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Journal of Lipid Research, Vol. 44, 388-398, February 2003
Copyright © 2003 by Lipid Research, Inc.

Down-regulation of acyl-CoA oxidase gene expression and increased NF-B activity in etomoxir-induced cardiac hypertrophy

Àgatha Cabrero, Manuel Merlos, Juan C. Laguna and Manuel Vázquez Carrera¹

Unitat de Farmacologia, Departament de Farmacologia i Química Terapeùtica, Facultat de Farmàcia, Universitat de Barcelona, Spain

Published, JLR Papers in Press, November 4, 2002. DOI 10.1194/jlr.M200294-JLR200

¹ To whom correspondence should be addressed. e-mail: mvaz{at}farmacia.far.ub.es

	ABSTRACT

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Activation of nuclear factor-B (NF-B) is required for hypertrophic growth of cardiomyocytes. Etomoxir is an irreversible inhibitor of carnitine palmitoyltransferase I (CPT-I) that activates peroxisome proliferator-activated receptor (PPAR) and induces cardiac hypertrophy through an unknown mechanism. We studied the mRNA expression of genes involved in fatty acid oxidation in the heart of mice treated for 1 or 10 days with etomoxir (100 mg/kg/day). Etomoxir administration for 1 day significantly increased (4.4-fold induction) the mRNA expression of acyl-CoA oxidase (ACO), which catalyzes the rate-limiting step in peroxisomal ß-oxidation. In contrast, etomoxir treatment for 10 days dramatically decreased ACO mRNA levels by 96%. The reduction in ACO expression in the hearts of 10-day etomoxir-treated mice was accompanied by an increase in the mRNA expression of the antioxidant enzyme glutathione peroxidase and the cardiac marker of oxidative stress bax. Moreover, the activity of the redox-regulated transcription factor NF-B was increased in heart after 10 days of etomoxir treatment.

Overall, the findings here presented show that etomoxir treatment may induce cardiac hypertrophy via increased cellular oxidative stress and NF-B activation.

Abbreviations: ACO, acyl-CoA oxidase; COUP-TF II, chicken ovalbumin upstream promoter transcription factor II; CTE, cytosolic acyl-CoA thioesterase; GPX, glutathione peroxidase; MCAD, medium-chain acyl-CoA dehydrogenase; M-CPT-I, muscle-type carnitine palmitoyl-transferase; NF-B, nuclear factor B; PGC-1, PPAR coactivator 1; PPAR, peroxisome proliferator-activated receptor; PPRE, peroxisome proliferator response element; RXR, retinoid X receptor; UCP-3, uncoupling protein 3

Supplementary key words nuclear factor B • oxidative stress • PPAR • heart

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Energy demand of the heart depends on the oxidation of a variety of substrates, mainly fatty acids and glucose. This process is regulated during development and under various physiological and pathophysiological conditions depending on the substrate availability (1, 2). Thus, during the fetal period, cardiac metabolism relies on glucose, whereas after birth, myocardial energy increasingly switches from glucose to fatty acids oxidation, the latter being the major source of energy in the adult mammalian heart. In addition, during the development of cardiac hypertrophy in rodents and humans, a dramatic reduction in fatty acid oxidation is detected, since a shift in the source of energy is observed from fatty acids to glucose (1). The adjustments of cardiac metabolism to the substrate availability seem to involve changes in the transcriptional control of genes implicated in the transport and metabolism of fatty acids and glucose, which in turn are under the control of a class of transcription factors called peroxisome proliferator-activated receptors (PPARs). Three different PPAR subtypes (, /ß, and ) have been identified to date. PPAR is expressed primarily in tissues with a high level of fatty acid catabolism, such as liver, brown fat, kidney, heart, and skeletal muscle (3, 4). PPARß is ubiquitously expressed, and PPAR has a restricted pattern of expression, mainly in white and brown adipose tissues, whereas other tissues such as skeletal muscle and heart contain limited amounts (3). PPARs are activated by ligands, such as naturally occurring fatty acids, which are activators of all three PPAR subtypes (5, 6). In addition to fatty acids, several synthetic compounds, such as fibrates and thiazolidinediones, bind and activate specific PPAR subtypes. In order to be transcriptionaly active, PPARs need to heterodimerize with the retinoid X receptor (RXR). PPAR-RXR heterodimers bind to DNA-specific sequences called peroxisome proliferator response elements (PPREs), consisting of an imperfect direct repeat of the consensus binding site for nuclear hormone receptors (AGGTCA) separated by one nucleotide (DR-1). This direct repeat is known to bind potential competitors such as homodimers of other nuclear receptors including RXR, chicken ovalbumin upstream promoter transcription factor II (COUP-TF-II, also called apolipoprotein A-I regulatory protein, ARP-1), and hepatic nuclear factor-4 (HNF-4) (4).

