Chemicals and reagents

Nutrients for diet preparation were of analytical grade, with the exception of soyabean oil (Cada Día), sucrose and maize starch, which were food grade and obtained from local sources. CLA oil was obtained from Lipid Nutrition B.V. and consisted of an equimolecular mixture of c9,t11-CLA (38·99 %, w/w) and t10,c12-CLA (38·76 %, w/w). All solvents and reagents used for the FA quantification were of chromatography grade and were purchased from Merck. GLC-463 standards containing fifty-two fatty acid methyl esters (FAME) mixtures (purity > 99 %) were purchased from Nu-Chek Prep, Inc.. CLA, cis/trans mix (catalogue no. 05507) was purchased from Sigma-Aldrich, Inc.. The International CYTED Net (208RT0343) provided other FAME standards. Primers used for PCR analysis were synthesised by Invitrogen. For the enzyme assays, the materials were from Sigma-Aldrich, Inc.. All the other chemicals and reagents utilised were at least American Chemical Society degree or molecular grade and were acquired from Merck, Invitrogen and Applied Biosystems. The TAG test kit was obtained from the Sociedad de Bioquímicos.

Animals

Male and virgin mature female Wistar rats were provided by the facilities of our university. The animals were housed in collective cages, with the exception of mating, pregnancy and lactation periods, under controlled conditions (23 (sd 2) °C and 12 h light–12 h dark) with free access to standard food and water. All the experiments were conducted in compliance with the Guide for the Care and Use of Experimental Laboratory Animals^{(Reference Bayne23)} and were approved by the Animal Ethics Committee of the School of Biochemistry (Universidad Nacional del Litoral).

Diet preparation

For all the experiments, three diets (Table 1) were used: control (C), HF and HF+CLA diets. The composition of the C diet was based on the American Institute of Nutrition Ad Hoc Committee recommendation (AIN-93G) formulated for the growth, pregnancy and lactation phases of rodents^{(Reference Reeves, Nielsen and Fahey24)}, using 7 % soyabean oil as a source of fat. The HF diet was enriched in fat by substituting 13 g of carbohydrate/100 g of diet with an equal amount of soyabean oil, reaching 20 g of fat/100 g of diet. The percentage of energy provided by fat (38 5 %) in the HF and HF+CLA diets slightly exceeds the recommended amount of dietary fat for the healthy adult population (20–35 % of energy)^{(Reference Vannice and Rasmussen25)}; however, it is reasonable for the human population^{(Reference Astorg, Arnault and Czernichow26)}. The amount of CLA used reflects the frequently consumed levels of nutritional supplementation. The HF+CLA diet was obtained by substituting 2·86 % (w/w) of soyabean oil in the HF diet with the same amount of CLA oil. The diets were freshly prepared, gassed with N₂ and stored at 0–4°C. The FA composition of the experimental diets (Table 2) was determined by GC as indicated below.

Table 1. Composition of experimental diets (g/100 g dry diet)*

C, control diet; HF, high-fat diet; HF+CLA, HF diet supplemented with conjugated linoleic acid.

* C: based on the American Institute of Nutrition Ad Hoc Committee recommendation (AIN-93 G) formulated for growth, pregnancy and lactation phases of rodents^{(Reference Reeves, Nielsen and Fahey24)}. Vitamin mixture (per kg of diet): nicotinic acid, 30·0 mg; pantothenate, 15·0 mg; pyridoxine, 6·0 mg; thiamin, 5·0 mg; riboflavin, 6·0 mg; folic acid, 2·0 mg; vitamin K, 750·0 μg; d-biotin, 200·0 μg; vitamin B₁₂, 24·0 μg; retinyl acetate, 1·2 mg; cholecalciferol, 0·025 mg; dl-α-tocopheryl acetate, 50 mg. Mineral mixture (mg/kg of diet): Ca, 5000·0; P, 1561·0; K, 3600·0; S, 300·0; Na 1019·0; Cl, 1571·0; Mg, 507·0; Fe, 35·0; Zn, 30·0; Mn, 10·0; Cu, 6·0; iodine, 0·2; Mo, 0·15; Se, 0·15; Si, 5·0; Cr, 1·0; F, 1·0; Ni, 0·5; B, 0·5; Li, 0·1 and V, 0·1.

Table 2. Fatty acid composition of experimental diets*

HF, high-fat diet; HF+CLA, HF diet supplemented with conjugated linoleic acid; ND, not detected.

