Obesity has reached epidemic levels in Western countries. It reduces life expectancy and is considered as a key factor in the development of the metabolic syndrome(Reference Haslam and James1). Obesity results from a sustained imbalance between energy intake and energy expenditure by physical activity and is characterised by the storage of excessive TAG in adipose tissue and in additional ectopic depots, such as in the liver and muscle(Reference Ravussin and Smith2). In understanding the genetic and environmental basis of obesity, animal models have proven to be useful by allowing manipulations technically or ethically not feasible in human subjects(Reference Speakman, Hambly and Mitchell3). Although monogenic(Reference Zhang, Proenca and Maffei4) and pharmacologically induced(Reference Brecher and Waxler5) models of obesity have provided insights into critical pathways, the polygenic nature of obesity calls for more realistic approaches to generate rodent-based obesity models.
In this context, high-fat diets have been applied to induce obesity in rodents since the early 1950s(Reference Fenton and Carr6) and have been shown to cause pathophysiological changes similar to those found in human obesity(Reference Buettner, Scholmerich and Bollheimer7). These changes are strain-dependent: some strains, such as the AKR/J mouse, are obesity-prone while others, such as the SWR/J mouse strain, are obesity-resistant(Reference West, Waguespack and McCollister8, Reference Svenson, Von Smith and Magnani9). Dietary fat influences body adiposity quantitatively(Reference West, Waguespack and McCollister8, Reference Boozer, Schoenbach and Atkinson10) but also qualitatively, depending on the fatty acid composition of the diet(Reference Boozer, Schoenbach and Atkinson10, Reference Buettner, Parhofer and Woenckhaus11). However, it is not yet clear whether fat per se has an obesogenic effect. Some studies have reported that animals fed an isoenergetic high-fat diet had a greater body-weight gain than animals fed a control or low-fat diet(Reference Wade12), but others have failed to show any major differences(Reference Woods, Seeley and Rushing13). In human subjects, total energy intake, and not dietary fat content alone, has been shown to determine body fat accumulation(Reference Willett14, Reference Willett and Leibel15). Therefore, it seems sensible to induce obesity in rodent models not only by increasing the amount of dietary fat but also by means of hyperphagia. Cafeteria diets have been introduced for this purpose: animals are offered a choice of several palatable food items of variable composition, appearance and texture in addition to a (most often) non-purified diet. These diets have been shown to induce obesity based on hyperphagia in both rats and mice(Reference Sclafani and Springer16, Reference Rothwell and Stock17). Furthermore, diets used in feeding trials can substantially vary with respect to their hardness and diets presenting a hard texture have been shown to cause reduced body-weight gains in rodents(Reference Ford18–Reference Nojima, Ikegami and Fujisawa21).
We decided to compare the effects of three different purified diets on body-weight development and physiological parameters in C57BL/6N mice when identical diets were either provided in powder form or as pellets. Mice were given a control (C) diet (4·2 % fat, w/w), a high-fat (HF) diet (34 % fat, w/w) or a Western-style (W) diet (17 % fat, w/w). The latter consisted of three differently flavoured diets, with exactly the same energy density and macronutrient composition, offered simultaneously to the mice. Based on the analysis of body fat compartments, gene expression in visceral and brown adipose tissue (BAT), plasma clinical chemistry and hormone/cytokine concentration, health status was assessed against an obese phenotype background.
Materials and methods
Animals and experimental protocols
Conventional 8-week-old male C57BL/6N mice were obtained from Charles River Laboratories and individually maintained in a controlled environment (12 h light–dark cycle, 22°C), and had free access to water and food. A first cohort of mice was fed a non-purified diet (catalogue no. V1534; Ssniff GmbH) for 2 weeks and thereafter divided into three groups (n 12) with a similar mean body weight. Mice were then fed for 12 weeks group-specific pellet diets (H for hard) (catalogue no. E15000-04, E15741-34 and S0372-E0222, -E0242 and -E0262, respectively; Ssniff GmbH). For the W group, mice had free access to three differently flavoured diets (peanut, banana and chocolate, respectively) given simultaneously and characterised by the same macronutrient composition and an increased content of both fat and sugars. The diet composition is provided in Table 1. Throughout the feeding trial, body weight, food and water consumption were recorded once per week. To correct food intake for loss of food, metal grids were placed below the food containers, allowing the collection of spillage. A second cohort of mice underwent the same dietary treatment but this time identical diets were given as powder (S for soft) in small cups (non-purified diet: catalogue no. V1530; C: E15000-00; HF: E15741-30; W: S0372-E0220, -E0240 and -E0260). As all mice in this second cohort developed the same body weights, but lower than those observed in the first cohort, we decided to extend the length of the feeding trial to 18 weeks so that their mean body weight matched that of the mice from the first cohort fed the HF diet. Moreover, to determine whether the difference in age played a significant role in the effects observed, a third cohort of mice underwent the same dietary treatment but this time only the C and HF diets, in powder and pellet forms, were given to the mice for 12 weeks.
