Hostname: page-component-586b7cd67f-g8jcs Total loading time: 0 Render date: 2024-11-23T03:28:09.612Z Has data issue: false hasContentIssue false

A polyphenol extract modifies quantity but not quality of liver fatty acid content in high-fat–high-sucrose diet-fed rats: possible implication of the sirtuin pathway

Published online by Cambridge University Press:  02 August 2010

Manar Aoun
Affiliation:
INRA UMR 866, Différentiation Cellulaire et Croissance, 34060Montpellier, France UMR 204 NUTRIPASS IRD/Montpellier-1/Montpellier-2/Supagro, 34000Montpellier, France
Francoise Michel
Affiliation:
UMR 204 NUTRIPASS IRD/Montpellier-1/Montpellier-2/Supagro, 34000Montpellier, France
Gilles Fouret
Affiliation:
INRA UMR 866, Différentiation Cellulaire et Croissance, 34060Montpellier, France
Francois Casas
Affiliation:
INRA UMR 866, Différentiation Cellulaire et Croissance, 34060Montpellier, France
Melanie Jullien
Affiliation:
INRA UMR 866, Différentiation Cellulaire et Croissance, 34060Montpellier, France
Chantal Wrutniak-Cabello
Affiliation:
INRA UMR 866, Différentiation Cellulaire et Croissance, 34060Montpellier, France
Jeanne Ramos
Affiliation:
Laboratoire d'Anatomie Pathologique, CHU Gui de Chauliac, 80, Avenue Augustin Fliche, 34295 Montpellier Cedex 5, France
Jean-Paul Cristol
Affiliation:
UMR 204 NUTRIPASS IRD/Montpellier-1/Montpellier-2/Supagro, 34000Montpellier, France
Charles Coudray
Affiliation:
INRA UMR 866, Différentiation Cellulaire et Croissance, 34060Montpellier, France
Marie-Annette Carbonneau
Affiliation:
UMR 204 NUTRIPASS IRD/Montpellier-1/Montpellier-2/Supagro, 34000Montpellier, France
Christine Feillet-Coudray*
Affiliation:
INRA UMR 866, Différentiation Cellulaire et Croissance, 34060Montpellier, France
*
*Corresponding author: Dr Christine Feillet-Coudray, fax +33 4 67 54 56 94, email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

High-fat or high-fat–high-sucrose diets are known to induce non-alcoholic fatty liver disease and this is emerging as one of the most common liver diseases worldwide. Some polyphenols have been reported to decrease rat hepatic lipid accumulation, in particular those extracted from red grapes such as resveratrol. The present study was designed to determine whether a polyphenol extract (PPE), from red grapes, modulates liver fatty acid composition and desaturase activity indexes in rats fed a high-fat–high-sucrose (HFHS) diet, and to explore whether sirtuin-1 deacetylase activation was implicated in the effect of the PPE against liver steatosis. The effect of this PPE on mitochondriogenesis and mitochondrial activity was also explored. The PPE decreased liver TAG content in HFHS+PPE diet-fed rats in comparison with HFHS diet-fed rats. The PPE had no effect on liver fatty acid composition, desaturase activity indexes and stearoyl-CoA desaturase 1 (SCD1) gene expression. Sirtuin-1 deacetylase protein expression was significantly increased with the PPE; AMP kinase protein expression was higher with the PPE in comparison with the HFHS rats, but no modification of phosphorylated AMP kinase was observed. Protein expression of phospho-acetyl-CoA carboxylase was decreased in HFHS rats and returned to basal values with the PPE. Finally, the PPE modulated PPARγ coactivator-1α (PGC-1α) but did not modify mitochondriogenesis and mitochondrial activity. In conclusion, the PPE partially prevented the accumulation of TAG in the liver by regulating acetyl-CoA carboxylase phosphorylation, a key enzyme in lipid metabolism, probably via sirtuin-1 deacetylase activation. However, the PPE had no effect on the qualitative composition of liver fatty acids.

Type
Full Papers
Copyright
Copyright © The Authors 2010

The incidence of obesity and insulin resistance is increasing rapidly in wealthy societies, and has become a major public health problem, essentially resulting from imbalanced energy intake and expenditure of the body from a metabolic point of view(Reference Barness, Opitz and Gilbert-Barness1). This trend is associated with a parallel increase in the prevalence of non-alcoholic fatty liver disease (NAFLD)(Reference Fromenty, Robin and Igoudjil2). NAFLD is one of the most common liver disease disorders, having a spectrum ranging from simple steatosis to cirrhosis(Reference Erickson3). The leading hypothesis for NAFLD is the two-hit hypothesis. The ‘first’ hit is the accumulation of lipids in the hepatocytes (steatosis) and the ‘second’ hit leads to hepatocyte injury, inflammation and fibrosis (steatohepatitis/cirrhosis). Some of the probable second hits include oxidative stress, mitochondrial dysfunction and insulin resistance(Reference Cave, Deaciuc and Mendez4, Reference Mantena, King and Andringa5).

Recent studies demonstrated that some polyphenols(Reference Baur, Pearson and Price6Reference Shang, Chen and Xiao10) or polyphenol extracts (PPE)(Reference Feillet-Coudray, Sutra and Fouret11) may prevent, at least partially, hepatic steatosis induced by high-fat–high-sugar Western diet administration. Indeed, polyphenols may act on lipid metabolism by modulating desaturase activity. For example, some polyphenols have been shown to reduce the gene expression of Δ-9 desaturase (stearoyl-CoA desaturase 1; SCD1)(Reference Ajmo, Liang and Rogers12, Reference Klaus, Pultz and Thone-Reineke13) and to decrease the activity of Δ-6 desaturase(Reference Ogino, Osada and Nakamura14). Nevertheless, whether polyphenols may modulate not only liver total lipid content but also liver fatty acid composition has never been addressed.

Polyphenols may also act on lipid metabolism signalling pathways, including lipid synthesis and degradation. Different reports(Reference Zang, Xu and Maitland-Toolan15, Reference Hou, Xu and Maitland-Toolan16) showed that elevated glucose inhibited AMP kinase activity and acetyl-CoA carboxylase phosphorylation and thus increased hepatocellular lipid accumulation. However, supplementation with polyphenols reversed the inhibition of AMP-activated protein kinase activity and acetyl-CoA carboxylase phosphorylation(Reference Zang, Xu and Maitland-Toolan15). Moreover, they demonstrated that polyphenols stimulated AMP kinase and prevented hepatocyte lipid accumulation probably by activating sirtuin-1 deacetylase(Reference Hou, Xu and Maitland-Toolan16).

As mitochondria are both a major site for fat metabolism and the main source of reactive oxygen and/or nitrogen species in hepatocytes, they are postulated to play a central role in the progression of NAFLD to non-alcoholic steatohepatitis and cirrhosis(Reference Mantena, King and Andringa5). Some polyphenols have also been shown to modify mitochondrial activity and increase mitochondriogenesis(Reference Csiszar, Labinskyy and Pinto17). Such an effect may enhance mitochondrial lipid catabolism and hence attenuate liver fatty acid accumulation.

The present study was thus designed to determine whether a PPE modulates liver fatty acid content and their composition and desaturase activity indexes in rats fed a high-fat–high-sucrose diet, and to explore whether the sirtuin-1–AMP kinase signalling pathway is implicated in the preventive effect of this PPE against liver steatosis. Moreover, as mitochondrial dysfunction may be implicated in the progression of steatosis to non-alcoholic steatohepatitis, the effect of the PPE on mitochondriogenesis and mitochondrial activity was also explored.

