Hostname: page-component-cd9895bd7-p9bg8 Total loading time: 0 Render date: 2024-12-23T00:00:58.691Z Has data issue: false hasContentIssue false

The effects of a cafeteria diet on insulin production and clearance in rats

Published online by Cambridge University Press:  12 December 2011

Anna Castell-Auví
Affiliation:
Nutrigenomics Research Group, Departament de Bioquímica i Biotecnologia, Universitat Rovira i Virgili, c/Marcel·lí Domingo s/n, 43007Tarragona, Spain
Lídia Cedó
Affiliation:
Nutrigenomics Research Group, Departament de Bioquímica i Biotecnologia, Universitat Rovira i Virgili, c/Marcel·lí Domingo s/n, 43007Tarragona, Spain
Victor Pallarès
Affiliation:
Nutrigenomics Research Group, Departament de Bioquímica i Biotecnologia, Universitat Rovira i Virgili, c/Marcel·lí Domingo s/n, 43007Tarragona, Spain
Mayte Blay
Affiliation:
Nutrigenomics Research Group, Departament de Bioquímica i Biotecnologia, Universitat Rovira i Virgili, c/Marcel·lí Domingo s/n, 43007Tarragona, Spain
Anna Ardévol
Affiliation:
Nutrigenomics Research Group, Departament de Bioquímica i Biotecnologia, Universitat Rovira i Virgili, c/Marcel·lí Domingo s/n, 43007Tarragona, Spain
Montserrat Pinent*
Affiliation:
Nutrigenomics Research Group, Departament de Bioquímica i Biotecnologia, Universitat Rovira i Virgili, c/Marcel·lí Domingo s/n, 43007Tarragona, Spain
*
*Corresponding author: M. Pinent, fax +34 977 558232, email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

The aim of the present study was to determine the effects of a cafeteria diet on the function and apoptosis of the pancreas, and the activity and expression of the insulin-degrading enzyme (IDE). Female Wistar rats were fed either with a cafeteria diet or a control diet for 17 weeks, and blood and tissues were then collected for analysis. The cafeteria diet-treated rats had higher plasma insulin and C-peptide levels (P < 0·05), showing increased insulin secretion by the pancreas. Insulin protein and gene expression levels were higher in the pancreas of obese rats, as was its transcriptional controller, pancreatic duodenal homeobox 1 (P < 0·05). Feeding a cafeteria diet down-regulated the gene expression of the anti-apoptotic marker B-cell/lymphoma 2 (BCL2), and up-regulated the protein levels of BCL2-associated X protein, a pro-apoptotic marker (P < 0·05). The cafeteria diet caused lipid accumulation in the pancreas and modified the expression of key genes that control lipid metabolism. To assay whether insulin clearance was also modified, we checked the activity of the IDE, one of the enzymes responsible for insulin clearance. We found increased liver IDE activity (P < 0·05) in the cafeteria diet-fed animals, which could, in part, be due to an up-regulation of its gene expression. Conversely, IDE gene expression was unmodified in the kidney and adipose tissue; although when the adipose tissue weight was considered, the insulin clearance potential was higher in the cafeteria diet-treated rats. In conclusion, treatment with a cafeteria diet for 17 weeks in rats mimicked a pre-diabetic state, with ectopic lipid accumulation in the pancreas, and increased the IDE-mediated insulin clearance capability.

Type
Full Papers
Copyright
Copyright © The Authors 2011

The prevalence of overweight and obesity is quickly increasing to epidemic proportions around the world(Reference Abelson and Kennedy1). Obesity is associated with a higher incidence of a number of diseases, including CVD, cancer(Reference Hurt, Kulisek and Buchanan2) and diabetes(Reference Field, Coakley and Must3). There are several causes of obesity, some of which are genetically defined, but some others are related to environmental factors. To study obesity, several animal models have been used, including both genetic and diet-induced obesity models. Among them, the cafeteria diet has been used as a robust model because it is a good reproduction of the diet in Western society(Reference Sampey, Vanhoose and Winfield4).

The cafeteria diet model has been described in terms of the effects of the diet on increasing body weight and modulating adipogenesis and inflammation(Reference Sampey, Vanhoose and Winfield4Reference Campion, Milagro and Fernandez6). The diet consists of feeding animals with a substantial amount of salt, sugar and fat; thus, mimicking the diet consumed by Western cultures(Reference Sampey, Vanhoose and Winfield4). The diet promotes voluntary hyperphagia that results in rapid weight gain, increases fat pad mass and leads to a pre-diabetic state(Reference Sampey, Vanhoose and Winfield4, Reference Rolls, Rowe and Turner7). Different studies have shown that the cafeteria diet increases plasma insulin levels and alters glucose metabolism(Reference Sampey, Vanhoose and Winfield4, Reference Sishi, Loos and Ellis8Reference Vanzela, Ribeiro and de Oliveira11). Despite the key role of the pancreas in glucose metabolism, scarce work has been performed to study the chronic effects of this type of high-fat diet on this organ.

Insulin resistance induced by the diet might ultimately lead to the impairment of β-cell function and reduced β-cell mass, in part due to an increase in the apoptosis of these cells, and thus might lead to diabetes(Reference DeFronzo12). The impairment of β-cell function partly results from the accumulation of TAG in the pancreas, as in other non-adipose tissues, when a positive net energy balance occurs(Reference Lewis, Carpentier and Adeli13). Studies in human islets have confirmed that insulin secretion at high glucose concentrations is impaired in a time-dependent fashion by exposure to NEFA, and NEFA also produce a decrease in insulin biosynthesis(Reference Zhou and Grill14). Yet, few in vivo studies concerning the effects of the cafeteria diet on the pancreas are available in the literature. In female rats, feeding the cafeteria diet for 14 weeks has been reported to diminish the glucose (and other depolarising agent)-stimulated insulin secretion of isolated islets, probably through a defect in the Ca2+ mobilisation by these islets(Reference Vanzela, Ribeiro and de Oliveira11). Additionally, in male rats, treatment with the cafeteria diet for 15 weeks has been shown to induce changes in pancreatic islet morphology(Reference Sampey, Vanhoose and Winfield4). More studies concerning the effects of this diet in the pancreas would be beneficial for the description of this widely used obesity model, which allows the analysis of the environmental effects of the diet, free from possible genetic effects.