GE, gross energy; ME, metabolisable energy calculated using Atwater factors.
* Nutrient composition is expressed as g/kg.
† For the Western-style group, mice had free access to the three differently flavoured diets given simultaneously.
Food intake test
After 8 weeks of feeding, mice from the third cohort were subjected to a food intake test: the amount of food consumed 30, 60 and 120 min after the diets were provided again following overnight deprivation was measured.
Sample collections
At the end of the feeding trial, mice in a non-fasting state were anaesthetised using isoflurane and blood was collected from the retro-orbital sinus. Mice were then killed by cervical dislocation. Liver, epididymal (EAT), retroperitoneal and perirenal, mesenteric (MAT), inguinal adipose tissue and interscapular BAT samples were collected, weighed with a precision balance and snap-frozen in liquid N2. In addition, at the end of the feeding trial, body size of mice from the third cohort was measured as the nasal–anus length. Their caecum was collected, weighed with a precision balance and snap-frozen in liquid N2. Moreover, during the last week of this feeding trial, faeces produced were collected, dried at 50°C to constant weight and ground. Faecal gross energy content was determined using an isoperibol bomb calorimeter (model number 6300; Parr Instrument GmbH), with benzoic acid used as a standard. All procedures applied throughout the present study were conducted according to the German guidelines for animal care and approved by the state ethics committee under the reference number 209.1/211-2531-41/03.
Chemical analysis
Serum alanine and aspartate aminotransferase activities and glucose concentration were determined using Piccolo® Lipid Panel Plus Reagent Discs and a Piccolo Blood Chemistry Analyzer (Hitado Diagnostic Systems).
Serum insulin, leptin and resistin concentrations were determined using a MILLIPLEX MAP Mouse Serum Adipokine Panel (Millipore GmbH) according to the manufacturer's instructions with an inter-assay CV ≤ 12 % and an intra-assay CV ≤ 5 %.
To determine hepatic TAG content, liver samples were ground in liquid N2 and dissolved in 0·9 % NaCl. TAG were extracted as follows: after centrifugation (Biofuge 15R; Heraeus Laboratory Centrifuges) for 10 min at 10 000 g, supernatants were incubated in alcoholic KOH (30 min, 70°C). Magnesium sulphate was added at a final concentration of 0·15 mol/l and, after centrifugation for 10 min at 10 000 g, TAG concentration was determined using a commercial enzymatic colorimetric kit following the manufacturer's instructions (Triglycerides liquicolormono; Human GmbH). Values were normalised to the protein content of the samples, as determined by the Bradford assay(Reference Bradford22).
RNA isolation
Total RNA from the EAT, MAT and BAT was isolated using QIAzol® lysis reagent (Qiagen GmbH) according to the manufacturer's instructions and further purified using the QIAGEN RNeasy Mini Kit spin columns (Qiagen GmbH). RNA concentration was determined on a NanoDrop ND-1000 UV–Vis spectrophotometer (Peqlab Biotechnologie GmbH) and its quality analysed with an Agilent Bioanalyzer (Agilent Technologies Deutschland GmbH) using Agilent RNA 6000 Nano Chips, according to the manufacturer's instructions.
