Hostname: page-component-cd9895bd7-dk4vv Total loading time: 0 Render date: 2024-12-27T09:53:35.982Z Has data issue: false hasContentIssue false

Phytosterol supplementation reduces metabolic activity and slows cell growth in cultured rat cardiomyocytes

Published online by Cambridge University Press:  20 April 2011

Francesca Danesi
Affiliation:
Department of Food Sciences, Campus di Scienze degli Alimenti, Università di Bologna, Piazza Goidanich, 60, 47521Cesena, Italy
Federico Ferioli
Affiliation:
Department of Food Sciences, Campus di Scienze degli Alimenti, Università di Bologna, Piazza Goidanich, 60, 47521Cesena, Italy
Maria Fiorenza Caboni
Affiliation:
Department of Food Sciences, Campus di Scienze degli Alimenti, Università di Bologna, Piazza Goidanich, 60, 47521Cesena, Italy
Elisa Boschetti
Affiliation:
Department of Biochemistry “G. Moruzzi”, University of Bologna, Via Irnerio, 48, 40126Bologna, Italy
Mattia Di Nunzio
Affiliation:
Department of Biochemistry “G. Moruzzi”, University of Bologna, Via Irnerio, 48, 40126Bologna, Italy
Vito Verardo
Affiliation:
Department of Food Sciences, Campus di Scienze degli Alimenti, Università di Bologna, Piazza Goidanich, 60, 47521Cesena, Italy
Veronica Valli
Affiliation:
Department of Food Sciences, Campus di Scienze degli Alimenti, Università di Bologna, Piazza Goidanich, 60, 47521Cesena, Italy
Annalisa Astolfi
Affiliation:
Interdepartmental Centre for Cancer Research “G. Prodi”, University of Bologna, Via Massarenti, 9, 40138Bologna, Italy
Andrea Pession
Affiliation:
Department of Paediatrics, Haematology and Oncology Unit “Lalla Seragnoli”, St Orsola-Malpighi Hospital, University of Bologna, Via Massarenti, 9, 40138Bologna, Italy
Alessandra Bordoni*
Affiliation:
Department of Food Sciences, Campus di Scienze degli Alimenti, Università di Bologna, Piazza Goidanich, 60, 47521Cesena, Italy
*
*Corresponding author: A. Bordoni, fax +39 547 382348, email alessandra.bordoni@unibo.it
Rights & Permissions [Opens in a new window]

Abstract

Besides being cholesterol-lowering agents, phytosterols (PS) can inhibit the growth and development of tumours. The anti-neoplastic activity is accounted for by PS incorporation into cell membranes, resulting in the interference of membrane functionality. The similarity between the PS cholesterol-lowering and anti-neoplastic effective doses deserves attention on the possible adverse effects even in non-neoplastic cells. To date, few studies have addressed the clarification of this important issue. In the present study, we supplemented primary, non-neoplastic neonatal rat cardiomyocytes with two different PS concentrations (3 or 6 μg/ml), both within the range of human plasma concentration. Cardiac cells were chosen as an experimental model since the heart has been reported as the target organ for subchronic toxicity of PS. Following supplementation, a dose-dependent incorporation of PS and a decrease in cholesterol content were clearly evidenced. PS did not induce apoptosis but caused a reduction in metabolic activity (measured as 3-(4,5-dimethyldiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) conversion) and a slowing down of cell growth. The lower MTT conversion and the similar lactate dehydrogenase release could suggest that PS more efficiently target mitochondria than plasma membrane integrity. The replacement of cholesterol by PS could also have caused the observed slowing down of cell growth and the reduction in metabolic activity, which could rely on the PS increase, cholesterol decrease, or both. The present study is the first report on the effect of PS in cardiac cells, and although it is difficult to translate the obtained results to the health of heart tissue, it raises concerns about the safety of long-term exposure to physiologically relevant PS concentrations.

Type
Full Papers
Copyright
Copyright © The Authors 2011

Phytosterols or plant sterols (PS) are minor constituents and essential phytochemicals that are present in plant foods such as nuts, peanuts, sesame seeds, soyabean seeds and grains, as well as their products. The most common PS in foods are sitosterol (SS), campesterol and stigmasterol, representing about 50–65, 10–40 and 0–35 % of the total PS fraction, respectively(Reference Bradford and Awad1). PS are well-known cholesterol-lowering agents(Reference Abumweis, Barake and Jones2), and several theories have been proposed to explain their action(Reference Rozner and Garti3). Some studies have shown that PS compete with and displace cholesterol from bile salt/phospholipid micelles, the form from which cholesterol absorption occurs. SS has increased affinity for biliary micelles compared with cholesterol, so SS uptake by micelles is energetically favoured(Reference Awad, Chen and Fink4). Unlike cholesterol, PS are poorly absorbed, and the small absorbed amount is actively re-excreted into the bile, resulting in low serum levels of these sterol molecules. Notwithstanding the low plasma concentration, due to their similarities with cholesterol, PS can be incorporated into cell membranes and affect their composition and functionality(Reference Awad, Chen and Fink4).

Besides the cholesterol-lowering effect, PS have been shown to inhibit the growth and development of tumours(Reference Tapiero, Townsend and Tew5) at concentration levels within the physiological human blood range. Normal PS blood concentration in humans is about 10–15 μm, and it doubles when a vegetarian or a PS-rich diet is consumed(Reference Awad, Smith and Fink6, Reference Windler, Zyriax and Kuipers7). The anti-neoplastic activity of PS is accounted for by their incorporation into the cell membranes, resulting in the alteration of membrane fluidity, membrane-bound enzyme activity and signal transduction(Reference Ju, Clausen and Allred8).