It has been previously reported that development of pressure overload-induced ventricular hypertrophy in mice, which involves a shift in the substrate utilization from fatty acids to glucose, is associated with deactivation of PPAR (7, 8). Further, it has been shown that the energy substrate switch observed in cardiac hyperthrophy involves reactivation of fetal transcriptional control via members of the Sp and COUP-TF families of transcription factors (7). These changes may account for the down-regulation of enzymes involved in fatty acid oxidation. However, little is known about the effects of several drugs leading to cardiac hyperthrophy. In fact, several studies have shown that inhibition of mitochondrial ß-oxidation by carnitine palmitoyltransferase I (CPT-I) inhibitors, which were developed for the treatment of type 2 diabetes mellitus, is sufficient to cause cardiac hypertrophy (9). In order to delineate the molecular mechanisms involved in etomoxir-induced cardiac hypertrophy, we treated mice with this irreversible inhibitor of CPT-I. Treatment for 1 day with this drug, which in addition activates PPAR (10), resulted in a significant increase in the mRNA expression of acyl-CoA oxidase (ACO), the gene that catalyzes the rate-limiting step in peroxisomal ß-oxidation. In contrast, a dramatic reduction in ACO mRNA levels was observed after etomoxir administration for 10 days. On the other hand, the mRNA levels of PPAR, and of several of its target genes involved in mitochondrial ß-oxidation, were not significantly modified by etomoxir after 10 days of treatment. The fall in ACO expression after 10 days of etomoxir treatment was accompanied by increased activity of the redox-regulated transcription factor, nuclear factor B (NF-B). Overall, the results presented here suggest that etomoxir increases oxidative stress in cardiomyocytes, leading to NF-B activation, which is required for the hypertrophic growth of cardiomyocytes (11). The negative correlation in heart between enhanced oxidative stress and the reduction ACO expression suggests that peroxisomal ß-oxidation may be involved in cardiac hypertrophy after etomoxir treatment.

	MATERIALS AND METHODS

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Animals and treatment
Twenty male Swiss mice from Harlan (Barcelona, Spain) were used. They were maintained under standard conditions of illumination (12-h light/dark cycle) and temperature (21 ± 1°C) and fed a standard diet. The mice were randomly distributed into two groups. Each group was administered, respectively, either 0.5% carboximethyl cellulose (control group) or 100 mg/kg/day of etomoxir (dissolved in 0.5% carboximethyl cellulose) per os once a day for either 1 or 10 days (1 ml/100 g of body weight). Food and water were given ad libitum. Twenty-four hours after the last administration, mice were killed under pentobarbitone anesthesia to collect blood samples and to isolate hearts. Blood samples, obtained by cardiac puncture, were collected in EDTA tubes, and plasma was obtained by centrifugation at 2,200 g for 10 min at 4°C. Plasma glucose (Roche, Barcelona, Spain), triglycerides (Sigma), and nonesterified fatty acids (Wako, Germany) levels were determined with colorimetric test. Hearts were rapidly removed, washed in ice-cold 0.9% NaCl, frozen in liquid nitrogen, and stored at -80°C. Animal handling and disposal were performed in accordance with law 5/1995, 21st July, of the Generalitat de Catalunya.