Plasma insulin levels are highly dependent on pancreas functionality and the number of islet β-cells, but insulin clearance is also of importance in determining the levels in plasma. In vivo, a major role in the clearance and degradation of insulin is played by the metalloproteinase insulin-degrading enzyme (IDE)(Reference Duckworth, Bennett and Hamel15), and the IDE has been identified as a candidate gene for diabetes susceptibility in the Goto–Kakizaki rat, a genetic model of non-insulin-dependent diabetes(Reference Fakhrai-Rad, Nikoshkov and Kamel16). These animals exhibit elevated blood glucose and insulin levels(Reference Fakhrai-Rad, Nikoshkov and Kamel16) due to a mutated form of the IDE, which provokes reduced insulin degradation and causes symptoms typical of the human type 2 diabetes mellitus (DM2) syndrome(Reference Farris, Mansourian and Leissring17). The evidence for a putative influence of the IDE on the pathogenesis of DM2 has been confirmed with human genetic studies that have linked polymorphisms in the IDE gene to an increased risk for insulin resistance and DM2(Reference Nordman, Ostenson and Efendic18Reference Karamohamed, Demissie and Volcjak20). Furthermore, genome-wide association studies in human subjects have revealed that the IDE region of chromosome 10q contains a variant that confers DM2 risk(Reference Ragvin, Moro and Fredman21). Lastly, IDE knockout mice are both glucose-intolerant and hyperinsulinaemic, supporting the concept that the IDE is important in the maintenance of normal blood glucose and insulin levels(Reference Farris, Mansourian and Chang22).

Despite the data provided above, the specific effects of the cafeteria diet on insulin production and clearance remain unclear. Given the high prevalence of diet-induced obesity and the importance of this model of study, we aimed to investigate the effects of the cafeteria diet by analysing the pancreas functionality and apoptosis. Moreover, we also evaluated the effects of this diet on the activity and expression of the IDE, which, to our knowledge, have not been studied previously.

Materials and methods

Animal experimental procedures

Wistar female rats (Charles River Laboratories), weighing between 160 and 175 g, were housed in animal quarters at 22°C with a 12 h light–12 h dark cycle, and after 1 week in quarantine, the animals were treated as described previously(Reference Montagut, Blade and Blay23). Briefly, twelve rats were divided in two groups (n 6): a control group fed with a standard diet and a group fed with a cafeteria diet (Table 1) and water in addition to the standard diet. The animals were fed ad libitum, and the food was renewed daily. At the end of the treatment (17 weeks), the food was removed and 3 h later, the animals were killed by beheading. Blood was collected using heparin, and animal tissues were excised, frozen immediately in liquid N2 and stored at − 80°C until analysis. All procedures were approved by the Experimental Animals Ethics Committee of the Rovira i Virgili University.

Table 1 Cafeteria diet composition

Intraperitoneal glucose tolerance test and plasma parameters

Intraperitoneal glucose tolerance tests were carried out (2 g glucose/kg body weight) after overnight fasting at week 15 and also 3 d before killing at week 17. Glucose was measured with a glucometer after blood samples had been collected by tail bleeding (Menarini).

Insulin and C-peptide plasma levels at killing were assayed using ELISA methodology (Mercodia) following the manufacturer's instructions. Glucose plasma levels were determined using an enzymatic colorimetric kit (QCA).

Homeostatic model assessment for insulin resistance (HOMA-IR) and the HOMA-β index were calculated using the fasting values of glucose and insulin with the following formulas:

\begin{eqnarray} HOMA\hyphen IR = \frac {insulin\,(\mu U/ml)\times glucose\,(mm)}{22\cdot 5}, \end{eqnarray}
\begin{eqnarray} HOMA\hyphen \beta = \frac {20\times insulin\,(\mu U/ml)}{glucose\,(mm) - 3\cdot 5}. \end{eqnarray}

Insulin content in the pancreas

For insulin extraction, the pancreas was homogenised with an acid–ethanol solution (75 % ethanol, 1·0 m-glacial acetic acid and 0·1 m-HCl), and the extracts were kept overnight at 4°C and then centrifuged. The insulin levels from the extracts were measured using ELISA methodology (Mercodia).

TAG content in the pancreas

TAG from the pancreas were extracted using PBS containing 0·1 % Triton X-100 (Sigma-Aldrich), and the levels of TAG were determined using an enzymatic colorimetric kit (QCA). The protein content of each sample was measured using the Bradford method(Reference Bradford24) and was used to normalise the TAG values.

Insulin-degrading enzyme activity assay

Liver extracts were prepared by homogenising the tissue in Cytobuster Protein Extraction Reagent (Novagen) according to the manufacturer's recommended protocol. IDE activity was assessed with the InnoZyme Insulysin/IDE Immunocapture Activity Assay Kit (Calbiochem/Merck) and is expressed as relative fluorescent units.