Real-time quantitative PCR
For each sample, 10 ng of isolated total RNA were used for quantitative PCR using the QuantiTect® quantitative, real-time one-step RT-PCR kit (Qiagen GmbH) following the supplier's protocol. Gene sequences for primers were retrieved from the database Mouse Genome Informatics (http://www.informatics.jax.org/). Primers were designed with VectorNTI Advance 10 (Invitrogen) and tested for specificity using BLAST (Basic local alignment search tool) analysis and conventional PCR. The primers used are listed in Table S1 (available online). Quantitative PCR was performed using SYBR Green I dye and a Mastercycler ep realplex apparatus (Eppendorf AG). The following thermal cycling conditions were used: 30 min at 50°C (complementary DNA synthesis), 15 min at 95°C (RT enzyme inactivation) followed by forty cycles at 95°C for 15 s, 60°C for 30 s and 72°C for 30 s. The PCR was concluded with a melting curve analysis of the PCR product (1·75°C/min). Quantification cycle (Cq) values were retrieved from realplex 2.0 software (Eppendorf AG) and analysed following the efficiency-corrected method according to Pfaffl(Reference Pfaffl23), using β-actin as the invariant control to normalise the data. Primer efficiency was calculated with LinRegPCR(Reference Ruijter, Ramakers and Hoogaars24).
Statistical analysis
For all groups, data are expressed as means with their standard errors. Except for correlation analysis, the first two cohorts of mice were always analysed separately. The third cohort of mice was analysed using two-way ANOVA. Statistical analyses were performed using Prism 4 software (GraphPad Software). Before ANOVA, data were tested for equality of variances and transformed if needed. Tukey's test was used for pairwise comparisons. Differences in liver weight were tested using ANCOVA in SAS (version 9.2; SAS Institute, Inc.) with body weight as a covariate. Differences in weight gain over the feeding period were tested using the MIXED procedure in SAS with time as a repeated factor(Reference Littell, Henry and Ammerman25). The variables studied were subjected to seven covariance structures: unstructured covariance; compound symmetry; autoregressive order 1; autoregressive moving average order 1; heterogeneous compound symmetry; heterogeneous autoregressive order 1; Toeplitz. The goodness of fit of the models was compared using the Bayesian information criterion. Tukey's test was used as a post hoc test. For all tests, the bilateral α risk was α = 0·05.
Results
Mice fed the two high-energy pellet diets developed obesity
Feeding mice with the HF (HF-H) and the W (W-H) diets resulted in a significant increase in mean body weight (P< 0·001), whereas mice fed the C diet (C-H) remained lean (Fig. 1(A)). Final body weight, cumulative food, energy and water intake, as well as the feed efficiency ratio and food spillage are shown in Table 2. Mice fed the different diets presented statistically different final body weights, with mice given the HF diet being the most obese (C-H: 29·7 (sem 0·4) g; HF-H: 43·8 (sem 1·1) g; W-H: 39·7 (sem 1·3) g; P< 0·001). These results are in agreement with the measured energy intake since the higher the energy intake was, the heavier the mice were. Interestingly, the feed efficiency, defined as the amount of energy ingested for a weight gain of 1 g, was approximately 4-fold higher in C-H mice compared with HF-H and W-H mice.
ND, not detectable.
a,b,cMean values with unlike superscript letters were significantly different for a given variable (P< 0·05).
* Body weight, food and water consumption were recorded once per week.
Mice fed the powder diets all developed obesity and ingested similar levels of energy
Over the feeding trial, mice from all three groups showed a marked increase in body weight with no significant difference in weight gain over time (P= 0·889) as shown in Fig. 1(B). At the end of the feeding trial, mice did also not present statistically different final body weights (C-S: 45·1 (sem 1·0) g; HF-S: 45·1 (sem 1·3) g; W-S: 44·8 (sem 1·3) g; P= 0·986) and body weight was similar to that of mice fed the pellet HF (HF-H) diet. Mice fed the C-S diet had a higher food intake (3·8 (sem 0·1) g/d) compared with mice fed the W-S (3·1 (sem 0·1) g/d) and HF-S diets (2·6 (sem 0·0) g/d) (P< 0·001; Table 2). However, when energy intake rates were calculated by taking the different energy densities of the diets into account (Table 1), mice in all three dietary groups presented very similar energy intake (P= 0·111) and similar feed efficiencies (P= 0·944).