Materials and methods

Animals and diets

All animal experiments were performed according to European directives (86/609/CEE) and approved by the Comité d'Ethique en Matière d'Expérimentation Animale: Région Languedoc-Roussillon. Male Wistar rats (n 18; Charles River, L'Arbresle, France), aged 6 weeks, were used in the present study. Rats were housed two animals per cage under conditions of constant temperature (20–22°C), humidity (45–50 %) and a standard dark cycle (from 20.00 until 08.00 hours). Our institution guidelines for the care and use of laboratory animals were observed. The rats were randomised into three groups of six animals: (1) a control group was fed for 6 weeks a control semi-purified diet; (2) a high-fat–high-sucrose (HFHS) group was fed for 6 weeks a high-fat–high-sucrose diet; (3) a high-fat–high-sucrose diet plus PPE (HFHS+PPE) group was fed for 6 weeks a high-fat–high-sucrose diet containing 2 g PPE (Provinol™; Société Française de Distillerie, Vallon Pont d'Arc, France) per kg diet. The period of 6 weeks was chosen because it was described as sufficient to induce hepatic steatosis in rats(Reference Nanji18, Reference Ahmed, Redgrave and Oates19). The control diet contained the following (g/kg): casein, 200; starch, 660·7; soyabean oil, 40; cellulose, 50; mineral mix, 35(Reference Reeves, Nielsen and Fahey20); vitamin mix, 10(Reference Reeves, Nielsen and Fahey20); l-cystine, 1·8; choline bitartrate, 2·5. The HFHS diet contained the following (g/kg): casein, 200; starch, 100·7; sucrose, 300; soyabean oil, 40; olive oil, 100; coprah oil, 150; cellulose, 50; mineral mix, 35(Reference Reeves, Nielsen and Fahey20); vitamin mix, 10(Reference Reeves, Nielsen and Fahey20); l-cystine, 1·8; choline bitartrate, 2·5. The HFHS+PPE diet was the same as the HFHS diet, plus 2 g PPE/kg diet. The detailed fatty acid composition of the diets is given in Table 1. Rats were given free access to distilled water, and food, body growth and diet consumption were determined weekly. Food intake was determined as follows: dry rejected food was subtracted from dry presented food. The dry material percentage in the presented food was determined by drying a small amount of each presented diet (3 d at 80°C) and weighing before and after drying. The presented food was then determined by multiplying the weight of the presented fresh food by the dry material percentage. The rejected food was dried (3 d at 80°C) and weighed. The consumed dry material was calculated as follows: presented dry food – rejected dry food. The result was divided by 2 to take into account the presence of two rats per cage.

Table 1 Fatty acid composition of the experimental diets (% μg)*

HFHS, high-fat–high-sucrose; PPE, polyphenol extract.

* Values are based on identifiable peaks. Each diet was analysed in duplicate.

Provinol™ is a powdered PPE obtained from red wine produced in the Languedoc-Roussillon region of France. The extraction procedure involved adsorption of red wine phenolics on a preparative column, alcoholic desorption and gentle evaporation of the alcoholic eluent, and spraying of the concentrated residue to obtain the polyphenol powder extract. The Provinol™ powder contains a minimum of 95 % of total polyphenols (proanthocyanidols 46 %, prodelphinidol 21 %, total anthocyanins 6·1 %, catechin 3·8 %, epicatechin gallate 3 %, OH cinnamic acid 1·8 %, flavanol (quercetol) 1·4 %, resveratrol 0·15 %, free anthocyanins 0·095 %).

Sampling

Non-fasted rats were anaesthetised with pentobarbital (Ceva Santé Animale, Libourne, France) and blood was obtained from the abdominal vein with a heparinised syringe (sodium heparinate; Panpharma SA, Fougères, France). Blood samples were centrifuged at 1000 g for 10 min at 4°C, and plasma was collected and stored at − 80°C until analysis. Livers were quickly removed, frozen in liquid N2 and kept at − 80°C.

Routine biochemical analyses

Plasma glucose, total cholesterol, TAG and NEFA concentrations were measured by enzymic techniques (Konelab; Thermo Electron Corp., Vantaa, Finland). Plasma insulin and leptin levels were quantified with ELISA kits (Linco Research, St Charles, MO, USA). Protein levels in tissue homogenates were measured by Bradford's technique(Reference Bradford21).

Histological analysis

For microscopic studies, liver samples were fixed in 10 % neutral buffered formalin and embedded in paraffin. Serial tissue sections (5 μm) were processed. Liver injury, such as steatosis, portal inflammatory infiltrate and fibrosis, was evaluated by histological examination after haematoxylin and eosin staining.

Liver total lipid extraction and analysis

Liver was homogenised in NaCl (9 g/l) and Triton X-100 (0·1 %), using an Ultra Turax homogeniser and lipids were extracted from the liver homogenate using the method of Folch et al. (Reference Folch, Lees and Sloane Stanley22).

NEFA, TAG and total cholesterol in the liver homogenate were quantified directly by enzymic colorimetric methods (Wako-NEFA-C kit, Oxoid, Dardilly, France; Cholesterol RTU kit, Biomerieux, Lyon, France; TG PAP kit, Biomerieux, Lyon, France) and phosphorus was quantified in the chloroform–methanol homogenate in order to determine total phospholipid quantity as previously described(Reference Bartlett23).

The chloroform–methanol lipid extract, with 17 : 0 (2500 μg/ml) as fatty acid internal standard, was used for total fatty acid analysis by GC after transesterification.

Liver total fatty acid analysis by GC

The lipid extract was evaporated under N2 to dryness at 37°C and fatty acid samples were transesterified according to the method of Lepage & Roy(Reference Lepage and Roy24). Briefly, the methylation reagent was generated by mixing sulfuric acid with methanol and butylated hydroxytoluene (50 mg/l), then added to the extracted dried residue and the sample was heated at 90°C for 45 min to obtain the fatty acid methyl esters. After the addition of sodium bicarbonate, distilled water and hexane, the sample was vortexed, centrifuged, and the upper hexane layer was transferred to a glass vial, evaporated under an N2 stream at 37°C, and dissolved in iso-octane for GC analysis.

Samples were analysed on a FOCUS GC (Thermo Electron Corporation, Thermo Fisher Scientific, Courtaboeuf, France), equipped with a flame ionisation detector (Thermo Electron Corporation, Thermo Fisher Scientific). The capillary column was a TR-FAME (Thermo Electron Corporation, Thermo Fisher Scientific), 50 m × 0·32 mm internal diameter with film thickness of 0·25 μm. The carrier gas used was He under a constant flow rate of 1·8 ml/min. A 1 μl quantity of sample was injected using an AS-3000 autosampler, with a 1:6 split ratio. The temperature program was as follows: initial at 80°C with a 1 min hold; ramp: 15°C/min to 140°C, 1°C/min to 170°C, and 15°C/min to 220°C with a 10 min hold. The injector and detector were set at 220°C. Calibration was done with fatty acid methyl ester standards from SUPELCO 37 Comp FAME Mix (SUPELCO Analytical; Sigma Aldrich, Lyon, France). Chromatograms were collected and integrated with AZUR software (Thermo Electron Corporation, Thermo Fisher Scientific). The fatty acids were quantified using the chromatographic peak area according to the internal standard method.

Detailed analysis of the fatty acid compositions both of fractions containing lipid standards and of those derived from liver was carried out by GC–MS on a Trace GC ULTRA using a Trace DSQ–MS capillary column RTx-1 30 m × 0·32 mm internal diameter × 0·10 μm film thickness (Restek, Lisses, France) connected to a Trace DSQ mass selective detector (Thermo Fisher Scientific). Peaks were identified by comparison of electron impact ionisation spectra with a reference library.

