Oral glucose tolerance test

At each time, rats were fasted overnight, and then a local anaesthetisation was performed on the tail with lidocaine (EMLA 5 % cream; AstraZeneca) to take vein iterate blood samples. The first vein blood sample was taken (T0) (50 µl) and immediately after, an oral glucose solution (3 g/kg BW) was administered. Blood samples were collected at times 10, 20, 30, 45, 60, 90 and 120 min after glucose administration (50 µl at each time point). A fraction was immediately used for glucose determination using a glucometer (OneTouch®, Lifescan SAS); another fraction was collected in tubes containing heparin to separate the plasma by centrifugation at 10·000 g , 4°C. Plasma samples were stored at –20°C until further analysis of glucose, insulin, NEFA, leptin and adiponectin plasma concentrations. Plasma adiponectin and leptin concentrations were determined in ZO rats only.

Euglycaemic–hyperinsulinaemic clamp studies and 2-deoxyglucose experiments

The clamp was carried out in ZO only. Rats were subjected to clamp studies after 9 weeks of diet as described^{(Reference Marsollier, Kassis and Mezghenna18,Reference Joly-Amado, Soty and Philippe19)} . Briefly, rats were deprived of feed for 5 h (from 09.00 to 14.00) and anaesthetised with pentobarbital sodium (50 mg/kg BW). A catheter was inserted into the right jugular vein for blood sampling. Infusions (insulin, labelled and unlabelled glucose) were carried out using butterfly needles inserted in the saphenous vein. Before insulin infusion, two sets of blood samples were drawn for determination of basal blood glucose and insulin concentrations. A priming dose of [3–³H] glucose (5 µCi) and a priming dose of 20 mUI of insulin (Actrapid^®, Novo) dissolved in isotonic saline were injected through the saphenous vein, followed by a continuous infusion of tritiated glucose (0·2 µCi/min) and of insulin (0·4 U/kg/h) at a constant rate of 20 µl/min. During clamp, blood was sampled from caudal vessels every 5 min to determine blood glucose and to adjust the rate of unlabelled glucose infusion to maintain euglycaemia (glucose infusion rate). The euglycaemic clamp was attained within 30–40 min and maintained for 40 min thereafter. Steady-state-specific glucose radioactivity and blood glucose and insulin concentration were determined during the last 20 min of the clamp using three latest blood samples. Then, an injection of a bolus of 2-deoxy-D-[1-¹⁴C] glucose (2-DG, 5 µCi, Amersham), a glucose analogue that did not undergo further degradation following the 6-phosphate addition by the hexokinase, was done. Blood samples (50 µl) were collected from the tail at times 0, 5, 10, 20, 30, 40, 50 and 60 min until the end of the experiment where rats were killed by lethal pentobarbital injection, and muscle and adipose tissues were collected.

Calculation of glucose kinetics

Basal and steady-state plasma [3-³H] glucose radioactivity were measured as described^{(Reference Dufresne, Hoang and Ajambo12)}. Briefly, for [3-³H] glucose determination, plasma was deproteinised with Ba(OH)₂ and ZnSO₄. Aliquots of the supernatant of each sample were dried to remove ³H₂0, and the dry residues were dissolved in 0·5 ml water to which 10 ml scintillation solution was added (Aqualuma Plus^® scintillator, Lumac BV). Radioactivity was determined in a Packard Tri-Carb 460C liquid scintillation counter. The rate of glucose disappearance (Rd), reflecting glucose utilisation rate, was calculated according to the formula Rd = Ra (rate of appearance) = [3-³H] glucose infusion rate (dpm/min/kg) divided by blood glucose-specific activity (dpm/mg). Endogenous glucose production (given as mg/kg/min) was determined by subtracting the glucose infusion rate from total Ra (= Rd). In vivo glucose uptake (ng/mg of tissue/min) for muscle (tibialis anterior and soleus) and white adipose tissue (inguinal and peri-epididymal) was calculated based on the accumulation of 2-DG-6-phosphate in the respective tissues and the disappearance rate of 2-DG from plasma, as described^{(Reference Kim, Gimeno and Higashimori20)}.

Phosphoenolpyruvate carboxykinase and glucose-6-phosphatase enzymatic activities

Liver phosphoenolpyruvate carboxykinase (PEPCK) and glucose-6-phosphatase (G6Pase) enzyme activities were measured in the liver of ZO_FO and ZO_CO rats only. We previously showed that the best approach to preserve PEPCK and G6Pase activities at their initial level was to quickly freeze-clamp liver and intestine at liquid N₂ temperature and further maintain them at –80°C^{(Reference Rajas, Bruni and Montano21,Reference Mutel, Gautier-Stein and Abdul-Wahed22)} . Frozen liver samples were powdered into liquid N₂ and homogenised by sonication in 20 mM HEPES, 0·25 M sucrose (pH 7·3) (100 µg of wet tissue per millilitre). Homogenates were diluted ten times before determination of G6Pase at maximal velocity (20 mmol/l glucose-6 phosphate) at 30°C by complex formation of the phosphate produced, as previously described^{(Reference Rajas, Bruni and Montano21)}. Specific G6Pase activity was cleared of the contribution of non-specific phosphohydrolase activities by subtracting the activity towards β-glycerophosphate (20 mmol/l). PEPCK was determined in 100 000 × g supernatants of the homogenates, using the decarboxylation assay described by Rajas et al.^{(Reference Rajas, Croset and Zitoun23)} and by Jomain-Baum and Schramm^{(Reference Jomain-Baum and Schramm24)}.