Although, to date, clinical studies have demonstrated no obvious side effects of dietary PS, apart from a reduction in carotenoid blood levels(Reference Jones and AbuMweis9), the similarity between anti-neoplastic and cholesterol-lowering concentrations deserves attention. Few studies have addressed the effect of PS on non-neoplastic cells. Awad et al. (Reference Awad, Smith and Fink6) showed in an in vitro study that SS inhibited smooth muscle cell proliferation. Rubis et al. (Reference Rubis, Paszel and Kaczmarek10) evidenced strong cytotoxic properties of SS at a very low concentration (2 μm) in human abdominal aorta endothelial cells. These effects, keeping a balance between the proliferation and apoptosis of endothelial cells, have been considered positive in atherosclerosis prevention(Reference Mayr and Xu11). Notwithstanding, they further raise concerns about the possibility of the detrimental effects of PS on other non-neoplastic cell types and, therefore, on their long-term use as nutritional hypolipidaemic agents.

To further clarify this important issue, in the present study we evaluated the effect of the supplementation of a mixture of soyabean-derived PS, in which the main component was SS, using primary cultures of neonatal rat cardiomyocytes as a model of non-neoplastic cells. We chose primary cultures of cardiomyocytes for two main reasons. First, we wanted to avoid the use of immortalised cell lines derived from neoplastic cells. Second, the heart is considered to be the target organ for subchronic toxicity of PS(Reference Kim, Kang and Shin12). Due to the recommendation of high PS intake for a long time in primary and secondary cardiovascular prevention(Reference Marangoni and Poli13), the clarification of the effect of PS on cardiac cells is extremely important.

We supplemented cardiomyocytes with two different PS concentrations, both within the range of plasma concentration considered effective for the cholesterol-lowering effect(Reference Vanstone, Raeini-Sarjaz and Parsons14). To exclude that the observed effects, if any, could be accounted for by PS oxidation products (POP), which are negatively perceived in terms of health(Reference Hovenkamp, Demonty and Plat15), the POP content in the PS mixture used for supplementation was also determined.

The present results represent the first report of PS incorporation in cardiac cells and show evidence of the possibility of a negative effect related to their incorporation. It is important to consider that cultured cardiomyocytes represent a model system in which cells do not feel the effects of digestion, absorption, metabolism and hepatic detoxification. Results obtained in cultured cells do not unambiguously reflect what happens in the human body. Notwithstanding, they can focus on the activity of specific bioactive compounds and can represent the starting point for future clinical investigation.

Experimental methods

Materials

Horse serum, fetal calf serum, Ham F10 and other biochemicals, as well as the PS mixture (derived from soyabeans) used for supplementing cells, were from Sigma-Aldrich (St Louis, MO, USA). Chemicals and solvents, unless specified, were of analytical grade and purchased from Carlo Erba Reagenti (Rodano, Italy), Merck (Darmstadt, Germany) and Sigma-Aldrich. Dihydrocholesterol (assay 94·8 %), employed as an internal standard for the quantification of PS, and campesterol, stigmasterol and SS, used for the identification of PS compounds, were from Sigma-Aldrich. 19-Hydroxycholesterol from Steroloids (Newport, RI, USA) was employed as an internal standard to quantify POP in the PS mixture adopted for cell supplementation. Deionised water was obtained from a water purification system, Elix 10 (Millipore, Bedford, CT, USA).

Methods

Quantification of phytosterols and phytosterol oxidation products in the phytosterol mixture

Soyabean-derived PS mixture powder (10 mg) employed for cell supplementation was dissolved in 10 ml n-hexane–i-propanol (4:1, v/v). Dihydrocholesterol (0·2 mg) in n-hexane–i-propanol (4:1 (v/v), c = 1·9 mg/ml) was added as an internal standard to 1 ml of the PS solution. After silylation being performed according to Sweeley et al. (Reference Sweeley, Bentley and Makita16) and the addition of 4 ml of n-hexane, samples were centrifuged at 1000 g for 3 min. The resulting solution (1 μl) was analysed using a GC/MS apparatus model, GCMS-QP2010 Plus (Shimadzu, Tokyo, Japan). Gas chromatographic conditions were as follows: injector temperature, 310°C; oven temperature, from 265 to 310°C at 0·80°C/min, finally held at 310°C for 10 min; gas carrier (He) velocity, 30·0 cm/s. The separation was carried out on a fused silica capillary column Zebron ZB-5 (30 m × 0·25 mm internal diameter, 0·25 μm film thickness) coated with 95 % dimethyl–5 % diphenyl polysiloxane (Phenomenex, Torrance, CA, USA). Instrumental conditions employed for the MS detector were as follows: acquisition mode, total ion current; ion source temperature, 230°C; interface temperature, 210°C; detector voltage, 0·95 kV; scan range, from 40 to 600 m/z; scan speed, 1250 u/s; solvent delay time, 10 min. Data were filed and processed by the software GCMSsolution version 2.50 SU1 from Shimadzu. PS identification was achieved by comparing peak mass spectra with those obtained from a standard mixture containing campesterol, stigmasterol and SS and with the data reported by Pelillo et al. (Reference Pelillo, Iafelice and Marconi17). Quantification of identified PS was done relative to dihydrocholesterol.

To evaluate the content of POP in the soyabean-derived PS mixture, 10 μg of 19-hydroxycholesterol in n-hexane–i-propanol (4:1, v/v) were added as the internal standard (c = 0·1 mg/ml) to 3 ml of the aforementioned PS solution in n-hexane–i-propanol. After drying and the addition of 1 ml of n-hexane–ethyl acetate (95:5, v/v), POP were purified by solid-phase extraction(Reference Rose-Sallin, Huggett and Bosset18) using aminopropyl-bonded phase cartridges (STRATA NH2, 500 mg stationary phase, 3 ml reservoir volume) from Phenomenex. To evaluate the recovery of the procedure, 9 μg of dihydrocholesterol in n-hexane–i-propanol (4:1 (v/v), c = 0·07 mg/ml) were added to the POP-containing fraction, which was then silylated(Reference Sweeley, Bentley and Makita16), and centrifuged at 1000 g for 3 min after the addition of 300 μl of n-hexane. The resulting solution (1 μl) was analysed by GC/MS under the same conditions as reported earlier. POP were identified by comparing the peak mass spectra with those reported by Dutta(Reference Dutta, Guardiola, Dutta, Codony and Savage19). Quantification of identified POP was done relative to 19-hydroxycholesterol.