Mice fed the pellet control diet displayed increased caecal weight
Mice from the third cohort fed either the C or HF diet in powder and pellet form for 12 weeks showed the same features as described previously, with a lean phenotype when fed the C-H diet and an obese phenotype when fed the C-S, HF-S and HF-H diets (Fig. 1(A) and (B)). In this trial, we also determined whether any changes in overall body length could be observed; however, we did not detect any significant difference (P= 0·135; two-way ANOVA), as shown in Table 2. Therefore, body-weight differences originated mainly from different body fat mass. A striking finding, however, was the large increase in caecal weight found only in mice fed the C-H diet. Relative to body weight, caecal weight in these animals was increased 1·8-fold, accounting for 0·6 % of body weight, compared with mice fed the C-S, HF-S and HF-H diets with identical body weight (P< 0·001; two-way ANOVA; Table 3).
IHTG, intrahepatic TAG; BAT, brown adipose tissue.
a,b,cMean values with unlike superscript letters were significantly different for a given variable (P< 0·05).
* Organ weight is expressed as a percentage of body weight in each case.
† IHTG is expressed as mg TAG/g protein.
Mice fed the control diet as powder or pellets displayed a similar food intake following food deprivation
As shown in Table 4, when mice were presented their respective diet following overnight food deprivation, we did not observe any statistical difference in food intake after 30, 60 or 120 min between mice fed the C-H and C-S diets. Only mice given the HF-H diet presented an increased food intake after 60 and 120 min compared with mice fed the C diets.
a,bMean values with unlike superscript letters were significantly different for a given variable (P< 0·05).
* Food intake is expressed as g of food consumed when diets were presented for different times following overnight deprivation.
Blood chemistry and hormone/cytokine profiles
Mice fed the pellet diets displayed marked differences in blood chemistry and hormone/cytokine profiles. Obese mice from the HF-H and W-H groups displayed significantly increased concentrations of glucose, insulin and resistin when compared with C-H mice (Table 5). On the contrary, mice fed the different powder diets did not exhibit any significant differences in serum glucose, insulin and leptin concentrations; however, serum resistin concentration was significantly increased in mice fed the HF-S diet compared with C-S and W-S mice.
ALT, alanine aminotransferase; AST, aspartate aminotransferase.
a,b,cMean values with unlike superscript letters were significantly different for a given variable (P< 0·05).
In mice fed the pellet diets, serum alanine aminotransferase activities were increased significantly in the W diet group, while in mice given the HF diet, the increase did not reach significance. For serum aspartate aminotransferase activities, we observed a trend towards an increase in mice fed the energy-rich diets (P= 0·131). In mice fed the powder diets, serum alanine aminotransferase and aspartate aminotransferase activities were marginally increased (P= 0·051 and 0·096, respectively) in mice fed the W diet when compared with those receiving the C or HF diet.
All diets – except the control pellet diet – caused increased fat depots, liver weight and intrahepatic TAG concentrations
Organ weight, normalised to body weight, and intrahepatic TAG (IHTG) content are presented in Table 3. Mice fed the W diets presented significantly increased liver weight compared with mice fed the C or HF diet. IHTG content increased 3- to 4-fold in the HF and W groups given the pellet diets (P< 0·001). Feeding a W or HF diet in powder form also induced an increase in IHTG compared with the control mice (P= 0·029), although mice given the powder C diet already displayed elevated concentrations. When liver weight was plotted against the final body weight in individual mice, in all cases – except for control mice fed the pellet C (C-H) diet that also showed no increase in body weight – a significant correlation was observed (Fig. 2). Moreover, the projected intercepts on the x-axis between 31 and 32 g body weight and the lack of an increase in liver weight in mice that stayed below 32 g body weight suggest that this body weight is the threshold from where on any weight gain, caused by any diet, proportionally increases liver weight.
For the weight of the four depots of white adipose tissue (WAT) collected from mice fed the powder diets, no significant difference was observed, with the exception of the EAT depot in the HF-S group (P= 0·025). However, in mice given the HF and W diets provided as pellets, all fat depots increased significantly in relative weight when compared with the C group, which did not display a major weight gain. When compared with the powder diet groups, essentially similar fat depot sizes were observed, with the highest relative mass for the EAT depot, representing 5–6 % of total body mass (Table 3). The interscapular BAT was collected as well and similarly revealed a significant expansion with increased body mass. Whereas BAT mass accounted for 0·5–0·6 % of final body mass in all mice that became obese, mice fed the powder C and W diets showed a further increase in interscapular BAT mass accounting for 0·75 % of body mass (P= 0·005), as shown in Table 3.