RNA preparation and analysis
Total RNA was isolated by using the Ultraspec reagent (Biotecx, Houston). Relative levels of specific mRNAs were assessed by the reverse transcription-polymerase chain reaction (RT-PCR). cDNA was synthesized from RNA samples by mixing 0.5 µg of total RNA, 125 ng of random hexamers as primers in the presence of 50 mM Tris-HCl buffer (pH 8.3), 75 mM KCl, 3 mM MgCl₂, 10 mM dithiothreitol, 200 units of Moloney murine leukemia virus reverse transcriptase (Life Technologies), 20 units of RNAsin (Life Technologies), and 0.5 mM of each dNTP (Sigma) in a total volume of 20 µl. Samples were incubated at 37°C for 60 min. A 5 µl aliquot of the RT reaction was then used for subsequent PCR amplification with specific primers.

Each 25-µl PCR reaction contained 5 µl of the RT reaction, 1.2 mM MgCl₂, 200 µM dNTPs, 1.25 µCi [³²P]dATP (3,000 Ci/mmol, Amersham), 1 unit of Taq polymerase (Ecogen, Barcelona, Spain), 0.5 µg of each primer, and 20 mM Tris-HCl, pH 8.5. To avoid unspecific annealing, cDNA and Taq polymerase were separated from primers and dNTPs by using a layer of paraffin (reaction components contact only when paraffin fuses, at 60°C). The sequences of the sense and antisense primers used for amplification were: PPAR, 5'-GGCTCGGAGGGCTCTGTCATC-3' and 5'-ACATGCACTGGCAGCAGTGGA-3'; M-CPT-I, 5'-TTCACTGTGACCCCAGACGGG-3' and 5'-AATGGACCAGCCCCATGGAGA; MCAD, 5'-TCGAAAGCGGCTCACAAGCAG-3' and 5'-CACCGCAGCTTTCCGGAATGT-3'; UCP-3, 5'-GGAGCCATGGCAGTGACCTGT-3' and 5'-TGTGATGTTGGGCCAAGTCCC-3'; UCP-2, 5'-AACAGTTCTACACCAAGGGC-3' and 5'-AGCATGGTAAGGGCACAGTG-3'; ACO, 5'-ACTATATTTGGCCAATTTTGTG-3' and 5'-TGTGGCAGTGGTTTCCAAGCC-3'; CTE, 5'-CAGCCACCCCGAGGTAAAAGG-3' and 5'-CCTTGAGGCCATCCTTGGTCA-3'; RXR, 5'-GCTCTCCAACGGGTCGAGGCT-3' and 5'-TGGGTGTGGTGGGTACCGACA-3'; RXR, 5'-CCATGAAGACATGCCGGTGGA-5' and 5'-CCCGGTGCAGAATGACCTGGT-3'; PGC-1 5'-CCCGTGGATGAAGACGGATTG-3' and 5'-GTGGGTGTGGTTTGCTGCATG-3'; GPX, 5'-CGGCACAGTCCACCGTGTATG-3' and 5'-ACTGATTGCACGGGAAACCGA-3'; BAX, 5'-GGCCCACCAGCTCTGAACAGA-3' and 5'-AGCTGCCACCCGGAAGAAGAC-3'; and adenosyl phosphoribosyl transferase (APRT), 5'-AGCTTCCCGGACTTCCCCATC-3' and 5'-GACCACTTTCTGCCCCGGTTC-3'. PCR was performed in an MJ Research Thermocycler equipped with a peltier system and temperature probe. After an initial denaturation for 1 min at 94°C, PCR was performed for 20 (MCAD), 22 (GPX), 23 (UCP-2, PGC-1), 25 (UCP-3, PPAR, BAX), 26 (RXR and RXR), 27 (CTE), and 28 (M-CPT-I, ACO) cycles. Each cycle consisted of denaturation at 92°C for 1 min, primer annealing at 60°C (except 58°C for ACO), and primer extension at 72°C for 1 min and 50 s. A final 5-min extension step at 72°C was performed. Five microliters of each PCR sample was electrophoresed on a 1 mm thick 5% polyacrylamide gel. The gels were dried and subjected to autoradiography using Kodak X-ray films to show the amplified DNA products. Amplification of each gene yielded a single band of the expected size (PPAR: 645 bp; M-CPT-I: 222 bp; MCAD: 216 bp; UCP-3: 179 bp; UCP-2: 471 bp; ACO: 195 bp; CTE: 224 bp; RXR: 202 bp; RXR: 220 bp; PGC-1: 228 bp; GPX: 210 bp; BAX: 256 bp; and APRT: 329 bp). Preliminary experiments were carried out with varying amounts of cDNA to determine nonsaturating conditions of PCR amplification for all the genes studied. Therefore, under these conditions, relative quantification of mRNA was assessed by the RT-PCR method used in this study (12). Radioactive bands were quantified by videodensitometric scanning (Vilbert Lourmat Imaging). The results for the expression of specific mRNAs are always presented relative to the expression of the control gene (aprt).