Cell culture

Heart cells were obtained from the ventricles of 2–4-d-old Wistar rats as reported(Reference Danesi, Di Nunzio and Boschetti20). This investigation conforms to the Guide for the Care and Use of Laboratory Animals published by the US National Institutes of Health (publication no. 85-23, 5 revised 1996). The study was approved by the Ethical Committee for Animal Care of the University of Bologna (Italy) (protocol no. 58897-X/10). Apart from cell growth determination, due to technical reasons, cells were seeded at 1 × 106 cells/ml concentration. At 24 h after seeding (T0), cardiomyocytes were divided at random in control, grown in a control medium (Ham F10 plus 10 % fetal calf serum plus 10 % horse serum), and supplemented and grown in the same medium supplemented with PS (3 or 6 μg/ml). The PS stock solution (600 μg/ml) was prepared by dissolving the mother solution (derived from soyabeans, and containing 45 % SS, 35 % campesterol and 5 % stigmasterol, as determined) in 100 % ethanol. Control cells received a similar amount of ethanol ( < 0·01 %, v/v) to avoid interference due to the vehicle. Media were changed every 2 d, the last change being 48 h before the experiment. Before each determination, at each time point, viable cells were counted by trypan blue dye exclusion. On day 6 (T144), control cardiomyocytes were at complete confluence, as assessed by cell counting and by protein determination with the method of Bradford(Reference Bradford21).

Cell count: trypan blue exclusion test

The trypan blue exclusion test was performed by adding 25 μl of 0·1 % trypan blue solution to 100 μl of cells suspended in PBS. The cells that excluded the dye were counted on a haemocytometer as described(Reference Ahmad, White and Chang22).

Identification and quantification of phytosterols in cardiomyocytes by GC/MS

On day 6 (T144), cells were washed three times in PBS and scraped off in cold n-hexane–isopropanol (4:1, v/v). PS were recovered from lipids after a cold saponification(Reference Sander, Addis and Park23), using dihydrocholesterol as the internal standard. Before GC/MS analysis, the trimethylsilyl derivatives of PS were obtained as reported by Sweeley et al. (Reference Sweeley, Bentley and Makita16). The derivatised sample (1 μl) was analysed under the same conditions as reported previously. PS identification was achieved by comparing peak mass spectra with a standard mixture containing campesterol, stigmasterol and SS and with the data reported by Pelillo et al. (Reference Pelillo, Iafelice and Marconi17). Quantification of identified PS was done relative to dihydrocholesterol.

Cytotoxicity

According to the cytotoxicity assay techniques, cytotoxicity was evaluated as cell metabolic activity using the 3-(4,5-dimethyldiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) colorimetric assay(Reference Wichmann, Daegelmann and Herbarth24). At T144, after a washing with 0·9 % NaCl, 1 ml of MTT reagent diluted in Roswell Park Memorial Institute (RPMI)-1640 medium modified without phenol red (1 mg/ml) was added to each dish, and the cell cultures were incubated for 3 h at 37°C. After removal of the medium, the cells were lysed with isopropanol for 15–20 min. Formazan production, which is proportional to cell vitality, was determined spectrophotometrically at 560 nm.

Cell growth curve

Cells were seeded in twenty-four-well plates at a concentration of 2 × 105/well. For each time point, two to four replicates were performed. Viable cells were counted each day for the following 6 d (T0, T24, T48, T96, T120 and T144).

Cell cycle

Cells were seeded in duplicate in six-well plates. At each time point (T0, T12, T24, T48, T72, T96 and T144), cardiomyocytes were washed with PBS, harvested and resuspended in 500 μl of a solution (0·1 % sodium citrate, 0·1 % Triton X-100 in PBS) containing propidium iodide (PI, 50 μg/ml), as described(Reference Nicoletti, Migliorati and Pagliacci25). Cell cycle analysis was performed by cytofluorimetric detection of DNA content with a FACSCalibur Cytometer (Becton Dickinson, Mansfield, MA, USA) after staining with PI.

Apoptosis

Cells were plated in duplicate in six-well plates. At each time point (T0, T12, T24, T48, T72, T96 and T144), after counting for viable cells, cell number was normalised to 5 × 105, and apoptosis was verified using two different methods. In the first one (PI uptake), cells were washed with PBS, harvested and resuspended in 500 μl of PI buffer(Reference Nicoletti, Migliorati and Pagliacci25). PI-stained cells were analysed by flow cytometry as described previously; apoptotic cells were counted as the percentage of sub-G1 cells. In the second one (Annexin-V binding), cells were washed with PBS, harvested and resuspended in 100 μl of Annexin-V-Fluos and PI-labelling solution (Roche, Penzberg, Germany) for 15 min. The stained cells were analysed by flow cytometry with a FACSCalibur Cytometer (Becton Dickinson); apoptotic cells were counted as the percentage of Annexin-V-positive, PI-negative cells.

Cell membrane damage: lactate dehydrogenase release in media

Cells were seeded in duplicate in six-well plates. To evaluate the possible damage to cell membrane integrity, the release of the lactate dehydrogenase enzyme in the media was determined. At each time point (T24, T48, T96 and T144), lactate dehydrogenase activity in the media was determined spectrophotometrically by measuring NADH levels at 340 nm(Reference Korzeniewski and Callewaert26).

Statistical analysis

The reported data are the means of at least three samples obtained from independent cell cultures. Statistical analysis was carried out by one-way ANOVA using Tukey's post-test. P values less than 0·05 were considered significant.

Results

The composition of the supplemented PS solution was analysed before experiments and is reported in Fig. 1. The total POP content in the PS mixture was low (0·124 (sd 0·012) g/100 g), and the amount of single POP identified is shown in Fig. 2. As regards the performance of the analytical methods employed in the present study, the determination of PS after cold saponification ensured a good reproducibility, with a relative standard deviation associated with total PS amount, which was usually less than 5 %. POP purification in the cell feeding mixture by solid-phase extraction showed a high recovery percentage (85·9 (sd 1·5) %) and an acceptable reproducibility (approximately 9 %) with regard to the amount of total oxidised sterols detected.

