status of carotenoids in humans. Am J Clin Nutr 75, 526534.CrossRefGoogle Scholar
van Hof, K, Brouwer, I, West, C, Haddeman, E & van Dusseldorp, M (1999) Bioavailability of lutein from vegetables is 5 times higher than that of β-carotene. Am J Clin Nutr 70, 261268.CrossRefGoogle Scholar
van Hof, K, Gärtner, C, Wiersma, A, Tijburg, L & Weststrate, J (1999) Comparison of the bioavailability of natural palm oil carotenoids and synthetic β-carotene in humans. J Agric Food Chem 47, 15821586.CrossRefGoogle Scholar
Figure 0

Fig. 1 The percentage transfer of carotenoids to the basolateral chamber. Data are means representative of three of more independent experiments with their standard errors represented by vertical bars. (A) ■, α-carotene; □, β-carotene; , lycopene. (B) , lutein; , zeaxanthin. (C) , β-cryptoxanthin; , astaxanthin. a,b,c,d,e,f Mean values were significantly different for the following comparisons: av. all other β-carotene amounts (P < 0·01); bv. α-carotene at same amount (P < 0·05); cv. lycopene at same amount (P < 0·05); dv. 0·5 μg zeaxanthin (P < 0·05); ev. all other lutein amounts (P < 0·01); fv. astaxanthin at same amount (P < 0·05).

Figure 1

Table 1 The percentage carotene and xanthophyll carotenoids recovered from Caco-2 cells after 16 h incubation. Values are expressed as a percentage of the original quantities added to the cells and data are means representative of three or more independent experiments with their standard errors

Figure 2

Fig. 2 The percentage total uptake and secretion of carotenoids through the Caco-2 model. Data are means representative of three of more independent experiments with their standard errors represented by vertical bars. (A) ■, α-carotene; □, β-carotene; , lycopene. (B) , lutein; , zeaxanthin. (C) , β-cryptoxanthin; , astaxanthin. a,b,c,d,e,f Mean values were significantly different for the following comparisons: av. 0·5 μg lycopene (P < 0·05); bv. lycopene at same amount (P < 0·05); cv. 0·5 μg zeaxanthin (P < 0·05); dv. all other lutein amounts (P < 0·01); ev. 0·5 μg astaxanthin (P < 0·05); fv. β-cryptoxanthin at the same amount (P < 0·05).