Isolation of nuclear extracts
Crude nuclear extracts were isolated using the Dignam method (13) with the modifications described by Helenius et al. (14). Frozen hearts were weighed, transferred to Corning tubes, and ice-cold hypotonic buffer (1.5 mM MgCl₂, 10 mM KCl, 0.2 mM PMSF, 0.5 mM DTT, 10 mM HEPES, pH 7.9) was added to each sample. The volume was proportional to the weight of the tissue so as to give 15% homogenates. The tissues were left to thaw in an ice bath and homogenized (2 x 5 s) using a Polytron (Kinematica, Germany). Homogenates were incubated for 10 min on ice and centrifuged (25,000 g, 15 min, 4°C). Pellets were washed once with the same volume of hypotonic buffer used in the homogenization step and centrifuged (10,000 g, 4°C, 15 min). Supernatants were discarded and pellets were suspended in ice-cold low salt buffer (25% glycerol, 1.5 mM MgCl₂, 0.2 mM EDTA, 0.2 mM PMSF, 0.5 mM DTT, 20 mM KCl, 20 mM Hepes, pH 7.9) using half of the volume of the hypotonic buffer. Nuclear proteins were released by adding high-salt buffer (25% glycerol, 1.5 mM MgCl₂, 0.2 mM EDTA, 0.2 mM PMSF, 0.5 mM DTT, 1.2 M KCl, 20 mM Hepes, pH 7.9) drop-by-drop using half of the volume of the low-salt buffer. Samples were incubated on ice for 30 min. During incubation, the tubes were smoothly mixed frequently. Samples were centrifuged (25,000 g, 30 min, 4°C), and supernatants were collected in microfuge tubes and stored in aliquots at -80°C. The protein concentration of the nuclear extracts was then measured.

Electrophoretic mobility shift assays
Electrophoretic mobility shift assays (EMSAs) were performed using double-stranded oligonucleotides (Santa Cruz Biotechnology) for the consensus binding sites of PPRE (5'-CAAAACTAGGTCAAAGGTCA-3'), mutant PPRE (5'-CAAAACTAGCACAAAGCACA-3'), Sp1 (5'-ATTCGATCGGGGCGGGGCGAGC-3'), and Oct-1 (5'-TGTCGAATGCAAATCACTAGAA-3'). The NF-B consensus oligonucleotide (5'AGTTGAGGGGACTTTCCCAGGC-3') was from Promega. Oligonucleotides were labeled in the following reaction: 1 µl of oligonucleotide (20 ng/µl), 2 µl of 5x kinase buffer, 5 units of T4 polynucleotide kinase, and 3 µl of [-³²P]ATP (3,000 Ci/mmol at 10 mCi/ml) incubated at 37°C for 1 h. The reaction was stopped by adding 90 µl of TE buffer (10 mM Tris-HCl pH 7.4 and 1 mM EDTA). To separate the labeled probe from the unbound ATP, the reaction mixture was eluted in a Nick column (Pharmacia) according to the manufacturer's instructions. Eight micrograms of crude nuclear proteins were incubated for 15 min on ice in binding buffer [10 mM Tris-HCl pH 8.0, 25 mM KCl, 0.5 mM DTT, 0.1 mM EDTA pH 8.0, 5% glycerol, 5 mg/ml BSA, 100 µg/ml tRNA, and 50 µg/ml poly(dI-dC)], in a final volume of 15 µl. Labeled probe (50,000 cpm) was added and the reaction was incubated for 20 min at room temperature. Where indicated, specific competitor oligonucleotide was added before the addition of labeled probe and incubated for 10 min on ice. For supershift assays, antibodies were added after incubation with labeled probe for a further 30 min at room temperature. Protein-DNA complexes were resolved by electrophoresis at 4°C on a 5% acrylamide gel and subjected to autoradiography. Antibodies against COUP-TF II and p65 were from Santa Cruz Biotechnology.