Fig. 1 Gas chromatographic trace of trimethylsilyl ethers of sterols contained in the phytosterol mixture. Peak identification: internal standard (IS, dihydrocholesterol); 1, cholesterol; 2, brassicasterol; 3, campesterol; 4, campestanol; 5, stigmasterol; 6, stigmastanol; 7, clerosterol; 8, sitosterol; 9, sitostanol; 10, avenasterol; 11, fucosterol; 12, Δ7-sitosterol. For analytical conditions, see the Methods section.

Fig. 2 Gas chromatographic trace of trimethylsilyl ethers of phytosterol (PS) oxidation products purified from the PS mixture. Peak identification: internal standard 1 (IS1, dihydrocholesterol); IS2, 19-hydroxy cholesterol; 1, 7α-hydroxy campesterol; 2, 7α-hydroxy stigmasterol; 3, 7α-hydroxy sitosterol; 4, sitotrienol; 5, 7β-hydroxy sitosterol; 6, 7-ketocampesterol; 7, 7-ketostigamsterol; 8, 7-ketositosterol. Peaks marked with an asterisk were non-oxidised sterols. Other peaks were not identified. For analytical conditions, see the Methods section.

Incorporation of supplemented PS by cardiomyocytes was verified at T144. On that day, control cardiomyocytes were at complete confluence, as determined by microscopy. To evaluate whether PS-supplemented cardiomyocytes also reached confluence at T144, cells were counted and protein content was determined, showing no differences among groups (Table 1). As shown in Fig. 3, cardiomyocytes actively incorporated the supplemented PS, in a dose-dependent manner (r 2 0·92). Cholesterol content significantly decreased in PS-supplemented cardiomyocytes compared with controls, with no difference between the two supplemented groups. According to the composition of the supplemented PS solution, SS appeared to be the most incorporated one, followed by campesterol and stigmasterol (Fig. 4). Fig. 5 illustrates the different chromatographic traces of PS extracted from cardiomyocytes grown in non-supplemented and supplemented media.

Table 1 Cell number and protein content at day 6 (T144) in the different experimental conditions*

(Mean values and standard deviations of at least three samples obtained from independent cell cultures)

PS, phytosterol.

*  No differences in cell number and protein among the different experimental conditions were determined by one-way ANOVA.

Fig. 3 Total phytosterol (PS) and cholesterol content of unsupplemented and supplemented cardiomyocytes. PS and cholesterol concentrations were determined as described in the Methods section. Results are expressed as μg/dish and are means of at least three samples obtained from independent cell cultures, with standard deviations represented by vertical bars. Mean percentage changes with respect to unsupplemented cells are reported above the corresponding bar. Statistical analysis was carried out by one-way ANOVA (PS: P < 0·001, cholesterol: P < 0·01) using Tukey's post-test (control v. PS: * P < 0·05, ** P < 0·01, *** P < 0·001; 3 μg/ml v. 6 μg/ml: PS P < 0·001, cholesterol: NS). □, Control; , PS (3 μg/ml); , PS (6 μg/ml).

Fig. 4 Distribution of the different phytosterols (PS) in unsupplemented and supplemented cardiomyocytes. PS incorporation was determined as described in the Methods section. Results are expressed as μg/dish and are means of at least three samples obtained from independent cell cultures, with standard deviations represented by vertical bars. Mean percentage changes with respect to unsupplemented cells are reported above the corresponding bar. Statistical analysis was carried out by one-way ANOVA (campesterol, P < 0·001; stigmasterol, P < 0·001; sitosterol, P < 0·001; avenasterol, P < 0·01) using Tukey's post-test for evaluating differences between PS-supplemented cells and control (* P < 0·05, ** P < 0·01, *** P < 0·001) and between the two PS concentrations used (campesterol, P < 0·001; stigmasterol, P < 0·01; sitosterol, P < 0·001; avenasterol, NS). ND, not determined. □, Control; , PS (3 μg/ml); , PS (6 μg/ml).

Fig. 5 Gas chromatographic traces of trimethylsilyl ethers of sterols recovered from the lipid fraction of unsupplemented and phytosterol (PS)-supplemented cardiomyocytes. Cardiomyocytes were grown in unsupplemented (trace A), 3 μg/ml PS-supplemented (trace B) and 6 μg/ml PS-supplemented (trace C) media. Peak identification: internal standard (IS, dihydrocholesterol); 1, cholesterol; 2, campesterol; 3, campestanol; 4, stigmasterol; 5, stigmastanol; 6, clerosterol; 7, sitosterol; 8, sitostanol; 9, avenasterol. For analytical conditions, see the Methods section.

To verify the possible interference between the observed PS incorporation and cardiomyocyte metabolic activity, the MTT assay was also performed at T144. MTT conversion to formazan appeared reduced in supplemented cardiomyocytes compared with controls, independent of PS concentration in the media (Fig. 6).

Fig. 6 Metabolic activity in unsupplemented and phytosterol (PS)-supplemented cardiomyocytes. 3-(4,5-Dimethyldiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) conversion to formazan, as a measure of metabolic activity, was determined as reported in the Methods section and expressed as the percentage of the value obtained in unsupplemented cells (assigned as 100 %). Values are means of at least three samples obtained from independent cell cultures, with standard deviations represented by vertical bars. Mean percentage changes with respect to unsupplemented cells are reported above the corresponding bar. Statistical analysis was carried out by one-way ANOVA (P < 0·001) using Tukey's post-test (control v. PS: *** P < 0·001; 3 μg/ml v. 6 μg/ml: NS).

The pro- or anti-apoptotic effects of PS were investigated using two different independent methods: PI uptake (data not shown) and Annexin-V (Fig. 7). One of the earliest features of apoptosis is a morphological change in the plasma membrane. This involves the translocation of the membrane phospholipid phosphatidylserine from the internal layer to the external layer of the cell membrane. In the presence of Ca ions, Annexin-V has a high specificity and affinity for phospholipid phosphatidylserine. The translocation of phospholipid phosphatidylserine precedes detectable nuclear changes such as DNA degradation, allowing early apoptotic cells to be discerned. Apoptotic cells become Annexin-V-positive after nuclear condensation has started, but before the cell becomes permeable to PI. As a result, early apoptotic cells can be Annexin-V-positive and PI-negative. After having evidenced no differences at any time point in the number of apoptotic cells with PI staining, to be sure that PS supplementation did not cause apoptosis, we measured it with the Annexin-V assay. Even in this case, no differences between the control and supplemented cells were detected.