* Values are expressed as the mean (percentage of total fatty acid methyl esters). A mixture of CLA was used as the source of CLA isomers and had an equimolecular amount of c9,t11-CLA (38·99 %) and t10,c12-CLA (38·76 %).

Experimental design

After a 1-week adaptation period (Fig. 1), eighteen female rats (274·1 (sd 8·6) g) were randomly divided into three experimental dietary groups (n 6/group), considering that one female rat was housed with one male from the same treatment group. After mating, each female was placed in an individual cage. The rats were fed the C, HF or HF+CLA diet for 4 weeks before mating and throughout pregnancy and lactation. At parturition, litter size was standardised to eight pups per dam in the C, HF and HF+CLA diets. The pups were maintained with their own mothers until weaning. The post-weaning male offspring of mothers fed with the C or HF diet continued with the same diets as their mothers, leading to the formation of the C/C and HF/HF groups (initial weights 98·6 (sd 5·3) and 97·8 (sd 6·1) g, respectively) (n 6 per group); the offspring of mothers fed HF+CLA were divided into two groups fed with HF diet (HF+CLA/HF; initial weights 98·3 (sd 4·2) g) or HF+CLA diet (HF+CLA/HF+CLA; initial weights 101·2 (sd 2·3) g) (n 6 per group). Based on the preliminary studies, the time of experimental feeding of the offspring was 9 weeks after weaning. At the end of the dietary treatment, one set of twenty-four animals (n 6 per group) was fasted overnight and killed (09.00–11.00 hours) under anaesthesia (1 mg acepromazine + 100 mg ketamine/kg body weight) by cardiac exsanguination. Blood was collected, and serum was obtained after centrifugation (1000 g for 10 min at 4°C). The liver, gastrocnemius muscle and epididymal white adipose tissue (EWAT) were dissected, weighed and immediately frozen. All samples were stored at –80°C until analysis. The same experimental protocol of feeding was followed with a second set of twenty-four male offspring rats divided into four experimental groups (n 6 per group) for the hepatic TAG secretion rate (TAG-SR) experiments, as explained below.

Fig. 1. Experimental design. C, control diet; HF, high-fat diet; HF+CLA, HF diet supplemented with conjugated linoleic acid. Maternal diet: for 4 weeks before mating and throughout pregnancy and lactation; post-weaning male offspring diet: for 9 weeks after weaning. Name of offspring groups: C/C, HF/HF, HF+CLA/HF and HF+CLA/HF+CLA. In all cases, the denomination to the left of the dash corresponds to the mother’s feeding, and the denomination to the right of the dash corresponds to the offspring’s feeding.

GC analysis

The FA composition of the experimental diets, liver, EWAT and serum was determined by GC using a Shimadzu (GC 2014) chromatograph equipped with a flame ionisation detector. Analyses were carried out with a capillary column CP Sil 88 (100 m, 0·25 µm film thickness). The carrier gas was H₂ with a split ratio of 1:10. The column temperature was held at 75°C for 2 min after injection, then 5°C/min to 170°C, held for 40 min, 5°C/min to 220°C and held for 40 min. The injection volume was 0·5 µl, and the column flow was 0·8 ml/min. Total fats in diets, tissues and serum were extracted using the method described by Bligh & Dyer^{(Reference Bligh and Dyer27)}. The FAME were formed by transesterification with methanolic potassium hydroxide solution as an interim stage before saponification (ISO 5509:2000, Point 5 IUPAC method 2.301). FAME were identified by comparison of their retention times relative to those of commercial standards. Further GC details could be obtained from previous publications^{(Reference Saín, González and Lavandera28,Reference Masson, Alfaro and Camilo29)} . The values of FA content were expressed as the percentage of total FAME (Table 2). The detection limit for the main FAME identified ranged from 0·01 to 0·03 %.

TAG levels in serum and liver

TAG levels in serum were determined by spectrophotometric methods using a commercially available test kit (Sociedad de Bioquímicos). To assess the liver TAG levels, portions of frozen tissue (0·5 g) were powdered and homogenised in saline (10 %, w/v) for TAG content quantification. Liver TAG levels were determined by the method of Laurell^{(Reference Laurell30)}.