Western-blot analysis
Crude nuclear extracts (40 µg) from hearts were subjected to 10% SDS-polyacrylamide gel electrophoresis. Proteins were then transferred to Immobilon polyvinylidene fluoride transfer membranes (Millipore), and immunological detection was performed using a goat polyclonal antibody raised against COUP-TF II (dilution 1:1,000). Detection was achieved using the enhanced chemiluminiscence (ECL) detection system (Amersham). Blots were also incubated with a rabbit antibody against ß-tubulin (dilution 1:5,000) (Boehringer Mannheim), used as a control of equal abundance of nuclear extracts in the samples. Size of detected proteins was estimated using protein molecular mass standards (Life Technologies).

Statistical analyses
Results are expressed as means ± SD of four or five mice. Significant differences were established by Student's t-test using the computer program GraphPad Instat.

	RESULTS

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Effects of etomoxir in cardiac hypertrophy
First, we investigated the effect of the CPT-I inhibitor etomoxir on the ratio of heart weight to body weight of mice to assess cardiac hypertrophy. Etomoxir administration (100 mg/kg/day) to mice for 1 day did not cause cardiac hypertrophy. In contrast, 10 days of etomoxir treatment resulted in a significant increase in both the net heart weight (20%) and the ratio of heart weight to body weight (24%) compared with the control group, indicating the presence of cardiac hypertrophy (Table 1). On the other hand, we assessed the effects of etomoxir on plasma glucose levels. In the nonfasted normoglycemic mice used in this study, drug treatment did not modify glucose levels compared with the control group.

View larger version (62K): [in this window] [in a new window]   Fig. 1. Effects of etomoxir (100 mg/kg/day) for either 1 (A) or10 days (B) on the expression of ACO, MCAD, CTE, M-CPT-I, UCP-3, UCP-2, and PPAR mRNA levels in heart. A representative autoradiogram and the quantification of the APRT-normalized mRNA levels are shown. Data are expressed as mean ± SD of four or five mice. * P < 0.05 compared with control experiments. Exposition times for ACO mRNA levels were adjusted in order to better observe differences caused by drug treatment on days 1 and 10.

Effects of etomoxir treatment for 10 days on RXR and PPAR coactivator 1 mRNA levels in heart
The induction of PPAR-target genes, such as ACO and MCAD, by PPAR activators is reduced in livers of RXR-deficient mice (21). Therefore, in order to study whether reduced availability of the PPAR heterodimeric partner RXR was responsible for the reduced transcriptional activity of the ACO gene in 10-days etomoxir-treated mice, we determined the transcript levels of RXR and RXR. Etomoxir treatment for 10 days did not modify the mRNA expression of these transcription factors in heart compared with control mice (Fig. 2) . In addition, we studied the mRNA expression of PPAR coactivator 1 (PGC-1), which directly interacts with PPAR and has been postulated as a regulator of mitochondrial ß-oxidation (22). PGC-1 mRNA was not altered in the heart of 10-days etomoxir-treated mice. All these findings make unlikely a role for RXR and PGC-1 in the changes observed after etomoxir treatment for 10 days.

View larger version (41K): [in this window] [in a new window]   Fig. 2. Effects of etomoxir (100 mg/kg/day) for 10 days on the expression of RXR, RXR, and PGC-1 mRNA levels in heart. A representative autoradiogram and the quantification of the APRT-normalized mRNA levels are shown. Data are expressed as mean ± SD of four or five mice. * P < 0.05 compared with control experiments.