Western blot

Protein was extracted from the whole frozen pancreas using RIPA (radio-immunoprecipitation assay) lysis buffer (15 mm-Tris–HCl, 165 mm-NaCl, 0·5 % Na-deoxycholate, 1 % Triton X-100 and 0·1 % SDS), with a protease inhibitor cocktail (1:1000; Sigma-Aldrich) and 1 mm-PMSF (phenylmethanesulfonyl fluoride solution). Total protein levels of the lysate were determined using the Bradford method(Reference Bradford24). After boiling for 5 min, 100 μg of protein were loaded and electrophoresed through a 4–15 % SDS-polyacrylamide gel. The samples were then transferred to a polyvinylidene fluoride membrane (Bio-Rad Laboratories) and blocked at room temperature for 1 h using 5 % (w/v) non-fat milk in TTBS buffer (Tris-buffered saline (TBS) plus 0·5 % (v/v) Tween-20). The membranes were incubated overnight at 4°C with rabbit polyclonal B-cell/lymphoma 2 (BCL2)-associated X protein (BAX) primary antibody (Cell Signaling Technology) at a 1:1000 dilution in blocking solution or rabbit anti-β-actin antibody (diluted 1:750; Sigma-Aldrich). After washing with TTBS, the blots were incubated with peroxidase-conjugated monoclonal anti-rabbit secondary antibody (Sigma-Aldrich) at a 1:10 000 dilution at room temperature for 2 h. The blots were then washed thoroughly in TTBS, followed by TBS. Immunoreactive proteins were visualised with the ECL Plus Western Blotting Detection System (GE Healthcare) using a FluorChem system (Alpha Innotech) and software version 6.0.2. Densitometric analysis of the immunoblots was performed using ImageJ 1.44p software (National Institutes of Health); all of the proteins were quantified relative to the loading control.

Quantitative RT-PCR

Total RNA from the pancreas, liver and mesenteric adipose tissue was extracted using the TRIzol reagent, following the manufacturer's instructions. Complementary DNA was generated using the High-Capacity complementary DNA Reverse Transcription Kit (Applied Biosystems), and it was subjected to quantitative RT-PCR amplification using the Taqman Master Mix (Applied Biosystems). Specific Taqman probes (Applied Biosystems) were used for different genes, as follows: Rn01774648-g1 for insulin; Rn00565839-m1 for IDE; Rn00755591_m1 for pancreatic duodenal homeobox 1 (PDX1); Rn01754856-m1 for mitochondrial uncoupling protein 2 (UCP2); Rn00569117_m1 for fatty acid synthase (FASn); Rn00580702_m1 for carnitine palmitoyltransferase-1a (CPT1a); Rn99999125_m1 for BCL2; Rn01480160_g1 for BAX. β-Actin was used as the reference gene (Rn00667869-m1). The reactions were performed using a quantitative RT-PCR 7300 System (Applied Biosystems) according to the manufacturer's instructions. The relative mRNA expression levels were calculated using the ΔΔC t method.

Calculations and statistical analysis

The results are expressed as means with their standard errors, and the effects were assessed by Student's t test. All of the calculations were performed using SPSS software (SPSS, Inc.).

Results

Cafeteria diet increases insulin production in the pancreas

We first examined the effects of the cafeteria diet on pancreatic insulin production after 17 weeks of the treatment. The cafeteria diet-fed rats showed significantly higher plasma insulin (cafeteria: 0·94 (sem 0·2) nmv. control: 0·18 (sem 0·0) nm) and C-peptide levels (cafeteria: 2·54 (sem 0·4) nmv. control: 0·77 (sem 0·0) nm), demonstrating an increase in insulin secretion by the pancreas. After the intraperitoneal glucose tolerance tests at 15 and 17 weeks of the treatment, HOMA-IR and the HOMA-β index were calculated (Table 2). After 15 weeks of cafeteria-diet feeding, the HOMA-IR index indicated that the animals had peripheral insulin resistance, as we mentioned above, and the HOMA-IR index was even higher after two additional weeks of the treatment. In contrast, the values of the HOMA-β index at 15 weeks indicated that there were no significant differences in pancreas functionality, despite peripheral insulin resistance. However, after two more weeks of the treatment (at week 17), the HOMA-β values were significantly increased in the cafeteria-diet treatment group, suggesting that pancreas functionality in terms of the response to glucose was higher than that in the controls to counteract peripheral insulin resistance. We also determined insulin content in the pancreas, which showed that there was significantly more insulin accumulation in the pancreata of the cafeteria-fed rats (cafeteria: 69·90 (sem 17·2) ng/mg tissue v. control: 8·76 (sem 0·9) ng/mg tissue). The increased insulin secretion and pancreatic insulin content agree with the observed effect on insulin gene expression, which was significantly higher in the obese animals (Table 3). In addition, the cafeteria diet increased the expression of PDX1, an important regulator of insulin transcription (Table 3).

Table 2 Effects of the cafeteria diet on homeostatic model assessment for insulin resistance (HOMA-IR) and the homeostatic model assessment-β (HOMA-β) index

(Mean values with their standard errors)

* Mean values were significantly different between the treatments (P ≤ 0·05).

Table 3 Gene expression in the pancreas

(Mean values with their standard errors)

PDX1, pancreatic duodenal homeobox 1; UCP2, uncoupling protein 2; BCL2, B-cell/lymphoma 2; BAX, BCL2-associated X protein; CPT1a, carnitine palmitoyltransferase-1a; FASn, fatty acid synthase.

Mean values were significantly different between the treatments: *P ≤ 0·05, **P ≤ 0·1.

Cafeteria diet activates apoptosis biomarkers

To examine the effects of the cafeteria diet on apoptosis in the pancreas, we analysed the anti-apoptotic marker BCL2 and the pro-apoptotic marker BAX. The cafeteria-fed rats showed a decrease in the expression of BCL2 (Table 3). Concerning BAX expression, although the mRNA levels of this gene were not altered (Table 3), we did observe an increase in the protein levels of BAX in the cafeteria diet-fed group (Fig. 1).