Fig. 7 Apoptotic effect of phytosterol (PS) supplementation evaluated using Annexin-V at different time points. Values are means of at least three samples obtained from independent cell cultures, with standard deviations represented by vertical bars. Mean percentage changes with respect to unsupplemented cells are reported above the corresponding bar. No differences in the number of apoptotic cells were detected among groups at any time point by one-way ANOVA. □, Control; , PS (3 μg/ml); , PS (6 μg/ml).

Lactate dehydrogenase release in the media was also evaluated, and no differences were detected among groups at any time point (data not shown).

Regarding the cell cycle, the distribution of cell populations was similar in both the control and PS-supplemented cells (Fig. 8), but significant differences were observed in the growth curve. Performing this analysis, for technical reasons, cells were seeded at a lower concentration to prevent them from reaching confluence in an early stage, therefore hiding possible differences in cell growth. As evidenced in Fig. 9, the supplemented cardiomyocytes grew more slowly than the controls.

Fig. 8 Cell cycle distribution in control and phytosterol (PS)-supplemented cardiomyocytes at different time points. The bar graph shows the distribution of cells among the different phases of the cell cycle: G0/G1 phase, quiescent cells; S phase, DNA replicating cells; G2/M phase, cells with two full complements of DNA or at the mitotic phase. Values are means of at least three samples obtained from independent cell cultures, with standard deviations represented by vertical bars. No differences in the cell cycle distribution were detected among groups at any time point by one-way ANOVA. , G1 phase; , S phase; □, G2 phase.

Fig. 9 Cell growth analysis in unsupplemented and phytosterol (PS)-supplemented cardiomyocytes. Cell growth analysis was performed as reported in the Methods section, and cells counted at different time points. Values are means of at least three samples obtained from independent cell cultures, with standard deviations represented by vertical bars. Mean percentage changes with respect to unsupplemented cells are reported above the corresponding bar. Statistical analysis was carried out by one-way ANOVA (P < 0·05) using Tukey's post-test (control v. PS: * P < 0·05; 3 μg/ml v. 6 μg/ml: NS). ●, Control; , PS (3 μg/ml); ■, PS (6 μg/ml).

Discussion

In neoplastic cells, PS anti-proliferative activity is accounted for by their incorporation into cell membranes(Reference Awad, Downie and Fink27), but the effects of PS incorporation into normal cells have been described in few studies, and never into cardiac cells. In the present study, following supplementation, a dose-dependent incorporation of PS by cardiomyocytes was clearly evidenced. It was accompanied by a decrease in cholesterol content.

Although it has been reported that SS induces apoptosis in cancer cells through caspase activation(Reference Awad, Roy and Fink28), we did not observe apoptosis in cardiomyocytes. Recently, Bao et al. (Reference Bao, Li and Deng29) showed evidence that SS did not activate the caspase-dependent pathway in non-neoplastic macrophages. The observed death of these cells was caspase-independent, involving necroptosis and autophagy, and was induced by SS concentration higher than those used in the present study.

The reduction in MTT into formazan pigment predominantly depends upon mitochondrial reductase activity and is also correlated with the mitochondrial metabolic capacity(Reference Gomez, Alekseev and Aleksandrova30). The lower MTT conversion observed in PS-supplemented cells suggests that the study compounds more efficiently target mitochondria, including cytochrome activity, than plasma membrane integrity. This is in agreement with our data on lactate dehydrogenase release.

Mitochondrial metabolism provides the heart with very high amounts of ATP daily(Reference Opie and Weinberg31), and the importance of intermediary metabolism to sustain the function of the heart has long been appreciated. The decrease in MTT reduction activity in PS-supplemented cardiomyocytes could suggest that cardiac energy metabolism is switched from the β-oxidation of fatty acids to glycolysis(Reference Kakinuma, Miyauchi and Yuki32), and Taegtmeyer(Reference Taegtmeyer33) has proposed that metabolic changes often antedate functional contractile changes in the heart. The reduced cell metabolic activity could also explain the results obtained on the cell growth curve. Further studies focused on mitochondrial metabolic activity, as well as on the evaluation of PS incorporation into mitochondria, are needed before unambiguously concluding that PS alter mitochondrial function and cardiac cell energy metabolism.

The replacement of cholesterol by PS could also have caused the observed slowing down of cell growth and the reduction in metabolic activity, which could rely on the PS increase, cholesterol decrease, or both. High sterol concentration within the cells is cytotoxic, and the enzyme acyl-CoA cholesterol acyltransferase represents one of the most important mechanisms for reducing excess sterols, preventing cytotoxicity(Reference Chang, Chang and Cheng34, Reference Tabas35). Previous studies have shown that PS are relatively poor substrates for acyl-CoA cholesterol acyltransferase(Reference Temel, Gebre and Parks36, Reference Liu, Chang and Westover37). According to the present results, Melchert et al. (Reference Melchert, Liu and Granberry38) showed evidence that the decrease in cell cholesterol content, due to the inhibition of cholesterol synthesis by statins, reduces growth and MTT reduction in cardiac myocytes, without significant changes in PI staining. Furthermore, replacement of cholesterol molecules by PS increases ion permeability(Reference Vemuri and Philipson39) and modifies the activity of enzymes such as Na+/K+-ATPase(Reference Naito, Nagata and Takano40) in biomembranes.

Another possible explanation of the present results could be related to PS oxidation. POP are formed during the processing and storage of foods. Although the currently available observations do not suggest that dietary POP, in relatively low concentrations such as those reported in human plasma, may exert in vivo deleterious effects similar to those attributed to oxycholesterol(Reference Hovenkamp, Demonty and Plat15), whether they affect human health is still unknown. Particularly, PS oxidation processes could take place in cells, producing not only harmful epoxy forms but also generating free radicals(Reference Rubis, Paszel and Kaczmarek10). Although POP were present in low amounts in the PS mixture used for cell supplementation, negative effects of PS could be in part dependent on POP production within the cell. Further studies are in progress to clarify this point.