View larger version (48K): [in this window] [in a new window]   Fig. 3. Binding of cardiac nuclear proteins to a peroxisome proliferator response element (PPRE) probe is induced by etomoxir treatment for 10 days but not for 1 day. A: Autoradiograph of EMSA performed with a 32P-labeled PPRE nucleotide and crude nuclear protein extract (NE) shows four specific complexes (I to IV) based on competition with a molar excess of unlabeled probe but not by an equivalent amount of a mutant PPRE oligonucleotide (NSP). Autoradiograph of EMSA performed with a 32P-labeled PPRE nucleotide and NE from hearts of control and etomoxir-treated mice for 1 (B) or 10 days (C). Exposition times were adjusted in order to better observe differences caused by drug treatment on days 1 and 10. D: Autoradiograph of EMSA performed with a 32P-labeled Oct-1 nucleotide.

View larger version (44K): [in this window] [in a new window]   Fig. 4. Binding of cardiac nuclear proteins to an Sp1 probe is induced by etomoxir treatment for 10 days. Autoradiograph of EMSA performed with a 32P-labeled Sp1 nucleotide and crude nuclear protein extract (NE) from hearts of control mice and etomoxir-treated mice for 10 days. When indicated, a 20-fold molar excess of either specific unlabeled (SP) Sp1 oligonucleotide was included.

View larger version (14K): [in this window] [in a new window]   Fig. 5. Cardiac nuclear levels of COUP-TF II are increased in hearts of etomoxir treated mice for 10 days but not for 1 day. A representative autoradiograph of a Western blot performed with 40 µg of cardiac crude nuclear protein extract from etomoxir-treated mice for 1 (A) or 10 days (B). Protein mass markers are displayed on the right in kilodaltons (kDa). ß-tubulin levels are shown as a control of equal abundance of nuclear extracts in the samples.

View larger version (47K): [in this window] [in a new window]   Fig. 6. Identification of COUP-TF II in cardiac nuclear proteins complexes by antibody recognition experiments. The autoradiograph depicted represents EMSA antibody recognition studies performed with a PPRE probe and anti-COUP-TF II antibody (Ab). Cardiac nuclear proteins from control and 10 days etomoxir-treated mice were used. The positions of the supershifted immune complexes are indicated.

View larger version (17K): [in this window] [in a new window]   Fig. 7. Effects of etomoxir (100 mg/kg/day) for 10 days on the expression of GPX and bax mRNA levels in heart. A representative autoradiogram and the quantification of the APRT-normalized mRNA levels are shown. Data are expressed as mean ± SD of four or five mice. * P < 0.05 compared with control experiments.

NF-B activity is increased in hearts from 10-day etomoxir-treated mice

View larger version (42K): [in this window] [in a new window]   Fig. 8. Nuclear NF-B activity is reduced in hearts from 1-day etomoxir-treated mice but it is increased in 10-day etomoxir-treated mice. A: Autoradiograph of EMSA performed with a 32P-labeled NF-B nucleotide and crude nuclear protein extract (NE) shows three specific complexes (I to III), based on competition with a molar excess of unlabeled probe from etomoxir-treated mice for 10 days. Autoradiograph of EMSA performed with a 32P-labeled NF-B nucleotide and NE from hearts of control and etomoxir-treated mice for 1 (B) or 10 (C) days. When indicated, cardiac nuclear extracts were incubated with an antibody recognizing the NF-B subunit p65. Supershifted immune complex (IC) is denoted.