Gene expression analysis in adipose tissue
We determined the mRNA expression levels of genes known to be associated with obesity in WAT and BAT (Table 6). In mice receiving the HF and W diets as pellets, an expected large increase in leptin mRNA expression levels was observed in the EAT and MAT samples, compared with mice receiving the pellet C diet and remaining lean. In mice fed the same diets as powder, the differences were not significant, which is in agreement with the observed similar fat depot masses and body weights in these three dietary groups. In all HF and W diet groups, regardless of whether given in pellet or powder form, a significant decline in 11β-hydroxysteroid dehydrogenase type 1 (11-β-hsd-1) mRNA expression levels was observed in both EAT and MAT depots. This suggests that any expansion of fat depots leads to a reduced mRNA expression level of this gene. In the MAT fat, the resistin mRNA expression level significantly increased in obese mice fed the pellet diets, whereas its expression level in EAT was significantly decreased in mice given the HF diet as pellets. In BAT, we observed a decreased mRNA expression level of the uncoupling protein 1 (Ucp-1) in all mice fed the HF and W diets, regardless of whether given in pellet or powder form. The uncoupling protein 3 (Ucp-3) mRNA level was reduced in obese mice fed the pellet diets when compared with those on the C diet (C-H) without significant weight gain. The mRNA expression level of the adipose TAG lipase (Atgl) was decreased in obese mice fed the pellet diets, whereas in mice given the powder diets, those receiving the W diet displayed an increase in Atgl mRNA expression level, despite almost identical body weight and relative BAT mass.
11-β-hsd-1, 11β-hydroxysteroid dehydrogenase type 1; Ucp, uncoupling protein; Atgl, adipose TAG lipase.
a,bMean values with unlike superscript letters were significantly different for a given variable (α as superscript for control diet-fed mice, not shown).
* Data are expressed in fold changes compared with control diet-fed mice.
Discussion
In the present study, we compared the effects of diets with different macronutrient compositions, provided either as pellets or powder to mice, on the development of obesity and some associated health status markers. In addition to a standard high-starch C diet and a HF diet, we used a W diet with three different flavours. In contrast to the original cafeteria diet introduced by Sclafani & Springer(Reference Sclafani and Springer16), comprising human food items added to a basal diet, we employed defined diets of identical macronutrient composition with 36 % of energy coming from fat and 47 % of energy from carbohydrates. This enabled us to precisely measure food and energy intake, which can be difficult with the original cafeteria diet due to its complexity(Reference Moore26).
The most striking finding of the present study was that all mice, except those given the C pellet diet, gained weight with a similar slope and displayed final body weights of 40–45 g. Interestingly, mice fed the powder diets displayed almost identical daily energy intake rates. The estimated feed efficiency was consequently not different and amounted to approximately 430 kJ/g, independently of the diet. This was not the case for mice fed the pellet diets. Although, here, mice fed the HF diet had a significantly reduced food intake, energy intake in both HF and W diets was significantly higher than that in the C group and feed efficiency was markedly lower (P< 0·001), as shown in Table 2. Thus, in powder-fed mice, the hyperphagia frequently associated with the consumption of energy-dense diets in rodents(Reference Ramirez and Friedman27) as well as in human subjects(Reference Rolls28) could not be observed here. All groups presented a similar energy intake and a similar weight gain. Although there is a controversy as to whether flavour variety in diets affects food intake(Reference Treit, Spetch and Deutsch29, Reference Naim, Brand and Kare30), we did not observe major effects except that food intake, when compared with mice fed the HF diet, was higher in mice fed the W diet in both pellet and powder forms.