A very recent study has shown evidence that β-SS at concentrations similar to those used in the present study inhibited vascular smooth muscle cell proliferation, interrupting the progress of the cell cycle, without affecting MTT conversion(Reference Chien, Lee and Liang41). It is therefore evident that the effects of PS can vary among cell types. The present study is the first report on the incorporation of PS in cardiac cells and on its consequent effect. Although PS supplementation appeared less deleterious than in neoplastic cells, the present results deserve important consideration. It is important to note that we grew cardiomyocytes in PS-supplemented media, so reproducing more closely the in vivo situation when consuming a PS-rich diet. In other studies, higher PS concentrations were supplemented to cells for a short time period.

Although, at present, it is difficult to translate the obtained results to the health of heart tissue, the slowed cardiac cell growth and metabolic activity could represent a potential hazard. The present results are far from giving unambiguous answers to this important concern, but they represent the starting point for future research. In their light, as already suggested by Lizard(Reference Lizard42), further investigations, evaluating the biological impact of long-term exposure to physiologically relevant PS concentrations in human subjects, are needed. They could verify the existence of a potential hazard due to the wide use of these bioactive compounds in the prevention and treatment of hypercholesterolaemia.

Acknowledgements

The authors declare that there are no conflicts of interest. The present study was supported by grants of Fondazione Cassa di Risparmio di Cesena (Italy) and of Italian MIUR (RFO). The authors' contributions were as follows: F. F., E. B., M. D. N., V. Ve., V. Va. and A. A. performed the analysis together with F. D., who also did the data analysis and contributed to the drafting of the manuscript; M. F. C. and A. B. designed and supervised the study, and wrote the manuscript together with A. P.