Liver desaturase activity indexes

The activity of Δ5-desaturase, the enzyme that converts dihomo-γ-linoleic acid (20 : 3n-6) to arachidonic acid (20 : 4n-6), was estimated by the 20 : 4n-6/20 : 3n-6 ratio(Reference Biggemann, Laryea and Schuster25). The activity of Δ6-desaturase, the enzyme that converts linoleic acid (18 : 2n-6) to γ-linolenic acid (18 : 3n-6), was estimated by the 18 : 3n-6/18 : 2n-6 ratio(Reference Stefan, Peter and Cegan26). The activity of Δ9-desaturase, the enzyme that converts stearic acid (18 : 0) to oleic acid (18 : 1n-9), was estimated by the 16 : 1n-7/16 : 0 ratio or the 18 : 1n-9/18 : 0 ratio(Reference Stefan, Peter and Cegan26). A decrease in each of these ratios can be related to a decrease of the appropriate desaturase activity and vice versa.

Immunoblotting

Frozen liver samples were homogenised using an Ultra Turax homogeniser in an ice-cold extraction buffer containing 20 mm-2-amino-2-hydroxymethyl-propane-1,3-diol (Tris)-HCl, 150 mm-NaCl, 1 mm-EDTA, 0·5 % Triton X-100, 0·1 % SDS, 1 mm-phenylmethylsulfonyl fluoride, 10 μm-leupeptin, and 1 μm-pepstabtin. Proteins (50 μg) were separated with 10 or 8 % SDS-PAGE and then transferred to a nitrocellulose membrane (90 min; 120 V). Membranes were blocked in 5 % non-fat milk for 1 h at room temperature. Then, membranes were incubated overnight with primary antibodies against sirtuin-1 deacetylase (1/200; Santa Cruz Biotechnology, Santa Cruz, CA, USA), phospho-AMP kinase and AMP kinase (1/1000; Cell Signaling Technology, Inc., Danvers, MA, USA), phospho-acetyl-coA carboxylase (1/1000; Cell Signaling Technology, Inc.), fatty acid synthase (1/1000; Cell Signaling Technology, Inc.) and hepatocyte nuclear factor-4 (1/100; Santa Cruz Biotechnology) in blocking buffer. After washes in Tris buffered saline (TBS)/Tween under gentle agitation, membranes were incubated for 1 h with horseradish peroxidase-labelled antibody (1/5000 for Santa Cruz antibody or 1/2000 for Cell Signaling antibody). After further washes, blots were treated with enhanced chemiluminescence detection reagents (ECL, ThermoScientific). β-Actin was used as a loading reference, and blot intensities were measured using the BIO-Profil 1D software (Fisher Bioblock, Illkirch, France).

Liver mRNA expression

Real-time quantitative PCR (RT-qPCR) was used to measure target gene mRNA expression in liver. Total RNA was extracted with Trizol reagent (Invitrogen Life Technologies, Cergy Pontoise, France). Reverse transcription reaction was performed with 5 μg total RNA. cDNA was synthesised with the use of SuperScript II RT for first-strand cDNA synthesis (Invitrogen Life Technologies, Cergy Pontoise, France) and Oligo (dT) primers. The mRNA expressions of target genes were determined by RT-qPCR. RT-qPCR analysis was performed using IQ™ SYBR Green Supermix (Biorad, Hercules, CA, USA) with a MiniOpticon detection system (Biorad, Hercules, CA, USA). Results were normalised with the gene encoding 18S used as the reference. The primer sequences used for real-time RT-PCR are shown in Table 2. After normalisation by 18S, all results are expressed as percentage of control as mean values and standard deviations.

Table 2 Primer sequences used for real-time RT-PCR

PGC-1α, PPARγ coactivator-1α; SCD1, stearoyl-CoA desaturase 1.

Liver mitochondrial respiratory complex activities

Liver homogenates were prepared on ice in a ratio of 1 g wet tissue for 9 ml phosphate buffer (50 mm; pH 7) using a Polytron homogeniser and centrifuged at 1000 g for 10 min at 4°C. Complex II and complex II+III activities in supernatant fraction were determined spectrophotometrically according to Rustin et al. (Reference Rustin, Chretien and Bourgeron27). Complex IV or cytochrome c oxidase activity was measured spectrophotometrically according to Wharton & Tzagoloff(Reference Wharton and Tzagoloff28). Citrate synthase activity was measured spectrophotometrically according to Srere(Reference Srere29).

Statistical analysis

Results were expressed as mean values and standard deviations. Statistical analyses were based on one-way ANOVA followed by Fisher's multiple-comparisons test. The limit of statistical significance was set at P < 0·05. Statistical analyses were performed using the StatView program (SAS Institute, Cary, NC, USA).

Results

Characterisation of high-fat–high-sucrose-fed rats and high-fat–high-sucrose plus polyphenols-fed rats

Weight gain by kJ of diet was significantly higher in rats fed the HFHS diet and the HFHS+PPE diet, but no difference was observed between the HFHS group and the HFHS+PPE group. The body weight of rats fed the HFHS diet and the HFHS+PPE diet was higher, but not significantly, than that of rats fed the control diet, whereas liver weight was significantly higher (Tables 3 and 4). However, the liver weight:body weight ratio was similar among groups (Table 4). The mean dietary intake and energy intake during the experiment were not significantly modified among groups (Table 3).

Table 3 Body weight and weight gain, dietary and energy intakes and plasma glucose, lipids, insulin and leptin levels

(Mean values and standard deviations)

HFHS, high-fat–high-sucrose; PPE, polyphenol extract.

* Mean value was significantly different from that of the control group (P < 0·05).

Mean value was significantly different from that of the HFHS group (P < 0·05).

One-way ANOVA was used followed by Fisher's multiple-comparisons test. Significance was set at P < 0·05.

Table 4 Liver weight and lipid content, and mitochondrial respiratory complex activities

(Mean values and standard deviations)

HFHS, high-fat–high-sucrose; PPE, polyphenol extract; CS, citrate synthase; complex IV, cytochrome c oxidase.

* Mean value was significantly different from that of the control group (P < 0·05).

Mean value was significantly different from that of the HFHS group (P < 0·05).

One-way ANOVA was used followed by Fisher's multiple-comparisons test. Significance was set at P < 0·05.

Plasma TAG, total cholesterol and NEFA levels were not significantly different among control, HFHS and HFHS+PPE rats, even if plasma TAG and total cholesterol increased by about 10–15 % in HFHS rats, showing a great inter-individual variation (Table 3). Plasma glucose level was increased with the HFHS and HFHS+PPE diets in comparison with the control diet. Plasma insulin level was increased, but not significantly, in HFHS rats in comparison with control rats and significantly decreased with the HFHS-PPE diet in comparison with HFHS rats. Plasma leptin level was significantly increased in rats fed the HFHS diet and the HFHS+PPE diet in comparison with the control diet (Table 3).

Visual observation of liver from HFHS rats revealed a yellow macroscopic appearance, suggesting fatty change but less important in livers from HFHS+PPE rats and not in control rats. The histological features in the liver of control (Fig. 1(a)), HFHS (Fig. 1(b)) and HFHS+PPE (Fig. 1(c)) diet-fed rats were hepatic macro-steatosis with HFHS, recognisable by a preponderance of large droplets in which a single, bulky fat vacuole distends the hepatocyte and pushes the nucleus and cytoplasm to the side and microvacuolar steatosis with HFHS+PPE, with small intracytoplasmic droplets. In the control group, no steatosis was observed. This suggests that induction of hepatic steatosis by the HFHS diet was partially prevented by polyphenol administration.

Fig. 1 Liver histology after haematoxylin–eosin staining of liver sections from a representative rat of each group: (a) control diet; (b) high-fat–high-sucrose (HFHS) diet; (c) HFHS diet plus polyphenol extract.

Liver TAG, total cholesterol and phospholipid levels were higher in HFHS- and HFHS+PPE-fed rats in comparison with control rats (Table 4). Liver NEFA levels were not different among control, HFHS and HFHS+PPE rats. Moreover, hepatic TAG content was significantly reduced in rats fed the HFHS+PPE diet in comparison with the HFHS diet, which was consistent with the observed histological changes (Fig. 1).