Fig. 1 Effects of the cafeteria diet on B-cell/lymphoma 2-associated X protein (BAX) protein levels in the pancreas. BAX protein levels were quantified by Western blot analysis. A representative Western blot is provided. Protein expression was quantified relative to the β-actin loading control using ImageJ 1.44p software (National Institutes of Health). Values are means of six animals, with their standard errors represented by vertical bars. * Mean values were significantly different from the control group (P < 0·05).

Cafeteria diet increases pancreatic TAG content

Feeding a cafeteria diet leads to a higher amount of TAG and NEFA in the plasma. Under physiological conditions, most TAG are stored in adipocytes, but in animals with obesity, increased stores of TAG are detectable in other tissues. To determine whether the cafeteria diet treatment led to an accumulation of lipids in other tissues, we examined the TAG content in the pancreas, and found that it was four times higher in the obese animals than in the control group (Fig. 2). To better understand lipid metabolism in the pancreas, we also analysed the expression of key regulatory genes. We selected the FASn gene, the key enzyme of de novo fatty acid synthesis(Reference Smith25), and the CPT1a gene, the key controller of NEFA oxidation(Reference Del Bas, Ricketts and Baiges26). The cafeteria-fed rats showed a slight increase in CPT1a mRNA levels (Table 3). In contrast, the cafeteria diet tended to reduce the mRNA levels of FASn (Table 3).

Fig. 2 Effects of the cafeteria diet on pancreatic TAG content. After 17 weeks of the cafeteria diet, the animals were killed, and the pancreas was obtained. The TAG content in the pancreas was measured using an enzymatic colorimetric kit. Values are means of six animals, with their standard errors represented by vertical bars. * Mean values were significantly different from the control group (P < 0·05).

It has previously been reported that UCP2 expression is regulated in tandem with the level of NEFA(Reference Dulloo and Samec27, Reference Patane, Anello and Piro28); similarly, we observed that the cafeteria-fed rats showed a slight increase in the levels of UCP2 mRNA in the pancreas (Table 3).

Cafeteria diet modifies the activity and expression of insulin-degrading enzyme

The cafeteria diet-fed animals showed higher levels of plasma insulin due to a higher insulin production and secretion, but we speculated that insulin clearance could also have contributed to this effect. Thus, we analysed the gene expression and activity of one of the main factors responsible for insulin clearance: the IDE. Because the liver is an organ with high IDE mRNA and protein levels(Reference Yfanti, Mengele and Gkazepis29Reference Baumeister, Muller and Rehbein31), we determined IDE gene expression and activity in this tissue. Fig. 3 shows that IDE enzyme activity in the liver was increased by the cafeteria diet, and IDE mRNA levels were also slightly increased. This effect was stronger when the whole tissue weight was considered, which better correlates with the real capacity of liver IDE to remove insulin (Table 4). To analyse further the capacity of the cafeteria-fed rats to degrade insulin, we also determined IDE gene expression in the kidney, an important site of insulin clearance from the systemic circulation. The results did not show any effect of the cafeteria diet on renal IDE or when considering the total tissue weight. Furthermore, we did not observe any effect due to the cafeteria diet in white adipose tissue, where the IDE is also expressed (Table 4). However, when considering the total tissue weight, the cafeteria-fed rats had a higher capacity to remove insulin due to the IDE in the adipose tissue.

Fig. 3 Effects of the cafeteria diet on insulin-degrading enzyme (IDE) activity in the liver. IDE activity from liver samples was determined with an immunocapture-based fluorometric assay. Values are means of six animals, with their standard errors represented by vertical bars. * Mean values were significantly different from the control group (P < 0·05).

Table 4 Insulin-degrading enzyme gene expression in the liver, white adipose tissue (WAT) and kidney

(Mean values with their standard errors)

Mean values were significantly different between the treatments: *P ≤ 0·05, **P ≤ 0·1.

Discussion

Obesity, driven by an excess of fat intake, leads to a toxic lipid accumulation in non-adipose tissues, which is accompanied by insulin resistance. Concurrently, the increased insulin demand promotes a β-cell compensation that involves increased pancreas functionality and/or increased β-cell mass. Insulin resistance may develop into DM2, as driven by β-cell failure(Reference DeFronzo12, Reference DeFronzo32, Reference Weir and Bonner-Weir33).