References

1 Bradford, PG & Awad, AB (2007) Phytosterols as anticancer compounds. Mol Nutr Food Res 51, 161170.CrossRefGoogle ScholarPubMed
2 Abumweis, SS, Barake, R & Jones, PJ (2008) Plant sterols/stanols as cholesterol lowering agents: a meta-analysis of randomized controlled trials. Food Nutr Res 52 (Epublication ahead of print version 18 August 2008).CrossRefGoogle ScholarPubMed
3 Rozner, S & Garti, N (2006) The activity and absorption relationship of cholesterol and phytosterols. Colloids Surf A: Physicochem Eng Asp 282–283, 435456.CrossRefGoogle Scholar
4 Awad, AB, Chen, YC, Fink, CS, et al. (1996) Beta-sitosterol inhibits HT-29 human colon cancer cell growth and alters membrane lipids. Anticancer Res 16, 27972804.Google ScholarPubMed
5 Tapiero, H, Townsend, DM & Tew, KD (2003) Phytosterols in the prevention of human pathologies. Biomed Pharmacother 57, 321325.CrossRefGoogle ScholarPubMed
6 Awad, AB, Smith, AJ & Fink, CS (2001) Plant sterols regulate rat vascular smooth muscle cell growth and prostacyclin release in culture. Prostaglandins Leukot Essent Fatty Acids 64, 323330.CrossRefGoogle ScholarPubMed
7 Windler, E, Zyriax, BC, Kuipers, F, et al. (2009) Association of plasma phytosterol concentrations with incident coronary heart disease Data from the CORA study, a case–control study of coronary artery disease in women. Atherosclerosis 203, 284290.CrossRefGoogle ScholarPubMed
8 Ju, YH, Clausen, LM, Allred, KF, et al. (2004) Beta-sitosterol, beta-sitosterol glucoside, and a mixture of beta-sitosterol and beta-sitosterol glucoside modulate the growth of estrogen-responsive breast cancer cells in vitro and in ovariectomized athymic mice. J Nutr 134, 11451151.CrossRefGoogle Scholar
9 Jones, PJ & AbuMweis, SS (2009) Phytosterols as functional food ingredients: linkages to cardiovascular disease and cancer. Curr Opin Clin Nutr Metab Care 12, 147151.CrossRefGoogle ScholarPubMed
10 Rubis, B, Paszel, A, Kaczmarek, M, et al. (2008) Beneficial or harmful influence of phytosterols on human cells? Br J Nutr 100, 11831191.CrossRefGoogle ScholarPubMed
11 Mayr, M & Xu, Q (2001) Smooth muscle cell apoptosis in arteriosclerosis. Exp Gerontol 36, 969987.CrossRefGoogle ScholarPubMed
12 Kim, JC, Kang, BH, Shin, CC, et al. (2002) Subchronic toxicity of plant sterol esters administered by gavage to Sprague–Dawley rats. Food Chem Toxicol 40, 15691580.CrossRefGoogle ScholarPubMed
13 Marangoni, F & Poli, A (2010) Phytosterols and cardiovascular health. Pharmacol Res 61, 193199.CrossRefGoogle ScholarPubMed
14 Vanstone, CA, Raeini-Sarjaz, M, Parsons, WE, et al. (2002) Unesterified plant sterols and stanols lower LDL-cholesterol concentrations equivalently in hypercholesterolemic persons. Am J Clin Nutr 76, 12721278.CrossRefGoogle ScholarPubMed
15 Hovenkamp, E, Demonty, I, Plat, J, et al. (2008) Biological effects of oxidized phytosterols: a review of the current knowledge. Prog Lipid Res 47, 3749.CrossRefGoogle ScholarPubMed
16 Sweeley, CC, Bentley, R, Makita, M, et al. (2002) Gas–liquid chromatography of trimethylsilyl derivatives of sugars and related substances. J Am Chem Soc 85, 24972507.Google Scholar
17 Pelillo, M, Iafelice, G, Marconi, E, et al. (2003) Identification of plant sterols in hexaploid and tetraploid wheats using gas chromatography with mass spectrometry. Rapid Commun Mass Spectrom 17, 22452252.CrossRefGoogle ScholarPubMed
18 Rose-Sallin, C, Huggett, AC, Bosset, JO, et al. (1995) Quantification of cholesterol oxidation products in milk powders using [2H7]cholesterol to monitor cholesterol autoxidation artifacts. J Agric Food Chem 43, 935941.CrossRefGoogle Scholar
19 Dutta, PC (2002) Determination of phytosterol oxidation products in foods and biological samples. In Cholesterol and Phytosterol Oxidation Products – Analysis, Occurrence, and Biological Effects, pp. 335374 [Guardiola, F, Dutta, PC, Codony, R and Savage, GP, editors]. Champaign, IL: AOCS Press.Google Scholar
20 Danesi, F, Di Nunzio, M, Boschetti, E, et al. (2009) Green tea extract selectively activates peroxisome proliferator-activated receptor beta/delta in cultured cardiomyocytes. Br J Nutr 101, 17361739.CrossRefGoogle ScholarPubMed
21 Bradford, MM (1976) A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Anal Biochem 72, 248254.CrossRefGoogle ScholarPubMed
22 Ahmad, S, White, CW, Chang, LY, et al. (2001) Glutamine protects mitochondrial structure and function in oxygen toxicity. Am J Physiol Lung Cell Mol Physiol 280, L779L791.Google Scholar
23 Sander, BD, Addis, PB, Park, SW, et al. (1989) Quantification of cholesterol oxidation products in a variety of foods. J Food Prot 52, 109114.CrossRefGoogle Scholar
24 Wichmann, G, Daegelmann, C, Herbarth, O, et al. (2004) Inflammatory activity in river-water samples. Environ Toxicol 19, 594602.CrossRefGoogle ScholarPubMed
25 Nicoletti, I, Migliorati, G, Pagliacci, MC, et al. (1991) A rapid and simple method for measuring thymocyte apoptosis by propidium iodide staining and flow cytometry. J Immunol Methods 139, 271279.CrossRefGoogle ScholarPubMed
26 Korzeniewski, C & Callewaert, DM (1983) An enzyme-release assay for natural cytotoxicity. J Immunol Methods 64, 313320.CrossRefGoogle ScholarPubMed
27 Awad, AB, Downie, AC & Fink, CS (2000) Inhibition of growth and stimulation of apoptosis by beta-sitosterol treatment of MDA-MB-231 human breast cancer cells in culture. Int J Mol Med 5, 541545.Google ScholarPubMed
28 Awad, AB, Roy, R & Fink, CS (2003) Beta-sitosterol, a plant sterol, induces apoptosis and activates key caspases in MDA-MB-231 human breast cancer cells. Oncol Rep 10, 497500.Google ScholarPubMed
29 Bao, L, Li, Y, Deng, SX, et al. (2006) Sitosterol-containing lipoproteins trigger free sterol-induced caspase-independent death in ACAT-competent macrophages. J Biol Chem 281, 3363533649.CrossRefGoogle ScholarPubMed
30 Gomez, LA, Alekseev, AE, Aleksandrova, LA, et al. (1997) Use of the MTT assay in adult ventricular cardiomyocytes to assess viability: effects of adenosine and potassium on cellular survival. J Mol Cell Cardiol 29, 12551266.CrossRefGoogle ScholarPubMed
31 Opie, LH (1998) Fuels: aerobic and anaerobic metabolism. In The Heart: Physiology, from Cell to Circulation, 3rd ed., pp. 295342 [Weinberg, RWSK, editor]. Philadelphia, PA: Lippincott-Raven.Google Scholar
32 Kakinuma, Y, Miyauchi, T, Yuki, K, et al. (2000) Mitochondrial dysfunction of cardiomyocytes causing impairment of cellular energy metabolism induces apoptosis, and concomitant increase in cardiac endothelin-1 expression. J Cardiovasc Pharmacol 36, S201S204.CrossRefGoogle ScholarPubMed
33 Taegtmeyer, H (2010) Tracing cardiac metabolism in vivo: one substrate at a time. J Nucl Med 51, 80S87S.CrossRefGoogle ScholarPubMed
34 Chang, TY, Chang, CC & Cheng, D (1997) Acyl-coenzyme A:cholesterol acyltransferase. Annu Rev Biochem 66, 613638.CrossRefGoogle ScholarPubMed
35 Tabas, I (2002) Consequences of cellular cholesterol accumulation: basic concepts and physiological implications. J Clin Invest 110, 905911.Google Scholar
36 Temel, RE, Gebre, AK, Parks, JS, et al. (2003) Compared with Acyl-CoA:cholesterol O-acyltransferase (ACAT) 1 and lecithin:cholesterol acyltransferase, ACAT2 displays the greatest capacity to differentiate cholesterol from sitosterol. J Biol Chem 278, 4759447601.CrossRefGoogle ScholarPubMed
37 Liu, J, Chang, CC, Westover, EJ, et al. (2005) Investigating the allosterism of acyl-CoA:cholesterol acyltransferase (ACAT) by using various sterols: in vitro and intact cell studies. Biochem J 391, 389397.CrossRefGoogle ScholarPubMed
38 Melchert, RB, Liu, H, Granberry, MC, et al. (2001) Lovastatin inhibits phenylephrine-induced ERK activation and growth of cardiac. Cardiovasc Toxicol 1, 237252.Google Scholar
39 Vemuri, R & Philipson, KD (1989) Influence of sterols and phospholipids on sarcolemmal and sarcoplasmic reticular cation transporters. J Biol Chem 264, 86808685.CrossRefGoogle ScholarPubMed
40 Naito, Y, Nagata, T, Takano, Y, et al. (2003) Rapeseed oil ingestion and exacerbation of hypertension-related conditions in stroke prone spontaneously hypertensive rats. Toxicology 187, 205216.CrossRefGoogle ScholarPubMed
41 Chien, MH, Lee, TS, Liang, YC, et al. (2010) Beta-sitosterol inhibits cell cycle progression of rat aortic smooth muscle cells through increases of p21cip1 protein. J Agric Food Chem 58, 1006410069.CrossRefGoogle ScholarPubMed
42 Lizard, G (2008) Phytosterols: to be or not to be toxic; that is the question. Br J Nutr 100, 11501151.CrossRefGoogle ScholarPubMed
Figure 0

Fig. 1 Gas chromatographic trace of trimethylsilyl ethers of sterols contained in the phytosterol mixture. Peak identification: internal standard (IS, dihydrocholesterol); 1, cholesterol; 2, brassicasterol; 3, campesterol; 4, campestanol; 5, stigmasterol; 6, stigmastanol; 7, clerosterol; 8, sitosterol; 9, sitostanol; 10, avenasterol; 11, fucosterol; 12, Δ7-sitosterol. For analytical conditions, see the Methods section.

