Abstract
Emerging evidence demonstrates a close interplay between disturbances in mitochondrial function and ER homeostasis in the development of the metabolic syndrome. The present investigation sought to advance our understanding of the communication between mitochondrial dysfunction and ER stress in the onset of hepatic steatosis in male rodents with defective peroxisome proliferator-activated receptor-α (PPARα) signaling. Genetic depletion of PPARα or perturbation of PPARα signaling by high-fructose diet compromised the functional activity of metabolic enzymes involved in mitochondrial fatty acid β-oxidation and induced hepatic mitochondrial stress in rats and mice. Inhibition of PPARα activity further enhanced the expression of apolipoprotein B (apoB) mRNA and protein, which was associated with reduced mRNA expression of the sarco/endoplasmic reticulum calcium ATPase (SERCA), the induction of hepatic ER stress, and hepatic steatosis. Restoration of PPARα activity recovered the metabolic function of the mitochondria and ER, alleviated systemic hypertriglyceridemia, and improved hepatic steatosis. These findings unveil novel roles for PPARα in mediating stress signals between hepatic subcellular stress-responding machinery and in the onset of hepatic steatosis under conditions of metabolic stress.
Keywords: peroxisome proliferator-activated receptor-α, endoplasmic reticulum, mitochondrial and endoplasmic reticulum stress, apolipoprotein B, very-low density lipoprotein, hepatic steatosis
perturbations in lipid metabolism are involved in the pathogenesis of a cluster of chronic metabolic diseases, including fatty liver disease, insulin resistance, type 2 diabetes, and atherosclerosis. The peroxisome proliferator-activated receptor (PPAR) nuclear receptor family is a group of transcription factors that critically regulate signaling at the interface of lipid metabolism and inflammation (3). Among them, the isoform PPARα is expressed predominantly in the liver, where it promotes fatty acid β-oxidation, ketogenesis, lipid transport, and gluconeogenesis (4, 26). The majority of the genes involved in mitochondrial fatty acid β-oxidation are transcriptionally regulated by PPARα. As energy-regulating metabolic machinery, mitochondria dynamically communicate with other subcellular organelles such as the endoplasmic reticulum (ER) (10). Mitochondrial dysfunction is a contributing factor to the onset of insulin resistance; impairment of mitochondrial function in human myocytes increases predisposition to intramyocellular lipid accumulation and insulin resistance (17, 28).
Research over the past decade has established a compelling connection between lipid-induced ER stress and the metabolic syndrome (18, 23). The onset of obesity and hepatic steatosis are usually accompanied by increased secretion of hepatic very-low-density lipoprotein-triglyceride (VLDL-TG) and VLDL-apolipoprotein B (apoB) (5). Biosynthesis of apoB (a key structural component of VLDL) is modulated by both insulin and ER stress (21, 24, 29). Modest ER stress induced by free fatty acids increases apoB secretion, whereas greater lipid loading results in severe ER stress and inhibits apoB production in McA-RH777 cells (21). Furthermore, constant overproduction of apoB in hepatocytes stimulated by an atherogenic diet has been reported to directly provoke hepatic ER stress and may contribute to the onset of hepatic insulin resistance (30).
In the present study, we report that genetic depletion of PPARα (PPARα−/−) or suppression of PPARα signaling by high-fructose feeding compromises mitochondrial integrity and the function of metabolic enzymes involved in fatty acid β-oxidation. Impairment of PPARα signaling upregulated hepatic apoB expression at both the transcriptional and translational levels, which in turn suppressed expression of the sarco/endoplasmic reticulum calcium ATPase (SERCA) and induced hepatic ER stress, leading to systemic dyslipidemia and hepatic steatosis. Restoration of PPARα activity relieved mitochondrial and ER stress, alleviated systemic hypertriglyceridemia, and improved hepatic steatosis.
MATERIALS AND METHODS
Cell culture and treatments.