Total fatty acid composition of liver, desaturase activity indexes and stearoyl-CoA desaturase 1 mRNA expression

Total major SFA, MUFA and PUFA were in higher quantity in the liver of rats fed the HFHS and HFHS+PPE diets than in those fed the control diet (Table 5). In animals fed the HFHS+PPE diet, the PPE did not influence significantly the total fatty acids profile: total SFA, MUFA and PUFA quantities were not modified in comparison with rats fed the HFHS diet; surprisingly, total n-3 PUFA quantities, and in particular 22 : 6n-3 (DHA), were significantly lower in rats fed the HFHS+PPE diet in comparison with rats fed the HFHS diet (Table 5). The n-6:n-3 ratio did not significantly vary with diet, suggesting that the HFHS diet or the PPE did not influence the balance of these essential PUFA and highly unsaturated fatty acids (Table 5).

Table 5 Total fatty acid composition of rat liver (mg fatty acid/g tissue)

(Mean values and standard deviations)

HFHS, high-fat–high-sucrose; PPE, polyphenol extract; n.d., non-detectable.

* Mean value was significantly different from that of the control group (P < 0·05).

Mean value was significantly different from that of the HFHS group (P < 0·05).

One-way ANOVA was used followed by Fisher's multiple-comparisons test. Significance was set at P < 0·05.

The 18 : 1n-9/18 : 0 ratio, a Δ9-desaturase activity index, was in higher proportion in the liver of rats fed the HFHS and HFHS+PPE diets than in those fed the control diet, and the PPE did not modify it; in contrast the 16 : 1n-9/16 : 0 ratio, also a Δ9-desaturase activity index, was in lower proportion. The Δ6-desaturase activity index was increased and the Δ5-desaturase activity index was decreased in rats fed the HFHS diet and the HFHS+PPE diet in comparison with controls (Table 5).

There was a trend towards lower SCD1 mRNA expression in the liver of rats fed the HFHS (0·416 (sd 0·404)) or the HFHS+PPE (0·462 (sd 0·283)) diet in comparison with controls (1·00 (sd 0·75)) (P = 0·0716 for HFHS v. controls and P = 0·0944 for HFHS+PPE v. controls).

Sirtuin-1 deacetylase–AMP kinase signalling pathway

Sirtuin-1 deacetylase protein expression level was significantly increased in rats fed the HFHS+PPE diet in comparison with controls and HFHS-fed animals (Fig. 2), while sirtuin-1 deacetylase mRNA expression level was unchanged (data not shown).

Fig. 2 Sirtuin-1 deacetylase (SIRT1)–AMP kinase (AMPK) signalling pathway: relative protein expression in control diet-fed rats (), high-fat–high-sucrose (HFHS) diet-fed rats () and HFHS diet plus polyphenol extract-fed rats (). p-AMPK, phospho-AMPK; p-ACC, phospho-acetyl-CoA carboxylase; FAS, fatty acid synthase; HNF4, hepatocyte nuclear factor 4. Values are means (n 6 per group), with standard deviations represented by vertical bars. * Mean value was significantly different from that of the control group (P < 0·05). † Mean value was significantly different from that of the HFHS group (P < 0·05).

Total AMP kinase protein expression level was decreased, but not significantly, in rats fed the HFHS diet in comparison with controls, than significantly increased to control values in rats fed the HFHS+PPE diet in comparison with those fed the HFHS diet, while phosphorylated AMP kinase expression level was unchanged, as was phospho-AMP kinase:AMP kinase (Fig. 2).

Phosphorylated acetyl-CoA carboxylase protein expression level was significantly decreased in rats fed the HFHS diet in comparison with controls and returned to control values in rats fed the HFHS+PPE diet (Fig. 2). Phospho-acetyl-CoA carboxylase protein expression was almost negatively correlated with liver TAG content (r − 0·474; P = 0·0867).

Sterol regulatory element-binding protein-1c (SREBP-1c) mRNA expression level was unchanged (data not shown). Fatty acid synthase and hepatocyte nuclear factor-4 protein expression levels were not different among control, HFHS and HFHS+PPE rats (Fig. 2).

PPARγ coactivator-1α (PGC-1α) mRNA expression level was significantly decreased in rats fed the HFHS diet in comparison with controls, and PGC-1α mRNA expression level in rats fed the HFHS+PPE diet was increased in comparison with HFHS diet-fed rats but not significantly (1·00 (sd 0·43), 0·387 (sd 0·123), 0·708 (sd 0·525), for control, HFHS and HFHS+PPE, respectively). PGC-1α gene expression was negatively correlated with liver TAG content (r − 0·608; P < 0·05).

Carnitine palmitoyltransferase 1, malonyl-CoA decarboxylase, medium-chain acyl-CoA dehydrogenase, nuclear respiratory factor 1 and mitochondrial transcription factor A mRNA expression levels were not different among control, HFHS and HFHS+PPE rats (data not shown).

Mitochondrial respiratory complex activities

Liver complex II and complex II+III activities and complex II:citrate synthase and complex II+III:citrate synthase ratios were significantly decreased in rats fed the HFHS and HFHS+PPE diets in comparison with controls (Table 4). No significant difference was observed between rats fed the HFHS or the HFHS+PPE diet. Citrate synthase and complex IV activities were not different among control, HFHS and HFHS+PPE rats. Complex IV activity and complex IV:citrate synthase were significantly correlated with liver NEFA content (r 0·615, P < 0·01 and r 0·505, P < 0·05, respectively), while complex II+III activity, complex II+III:citrate synthase and complex II:citrate synthase were negatively correlated with liver TAG content (r − 0·558, P < 0·05, r − 0·666, P < 0·01 and r − 0·611, P < 0·01, respectively).

Discussion

Fatty liver, the initial stage of NAFLD, is characterised by an increased content of hepatocellular lipids. Our study was conducted to determine the effects of a PPE on both quantity and quality of liver lipids in HFHS diet-fed rats. The PPE was given mixed to the diet at a concentration that provided about 30 mg polyphenols/kg per d, which is only two-fold the estimated dietary intake in humans(Reference Scalbert and Williamson30).

Characteristics of rats

HFHS diet-fed rats gained significantly more weight than control rats and their plasma leptin level, among the best-known hormone marker for obesity(Reference Yang and Barouch31), was also increased. The supplementation of rats fed the HFHS+PPE diet did not modify significantly either weight gain or plasma leptin level, probably because the duration of the supplementation was too short to obtain a significant beneficial effect of this PPE. In fact, a potentially preventive effect on diet-induced obesity of polyphenol consumption has been described for a longer period of supplementation(Reference Bargalló, Grau and Fernández-Larrea32Reference Zheng, Sayama and Okubo34). It cannot be excluded nevertheless that the lack of effect was due to the different model (HFHS) used to induce fat accumulation in the liver with respect to the most common model of a high-fat diet, used in the studies cited.

Plasma glucose was significantly increased in the HFHS diet-fed rats by comparison with control rats. Moreover, insulin levels, plasma TAG and cholesterol tended to increase but non-significantly in the HFHS diet-fed rats compared with the control group, and plasma NEFA were not modified by the HFHS diet. Thus, the model of NAFLD used here (HFHS diet) seems to induce a very early stage of liver steatosis, as it lacks most of the hallmarks associated with NAFLD such as fatty acid increase, hypertriacylglycerolaemia and hyperinsulinaemia, usually observed with a high-fat diet. PPE intake modulated slightly this model by decreasing insulin levels in comparison with the HFHS group, but it failed to affect plasma glucose levels.