Figure 1

Fig. 2 Gas chromatographic trace of trimethylsilyl ethers of phytosterol (PS) oxidation products purified from the PS mixture. Peak identification: internal standard 1 (IS1, dihydrocholesterol); IS2, 19-hydroxy cholesterol; 1, 7α-hydroxy campesterol; 2, 7α-hydroxy stigmasterol; 3, 7α-hydroxy sitosterol; 4, sitotrienol; 5, 7β-hydroxy sitosterol; 6, 7-ketocampesterol; 7, 7-ketostigamsterol; 8, 7-ketositosterol. Peaks marked with an asterisk were non-oxidised sterols. Other peaks were not identified. For analytical conditions, see the Methods section.

Figure 2

Table 1 Cell number and protein content at day 6 (T144) in the different experimental conditions*(Mean values and standard deviations of at least three samples obtained from independent cell cultures)

Figure 3

Fig. 3 Total phytosterol (PS) and cholesterol content of unsupplemented and supplemented cardiomyocytes. PS and cholesterol concentrations were determined as described in the Methods section. Results are expressed as μg/dish and are means of at least three samples obtained from independent cell cultures, with standard deviations represented by vertical bars. Mean percentage changes with respect to unsupplemented cells are reported above the corresponding bar. Statistical analysis was carried out by one-way ANOVA (PS: P < 0·001, cholesterol: P < 0·01) using Tukey's post-test (control v. PS: * P < 0·05, ** P < 0·01, *** P < 0·001; 3 μg/ml v. 6 μg/ml: PS P < 0·001, cholesterol: NS). □, Control; , PS (3 μg/ml); , PS (6 μg/ml).

Figure 4

Fig. 4 Distribution of the different phytosterols (PS) in unsupplemented and supplemented cardiomyocytes. PS incorporation was determined as described in the Methods section. Results are expressed as μg/dish and are means of at least three samples obtained from independent cell cultures, with standard deviations represented by vertical bars. Mean percentage changes with respect to unsupplemented cells are reported above the corresponding bar. Statistical analysis was carried out by one-way ANOVA (campesterol, P < 0·001; stigmasterol, P < 0·001; sitosterol, P < 0·001; avenasterol, P < 0·01) using Tukey's post-test for evaluating differences between PS-supplemented cells and control (* P < 0·05, ** P < 0·01, *** P < 0·001) and between the two PS concentrations used (campesterol, P < 0·001; stigmasterol, P < 0·01; sitosterol, P < 0·001; avenasterol, NS). ND, not determined. □, Control; , PS (3 μg/ml); , PS (6 μg/ml).

Figure 5

Fig. 5 Gas chromatographic traces of trimethylsilyl ethers of sterols recovered from the lipid fraction of unsupplemented and phytosterol (PS)-supplemented cardiomyocytes. Cardiomyocytes were grown in unsupplemented (trace A), 3 μg/ml PS-supplemented (trace B) and 6 μg/ml PS-supplemented (trace C) media. Peak identification: internal standard (IS, dihydrocholesterol); 1, cholesterol; 2, campesterol; 3, campestanol; 4, stigmasterol; 5, stigmastanol; 6, clerosterol; 7, sitosterol; 8, sitostanol; 9, avenasterol. For analytical conditions, see the Methods section.

Figure 6

Fig. 6 Metabolic activity in unsupplemented and phytosterol (PS)-supplemented cardiomyocytes. 3-(4,5-Dimethyldiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) conversion to formazan, as a measure of metabolic activity, was determined as reported in the Methods section and expressed as the percentage of the value obtained in unsupplemented cells (assigned as 100 %). Values are means of at least three samples obtained from independent cell cultures, with standard deviations represented by vertical bars. Mean percentage changes with respect to unsupplemented cells are reported above the corresponding bar. Statistical analysis was carried out by one-way ANOVA (P < 0·001) using Tukey's post-test (control v. PS: *** P < 0·001; 3 μg/ml v. 6 μg/ml: NS).

Figure 7

Fig. 7 Apoptotic effect of phytosterol (PS) supplementation evaluated using Annexin-V at different time points. Values are means of at least three samples obtained from independent cell cultures, with standard deviations represented by vertical bars. Mean percentage changes with respect to unsupplemented cells are reported above the corresponding bar. No differences in the number of apoptotic cells were detected among groups at any time point by one-way ANOVA. □, Control; , PS (3 μg/ml); , PS (6 μg/ml).

Figure 8

Fig. 8 Cell cycle distribution in control and phytosterol (PS)-supplemented cardiomyocytes at different time points. The bar graph shows the distribution of cells among the different phases of the cell cycle: G0/G1 phase, quiescent cells; S phase, DNA replicating cells; G2/M phase, cells with two full complements of DNA or at the mitotic phase. Values are means of at least three samples obtained from independent cell cultures, with standard deviations represented by vertical bars. No differences in the cell cycle distribution were detected among groups at any time point by one-way ANOVA. , G1 phase; , S phase; □, G2 phase.

Figure 9

Fig. 9 Cell growth analysis in unsupplemented and phytosterol (PS)-supplemented cardiomyocytes. Cell growth analysis was performed as reported in the Methods section, and cells counted at different time points. Values are means of at least three samples obtained from independent cell cultures, with standard deviations represented by vertical bars. Mean percentage changes with respect to unsupplemented cells are reported above the corresponding bar. Statistical analysis was carried out by one-way ANOVA (P < 0·05) using Tukey's post-test (control v. PS: * P < 0·05; 3 μg/ml v. 6 μg/ml: NS). ●, Control; , PS (3 μg/ml); ■, PS (6 μg/ml).