Primary mouse and rat hepatocytes and a rat hepatoma cell line, McA-RH7777 (ATCC), were maintained in DMEM containing 20% FBS at 37°C, 5% CO2. Oleic acid, fructose, PPARα antagonist MK-886, and PPARα agonist WY-14643 were used at final concentrations of 400 μM, 6 mM, 10 μM, and 40 μM, respectively.
Animal protocols.
All animal experiments were approved by the animal ethics committee of the Hospital for Sick Children and conducted according to national guidelines. Male wild-type (WT) (C57BL/6J) and PPARα-knockout mice (B6.129S4-Pparatm1Gonz/J) were purchased from The Jackson Laboratory (Bar Harbor, ME) at 12 wk of age. The PPARα-knockout mice were initially generated from a 129S4/SvJae background and then backcrossed for 10 generations on to the C57BL/6J background. Heterozygotes were then intercrossed to generate homozygotes. C57BL/6J mice were used for controls, as recommended by the vendor. Male rats (340–360 g) were purchased from Charles River (Montreal, QC, Canada) at 12 wk of age. Animals were housed on alternating 12-h light and dark cycles with free access to food and water. After 1 wk of acclimatization and baseline blood collection (fasted for 5 h), animals were placed on a control chow diet (Table 1) or a high-fructose diet (60% fructose, ID: 161.506; Dyets, Bethlehem, PA) for 3 wk. WY-14643 treatment was used to activate PPARα in a diet-induced model of insulin resistance. High-fructose-fed (Fruc) and chow-fed (Chow) rats were randomly divided into two groups (n = 6). Chow/WY and Fruc/WY were dosed with WY-14643 (6 mg/kg ip) once every 2 days throughout the 3-wk feeding period. Control groups (Chow/Veh and Fruc/Veh) received injection of the vehicle [1.5 ml/kg of 0.5% (vol/vol) DMSO ip]. Tissue collection was performed after 3 wk as follows: animals were fasted (5 h) and anesthetized using isoflurane (3% mixed with oxygen), tissues were excised and flash-frozen in liquid nitrogen, and livers were then homogenized in solubilization buffer, as described previously (32).
Table 1.
Ingredients, %mass | Chow | Fructose |
---|---|---|
Protein | 16.4 | 22.21 |
Fat | 13.3 | 6.0 |
Starch | 56.4 | Trace |
Fructose | 0.2 | 60.0 |
Glucose | 0.1 | Trace |
Sucrose | 0.6 | Trace |
Cellulose fiber | 3.5 | 7.09 |
Salt mix | 5.9 | 3.5 |
Vitamin mix | 3.6 | 1.0 |
Choline bitartrate | Trace | 0.2 |
VLDL collection.
Animals were fasted for 5 h, and baseline blood was collected via tail vein bleed (100 μl). Animals were then treated with 20% poloxamer (500 mg/kg ip), and blood was collected at 1 and 2 h via tail vein bleed (100 μl), with final blood collections done at 3 h via cardiac puncture (500 μl). Plasma TG and cholesterol were assessed in all samples, as described below. VLDL fractions were separated from plasma (200 μl) via ultracentrifugation (45,000 rpm for 5 h at 4°C), and TG, cholesterol, and apoB were assessed as described below. VLDL isolation was performed only on the 3-h time point, as the other time points did not have enough volume for isolation.
Immunoblot analyses.
Immunoprecipitations and immunoblotting were performed as described previously (31). The following antibodies were used in this study: anti-human apoB, anti-apoE, and anti-albumin antibodies (Midland Bioproducts, Boone, IA); anti-KDEL monoclonal antibody (CalBiochem, San Diego, CA); anti-eukaryotic initiation factor-2α (eIF2α) and anti-phosphoserine-51 of eIF2α (Cell Signaling Technology, Danvers, MA); and anti-HSP60 polyclone antibody (Wuhan Boster). All antibodies were used at a final concentration of 0.1–1 μg/ml. After incubation with the appropriate horseradish peroxidase-conjugated anti-mouse or anti-rabbit IgG secondary antibody (1:2,000 dilution), proteins were visualized by enhanced chemiluminescence according to the manufacturer's instructions (Amersham Biosciences, Pittsburgh, PA).