The different results observed between the pellet and powder variants of the diets are of course striking and point at an effect of food texture on body-weight development. The impact of the hardness of the diet has already been addressed, and it has been shown that mice fed hard pellets had a lower body weight and improved blood glucose concentrations compared with mice fed soft or powder diets(Reference Ford18, Reference Koopman, Scholten and Roeleveld19, Reference Nojima, Ikegami and Fujisawa21). Rats have been shown to prefer soft pellets rather than the diet they are usually fed(Reference Sako, Okamoto and Mori31). Long-term feeding of soft pellets induced a larger increase in body weight and body fat content and lower postprandial thermogenesis despite similar food intake rates when compared with pellet-fed animals(Reference Oka, Sakuarae and Fujise20). Rothwell et al. (Reference Rothwell, Stock and Warwick32) observed that when rats were fed a low-fat or a HF diet given in powder form and greatly differing in energy density, all mice developed the same body weight with similar energy intake rates. In human subjects, diet hardness was found to be a significant determinant of waist circumference, independently of food intake, although no effect was observed on BMI(Reference Murakami, Sasaki and Takahashi33). Here, we show for the first time that a pellet-based high-carbohydrate/starch diet fails to trigger obesity, whereas the same diet given in powder form produces an obese phenotype similar to a HF or W diet. While all mice receiving the high-carbohydrate C diets ingested very similar amounts of food and lost similar quantities of energy through faeces, they displayed quite different body-weight gains. The most striking difference, however, was that feed efficiency was 4-fold higher in the powder diet compared with the pellet variant.
The pellets, as provided here for both the HF and W diets, are softer in texture than those of the C diet with high starch content (Table 1). Thus, those very hard pellets might elicit a higher postprandial thermogenic response(Reference LeBlanc, Cabanac and Samson34, Reference Garrel and de Jonge35), and mice consuming them may in addition need to utilise more energy for chewing (although we did not observe any difference in food intake over short periods of time following overnight food deprivation between the groups fed the powder or the pellet C diet, possibly due to adaptation of mice to their respective diet), for efficient handling (i.e. motility) in the stomach and intestine, and for digestion. That energy extraction in the small intestine may be limited from the high-starch pellet diet is suggested by a major increase in caecal mass found in these mice compared with all other animals. When non-digested starch reaches the caecum, microbiota mass increases and increased fermentation delivers SCFA that can be absorbed by the host. Yet, the energy delivered to the host is much less, accounting for about 7·2 kJ/g carbohydrate compared with 17·2 kJ/g when absorbed as glucose(Reference Livesey36).
Since all mice given the powder diets had the same final body weight and obesity state, as judged by the expansion of fat depots, we could assess the specific effects of diet composition on selected metabolic parameters that characterise an obese state. The organ that was most affected by changes in dietary composition was the liver. Liver weight and IHTG concentrations (in mg/g protein) increased proportionally to total body mass and independently of the diet after a ‘threshold’ body weight of about 32 g was reached. Increased concentrations of IHTG have been associated with hepatic and peripheral insulin resistance(Reference Korenblat, Fabbrini and Mohammed37) and are considered to represent a major determinant of the metabolic syndrome(Reference Marchesini, Bugianesi and Forlani38). The W diet, regardless of whether presented as pellet or powder, increased liver weight more than the HF diet, suggesting that a higher dietary sucrose/dextrin intake may be more deleterious for the liver than a higher fat intake. Recently, Fabbrini et al. (Reference Fabbrini, Magkos and Mohammed39) demonstrated in human subjects that the IHTG content, but not visceral adipose tissue mass, was a marker of obesity-related metabolic dysfunctions. We observed in all obese mice – although not feed-deprived – markedly increased plasma glucose and insulin concentrations, suggesting also an impaired glucose tolerance. Plasma TAG did not differ among any group, whereas cholesterol and HDL concentrations were higher in obese mice.
Since adipose tissue plays a central role in energy homeostasis and the development of insulin resistance, notably through adipokines(Reference Havel40), we measured the concentration of selected adipokines in serum and characterised changes in the mRNA expression levels of selected target genes involved in adipokine secretion or adipose tissue metabolism. Gene expression was studied in two visceral WAT depots and the interscapular BAT. Whereas MAT fat in particular is suspected to have a role in the aetiology of metabolic diseases(Reference Yang, Chen and Clements41), the BAT has been shown to play a significant role in energy balance via non-shivering thermogenesis(Reference Cannon and Nedergaard42).