The present study was designed to examine the effects of the cafeteria diet on insulin production by evaluating pancreas functionality and apoptosis and the activity and expression of the IDE, as an estimation of insulin clearance. We had previously shown that 17 weeks of feeding a cafeteria diet led to insulin resistance(Reference Montagut, Blade and Blay23). The fact that plasma TAG and fatty acids are increased by the cafeteria diet(Reference Sampey, Vanhoose and Winfield4, Reference Quesada, del Bas and Pajuelo34, Reference Kamalakkannan, Rajendran and Venkatesh35) indicates a failure in the adipose tissue, which is unable to remove the lipids from the circulation and might not respond to the insulin inhibition of lipolysis. In the present study, we found that TAG content in the pancreas was already increased by 17 weeks. The source of lipids for this increased TAG storage might be plasma NEFA, as under conditions of high NEFA, de novo fatty acid synthesis is inhibited, a condition that is in agreement with the present gene expression results for FASn. The lack of malonyl-CoA, secondary to the inhibited de novo fatty acid synthesis, avoids the main CPT1a-inhibitory regulation, thus allowing the entrance of fatty acids into the mitochondria for oxidation. In fact, we found a higher gene expression of CPT1a, suggesting that, in the pancreas, increased fatty acid β-oxidation occurred to counteract lipid accumulation. Increased fatty acid oxidation has also been observed in the rat insulinoma cell line INS-1 treated with oleate and palmitate for 72 h(Reference Pinnick, Neville and Clark36), and has been associated with impaired glucose-induced insulin secretion in INS-1 β-cells(Reference Pinnick, Neville and Clark36, Reference Rubi, Antinozzi and Herrero37) and islets(Reference Zhou and Grill38). Defects in glucose-stimulated insulin secretion in INS-1 cells after chronic fatty acid treatment could have been related, in part, to an increase in UCP2 mRNA that is associated with uncoupled mitochondria(Reference Lameloise, Muzzin and Prentki39, Reference Li, Skorpen and Egeberg40). We observed a tendency for the up-regulation in pancreatic UCP2 gene expression after feeding the cafeteria diet. Based on the present results, we cannot discern whether the individual β-cell insulin-secretory functionality was modified due to the cafeteria diet; however, we did find that, despite this increased lipid accumulation, the pancreata of the cafeteria diet-treated rats were still able to respond to an acute glucose load, with a similar increment in plasma insulin as the control rats, and, in fact, the HOMA-β index in the cafeteria-fed rats was better. To counteract peripheral insulin resistance, the cafeteria diet-treated animals exhibited increased insulin synthesis and secretion. We found higher insulin protein and gene expression in the pancreata of the cafeteria-treated rats and an up-regulation of PDX1, a transcriptional controller of insulin gene expression(Reference Moibi, Gupta and Jetton41). Altogether, it is likely that the increased amount of insulin and up-regulated insulin and PDX1 gene expression in the pancreas is due to an increase in β-cells. In mice, a high-fat diet leads to increased β-cell mass(Reference Hennige, Ranta and Heinzelmann42, Reference Owyang, Maedler and Gross43), and treatment with a cafeteria diet in rats has been shown to lead to larger pancreatic islets, although their functionality was not evaluated in that study(Reference Sampey, Vanhoose and Winfield4). Despite the results showing that pancreas still responded to a glucose load after the cafeteria diet treatment, we also observed that there were signs of apoptosis in the pancreas, specifically the down-regulation of BCL2 expression and increased BAX protein levels. Although we found that the BAX gene expression was not altered, changes in BAX protein levels without changes in gene expression have previously been shown to correlate with apoptosis(Reference Brown and Dunmore44). In vitro studies have reported that chronic hyperglycaemia and high NEFA can induce β-cell apoptosis(Reference El-Assaad, Buteau and Peyot45, Reference Piro, Anello and Di Pietro46). In Zucker diabetic fatty rats, obesity, chronic hyperglycaemia and worsening insulin resistance have been shown to lead ultimately to β-cell apoptosis(Reference Shimabukuro, Zhou and Levi47, Reference Finegood, McArthur and Kojwang48). In addition, male C57BL/6J mice fed a high-fat diet (60 % fat) for 8(Reference Hennige, Ranta and Heinzelmann42) or 12 weeks(Reference Owyang, Maedler and Gross43) have shown increased islet β-cell apoptosis. However, different results have also been reported, as a 60 % high-fat diet did not induce pancreatic apoptosis in mice(Reference Zmuda, Qi and Zhu49). In the present study, we showed that in rats, hyperglycaemia, increased fatty acids and/or pancreatic lipid accumulation derived from a 17-week cafeteria diet triggered the apoptosis process in the pancreata of rats, although this pancreatic damage was not reflected in insulin plasma concentrations.

We also focused on another important step for the regulation of glucose metabolism, the insulin clearance, specifically, one of its main regulators, the IDE. Alterations in gene coding for this enzyme have been linked with diabetes susceptibility(Reference Fakhrai-Rad, Nikoshkov and Kamel16Reference Ragvin, Moro and Fredman21). In adipocytes isolated from human patients, insulin degradation (probably mediated by the IDE) has been demonstrated to be reduced in pre-diabetic and diabetic states(Reference Fawcett, Sang and Permana50). In mice, the lack of the IDE leads to glucose intolerance and hyperinsulinaemia(Reference Farris, Mansourian and Chang22). The effects of the diet on the expression of the IDE in the brain have been studied in the context of insulin resistance as an underlying mechanism that is responsible for an increased risk of Alzheimer's disease and, thus, of the possible involvement of cerebral IDE in the development of β-amyloidosis. In APP/PS1 double transgenic mice (which develop memory deficits and amyloid plaques), providing 10 % sucrose-sweetened water ad libitum has been reported to not statistically modify brain IDE protein levels(Reference Cao, Lu and Lewis51). In another model of Alzheimer-disease-like neuropathology, the feeding of Tg2576 mice with a high-fat diet for 9 months led to insulin resistance and decreased IDE activity and protein expression in the brain(Reference Ho, Qin and Pompl52). However, the effects of a high-fat diet on the IDE in tissues responsible for insulin clearance and degradation have, to our knowledge, not been studied thus far. The present results showed that the liver activity of the IDE was increased in the cafeteria-fed animals, which could have been partially due to an up-regulation of its gene expression. We did not find the same effects in other tissues. Despite the role of the kidney in degrading insulin(Reference Duckworth, Bennett and Hamel15), we did not observe any effects of the cafeteria diet on renal IDE gene expression, nor did we find any modification of IDE gene expression in adipose tissue. Because we are studying obesity, we must also consider the tissue size, which is mainly relevant for the adipose tissue. When the adipose tissue weight is taken into consideration, the insulin clearance potential is higher in cafeteria diet-treated rats(Reference Ardevol, Adan and Canas53). This has been described in fa/fa genetically obese animals and in obese human subjects, where the potential of insulin cleavage by adipose tissue in obese patients was higher than that in the controls, implying that both insulin secretion and turnover are increased in obese individuals(Reference Rafecas, Fernandez-Lopez and Salinas54). When considering the whole amount of tissue, the cafeteria diet-fed rats in the present study exhibited a higher capacity to degrade insulin. This fact suggests that feeding a high-fat diet is accompanied by a mechanism to eliminate high plasma insulin levels, and at least with the experimental procedure used in the present study (cafeteria-diet for 17 weeks), it appears that hyperinsulinaemia was not due to impaired insulin clearance but that it was counteracted by enhanced insulin degradation. The present results are not in agreement with previous studies suggesting that hepatic insulin degradation may be reduced as an adaptive mechanism to relieve stress on pancreatic β-cells imposed by insulin resistance that is induced by a high-fat diet(Reference Mittelman, Van Citters and Kim55, Reference Lam, Yoshii and Haber56). Remarkably, the experimental models differ vastly, suggesting that there could be different stages in diet-induced obesity and insulin resistance with different degrees of involvement of hepatic glucose clearance. Thus, the cafeteria diet acts on IDE expression and activity in the liver; it does not directly modulate IDE activity in adipose tissue. However, the increased amount of such tissue induced by the feeding of a cafeteria diet would contribute to the amount of insulin clearance.