Metabolic labeling, ultracentrifugation, and fractionation.
McA-RH7777 cells (1 × 106) were cultured with or without MK-866 (10 μM) for 48 h, deprived of methionine and cysteine for 1 h in the presence or absence of MK-866 (10 μM), and then pulsed with 100 μCi/ml [35S]methionine in the presence of oleate (400 μM) for 3 h. Media were collected and subjected to fractionation by ultracentrifugation. Briefly, media were collected and adjusted to 1.1 g/ml with NaBr, which was overlaid with a 1.06, 1.02, and 1.006 g/ml gradient and ultracentrifuged at 35,000 rpm for 18 h using a Beckman Optima LE-80K Ultracentrifuge. Fractions were collected, immunoprecipitated for apoB, and subjected to SDS-PAGE.
Lipid extraction and TG and cholesterol mass measurement from tissue.
Lipid extraction and analysis were performed as described previously (2). Briefly, ∼300 mg of liver tissue was added to 20 volumes of a 2:1 chloroform-methanol mixture and incubated for 24 h at room temperature. Following the incubation period, 0.2 volumes of 0.9% NaCl were added to the solvent mixture. The samples were thoroughly vortexed and then centrifuged at 2,000 rpm for 3 min. The upper aqueous phase was removed, and the solvent layer was allowed to evaporate. The dried lipid was resuspended in 1 ml of 100% ethanol, and TG and cholesterol concentrations were determined using commercially available kits from Randox (Mississauga, ON, Canada) as per the manufacturer's instructions. Lipid data are expressed in milligrams of lipid per gram of liver tissue.
RNA isolation and RT-PCR.
Total RNA was extracted from liver tissues and primary rat hepatocytes using the Qiagen (Mississauga, ON, Canada) RNeasy mini kit. cDNA was synthesized using Applied Biosystems TaqMan Reverse Transcription Reagents (Foster City, CA). RT-PCR was performed using appropriate primers to measure the mRNA levels of the indicated genes. PCR reactions were carried out using SYBR Green PCR Master Mix (Applied Biosystems, Streetsville, ON, Canada). Relative quantities of mRNA were calculated from threshold cycle (CT) values with the comparative CT method, using 18S rRNA as an internal reference.
Immunofluorescence microscopy.
McA-RH7777 cells cultured on collagen-coated coverslips in six-well microplates were fixed with 4% paraformaldehyde in 1× phosphate-buffered solution (PBS) for 15 min and then permeabilized with 0.1% Triton X-100 in 1× PBS for 5 min. Cells were incubated with anti-human apoB antibody [1:1,000 in 5% bovine serum albumin (BSA)], followed by incubation with the secondary antibody Alexa Fluor 594 donkey anti-goat IgG (Invitrogen; 1:1,000 in 5% BSA), both for 1 h at room temperature. Finally, nuclei were stained with 4,6-diamidino-2-phenylindole for 15 min at room temperature (1:1,000 in 5% BSA). Images were captured with a Quorum spinning disk confocal microscope (Quorum Technologies, Guelph, ON, Canada) and Volocity 6 software (PerkinElmer, Woodbridge, ON, Canada).
Mitochondrial JC-1 staining in primary mouse hepatocytes.
Isolated primary hepatocytes were allowed 3 h to attach on six-well plates (0.5 × 106 cells/well) and then treated for 24 h with either DMSO (0.5%), MK-886 (20 μM) or fructose (12 mM). Cells were washed twice with warm DMEM and then incubated with JC-1 staining reagent (Cayman Chemical, Ann Arbor, MI) for 15 min at 37°C (according to the manufacturer's instructions). Healthy cells (mainly JC-1 aggregates) appear red; unhealthy apoptotic cells (mainly JC-1 monomers) appear green.
Statistical analyses.