Liver steatosis and total lipid content

Liver macrosteatosis was observed in HFHS diet-fed rats and liver microsteatosis, the first step to liver macrosteatosis, was observed in the HFHS+PPE group but not in the control group. Insulin resistance is currently considered as the basis for intrahepatic lipid accumulation(Reference Tessari, Coracina and Cosma35). However, insulinaemia was not significantly increased in the HFHS diet-fed rats with liver steatosis. It was suggested recently that hepatic steatosis is not necessarily associated with insulin resistance and that accumulation of intrahepatic lipids may precede the state of insulin resistance, while hepatic TAG itself may not be toxic and may in fact protect the liver from lipotoxicity by buffering the accumulation of fatty acids(Reference Postic and Girard36).

In accordance with visual observation of liver steatosis, liver TAG content was increased in HFHS diet-fed rats and this increase was less important with PPE supplementation. Thus, the PPE partially prevented the accumulation of TAG in the liver, as previously observed with other polyphenols(Reference Kim, Lee and Cha37Reference Quesada, Del Bas and Pajuelo40).

Liver fatty acid composition

Dietary lipids influenced the rat liver fatty acid composition, as SFA and MUFA, but not PUFA, were found in the same proportion in diets and in rat livers. Similar results were also observed in fatty composition of the different lipid sub-classes of phospholipids, TAG, cholesteryl ester and NEFA (data not shown). These results suggest that liver lipid homeostasis is modulated by dietary fatty acids. Concerning PUFA, the dietary fatty acid levels of 18 : 2n-6 and 18 : 3n-3 were 5-fold lower in the HFHS diet but significantly higher in the liver of rats fed the HFHS and HFHS+PPE diets in comparison with control rats. These fatty acids may be stored or metabolically converted to highly unsaturated fatty acids (20 : 4n-6, 20 : 5n-3 and 22 : 6n-3)(Reference Sealls, Gonzalez and Brosnan41), and as the 20 : 4n-6 content was not significantly different in the livers of rats fed the different diets, there was probably suppression of the conversion of 18 : 2n-6 PUFA to 20 : 4n-6 highly unsaturated fatty acid and net accumulation of 18 : 2n-6 from the diet in the liver of rats fed the HFHS diets. The 18 : 3n-3 content was very low and 20 : 5n-3 content was undetectable in rats fed the different diets, suggesting a nearly 100 % conversion of these n-3 fatty acids to 22 : 6n-3. Surprisingly, the 22 : 6n-3 level increased in the liver of rats fed the HFHS or HFHS+PPE diet in comparison with controls, although the proportion of 18 : 3n-3, precursor of 22 : 6n-3, was 5-fold higher in the control diet than in the HFHS diets. Such an effect of 18 : 3n-3 conversion into its long-chain derivatives such as DHA has previously been found(Reference Morise, Mourot and Boue42). Moreover, 22 : 6n-3 and n-3 PUFA contents decreased in the liver of rats fed the HFHS+PPE diet in comparison with the HFHS diet, but we have no explanation for this observation.

SCD1 is a microsomal enzyme that catalyses the synthesis of monounsaturated long-chain fatty acids from saturated fatty acyl-CoA(Reference Stefan, Peter and Cegan26), and its preferred substrates are palmitoyl- (16 : 0) and stearoyl-CoA (18 : 0). The 18 : 1n-9/18 : 0 ratio, which is usually used to express Δ9-desaturase activity(Reference Stefan, Peter and Cegan26), was higher in rats fed the HFHS diets in comparison with controls, with no effect of PPE observed. However, this ratio probably did not express the real activity of Δ9-desaturase in the present study, because 18 : 1n-9 and 18 : 0 were in higher proportion in the HFHS diets than in the control diet. On contrary, the 16 : 1n-7/16 : 0 ratio was lower in rats fed the HFHS diets in comparison with controls, and as the control and HFHS diets provided the same proportion of these two fatty acids, this result also suggested a decreased Δ9-desaturase activity. In accordance, SCD1 gene expression decreased in rats fed the HFHS or HFHS+PPE diet in comparison with controls, but unlike what was described in mice fed a high-fat diet(Reference Li, Berk and McIntyre43). Also, no effect of the PPE was observed on SCD1 gene expression, unlike previously described(Reference Ajmo, Liang and Rogers12, Reference Klaus, Pultz and Thone-Reineke13). It is possible that the high intake of 18 : 1n-9 in rats fed the HFHS diets suppressed de novo 18 : 1n-9 MUFA synthesis. Δ6-Desaturase and Δ-5 desaturase activity indexes were modulated according to the quantity of lipids in the diet, with no effect of the PPE.

The sirtuin-1 deacetylase–AMP kinase signalling pathway

Sirtuin-1 deacetylase and AMP kinase are two critical signalling molecules controlling the pathways of hepatic lipid metabolism. Resveratrol and other polyphenols have been identified as potent agonists of sirtuin-1 deacetylase(Reference Howitz, Bitterman and Cohen44) and several lines of investigation have demonstrated that resveratrol modulates lipid metabolism mainly through activation of sirtuin-1 deacetylase signalling(Reference Baur, Pearson and Price6, Reference Lagouge, Argmann and Gerhart-Hines45, Reference Rodgers, Lerin and Haas46). In the present study and in agreement with such observations, the expression of sirtuin-1 deacetylase protein increased significantly in the liver of rats fed the HFHS+PPE diet in comparison with rats fed the HFHS and control diets.

Although many other factors may contribute to the hepatocyte metabolic effects of sirtuin-1 deacetylase, sirtuin-1 deacetylase activation by polyphenols may stimulates AMP kinase(Reference Hou, Xu and Maitland-Toolan16). In the present study, the expression of total AMP kinase was increased in HFHS+PPE diet-fed rats in comparison with HFHS-fed rats. However, the expression of phosphorylated AMP kinase, the active form, did not change whatever the administered diet; this was probably linked to the great variability observed within the same group and the transitory phenomenon of protein phosphorylation.

Activated acetyl-CoA carboxylase is a key enzyme that plays a key role in the regulation of fatty acid metabolism, by modulating lipid synthesis and lipid catabolism in mitochondria(Reference Zang, Xu and Maitland-Toolan15). In the present study, the expression of phosphorylated acetyl-CoA carboxylase (inactive form) decreased in HFHS diet-fed rats in comparison with controls, and was restored to control values in rats fed the HFHS+PPE diet. It was almost significantly correlated to the liver TAG content, underlying its central role in liver lipid accumulation. In agreement with the present results, previous studies have also demonstrated that acetyl-CoA carboxylase is up-regulated in the obese state and in response to high-carbohydrate diets(Reference Munday, Milic and Takhar47, Reference Hastings and Hill48) while it is down-regulated by various polyphenols(Reference Zang, Xu and Maitland-Toolan15, Reference Hou, Xu and Maitland-Toolan16, Reference Kim, Lee and Cha37, Reference Lin, Huang and Lin49).

SREBP-1c is a transcriptional factor that activates the expression of key enzymes involved in lipogenesis(Reference Mulvihill, Allister and Sutherland7, Reference Begriche, Igoudjil and Pessayre50). Moreover, hepatocyte nuclear factor-4, a downstream target of AMP kinase(Reference Hong, Varanasi and Yang51), is essential for the maintenance of lipid homeostasis(Reference Hayhurst, Lee and Lambert52). In the present study, the gene expression of SREBP1-c was unchanged among the three groups. Moreover, the protein expression of hepatocyte nuclear factor-4 was not modified whatever the diet. The amount of protein fatty acid synthase, a target of SREBP1-c, that plays a central role in de novo lipogenesis, was also unchanged(Reference Wakil, Stoops and Joshi53). Thus, it was probably not SREBP1-c-inhibited lipogenesis that contributes to lower hepatic TAG accumulation with polyphenols.