In conclusion, we showed that the cafeteria diet treatment for 17 weeks in rats mimicked a pre-diabetic state with ectopic lipid accumulation in the pancreas. At this time point, the insulin content and gene expression in the pancreas were higher in the cafeteria diet-treated group than in the control rats, a condition that leads to hyperinsulinaemia. In addition, initial signs of apoptosis appeared in the pancreas. We also showed that IDE-mediated insulin clearance capability was higher in the cafeteria diet-treated rats than in the controls.

Acknowledgements

This study was supported by a grant (AGL2008-01310) from the Spanish government. A. C.-A. is the recipient of an FPU fellowship from the Ministerio de Educación of the Spanish government. L. C. is the recipient of an FPI fellowship from Generalitat de Catalunya, and V. P. is the recipient of a fellowship from Universitat Rovira i Virgili. A. A., M. B. and M. P. designed the research. A. C.-A., L. C., V. P., A. A. and M. P. conducted the research. A. C.-A., L. C. and V. P. analysed the data. A. C.-A., L. C., A. A. and M. P. wrote the paper. A. A. and M. P. 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.

References

1Abelson, P & Kennedy, D (2004) The obesity epidemic. Science 304, 1413.Google Scholar
2Hurt, RT, Kulisek, C, Buchanan, LA, et al. (2010) The obesity epidemic: challenges, health initiatives, and implications for gastroenterologists. Gastroenterol Hepatol (N Y) 6, 780792.Google ScholarPubMed
3Field, AE, Coakley, EH, Must, A, et al. (2001) Impact of overweight on the risk of developing common chronic diseases during a 10-year period. Arch Intern Med 161, 15811586.CrossRefGoogle ScholarPubMed
4Sampey, BP, Vanhoose, AM, Winfield, HM, et al. (2011) Cafeteria diet is a robust model of human metabolic syndrome with liver and adipose inflammation: comparison to high-fat diet. Obesity 19, 11091117.Google Scholar
5Terra, X, Pallares, V, Ardevol, A, et al. (2011) Modulatory effect of grape-seed procyanidins on local and systemic inflammation in diet-induced obesity rats. J Nutr Biochem 22, 380387.Google Scholar
6Campion, J, Milagro, FI, Fernandez, D, et al. (2006) Diferential gene expression and adiposity reduction induced by ascorbic acid supplementation in a cafeteria model of obesity. J Physiol Biochem 62, 7180.Google Scholar
7Rolls, BJ, Rowe, EA & Turner, RC (1980) Persistent obesity in rats following a period of consumption of a mixed, high energy diet. J Physiol 298, 415427.CrossRefGoogle ScholarPubMed
8Sishi, B, Loos, B, Ellis, B, et al. (2011) Diet-induced obesity alters signalling pathways and induces atrophy and apoptosis in skeletal muscle in a prediabetic rat model. Exp Physiol 96, 179193.Google Scholar
9Brandt, N, De Bock, K, Richter, EA, et al. (2010) Cafeteria diet-induced insulin resistance is not associated with decreased insulin signaling or AMPK activity and is alleviated by physical training in rats. Am J Physiol Endocrinol Metab 299, E215E224.Google Scholar
10Mercader, J, Granados, N, Caimari, A, et al. (2008) Retinol-binding protein 4 and nicotinamide phosphoribosyltransferase/visfatin in rat obesity models. Horm Metab Res 40, 467472.Google Scholar
11Vanzela, EC, Ribeiro, RA, de Oliveira, CA, et al. (2010) Pregnancy restores insulin secretion from pancreatic islets in cafeteria diet-induced obese rats. Am J Physiol Regul Integr Comp Physiol 298, R320R328.CrossRefGoogle ScholarPubMed
12DeFronzo, RA (2004) Pathogenesis of type 2 diabetes mellitus. Med Clin North Am 88, 787835, ix.CrossRefGoogle ScholarPubMed
13Lewis, GF, Carpentier, A, Adeli, K, et al. (2002) Disordered fat storage and mobilization in the pathogenesis of insulin resistance and type 2 diabetes. Endocr Rev 23, 201229.Google Scholar
14Zhou, YP & Grill, V (1995) Long term exposure to fatty acids and ketones inhibits B-cell functions in human pancreatic islets of Langerhans. J Clin Endocrinol Metab 80, 15841590.Google ScholarPubMed
15Duckworth, WC, Bennett, RG & Hamel, FG (1998) Insulin degradation: progress and potential. Endocr Rev 19, 608624.Google ScholarPubMed
16Fakhrai-Rad, H, Nikoshkov, A, Kamel, A, et al. (2000) Insulin-degrading enzyme identified as a candidate diabetes susceptibility gene in GK rats. Hum Mol Genet 9, 21492158.Google Scholar
17Farris, W, Mansourian, S, Leissring, MA, et al. (2004) Partial loss-of-function mutations in insulin-degrading enzyme that induce diabetes also impair degradation of amyloid beta-protein. Am J Pathol 164, 14251434.Google Scholar
18Nordman, S, Ostenson, CG, Efendic, S, et al. (2009) Loci of TCF7L2, HHEX and IDE on chromosome 10q and the susceptibility of their genetic polymorphisms to type 2 diabetes. Exp Clin Endocrinol Diabetes 117, 186190.Google Scholar
19Furukawa, Y, Shimada, T, Furuta, H, et al. (2008) Polymorphisms in the IDE–KIF11–HHEX gene locus are reproducibly associated with type 2 diabetes in a Japanese population. J Clin Endocrinol Metab 93, 310314.Google Scholar
20Karamohamed, S, Demissie, S, Volcjak, J, et al. (2003) Polymorphisms in the insulin-degrading enzyme gene are associated with type 2 diabetes in men from the NHLBI Framingham Heart Study. Diabetes 52, 15621567.Google Scholar
21Ragvin, A, Moro, E, Fredman, D, et al. (2010) Long-range gene regulation links genomic type 2 diabetes and obesity risk regions to HHEX, SOX4, and IRX3. Proc Natl Acad Sci U S A 107, 775780.CrossRefGoogle ScholarPubMed
22Farris, W, Mansourian, S, Chang, Y, et al. (2003) Insulin-degrading enzyme regulates the levels of insulin, amyloid beta-protein, and the beta-amyloid precursor protein intracellular domain in vivo. Proc Natl Acad Sci U S A 100, 41624167.Google Scholar
23Montagut, G, Blade, C, Blay, M, et al. (2010) Effects of a grapeseed procyanidin extract (GSPE) on insulin resistance. J Nutr Biochem 21, 961967.Google Scholar
24Bradford, 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
25Smith, S (1994) The animal fatty acid synthase: one gene, one polypeptide, seven enzymes. FASEB J 8, 12481259.Google Scholar
26Del Bas, JM, Ricketts, ML, Baiges, I, et al. (2008) Dietary procyanidins lower triglyceride levels signaling through the nuclear receptor small heterodimer partner. Mol Nutr Food Res 52, 11721181.CrossRefGoogle ScholarPubMed