Data obtained by densitometry or fluorography were evaluated using one-way ANOVA (GraphPad Prism 5, La Jolla, CA). Posttest analysis was performed to determine the significance between groups, using unpaired two-way Student t-tests. All results are presented as means ± SE. Single and double asterisks in the figures indicate statistically significant differences of P < 0.05 or P < 0.01, respectively, compared with controls.
RESULTS
Impairment of PPARα signaling disrupts hepatic mitochondrial integrity and induces mitochondrial stress.
Mitochondrial β-oxidation of fatty acids starts with the transportation of activated long-chain fatty acids into the matrix of the mitochondria. In the liver, this process is performed mainly by the enzyme carnitine palmitoyltransferase 1α (CPT-1α), a direct target gene of PPARα. As expected, we found that in livers of PPARα−/− mice, mRNA expression of CPT-1α was significantly reduced compared with age-matched controls. Additionally, other PPARα target genes involved in fatty acid β-oxidation, including CPT-1, acetyl-CoA dehydrogenase very-long chain (ACADVL), and long-chain acyl-CoA dehydrogenase, were also decreased in livers of PPARα−/− mice (Fig. 1A). Decreased mRNA levels of metabolic enzymes involved in mitochondrial lipid metabolism were associated with reduction of fatty acid β-oxidation and altered lipid metabolism (1). We also observed that there was a significant accumulation of lipid droplets (as assessed by Oil Red O staining) and a marked elevation in lipid content, including TG and cholesterol, in the livers of PPARα−/− mice (Fig. 1B and data not shown). Further investigation of mitochondrial integrity in PPARα−/− mice showed that expression of a mitochondrial stress marker, heat shock protein 60 (HSP60), which plays a role in alleviating mitochondrial protein aggregation (11, 19, 35), was significantly increased in livers of PPARα−/− mice compared with their PPARα+/+ controls (Fig. 1C). This suggests activation of the mitochondrial stress response. The direct impact of PPARα on mitochondrial integrity was further investigated by treating primary mouse hepatocytes with a PPARα antagonist, MK-886, followed by a JC-1 staining assay (20). As shown in Fig. 1D, inhibition of PPARα signaling disturbed mitochondrial membrane integrity and altered the oxidation reduction potential of the mitochondria, which was indicated by the reduced ratio between red/green fluorescence intensity in the MK-886-treated cells (Fig. 1D, images c and d). Incubation of McA-RH7777 cells with MK-886 induced further accumulation of lipid droplets in the hepatocellular cytosol compared with the untreated cells (Fig. 1E, images c and d). These results suggest that impairment of PPARα signaling disrupts mitochondrial physiology.
To corroborate this finding, we used a diet-induced animal model of insulin resistance, the high-fructose-fed rat model. We fed two groups of rats either a regular chow diet (60% of its calories from carbohydrates, predominantly from starch; Chow), or a high-fructose diet (60% of its calories from fructose; Fruc) for 3 wk. Fructose feeding resulted in about a 60% reduction of hepatic PPARα mRNA compared with control (chow-fed) rats. Reduced expression of PPARα in turn affected transcription of its target genes, with mRNA levels of CPT-1α and ACADVL decreased ∼65 and 50%, respectively, after fructose feeding (Fig. 1F). Interestingly, expression of another PPARα target gene, acyl-CoA oxidase 1, which catalyzes the initial step of peroxisomal β-oxidation, was also suppressed by the high-fructose diet, but this reduction was not statistically significant (Fig. 1F). This suggests that PPARα exerts greater regulatory effects on mitochondrial β-oxidation genes than on peroxisomal ones. The impairment of PPARα activity and reduced expression of mitochondrial β-oxidation enzymes upon high-fructose feeding was accompanied by the accumulation of lipid droplets and overexpression of HSP60 in rat livers (Fig. 1, G and H). Fructose treatment also decreased the membrane integrity and altered the oxidation reduction potential of the mitochondria (Fig. 1D, images e and f) and induced accumulation of lipid droplets in the cytoplasm of McA-RH7777 cells (Fig. 1E, images e and f). Together, these data suggest that impairment of PPARα activity compromises hepatic mitochondrial lipid metabolism and disrupts mitochondrial metabolic homeostasis.