Serum leptin concentration was significantly elevated in all obese mice, and there was no detectable effect of the diet. Since leptin concentration correlates with body fat mass and adipocyte size(Reference Friedman and Halaas43), this was not surprising, based on the increase in body fat mass in all mice, except for the C-H diet. Similarly, the mRNA expression level of leptin was higher in obese mice in EAT as well as MAT depots with no effect of the diet. Resistin showed significantly elevated mRNA expression levels in MAT depots when compared with mice given a C pellet diet, and displayed a marginally significant increase when compared with mice given a C powder diet. Resistin, at least in rodents, has been shown to counteract insulin activity(Reference Steppan, Bailey and Bhat44), and therefore the finding that adipose tissue depots increase resistin expression may result from an adaptation to the elevated serum insulin, which could additionally enhance insulin resistance, in particular in mice fed pellets. Interestingly, in mice fed the powder diets, a HF diet induced a significant increase in circulating resistin concentration, although mice displayed similar insulin concentrations. The mRNA expression level of 11-β-hsd-1 decreased significantly in all obese mice and more so in mice fed the HF and W powder diets. This suggests that any expansion of fat depots leads to a reduced mRNA expression level of this enzyme. 11-β-hsd-1 is involved in glucocorticoid synthesis in adipose tissue and has been implicated in the pathology of the metabolic syndrome(Reference Morton, Ramage and Seckl45). The present results are in accordance with those of Morton et al. (Reference Morton, Ramage and Seckl45) who proposed that the decrease in 11-β-hsd-1 expression might also represent a protective mechanism during chronic high fat feeding. Taken together, changes in gene expression observed in the different fat depots are mainly a measure of fat mass expansion and only subtle effects of diet composition are detectable.
In summary, we observed a very interesting phenomenon when inducing obesity in C57BL/6N mice with two types of high-energy diets of identical macronutrient composition, provided either as pellet or in powder form. Regardless of the source of energy – whether based on a high-fat diet, or a W diet with lower fat but higher sucrose/dextrin content, or a starch-based C diet – all mice, when fed the powder diets, became obese with roughly the same weight gain. Although food intake rates were different, based on almost identical daily energy intake rates and identical feed efficiency values, the powder-fed mice displayed essentially the same proportional expansion of WAT depots and, as a consequence, possessed similar serum leptin concentrations. The only difference found between the diets was an increase in liver weight (absolute and relative to body mass) and IHTG concentrations in mice fed the W diet, which in this respect seems to be more deleterious to the liver than a pure HF diet providing 60 % energy as fat. In mice fed the pellet diets, IHTG concentration was similarly elevated in the HF and W groups, although the latter displayed decreased body weight and WAT depot expansion compared with mice fed the HF diet. Most interestingly, both liver weight and IHTG concentrations increased proportionally to body mass in all mice after a threshold level of approximately 32 g body weight had been reached. Finally, we would like to critically ask whether a pellet-based, high-carbohydrate/starch diet is a proper C diet when used for comparison with HF diets. Feeding diets with >45 % energy as fat is meanwhile accepted as a ‘gold standard’ to induce obesity in normal or transgenic mice models. The pellets of this C diet have an exceptionally hard texture and are therefore difficult to chew, to swallow and may need huge amounts of energy for handling in the gastrointestinal tract. They may also cause a loss of energy by the delivery of larger amounts of undigested starch to the microbiota and may after all produce an artificially ‘lean phenotype’.
Supplementary material
To view supplementary material for this article, please visit http://dx.doi.org/10.1017/S0007114512003340
Acknowledgements
We thank Adelmar Stamfort for his help in statistical analysis, and Elmar Jocham and Johanna Welzhofer for their technical assistance. C. D. was funded by the European Union FP6 project Nutrient Sensing in Satiety Control and Obesity (NuSISCO, grant no. MEST-CT-2005-020494). The responsibilities of the authors are as follows: C. D., T. L., B. L. B. and H. D. designed the research; C. D., T. L., R. S. and N. R. conducted the research; C. D. and T. L. analysed the data; C. D., T. L. and H. D. wrote the paper; H. D., M. K. and B. L. B. had primary responsibility for the final content. All authors read and approved the final manuscript. The authors declare that they have no conflict of interest.