27Dulloo, AG & Samec, S (2001) Uncoupling proteins: their roles in adaptive thermogenesis and substrate metabolism reconsidered. Br J Nutr 86, 123139.Google Scholar
28Patane, G, Anello, M, Piro, S, et al. (2002) Role of ATP production and uncoupling protein-2 in the insulin secretory defect induced by chronic exposure to high glucose or free fatty acids and effects of peroxisome proliferator-activated receptor-gamma inhibition. Diabetes 51, 27492756.Google Scholar
29Yfanti, C, Mengele, K, Gkazepis, A, et al. (2008) Expression of metalloprotease insulin-degrading enzyme insulysin in normal and malignant human tissues. Int J Mol Med 22, 421431.Google Scholar
30Kuo, WL, Montag, AG & Rosner, MR (1993) Insulin-degrading enzyme is differentially expressed and developmentally regulated in various rat tissues. Endocrinology 132, 604611.Google Scholar
31Baumeister, H, Muller, D, Rehbein, M, et al. (1993) The rat insulin-degrading enzyme. Molecular cloning and characterization of tissue-specific transcripts. FEBS Lett 317, 250254.Google Scholar
32DeFronzo, RA (2010) Insulin resistance, lipotoxicity, type 2 diabetes and atherosclerosis: the missing links. The Claude Bernard Lecture 2009. Diabetologia 53, 12701287.CrossRefGoogle Scholar
33Weir, GC & Bonner-Weir, S (2004) Five stages of evolving beta-cell dysfunction during progression to diabetes. Diabetes 53, Suppl. 3, S16S21.Google Scholar
34Quesada, 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.Google Scholar
35Kamalakkannan, S, Rajendran, R, Venkatesh, RV, et al. (2010) Antiobesogenic and antiatherosclerotic properties of Caralluma fimbriata extract. J Nutr Metab 2010, 285301.Google Scholar
36Pinnick, K, Neville, M, Clark, A, et al. (2010) Reversibility of metabolic and morphological changes associated with chronic exposure of pancreatic islet beta-cells to fatty acids. J Cell Biochem 109, 683692.Google Scholar
37Rubi, B, Antinozzi, PA, Herrero, L, et al. (2002) Adenovirus-mediated overexpression of liver carnitine palmitoyltransferase I in INS1E cells: effects on cell metabolism and insulin secretion. Biochem J 364, Pt 1, 219226.Google Scholar
38Zhou, YP & Grill, VE (1994) Long-term exposure of rat pancreatic islets to fatty acids inhibits glucose-induced insulin secretion and biosynthesis through a glucose fatty acid cycle. J Clin Invest 93, 870876.Google Scholar
39Lameloise, N, Muzzin, P, Prentki, M, et al. (2001) Uncoupling protein 2: a possible link between fatty acid excess and impaired glucose-induced insulin secretion? Diabetes 50, 803809.Google Scholar
40Li, LX, Skorpen, F, Egeberg, K, et al. (2002) Induction of uncoupling protein 2 mRNA in beta-cells is stimulated by oxidation of fatty acids but not by nutrient oversupply. Endocrinology 143, 13711377.Google Scholar
41Moibi, JA, Gupta, D, Jetton, TL, et al. (2007) Peroxisome proliferator-activated receptor-gamma regulates expression of PDX-1 and NKX6.1 in INS-1 cells. Diabetes 56, 8895.CrossRefGoogle ScholarPubMed
42Hennige, AM, Ranta, F, Heinzelmann, I, et al. (2010) Overexpression of kinase-negative protein kinase Cdelta in pancreatic beta-cells protects mice from diet-induced glucose intolerance and beta-cell dysfunction. Diabetes 59, 119127.Google Scholar
43Owyang, AM, Maedler, K, Gross, L, et al. (2010) XOMA 052, an anti-IL-1{beta} monoclonal antibody, improves glucose control and {beta}-cell function in the diet-induced obesity mouse model. Endocrinology 151, 25152527.Google Scholar
44Brown, JE & Dunmore, SJ (2007) Leptin decreases apoptosis and alters BCL-2: Bax ratio in clonal rodent pancreatic beta-cells. Diabetes Metab Res Rev 23, 497502.Google Scholar
45El-Assaad, W, Buteau, J, Peyot, ML, et al. (2003) Saturated fatty acids synergize with elevated glucose to cause pancreatic beta-cell death. Endocrinology 144, 41544163.Google Scholar
46Piro, S, Anello, M, Di Pietro, C, et al. (2002) Chronic exposure to free fatty acids or high glucose induces apoptosis in rat pancreatic islets: possible role of oxidative stress. Metabolism 51, 13401347.CrossRefGoogle ScholarPubMed
47Shimabukuro, M, Zhou, YT, Levi, M, et al. (1998) Fatty acid-induced beta cell apoptosis: a link between obesity and diabetes. Proc Natl Acad Sci U S A 95, 24982502.Google Scholar
48Finegood, DT, McArthur, MD, Kojwang, D, et al. (2001) Beta-cell mass dynamics in Zucker diabetic fatty rats. Rosiglitazone prevents the rise in net cell death. Diabetes 50, 10211029.Google Scholar
49Zmuda, EJ, Qi, L, Zhu, MX, et al. (2010) The roles of ATF3, an adaptive-response gene, in high-fat-diet-induced diabetes and pancreatic beta-cell dysfunction. Mol Endocrinol 24, 14231433.Google Scholar
50Fawcett, J, Sang, H, Permana, PA, et al. (2010) Insulin metabolism in human adipocytes from subcutaneous and visceral depots. Biochem Biophys Res Commun 402, 762766.Google Scholar
51Cao, D, Lu, H, Lewis, TL, et al. (2007) Intake of sucrose-sweetened water induces insulin resistance and exacerbates memory deficits and amyloidosis in a transgenic mouse model of Alzheimer disease. J Biol Chem 282, 3627536282.Google Scholar
52Ho, L, Qin, W, Pompl, PN, et al. (2004) Diet-induced insulin resistance promotes amyloidosis in a transgenic mouse model of Alzheimer's disease. FASEB J 18, 902904.Google Scholar
53Ardevol, A, Adan, C, Canas, X, et al. (1996) Adipose tissue extraction of circulating insulin in anaesthetized Zucker obese rats. Int J Obes Relat Metab Disord 20, 837841.Google ScholarPubMed
54Rafecas, I, Fernandez-Lopez, JA, Salinas, I, et al. (1995) Insulin degradation by adipose tissue is increased in human obesity. J Clin Endocrinol Metab 80, 693695.Google ScholarPubMed
55Mittelman, SD, Van Citters, GW, Kim, SP, et al. (2000) Longitudinal compensation for fat-induced insulin resistance includes reduced insulin clearance and enhanced beta-cell response. Diabetes 49, 21162125.Google Scholar
56Lam, T, Yoshii, H, Haber, A, et al. (2000) Free fatty acids time-dependently impair glucose metabolism by mechanisms unrelated to the Randle's cycle. Diabetes 49, A286A286.Google Scholar
Figure 0