	DISCUSSION

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In the present work, etomoxir administration to mice for 10 days resulted in cardiac hypertrophy, as previously reported (33). However, the cardiac hypertrophy, achieved after 10 days of etomoxir treatment (24% increase in the ratio of heart weight to body weight) should be considered in its initial stage, since it has been reported that longer treatments at the same dose do not always result in cardiac hypertrophy (33). In addition, other models of cardiac hypertrophy, such as the pressure overload-induced cardiac hypertrophy, may induce a rapid and higher degree of hypertrophy, achieving a 39% increase in the ratio of left ventricle to body weight (34). In the etomoxir-induced cardiac hypertrophy model used in this work, ACO mRNA levels were nearly abolished, whereas the expression of either PPARs or several of their target genes, such as M-CPT-I, MCAD, or UCP-3, were not affected. In contrast, in hearts of 1-day etomoxir-treated mice, a high increase in ACO mRNA levels was observed compared with control animals. The effects of 1-day etomoxir treatment on ACO expression in heart are in agreement with those reported by Djouadi et al. (15). They showed the effects of etomoxir (50 mg/kg/day) administration for either 1 or 5 days on ACO and MCAD mRNA levels in heart. ACO mRNA levels increased 4.5-fold after 1 day of treatment and 2-fold after 5 days, showing a tendency to decrease, whereas MCAD mRNA levels only increased (2-fold) after 5 days of treatment. Therefore, in short treatments (1–5 days), when cardiac hypertrophy is not present, etomoxir activates PPAR in heart, which results in an increase in the expression of PPAR target genes. The mechanism by which inhibitors of CPT-I, such as etomoxir, activate PPAR includes direct binding to this receptor (10), and, indirectly, as metabolic inhibitors, may lead to the accumulation of endogenous fatty acid ligands. In contrast, in longer treatments leading to cardiac hypertrophy, the expression of ACO mRNA levels falls, whereas the induction of PPAR target genes involved in mitochondrial ß-oxidation is abolished, without changes in PPAR mRNA levels.

The data presented here do not establish the mechanisms involved in ACO down-regulation in heart after etomoxir treatment. It is likely that the enhanced sensitivity to insulin caused by etomoxir may contribute to the reduction in ACO expression without affecting other PPAR-target genes. This is supported by the fact that peroxisomal fatty acid oxidation is inhibited at a much lower insulin concentration than is mitochondrial oxidation (35).

Interestingly, in this study we show that etomoxir treatment results in increased cardiac oxidative stress. This finding is in agreement with previous results reported by our group in C2C12 skeletal muscle cells (36). Several factors may be involved in increased oxidative stress after etomoxir treatment. Thus, inhibition of CPT-I by etomoxir prevents the entrance of palmitoyl-CoA into mitochondria, leading to its accumulation in the cytoplasm. Because palmitoyl-CoA is a precursor of sphingolipid synthesis, etomoxir treatment may result in enhanced ceramide synthesis and apoptosis (37). However, we have demonstrated that ceramides do not cause apoptosis in C2C12 skeletal muscle cells after etomoxir treatment (36). In addition, increased CTE mRNA levels in hearts of 10-days etomoxir-treated mice may reduce the accumulation of fatty acyl-CoA in cardiomyocytes. Here we show that down-regulation of ACO, the rate-limiting step of the peroxisomal ß-oxidation system correlates with enhanced cardiac oxidative stress, suggesting that it may be involved. Peroxisomal ß-oxidation is implicated in the degradation of proinflammatory molecules such as leukotriene B4 and 8(S)-hydroxyeicosatetraenoic acid. Leukotriene B4 is a potent chemoattractant that induces ROS generation (38). Therefore, it is likely that reduced degradation of these agents in 10-days etomoxir-treated mice may lead to an increased inflammatory response that generates ROS. In agreement with this, the ACO knockout mouse presented elevated levels of H₂O₂ in liver (39). In this study we show that when ACO mRNA levels are down-regulated, GPX mRNA levels are increased, suggesting increased H₂O₂ levels. In fact, it has been reported that GPX mRNA levels increase in skeletal muscle cells treated with H₂O₂ (24). Elimination of H₂O₂ is critical to protect heart tissue against oxidative stress, because superoxide is converted to H₂O₂ by superoxide dismutase, and in the presence of cardiac myocytes, H₂O₂ forms hydroxyl radical, one of the most toxic oxygen free radicals. In the myocardium, GPX plays a predominant role in the scavenging of H₂O₂, given that catalase, the other major H₂O₂-scavenging enzyme, shows a very low activity (40). The induction in the transcript levels of bax also correlates with ACO down-regulation and suggests that apoptotic levels of oxidative stress are reached in etomoxir-treated hearts. It is important to note that NF-B and apoptosis signal-regulating kinase 1 (ASK1) have been recently involved in the cardiomyocyte hypertrophy induced by G-protein-coupled receptor agonist (41). Interestingly, H₂O₂ induces dimerization or oligomerization of ASK1 and activates its kinase activity (42), supporting a role for H₂O₂ as a mediator of cardiac hypertrophy.