Sirtuin-1 deacetylase has been shown to modulate PGC-1α activity(Reference Rodgers, Lerin and Haas46, Reference Lin, Handschin and Spiegelman54) while PGC-1α increases the oxidation of fatty acids via increasing mitochondrial capacity and function(Reference Medina-Gomez, Gray and Vidal-Puig55). In the present study, the gene expression of PGC-1α decreased in HFHS diet-fed rats in comparison with controls and returned almost to control values with the PPE, as previously described with resveratrol(Reference Ajmo, Liang and Rogers12, Reference Lagouge, Argmann and Gerhart-Hines45). Moreover, PGC-1α gene expression was negatively correlated with liver TAG content. Nevertheless, the expression of its target genes carnitine palmitoyltransferase 1 and medium-chain acyl-CoA dehydrogenase, that regulate mitochondrial fatty acid β-oxidation(Reference Fromenty and Pessayre56), was not modified whatever the diet. It would be interesting to explore whether the PPE rather modulates their activities. Thus, PPE may attenuate fatty liver induced by the HFHS diet through the activation of hepatic sirtuin-1 deacetylase, and by the regulation of acetyl-CoA carboxylase phosphorylation. Nevertheless, we cannot exclude that the PPE may exert part of its hypolipidaemic effect by inhibiting the intestinal absorption of dietary lipids and diminishing chylomicron secretion by enterocytes, as it has been demonstrated for green tea catechins(Reference Raederstorff, Schlachter and Elste57, Reference Koo and Noh58). This hypothesis deserves further study, as this has never been addressed for wine polyphenols.

Mitochondrial biogenesis and mitochondrial activity

Mitochondria are the principal energy sources of the cell that convert nutrients into energy through cellular respiration(Reference Wallace59), and mitochondrial biogenesis in the liver is controlled, in large part, by the transcriptional coactivator PGC-1α(Reference Baur, Pearson and Price6, Reference Lin, Handschin and Spiegelman54). Thus, we have explored PGC-1α target mitochondrial genes and maximal activities of mitochondrial respiratory chain complexes. The gene expression of PGC-1α was down-regulated with the HFHS diet and up-regulated with the PPE. However, the expression of nuclear respiratory factor 1 and mitochondrial transcription factor A was unchanged among the three experimental groups. We observed that citrate synthase, an indicator of increased mitochondrial content, even if it may reflect also high activation of the tricarboxylic acid cycle, was not modified in the HFHS rats. In HFHS diet-fed rats, maximal activities of complex II and complex II+III were significantly decreased while the PPE had no effect. Moreover, the maximal activity of complex IV was not modified whatever the diet. Interestingly, complex IV activity was significantly correlated with the liver NEFA content. Moreover, complex II and complex II+III activities were negatively correlated with liver TAG content. It is possible that this reflects modification of the composition of the lipid moiety of the mitochondrial membrane in which the complexes are embedded, thus affecting their activity. The observed alteration of the maximal activity of the mitochondrial respiratory chain complexes in the liver of HFHS die-fed rats was coherent with previous studies(Reference Feillet-Coudray, Sutra and Fouret11, Reference Iossa, Lionetti and Mollica60Reference Garcia-Ruiz, Rodriguez-Juan and Diaz-Sanjuan64) and with the observation of steatosis, as a dysregulation of mitochondrial function might be implicated in fat accumulation in liver(Reference Mantena, King and Andringa5).

Conclusion

In the present study, we confirmed that a PPE partially prevented the accumulation of TAG in liver by regulating acetyl-CoA carboxylase phosphorylation, a key enzyme in lipid metabolism, probably through the activation of hepatic sirtuin-1 deacetylase. Up-regulated fatty acid β-oxidation activity by the PPE is probably involved in the lower liver lipid accumulation with the HFHS diet, while hepatic lipogenesis did not seem altered. Desaturase activity indexes were not modified and the PPE did not modulate liver fatty acid composition, while liver fatty acid composition mostly reflected fatty acids in dietary lipids. The PPE modulated PGC-1α expression but did not modify mitochondriogenesis and mitochondrial activity. Whether this PPE should be effective at ameliorating hepatic lipid accumulation in humans deserves further study. A diagram of the pathways affected by the PPE is provided in Fig. 3.

Fig. 3 Explanatory diagram showing the pathways found to be affected by polyphenol extract (PPE). As shown, PPE activates hepatic sirtuin-1 deacetylase. This latter activates directly or indirectly PPARγ coactivator-1α (PGC-1α) and inactivates acetyl-CoA carboxylase by enhancing its phosphorylation via AMP kinase. Both PGC-1α and acetyl-CoA carboxylase may contribute to increase mitochondrial fatty acid oxidation. On the other hand, PPE does not alter sterol regulatory element-binding protein-1c (SREBP1-c) gene expression involved in lipid synthesis. So, mitochondrial up-regulated fatty acid β-oxidation activity by PPE is probably involved in the lower liver lipid accumulation with the high-fat–high-sucrose diet, while hepatic lipogenesis does not seem to be altered.

Acknowledgements

The authors thank L. Lepourry and B. Bonnafos for the use of the animal facilities. The authors acknowledge the Société Française de Distellerie (Mr D. Ageron), which supplied the powdered PPE.

This research received no specific grant from any funding agency in the public, commercial or not-for-profit sectors.

C. C. and C. F.-C. designed the research; M. A., F. M., G. F., M. J., J. R. and C. F.-C. conducted the research. F. M., F. C., J.-P. C., C. W.-C., C. C., M.-A. C. and C. F.-C. analysed the data; C. F.-C. wrote the paper and had responsibility for the final content. All authors read and approved the final manuscript.

The authors declare no conflict of interest.