Impairment of PPARα activity augments hepatic VLDL biogenesis.
Since dysregulation of lipid metabolism is closely related to hepatic VLDL biosynthesis and secretion, hepatic lipid accumulation of PPARα-defective rodents prompted us to investigate the secretion rate of VLDL in vivo. Hyperlipidemia has been reported previously in PPARα-defective animal models (15), and reduced lipoprotein lipase-mediated intravascular TG hydrolysis has been proposed to be one of the mechanisms for this disorder (25). To determine whether increased secretion of VLDL is also a contributing factor to the induction of hyperlipidemia, we performed an in vivo VLDL collection assay. Lipoprotein lipase activity was inhibited in both WT and PPARα-null mice by treating the mice with poloxamer (1,000 mg/kg) through ip injection. As shown in Fig. 2, A and B, despite the shutdown of lipoprotein hydrolysis in the circulating plasma, TG and cholesterol were significantly higher in the PPARα-null mice at all time points compared with WT age-matched controls. VLDL-TG and cholesterol were also increased at 3 h in PPAR−/− mice. In vitro, when determining the impact of the PPARα antagonist MK-886 on the assembly and secretion of lipoprotein particles in McA-RH7777 cells, we observed that, in lipid-rich conditions (presence of oleate), MK-886 significantly increased the secretion of VLDL particles, which was indicated by the increased secretion of newly synthesized apoB-100 in this fraction, whereas the secretion of other lipoprotein particles remained unchanged (Fig. 2C, fractions 1 and 2). Taken together, these results support a model whereby impairment of PPARα activity induces overproduction of VLDL and contributes to systemic hyperlipidemia.
PPARα signaling transcriptionally regulates hepatic apoB synthesis.
The increased secretion of VLDL in the previous experiment prompted us to further investigate the regulation of apoB, a key structural protein in VLDL particles, in the PPARα-defective animal models. Protein expression of apoB-100 and apoB-48 was significantly increased in the livers of PPARα−/− mice, which was specific to apoB, since expression of another apolipoprotein, apoE, remained unchanged in the PPARα−/− mice (Fig. 3A). This phenotype was mirrored in the fructose-fed rat model; protein expression of both apoB-100 and apoB-48 was markedly elevated in the livers of rats following fructose feeding (Fig. 3B). To examine whether the increased expression of apoB-100 observed in the PPARα-defective mice was regulated by increasing de novo protein synthesis or by reducing protein degradation, we determined the mRNA levels of apoB in livers of both PPARα+/+ and PPARα−/− mice by quantitative (q)RT-PCR. As shown in Fig. 3C, compared with PPARα+/+ mice, expression of apoB mRNA was increased by ∼60% in PPARα−/− mice. The direct regulatory effect of PPARα on apoB is supported by our observation that treatment of primary rat hepatocytes with the PPARα inhibitor MK-886 also stimulated expression of apoB mRNA (Fig. 3D). Research on VLDL metabolism has suggested that apoB synthesis is prone to cotranslational and posttranslational regulation (9, 27). To investigate whether the elevated apoB mRNA contributed to the overproduction of apoB when PPARα was defective, we performed a pulse chase assay to quantify the amount of newly synthesized apoB-100 in the presence or absence of MK-886. McA-RH7777 cells were treated with MK-886 or vehicle for 48 h and then pulsed with [35S]methionine for 2 h. Labeled apoB-100 and albumin were immunoprecipitated from the cell lysates. Incubation of cells with MK-886 induced significant increases of newly synthesized apoB-100 in hepatocytes compared with the vehicle incubations at all time points (Fig. 3E, left). In contrast, no alteration in albumin protein synthesis was detected in the presence of MK-886 (Fig. 3E, right). To further demonstrate that impairment of PPARα exerts a greater impact on apoB mRNA expression than on apoB protein stabilization, we treated McA-RH7777 cells with MK-886 and immunostained the treated cells with anti-apoB antibody and BODIPY for lipid droplets. Confocal imaging showed that increased protein expression of apoB was induced by MK-886 treatment (Fig. 3F, image e). The majority of the accumulated lipid droplets induced by MK-886 treatment were colocalized with apoB in the cytoplasm (Fig. 3F, image f). It has been well accepted that proper lipidation of apoB in the ER under lipid-rich conditions prevents apoB from being retrograded to the cytoplasm and degraded by the proteasome (9), whereas apoB colocalized with lipid droplets in the cytosolic compartment is prone to proteasomal degradation (27). As such, the colocalization of apoB and lipid droplets in the MK-886-treated cells indicates that inhibition of PPARα activity is unlikely to stabilize apoB but would rather subject the protein to degradation. Hence, we conclude that accumulation of apoB-100 in the MK-886-treated cells is a consequence of increased apoB synthesis from elevated apoB mRNA transcripts.