For PEPCK protein quantification, 30 µg protein was separated by electrophoresis in 9 % polyacrylamide gels in the presence of SDS. Protein concentration was assayed by the Lowry protein assay^{(Reference Lowry, Rosebrough and Farr25)}. The method combines the reactions of copper ions with the peptide bonds under alkaline conditions (the Biuret test) with the oxidation of aromatic protein residues. The Lowry method is based on the reaction of Cu⁺, produced by the oxidation of peptide bonds, with Folin–Ciocalteu reagent (a mixture of phosphotungstic acid and phosphomolybdic acid). This reagent allows the aromatic amino acids (tyrosine and tryptophan) to be reduced, leading to the formation of a dark blue coloured complex (heteropolymolybdenum blue) whose absorbance will be measured by absorbance at 660 nm. As a result, the total concentration of protein in the sample can be deduced from the concentration of tryptophan and tyrosine residues that reduce the Folin–Ciocalteu reagent.

Total protein extracts were then quantified using a DC protein assay (Biorad), and concentration was determined quantitatively using 96-well micro-plates (Nunc) and a micro-plate reader connected to KC4 v3 software (Bio-Tek Instruments, Inc.).

After electro transfer to polyvinylidene fluoride immobilon membranes (Millipore Corp.), immunodetection was performed using anti-PEPCK antibodies at dilutions of 1:7000^{(Reference Jomain-Baum and Schramm24)}. Membranes were re-blotted with anti-β-tubulin (use at 1:2000; Santa Cruz Biotechnology, Inc.) for standardisation.

Plasma parameters

Blood glucose was determined by reflectometry using a glucose analyser (Accu-Chek^®, Roche). The system was calibrated using whole blood with different glucose levels. Reference values were determined using the hexokinase method calibrated against the ID-GCMS method. This reference method was standardised using isotope dilution gas chromatography–mass spectrometry, the best metrological quality assurance method (order), and meets the NIST standard (traceable).

Insulin, leptin and adiponectin plasma concentrations were determined by rat ELISA kits (ALPCO Diagnostics) with a sensitivity of 0·124 ng/ml and dynamic range: 0·15–5·5 ng/ml for insulin, a sensitivity of 0·01 ng/ml and dynamic range: 0·025–1·6 ng/ml for leptin, a sensitivity of 0·08 ng/ml and 0·25–10 ng/ml dynamic range for adiponectin.

NEFA concentrations were measured using an enzymatic assay (NEFA-C test^®; Wako Chemicals GmbH) with a sensitivity 0·005 mmol/l. The Wako NEFA C test kit utilises an in vitro enzymatic colorimetric method.

Extraction and analysis of fatty acids content in diets

Total lipid extracts from diets were obtained by using the method of Bligh and Dyer^{(Reference Bligh and Dyer26)}. The extract was evaporated, dissolved in CHCl₃–MeOH (98:2) and then stored under nitrogen atmosphere at –20°C until analysis. After evaporation to dryness, lipid fractions were esterified with MeOH-H₂SO₄ (98:2) in excess for one night at 50°C. After cooling, 2 ml of hexane and 1 ml of water were added, and the mixture was vortexed. The upper organic phase containing fatty acid methyl esters was collected and separation was carried out on a GC (PerkinElmer Autosystem) equipped with a flame ionisation detector, an on-column injector and a fused silica column (BPX, 60 m × 0·25 mm; 0·25 µm film thickness, SGE) programmed from 55°C (for 2 min) to 150°C at 20°C/min. Identification of fatty acid methyl esters was based on the comparison of their retention times with those of authentic standards, and quantification of peak area was done using margaric acid (17:0) as internal standard added at the time of lipid extraction^{(Reference Berge, Debiton and Dumay27)}.

Extraction and analysis of ceramides and diacylglycerol content in the hypothalamus

DAG and ceramide levels in tissue extracts were measured by the DAG kinase enzymatic method as previously described^{(Reference Escalante-Alcalde, Hernandez and Le Stunff28,Reference Le Stunff, Galve-Roperh and Peterson29)} in ZO rats only. Briefly, aliquots of the chloroform phases from cellular lipid extracts were re-suspended in 7·5 % (w/v) octyl-β-D-glucopyranoside/5 mM cardiolipin in 1 mM DETPAC/10 mM imidazole (pH 6·6). The enzymatic reaction was started by the addition of 20 mM DTT, 0·88 U/ml E. coli DAG kinase, 5 µCi/10 mM [γ-³²P] ATP and the reaction buffer (100 mM imidazole (pH 6·6), 100 mM NaCl, 25 mM MgCl₂ and 2 mM EGTA). After incubation for 1 h at room temperature, lipids were extracted with chloroform/methanol/HCl (100:100:1, v/v) and 1 M KCl. [γ-32P]-phosphatidic acid was resolved by TLC with chloroform/acetone/methanol/acetic acid/water (10:4:3:2:1, v/v) and quantified with a Molecular Dynamics Storm PhosphorImager^®. Known amounts of DAG and ceramide standards were included with each assay. Ceramide and DAG levels were expressed as picomoles by nanomoles of phospholipid levels.

Measurement of total cellular phospholipids in hypothalamus

In order to normalise the ceramide and DAG content in hypothalamus, total phospholipids present in cellular lipid extracts used for ceramide analysis were quantified as described previously^{(Reference Le Stunff, Galve-Roperh and Peterson29)} with minor modifications. Briefly, a mixture of 10N H₂SO₄/70 % perchloric acid (3:1, v/v) was added to lipid extracts, which were incubated for 30 min at 210°C. After cooling, water and 4·2 % ammonium molybdate in 4 N HCl/0·045 % malachite green (1:3 v/v) were added. Samples were incubated at 37°C for 30 min, and absorbance was measured at 660 nm. Total phospholipid levels were expressed as nanomoles of phospholipid.