References

1Barness, LA, Opitz, JM & Gilbert-Barness, E (2007) Obesity: genetic, molecular, and environmental aspects. Am J Med Genet A 143, 30163034.CrossRefGoogle Scholar
2Fromenty, B, Robin, MA, Igoudjil, A, et al. (2004) The ins and outs of mitochondrial dysfunction in NASH. Diabetes Metab 30, 121138.CrossRefGoogle ScholarPubMed
3Erickson, SK (2009) Nonalcoholic fatty liver disease. J Lipid Res 50, Suppl., S412S416.CrossRefGoogle ScholarPubMed
4Cave, M, Deaciuc, I, Mendez, C, et al. (2007) Nonalcoholic fatty liver disease: predisposing factors and the role of nutrition. J Nutr Biochem 18, 184195.CrossRefGoogle ScholarPubMed
5Mantena, SK, King, AL, Andringa, KK, et al. (2008) Mitochondrial dysfunction and oxidative stress in the pathogenesis of alcohol- and obesity-induced fatty liver diseases. Free Radic Biol Med 44, 12591272.CrossRefGoogle ScholarPubMed
6Baur, JA, Pearson, KJ, Price, NL, et al. (2006) Resveratrol improves health and survival of mice on a high-calorie diet. Nature 444, 337342.CrossRefGoogle ScholarPubMed
7Mulvihill, EE, Allister, EM, Sutherland, BG, et al. (2009) Naringenin prevents dyslipidemia, apoB overproduction and hyperinsulinemia in LDL-receptor null mice with diet-induced insulin resistance. Diabetes 58, 21982210.CrossRefGoogle ScholarPubMed
8Yalniz, M, Bahcecioglu, IH, Kuzu, N, et al. (2007) Preventive role of genistein in an experimental non-alcoholic steatohepatitis model. J Gastroenterol Hepatol 22, 20092014.CrossRefGoogle Scholar
9Kuzu, N, Bahcecioglu, IH, Dagli, AF, et al. (2008) Epigallocatechin gallate attenuates experimental non-alcoholic steatohepatitis induced by high fat diet. J Gastroenterol Hepatol 23, e465e470.CrossRefGoogle ScholarPubMed
10Shang, J, Chen, LL, Xiao, FX, et al. (2008) Resveratrol improves non-alcoholic fatty liver disease by activating AMP-activated protein kinase. Acta Pharmacol Sin 29, 698706.CrossRefGoogle ScholarPubMed
11Feillet-Coudray, C, Sutra, T, Fouret, G, et al. (2009) Oxidative stress in rats fed a high-fat high-sucrose diet and preventive effect of polyphenols: involvement of mitochondrial and NAD(P)H oxidase systems. Free Radic Biol Med 46, 624632.CrossRefGoogle ScholarPubMed
12Ajmo, JM, Liang, X, Rogers, CQ, et al. (2008) Resveratrol alleviates alcoholic fatty liver in mice. Am J Physiol Gastrointest Liver Physiol 295, G833G842.CrossRefGoogle ScholarPubMed
13Klaus, S, Pultz, S, Thone-Reineke, C, et al. (2005) Epigallocatechin gallate attenuates diet-induced obesity in mice by decreasing energy absorption and increasing fat oxidation. Int J Obes (Lond) 29, 615623.CrossRefGoogle ScholarPubMed
14Ogino, Y, Osada, K, Nakamura, S, et al. (2007) Absorption of dietary cholesterol oxidation products and their downstream metabolic effects are reduced by dietary apple polyphenols. Lipids 42, 151161.CrossRefGoogle ScholarPubMed
15Zang, M, Xu, S, Maitland-Toolan, KA, et al. (2006) Polyphenols stimulate AMP-activated protein kinase, lower lipids, and inhibit accelerated atherosclerosis in diabetic LDL receptor-deficient mice. Diabetes 55, 21802191.CrossRefGoogle ScholarPubMed
16Hou, X, Xu, S, Maitland-Toolan, KA, et al. (2008) SIRT1 regulates hepatocyte lipid metabolism through activating AMP-activated protein kinase. J Biol Chem 283, 2001520026.CrossRefGoogle ScholarPubMed
17Csiszar, A, Labinskyy, N, Pinto, JT, et al. (2009) Resveratrol induces mitochondrial biogenesis in endothelial cells. Am J Physiol Heart Circ Physiol 297, H13H20.CrossRefGoogle ScholarPubMed
18Nanji, AA (2004) Animal models of nonalcoholic fatty liver disease and steatohepatitis. Clin Liver Dis 8, 559574, ix.CrossRefGoogle ScholarPubMed
19Ahmed, U, Redgrave, TG & Oates, PS (2009) Effect of dietary fat to produce non-alcoholic fatty liver in the rat. J Gastroenterol Hepatol 24, 14631471.CrossRefGoogle ScholarPubMed
20Reeves, PG, Nielsen, FH & Fahey, GC Jr (1993) AIN-93 purified diets for laboratory rodents: final report of the American Institute of Nutrition ad hoc writing committee on the reformulation of the AIN-76A rodent diet. J Nutr 123, 19391951.CrossRefGoogle Scholar
21Bradford, 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
22Folch, J, Lees, M & Sloane Stanley, GH (1957) A simple method for the isolation and purification of total lipides from animal tissues. J Biol Chem 226, 497509.CrossRefGoogle ScholarPubMed
23Bartlett, GR (1959) Phosphorus assay in column chromatography. J Biol Chem 234, 466468.CrossRefGoogle ScholarPubMed
24Lepage, G & Roy, CC (1986) Direct transesterification of all classes of lipids in a one-step reaction. J Lipid Res 27, 114120.CrossRefGoogle Scholar
25Biggemann, B, Laryea, MD, Schuster, A, et al. (1988) Status of plasma and erythrocyte fatty acids and vitamin A and E in young children with cystic fibrosis. Scand J Gastroenterol Suppl 143, 135141.CrossRefGoogle Scholar
26Stefan, N, Peter, A, Cegan, A, et al. (2008) Low hepatic stearoyl-CoA desaturase 1 activity is associated with fatty liver and insulin resistance in obese humans. Diabetologia 51, 648656.CrossRefGoogle ScholarPubMed
27Rustin, P, Chretien, D, Bourgeron, T, et al. (1994) Biochemical and molecular investigations in respiratory chain deficiencies. Clin Chim Acta 228, 3551.CrossRefGoogle ScholarPubMed
28Wharton, D & Tzagoloff, A (1967) Cytochrome oxidase from beef heart mitochondria. Methods Enzymol 10, 245250.CrossRefGoogle Scholar
29Srere, P (1969) Citrate synthase. Methods Enzymol 13, 311.CrossRefGoogle Scholar
30Scalbert, A & Williamson, G (2000) Dietary intake and bioavailability of polyphenols. J Nutr 130, Suppl. 8S, 2073S2085S.CrossRefGoogle ScholarPubMed
31Yang, R & Barouch, LA (2007) Leptin signaling and obesity: cardiovascular consequences. Circ Res 101, 545559.CrossRefGoogle ScholarPubMed
32Bargalló, MV, Grau, AA, Fernández-Larrea, J, et al. (2006) Moderate red-wine consumption partially prevents body weight gain in rats fed a hyperlipidic diet. J Nutr Biochem 17, 139142.CrossRefGoogle Scholar
33Decorde, K, Teissedre, PL, Sutra, T, et al. (2009) Chardonnay grape seed procyanidin extract supplementation prevents high-fat diet-induced obesity in hamsters by improving adipokine imbalance and oxidative stress markers. Mol Nutr Food Res 53, 659666.CrossRefGoogle ScholarPubMed
34Zheng, G, Sayama, K, Okubo, T, et al. (2004) Anti-obesity effects of three major components of green tea, catechins, caffeine and theanine, in mice. In Vivo 18, 5562.Google ScholarPubMed
35Tessari, P, Coracina, A, Cosma, A, et al. (2009) Hepatic lipid metabolism and non-alcoholic fatty liver disease. Nutr Metab Cardiovasc Dis 19, 291302.CrossRefGoogle ScholarPubMed
36Postic, C & Girard, J (2008) Contribution of de novo fatty acid synthesis to hepatic steatosis and insulin resistance: lessons from genetically engineered mice. J Clin Invest 118, 829838.CrossRefGoogle ScholarPubMed
37Kim, WS, Lee, YS, Cha, SH, et al. (2009) Berberine improves lipid dysregulation in obesity by controlling central and peripheral AMPK activity. Am J Physiol Endocrinol Metab 296, E812E819.CrossRefGoogle ScholarPubMed
38Jang, EM, Choi, MS, Jung, UJ, et al. (2008) Beneficial effects of curcumin on hyperlipidemia and insulin resistance in high-fat-fed hamsters. Metabolism 57, 15761583.CrossRefGoogle ScholarPubMed
39Wang, JQ, Li, J, Zou, YH, et al. (2009) Preventive effects of total flavonoids of Litsea coreana leve on hepatic steatosis in rats fed with high fat diet. J Ethnopharmacol 121, 5460.CrossRefGoogle ScholarPubMed
40Quesada, H, Del Bas, JM, Pajuelo, D, et al. (2009) Grape seed proanthocyanidins correct dyslipidemia associated with a high-fat diet in rats and repress genes controlling lipogenesis and VLDL assembling in liver. Int J Obes (Lond) 33, 10071012.CrossRefGoogle ScholarPubMed
41Sealls, W, Gonzalez, M, Brosnan, MJ, et al. (2008) Dietary polyunsaturated fatty acids (C18:2 ω6 and C18:3 ω3) do not suppress hepatic lipogenesis. Biochim Biophys Acta 1781, 406414.CrossRefGoogle Scholar
42Morise, A, Mourot, J, Boue, C, et al. (2006) Gender-related response of lipid metabolism to dietary fatty acids in the hamster. Br J Nutr 95, 709720.CrossRefGoogle ScholarPubMed
43Li, ZZ, Berk, M, McIntyre, TM, et al. (2009) Hepatic lipid partitioning and liver damage in nonalcoholic fatty liver disease: role of stearoyl-CoA desaturase. J Biol Chem 284, 56375644.CrossRefGoogle ScholarPubMed
44Howitz, KT, Bitterman, KJ, Cohen, HY, et al. (2003) Small molecule activators of sirtuins extend Saccharomyces cerevisiae lifespan. Nature 425, 191196.CrossRefGoogle ScholarPubMed
45Lagouge, M, Argmann, C, Gerhart-Hines, Z, et al. (2006) Resveratrol improves mitochondrial function and protects against metabolic disease by activating SIRT1 and PGC-1α. Cell 127, 11091122.CrossRefGoogle ScholarPubMed
46Rodgers, JT, Lerin, C, Haas, W, et al. (2005) Nutrient control of glucose homeostasis through a complex of PGC-1α and SIRT1. Nature 434, 113118.CrossRefGoogle ScholarPubMed
47Munday, MR, Milic, MR, Takhar, S, et al. (1991) The short-term regulation of hepatic acetyl-CoA carboxylase during starvation and re-feeding in the rat. Biochem J 280, 733737.CrossRefGoogle ScholarPubMed
48Hastings, IM & Hill, WG (1990) Analysis of lines of mice selected for fat content. 2. Correlated responses in the activities of enzymes involved in lipogenesis. Genet Res 55, 5561.CrossRefGoogle ScholarPubMed
49Lin, CL, Huang, HC & Lin, JK (2007) Theaflavins attenuate hepatic lipid accumulation through activating AMPK in human HepG2 cells. J Lipid Res 48, 23342343.CrossRefGoogle ScholarPubMed
50Begriche, K, Igoudjil, A, Pessayre, D, et al. (2006) Mitochondrial dysfunction in NASH: causes, consequences and possible means to prevent it. Mitochondrion 6, 128.CrossRefGoogle Scholar
51Hong, YH, Varanasi, US, Yang, W, et al. (2003) AMP-activated protein kinase regulates HNF4α transcriptional activity by inhibiting dimer formation and decreasing protein stability. J Biol Chem 278, 2749527501.CrossRefGoogle ScholarPubMed
52Hayhurst, GP, Lee, YH, Lambert, G, et al. (2001) Hepatocyte nuclear factor 4α (nuclear receptor 2A1) is essential for maintenance of hepatic gene expression and lipid homeostasis. Mol Cell Biol 21, 13931403.CrossRefGoogle ScholarPubMed
53Wakil, SJ, Stoops, JK & Joshi, VC (1983) Fatty acid synthesis and its regulation. Annu Rev Biochem 52, 537579.CrossRefGoogle ScholarPubMed
54Lin, J, Handschin, C & Spiegelman, BM (2005) Metabolic control through the PGC-1 family of transcription coactivators. Cell Metab 1, 361370.CrossRefGoogle ScholarPubMed
55Medina-Gomez, G, Gray, S & Vidal-Puig, A (2007) Adipogenesis and lipotoxicity: role of peroxisome proliferator-activated receptor γ (PPARγ) and PPARγ coactivator-1 (PGC1). Public Health Nutr 10, 11321137.CrossRefGoogle ScholarPubMed
56Fromenty, B & Pessayre, D (1995) Inhibition of mitochondrial β-oxidation as a mechanism of hepatotoxicity. Pharmacol Ther 67, 101154.CrossRefGoogle ScholarPubMed
57Raederstorff, DG, Schlachter, MF, Elste, V, et al. (2003) Effect of EGCG on lipid absorption and plasma lipid levels in rats. J Nutr Biochem 14, 326332.CrossRefGoogle ScholarPubMed
58Koo, SI & Noh, SK (2007) Green tea as inhibitor of the intestinal absorption of lipids: potential mechanism for its lipid-lowering effect. J Nutr Biochem 18, 179183.CrossRefGoogle ScholarPubMed
59Wallace, DC (2005) A mitochondrial paradigm of metabolic and degenerative diseases, aging, and cancer: a dawn for evolutionary medicine. Annu Rev Genet 39, 359407.CrossRefGoogle ScholarPubMed
60Iossa, S, Lionetti, L, Mollica, MP, et al. (1999) Fat balance and hepatic mitochondrial function in response to fat feeding in mature rats. Int J Obes Relat Metab Disord 23, 11221128.CrossRefGoogle ScholarPubMed
61Iossa, S, Lionetti, L, Mollica, MP, et al. (2000) Effect of long-term high-fat feeding on energy balance and liver oxidative activity in rats. Br J Nutr 84, 377385.CrossRefGoogle ScholarPubMed
62Iossa, S, Lionetti, L, Mollica, MP, et al. (2003) Effect of high-fat feeding on metabolic efficiency and mitochondrial oxidative capacity in adult rats. Br J Nutr 90, 953960.CrossRefGoogle ScholarPubMed
63Perez-Carreras, M, Del Hoyo, P, Martin, MA, et al. (2003) Defective hepatic mitochondrial respiratory chain in patients with nonalcoholic steatohepatitis. Hepatology 38, 9991007.CrossRefGoogle ScholarPubMed
64Garcia-Ruiz, I, Rodriguez-Juan, C, Diaz-Sanjuan, T, et al. (2006) Uric acid and anti-TNF antibody improve mitochondrial dysfunction in ob/ob mice. Hepatology 44, 581591.CrossRefGoogle ScholarPubMed
Figure 0