It is well known that cellular activation of PPARs has been demonstrated to antagonize the activity of NF-B (4), probably through competition by limiting amounts of essential transcription coactivators such as CBP/p300 or SRC-1. Therefore, PPAR activation by etomoxir can explain the reduction in NF-B binding activity in cardiac nuclear extracts after 1 day of treatment. However, NF-B binding activity in cardiac nuclear extracts was increased after 10 days of treatment. The data here presented indicate that after 10 days of etomoxir treatment, an increase in oxidative cellular stress appears in cardiomyocytes, resulting in NF-B activation. Therefore, treatment for 10 days with etomoxir results in NF-B activation in heart, similar to the effects attained by peroxisome proliferators in liver (43–45).

Further, in the present study we show that etomoxir treatment results in a strong increase in the protein levels of the PPAR-transcriptional repressor, COUP-TF II. According to previous studies (46, 47), the mechanism by which COUP-TF antagonizes PPAR signaling involves competitive occupation of the DR-1 present in the PPRE. However, we were unable to show increased binding of COUP- TF to the PPRE cis-element, making unlikely a role for this transcription factor in the effects caused by etomoxir. This idea is supported by the different effects observed after etomoxir treatment in ACO and MCAD genes. The expression of the former was nearly abolished by etomoxir, whereas the second was not modified by the treatment, although it has been reported that MCAD down-regulation in hypertrophied hearts through COUP-TF (7). The mechanism involved in the increased nuclear levels of COUP-TF II is unknown, but it has been speculated that a post-translational modification such as phosphorylation could be implicated (48). It is noteworthy that inhibition of CPT-I by etomoxir leads to accumulation of fatty acyl-CoA derivatives, which have been implicated in the regulation of the activity of several kinases (49), affording a possible explanation for the increase in COUP-TF II levels.

Previous studies performed in the pressure overload-induced hypertrophy mouse heart have proposed a role for the Sp family of transcription factors in cardiac hypertrophy (7). In the present study, the binding of cardiac nuclear proteins to an Sp1 probe was increased in etomoxir-treated mice compared with control mice, suggesting that Sp1 or proteins competing for Sp1 binding sites (such as early growth response-1 gene, egr-1) are also involved in cardiac hypertrophy induced by etomoxir. The role of the Sp family transcription factors in cardiac hypertrophy is not well characterized. They usually act as transcriptional activators, but in addition, they may repress gene expression in a promoter context-dependent manner (50, 51). Further, the presence of several Sp binding sites in the promoter region of M-CPT-I, MCAD (7), and PPAR genes (52) suggests a role for Sp proteins in the coordinate regulation of genes involved in cardiac fatty acid oxidation.

In summary, we have shown increased cellular oxidative stress and NF-B activity in hearts of etomoxir-treated mice. It remains to study whether the increase in cellular oxidative stress in cardiomyocytes occurs as a result of ACO down-regulation.

	ACKNOWLEDGMENTS

 
We thank the Language Advisory Service of the University of Barcelona for helpful assistance. This study was partly supported by grants from the FPCNL, Ministerio de Ciencia y Tecnología of Spain (SAF00-0201), and FIS (00/1124). We also thank the Generalitat de Catalunya for grants 1998SGR-33 and 2000SGR-45. À.C. was supported by a grant from the Ministerio de Educación of Spain.

Manuscript received July 26, 2002 and in revised form October 15, 2002.

	REFERENCES

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

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