Accumulation of apoB in the hepatic ER induces ER stress.
SERCA is a critical enzyme involved in ER calcium metabolism. Inhibition of SERCA activity due to changes in lipid composition is a contributing factor to hepatic ER stress in obesity (8). Previously, our group had reported that accumulation of apoB-100 in hepatocytes is a causal factor in high-fat diet-induced hepatic ER stress (30). Here, we investigated whether accumulation of apoB alone was sufficient to inhibit SERCA mRNA expression. Using two McA-RH7777 cell lines that constitutively express either a COOH-terminal-truncated apoB construct (apoB-50WT) or an apoB mutant (apoB5–0N158–1496), which are more prone to protein misfolding and ER retention, we found that expression of SERCA mRNA was significantly reduced in the apoB-overexpressing cells compared with mock transfected cells (Fig. 4A). Analyzing the mRNA levels of SERCA in the livers of the experimental models, we found that either deletion of PPARα or high-fructose feeding suppressed hepatic transcription of SERCA mRNA in hepatocytes (Fig. 4, B and C). Analysis of ER stress biomarkers in the livers of PPAR−/− mice showed that deletion of PPARα significantly induced mRNA expression of C/EBP homologous protein (CHOP) and protein expression of the ER chaperones Grp94 and Grp78 compared with WT mice (Fig. 4, D and E). Phosphorylation of eIF2α was elevated without total eIF2α protein levels being changed (Fig. 4E). Increased CHOP mRNA level and phosphorylation of the eIF2α were also detected in livers of rats after 3 wk of high-fructose feeding (Fig. 4, F and G). Taken together, these data suggest that overproduction of apoB induced by defective PPARα signaling disturbs hepatic ER metabolic homeostasis.
Restoring PPARα signaling normalizes mitochondrial and ER homeostasis.
To investigate whether the restoration of PPARα activity using a PPARα agonist is able to rescue cells from both mitochondrial and ER stress, two groups of rats were fed either chow or fructose diet. Within each diet group, rats were treated with either vehicle (0.5% DMSO) or WY-14645 (6 mg/kg body wt ip) once every other day for 3 wk. At the end point, livers were isolated for analysis. Examining the mitochondrial stress marker HSP60, we noticed that expression of HSP60 protein was increased by ∼50% in the livers of fructose-fed rats compared with the chow diet group. Treating fructose-fed rats with WY-14643 reduced HSP60 expression by ∼40% (Fruc/WY vs. Fruc/Veh; Fig. 5A). Moreover, recovery of PPARα activity rescued hepatocytes from ER stress, as the expression of CHOP mRNA and phosphorylation of the c-Jun-NH2-terminal kinase (JNK) in the Fruc/WY group was reduced to a level comparable with the control group (Chow/Veh; Fig. 5, B and C). Phosphorylation of eIF2α was also significantly reduced in the WY-treated group (Fig. 5C). Ex vivo, incubation of primary rat hepatocytes with fructose (6 mM) in the presence or absence of WY-14643 for 48 h prevented the induction of GRP78 overexpression and phosphorylation of eIF2α compared with cells treated with fructose alone (Fig. 5D). These results demonstrate that recovery of PPARα activity protects hepatocytes from mitochondrial and ER stress.