Table 1 Fatty acid composition of the experimental diets (% μg)*

Figure 1

Table 2 Primer sequences used for real-time RT-PCR

Figure 2

Table 3 Body weight and weight gain, dietary and energy intakes and plasma glucose, lipids, insulin and leptin levels‡(Mean values and standard deviations)

Figure 3

Table 4 Liver weight and lipid content, and mitochondrial respiratory complex activities‡(Mean values and standard deviations)

Figure 4

Fig. 1 Liver histology after haematoxylin–eosin staining of liver sections from a representative rat of each group: (a) control diet; (b) high-fat–high-sucrose (HFHS) diet; (c) HFHS diet plus polyphenol extract.

Figure 5

Table 5 Total fatty acid composition of rat liver (mg fatty acid/g tissue)‡(Mean values and standard deviations)

Figure 6

Fig. 2 Sirtuin-1 deacetylase (SIRT1)–AMP kinase (AMPK) signalling pathway: relative protein expression in control diet-fed rats (), high-fat–high-sucrose (HFHS) diet-fed rats () and HFHS diet plus polyphenol extract-fed rats (). p-AMPK, phospho-AMPK; p-ACC, phospho-acetyl-CoA carboxylase; FAS, fatty acid synthase; HNF4, hepatocyte nuclear factor 4. Values are means (n 6 per group), with standard deviations represented by vertical bars. * Mean value was significantly different from that of the control group (P < 0·05). † Mean value was significantly different from that of the HFHS group (P < 0·05).

Figure 7

Fig. 3 Explanatory diagram showing the pathways found to be affected by polyphenol extract (PPE). As shown, PPE activates hepatic sirtuin-1 deacetylase. This latter activates directly or indirectly PPARγ coactivator-1α (PGC-1α) and inactivates acetyl-CoA carboxylase by enhancing its phosphorylation via AMP kinase. Both PGC-1α and acetyl-CoA carboxylase may contribute to increase mitochondrial fatty acid oxidation. On the other hand, PPE does not alter sterol regulatory element-binding protein-1c (SREBP1-c) gene expression involved in lipid synthesis. So, mitochondrial up-regulated fatty acid β-oxidation activity by PPE is probably involved in the lower liver lipid accumulation with the high-fat–high-sucrose diet, while hepatic lipogenesis does not seem to be altered.