Lipoprotein lipase activity in adipose tissue and gastrocnemius muscle

The removal capability of TAG-rich lipoproteins was evaluated by lipoprotein lipase (LPL) activities in the main tissues responsible for the uptake of TAG: adipose tissue and muscle. The LPL enzyme activity of adipose tissue was quantified in EWAT acetone powder by the fluorometric method of Del Prado et al. ^{(Reference Del Prado, Hernandez-Montes and Villalpando31)}. Briefly, EWAT samples were delipidated by double extraction with cold acetone followed by double extraction with diethyl ether. The powders obtained were resuspended and incubated in a buffer (25 mm NH₄Cl, pH 8·1 containing 1 IU/ml of heparin). The enzymatic reaction was carried out in a medium containing dibutyryl fluorescein as the enzyme substrate. The quantification of LPL activity was performed by measuring the increase in fluorescence (λ _excitation = 490 nm; λ _emission = 530 nm). In parallel, an identical assay was carried out in the same samples but in the presence of NaCl during the incubation to inhibit specific enzyme activity. LPL activity was estimated as the difference between non-specific lipolytic and total lipolytic activity. Values are expressed as pmol fluorescein/min per g of tissue and as nmol fluorescein/min per total EWAT. To assess muscle LPL activity, gastrocnemius muscle samples were homogenised in NH₄Cl/NH₄OH-heparin buffer. Then, the quantification of LPL activity in muscle was performed as previously described for adipose tissue^{(Reference Del Prado, Hernandez-Montes and Villalpando31)}. The measured activity was expressed as nmol fluorescein/min per mg of protein.

Hepatic TAG secretion rate

A second set of animals subjected to the same dietary treatments was fasted overnight and anaesthetised as indicated above. Then, 600 mg/kg of body weight of Triton WR 1339 in saline solution, an agent known to inhibit the peripheral removal of TAG-rich lipoproteins, was injected intravenously. Blood samples were taken immediately before and 120 min after the injection of the Triton solution for the estimation of TAG accumulation in serum. The hepatic TAG-SR was estimated based on the serum TAG concentration at 0 and 120 min, plasma volume and body weight. Further details have been previously reported^{(Reference Mocchiutti and Bernal32)}.

Liver enzyme activities

Liver samples were homogenised in buffer (pH 7·6) containing 150 mm KCl, 1 mm MgCl₂, 10 mm N-acetyl-cysteine and 0·5 mm dithiothreitol. After centrifugation at 100 000 g for 40 min at 4°C, the supernatant fraction was used for the quantification of enzyme activities. Acetyl-CoA carboxylase (ACC, EC 6.4.1.2), FA synthase (FAS, EC 2.3.1.85) and glucose-6 phosphate dehydrogenase (G6PDH, EC 1.1.1.49) activities were measured following a previously used protocol^{(Reference Sain, Gonzalez and Lasa33)}. Enzyme activities were expressed as mU/mg protein, where 1 mU was 1 nmol NADH consumed (ACC), 1 nmol NADPH consumed (FAS) or 1 nmol NADPH produced (G6PDH), per min. Carnitine palmitoyltransferase-Ia (CPT-Ia; EC 1.3.99.3) activity was assessed in the mitochondrial fraction. Liver samples were homogenised in a buffer (pH 7·4) containing 0·25 m sucrose, 1 mm EDTA and 10 mm Tris-HCl. Homogenates were centrifuged at 700 g for 10 min at 4°C, and supernatant fluid was centrifuged again (12 000 g, 15 min, 4°C). Pellets were resuspended in a buffer (pH 7·4) containing 70 mm sucrose, 220 mm mannitol, 1 mm EDTA and 2 mm 4-(2-hydroxyethyl)piperazine-1-ethanesulfonic acid (HEPES). CPT-Ia activity was assessed in the pellet by the method of Bieber et al. ^{(Reference Bieber, Abraham and Helmrath34)}. The pellet protein content was obtained as described above. The CPT-Ia activities were expressed as mU/mg protein (1 mU = 1 nmol CoA/min). The protein content was determined using bovine serum albumin as a standard^{(Reference Lowry, Rosebrough and Farr35)}.