Restoration of mitochondrial and ER homeostasis improves hepatic steatosis and alleviates systemic hyperlipidemia.
Restoration of PPARα signaling using the PPARα agonist WY-14643 inhibited expression of apoB-100 and apoB-48 by ∼75 and 50%, respectively, in the Fruc/WY group compared with the Fruc/Veh group (Fig. 6A), whereas expression of apoE remained unchanged or even slightly increased in the WY-14643-treated groups (Fig. 6A), suggesting a specific inhibitory effect of WY-14643 on apoB biosynthesis. Measurement of the lipid content in the livers of fructose-fed rats showed that treatment with WY-14643 improved hepatic lipid metabolism, which was evident by the significant decreases in hepatic triglyceride and cholesterol. (Fig. 6B). Additionally, Oil Red O staining of liver tissue sections revealed that there were only trace levels of lipid droplets in the livers of animals treated with the PPARα agonist Fruc/WY vs. Fruc/Veh (Fig. 6C). In parallel with the changes in lipid profile of the liver, plasma TG in the Fruc/WY group rats was reduced to a level comparable with that of control rats (Chow/Veh) (Fig. 6D). Of note is that rats remained free of hepatotoxicity with short-term treatment with WY-14643, as reflected by the absence of aspartate transaminase and alanine transaminase elevation in all four groups (data not shown). These data suggest that restoration of PPARα activity protects against hepatic steatosis induced by fructose and improves systemic hyperlipidemia.
DISCUSSION
Our goals in the present study were to characterize the role of PPARα in conveying hepatic lipid status to the mitochondria and ER as well as to determine the regulatory effect of PPARα on hepatic apoB biosynthesis during the onset of hepatic steatosis and hyperlipidemia. Over the past decade, ER stress induced by various pathogens has been well characterized as a central abnormality linking obesity, hepatic steatosis, and insulin resistance (22, 23). Here, we have demonstrated that impairment of PPARα signaling plays a role, at least partially, in the pathological metabolic stresses derived from certain lipogenic nutrients, particularly fructose.
The responses of PPARα to different dietary nutrients are distinct. Fatty acids, especially if polyunsaturated, are thought to be preferred PPARα ligands (7). Chronic consumption of a high-fat diet increases the rate of fatty acid catabolism in muscles by allowing overwhelming amounts of fatty acids to enter the mitochondria. A pharmaceutical inhibitor of CPT-1, which suppresses the hyperactive mitochondrial fatty acid β-oxidation, was able to reverse the diabetic symptoms of these animals. This study implicates mitochondrial lipid overload and increased fatty acid β-oxidation as the principal contributing factors to lipid-induced insulin resistance in skeletal muscle (14). In contrast, in the present study we found that fructose suppressed PPARα signaling, which is associated with the induction of mitochondrial and ER stress.