Table 1 Cafeteria diet composition

Figure 1

Table 2 Effects of the cafeteria diet on homeostatic model assessment for insulin resistance (HOMA-IR) and the homeostatic model assessment-β (HOMA-β) index(Mean values with their standard errors)

Figure 2

Table 3 Gene expression in the pancreas(Mean values with their standard errors)

Figure 3

Fig. 1 Effects of the cafeteria diet on B-cell/lymphoma 2-associated X protein (BAX) protein levels in the pancreas. BAX protein levels were quantified by Western blot analysis. A representative Western blot is provided. Protein expression was quantified relative to the β-actin loading control using ImageJ 1.44p software (National Institutes of Health). Values are means of six animals, with their standard errors represented by vertical bars. * Mean values were significantly different from the control group (P < 0·05).

Figure 4

Fig. 2 Effects of the cafeteria diet on pancreatic TAG content. After 17 weeks of the cafeteria diet, the animals were killed, and the pancreas was obtained. The TAG content in the pancreas was measured using an enzymatic colorimetric kit. Values are means of six animals, with their standard errors represented by vertical bars. * Mean values were significantly different from the control group (P < 0·05).

Figure 5

Fig. 3 Effects of the cafeteria diet on insulin-degrading enzyme (IDE) activity in the liver. IDE activity from liver samples was determined with an immunocapture-based fluorometric assay. Values are means of six animals, with their standard errors represented by vertical bars. * Mean values were significantly different from the control group (P < 0·05).

Figure 6

Table 4 Insulin-degrading enzyme gene expression in the liver, white adipose tissue (WAT) and kidney(Mean values with their standard errors)