Extraction and analysis of RNA and quantification by RT-PCR

Total RNA was isolated from the liver using TRIzol (Invitrogen), according to the manufacturer’s instructions. RNA samples were then treated with a DNA-free kit (Applied Biosystems) to remove any contamination with genomic DNA. The yield and quality of the RNA were assessed by measuring the absorbance at 260, 270, 280 and 310 nm and by electrophoresis on 1·3 % agarose gels. A quantity of 1 μg of total RNA from each sample was reverse-transcribed to first-strand complementary DNA (cDNA) using Moloney murine leukaemia virus reverse transcriptase (M-MLV RT). Relative mRNA levels were quantified using real-time PCR with a StepOne 18^TM Real-Time PCR Detection System (Applied Biosystems). Sequence-specific commercially synthesised primers (Invitrogen Custom Primers) were used (Genbank: ACC, NM_022193.1; FAS, NM_017332.1; sterol regulatory element-binding protein-1c (SREBP-1c), NM_0012 76708.1; stearoyl-CoA desaturase-1 (SCD-1), NM_139192.2; CPT-Ia, NM_031559.2; PPARα, NM_013196.1; β-actin, NM_031144.3; ubiquitin C (UBC), NM_017314.1 and hypoxanthine phosphoribosyltransferase 1 (HPRT1), NM_012583.2), and the sequences were as follows: ACC: 5′-AAC AGT GTA CAG CAT CGC CA-3′ (forward), 5′-CAT GCC GTA GTAG GTT GAG GT-3′ (reverse); FAS, 5′-CAG AAC TCT TCC AGG ATAG TCA ACA-3′ (forward), 5′-GTC GCC CTAG TCA AGG TTC AG-3′ (reverse); SREBP-1c, 5′-GGA GCC ATAG GAT TAGC ACA TT-3′ (forward), 5′-GCT TCC AGA GAG GAG CCC AG-3′ (reverse); SCD-1, 5′-CAC ACG CCG ACC CTC ACA ACT-3′ (forward), 5′-TCC GCC CTT CTC TTT GAC AGC C-3′ (reverse); CPT-Ia, 5′-ACG TAGA GTAG ACT GGT GGG AAG AAT-3′ (forward), 5′-TCT CCA TAGG CGT AGT AGT TAGC TAGT-3′ (reverse); PPARα, 5′-CCC CAC TTAG AAG CAG ATAG ACC-3′ (forward), 5′-CCC TAA GTA CTAG GTA GTC CGC-3′ (reverse); β-actin 5′-CAT GAA GAT CAA GAT CAT TAGC TCC T-3′ (forward), 5′-CTAG CTT GCT GAT CCA CAT CTAG-3′ (reverse); UBC 5′-ACACCAAGAAGGTCAAACAGGA-3′ (forward), 5′-CA CCTCCCCATCAAACCCAA-3′ (reverse); HPRT1 5′-TCCTCCTCA GACCGCTT TTC-3′ (forward), 5′-ATCACTAATCACGACGCT GGG-3′ (reverse). Standard curves for each primer were generated on separate runs using several serial dilutions (1/10–1/1000) of pooled cDNA samples. The corresponding primer efficiency (E) of one cycle in the exponential phase was calculated according to the equation E = 10 (−1/slope)^{(Reference Rasmussen, Meuer, Wittwer and Nakagawara36)}. All the efficiencies of the primers were 100 % (sem 10 %). Target genes were standardised with the geometric mean of three housekeeping genes: β-actin, UBC and HPRT1. Relative expression ratios were calculated using the recommended 2^–ΔΔCt method^{(Reference Vandesompele, De Preter and Pattyn37)}.

Statistical analysis

Values in Tables 3–6 are expressed as the mean values with their standard errors of six animals per group. The sample size was calculated taking into account a minimum test power of 0·80, at a level of significance of α = 0·05, and a maximum difference between the response of each variable of the control group with respect to the average of the differences with the experimental groups. The combined standard deviation was estimated from the data to generate the power curve. In all cases, these conditions were met with six^{(Reference Cohen38)}, which did not require further adjustment. The R software package pwr was used.

Table 3. Body and tissue weights of offspring*

(Mean values with their standard errors; six animals per group)

C, control diet; HF, high-fat diet; HF+CLA, HF diet supplemented with conjugated linoleic acid; BW, body weight; EWAT, epididymal white adipose tissue.

^a,b Mean values within a row with unlike superscript letters were significantly different (P < 0·05).

* C/C, HF/HF, HF+CLA/HF, HF+CLA/HF+CLA: in all cases, the denomination to the left of the dash corresponds to the mother feeding, and the denomination to the right of the dash corresponds to the offspring feeding. Statistical analyses between groups were established by one-way ANOVA, followed by Tukey’s post hoc test to determine the critical differences between the groups.

The statistical analyses displayed in Tables 3–6 to compare the treatments for each variable were performed using SPSS 17.0 (SPSS, Inc.) by one-way ANOVA. To determine the differences between the groups, post hoc Tukey’s test was used. When there was no homogeneity of variance, the Games–Howell non-parametric test was applied. For the significant differences between the c9,t11-CLA and t10,c12-CLA levels in serum, liver and EWAT (described in the Results section), Student’s t test was performed. For all statistical analyses, significant differences were considered at P < 0·05.