Fructose is a highly lipogenic sugar that has profound metabolic effects on various organs, including liver, adipose tissue, and the central nervous system. High fructose intake has been associated with many of the components of the metabolic syndrome, such as insulin resistance, elevated waist circumference, dyslipidemia, and hypertension. In contrast to glucose, consumption of fructose does not stimulate insulin secretion or require insulin for the initial steps of its hepatic metabolism. The rate of hepatic uptake of fructose from portal circulation is greater than the rate of glucose uptake, and because fructose metabolism bypasses phosphofructokinase, its metabolism is not under the regulatory control of insulin (6). The increased rate of fructose-induced de novo lipogenesis generates fatty acids that can then be incorporated into hepatic TG or other lipid species via increases in both the carbohydrate regulatory element-binding protein and sterol regulatory element-binding protein-1 activity (6). These, coupled with the lipid diverted from reduced mitochondrial fatty acid oxidation, lead to the accumulation of lipids in the livers of the PPARα−/− mice and fructose-fed rats. Increased hepatic lipid levels are associated with increased VLDL synthesis and secretion. apoB is essential for the intracellular assembly of TG into VLDL, and apoB degradation is reduced when hepatic lipid is increased, which leads to the accumulation of apoB in the hepatic ER and causes ER stress (30). Additionally, we demonstrated that impairment of PPARα signaling upregulates apoB expression at the transcriptional level. One of the potential mechanisms could be mediated by the eIF2α-activating transcription factor 4 (ATF4) pathway. Phosphorylation of eIF2α suppresses global protein synthesis by inhibiting delivery of the initiator Met-tRNAi to the initiation complex. However, phosphorylation of eIF2α also favors the translation of a selected number of mRNAs containing short upstream open reading frames (34). ATF4 is one of these proteins that plays a crucial role in adaptation to stresses by regulating the transcription of many genes (16, 33). A recent study has demonstrated that activation of ATF4 by PKR-like endoplasmic reticulum kinase upon ER stress is involved in the upregulation of hepatic VLDL receptor mRNA expression and the development of fatty liver disease (13). It is very likely that the induction of eIF2α phosphorylation in both PPARα-null mice and fructose-fed rats activates ATF4, which in turn enhances expression of apoB mRNA and protein. The potential regulatory effect of ATF4 and ATF6 on apoB biosynthesis and hepatic VLDL assembly is currently under investigation by our group.
Imbalance of ER lipid composition has been proposed to induce ER stress via inhibition of SERCA activity. Correcting the obesity-induced alteration of ER phospholipid composition or hepatic SERCA overexpression in vivo reduces chronic ER stress and improves glucose homeostasis (8). In this study, we showed that accumulation of apoB in the ER suppresses mRNA expression of SERCA, which could be one of the contributing factors to the induction of ER stress in the PPARα-defective animals. The biological activity of the ER is closely associated with the metabolic homeostasis of the mitochondria. Activation of JNK has been demonstrated to induce expression of CHOP and C/EBPβ, which in turn may stimulate transcription of the mitochondrial stress markers HSP60 and ClpP (12). Our study further demonstrated that both mitochondrial stress and ER stress are occurring in the PPARα-defective rodent models. Correction of PPARα signaling was able to prevent the induction of both mitochondrial and ER stress and reduce the biosynthesis of apoB to improve hyperlipidemia and hepatic steatosis associated with fructose consumption.
The identification of molecular links between PPARα and apoB and their involvement in cellular stress signaling unveils a novel role for PPARα in cellular stress response. It also reveals a novel mechanistic pathway whereby lipogenic nutrients such as fructose can induce hyperlipidemia and hepatic steatosis. Our findings suggest that pharmaceutical approaches aimed at modulating the status of PPARα may be of benefit in the treatment of the metabolic syndrome linked to excessive caloric intake.
GRANTS
This work was supported by an operating grant from the Heart and Stroke Foundation of Ontario to K. Adeli. Q. Su was supported by a Postdoctoral Research Fellowship from the Canadian Institutes of Health Research (CIHR). P. Christian is a recipient of the CIHR Strategic Training Program in Protein Folding and Interaction Dynamics Studentship from the University of Toronto.
DISCLOSURES
No conflicts of interest, financial or otherwise, are declared by the authors.
AUTHOR CONTRIBUTIONS
Q.S. and K.A. conception and design of research; Q.S., C.B., P.C., M.N., X.T., K.Z., and M.S. performed experiments; Q.S. and K.A. analyzed data; Q.S. and K.A. interpreted results of experiments; Q.S. prepared figures; Q.S. drafted manuscript; Q.S., C.B., P.C., M.N., and K.A. edited and revised manuscript; Q.S., K.Z., and K.A. approved final version of manuscript.
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