Characterization of the 70-kDa Peroxisomal Membrane Protein, an ATP Binding Cassette Transporter*

Tsuneo ImanakaDagger §, Kazutoshi AiharaDagger , Tatsuya Takano, Atsushi Yamashitaparallel , Ryuichiro Sato**, Yasuyuki SuzukiDagger Dagger , Sadaki Yokota§§, and Takashi Osumi¶¶

From the Dagger  Department of Biological Chemistry, Faculty of Pharmaceutical Sciences, Toyama Medical and Pharmaceutical University, 2630 Sugitani, Toyama 930-0194,  Departments of Microbiology and Molecular Pathology and parallel  Hygienic Chemistry and Nutrition, Faculty of Pharmaceutical Sciences, Teikyo University, Sagamiko, Kanagawa 199-0145, ** Laboratory of Biochemistry and Molecular Biology, Graduate School of Pharmaceutical Sciences, Osaka University, Suita, Osaka 565-0871, Dagger Dagger  Department of Pediatrics, Gifu University School of Medicine, Tsukasa, Gifu 500-8076, §§ Biological Laboratory, Yamanashi Medical University, Tamaho, Yamanashi 490-3898, and ¶¶ Department of Life Science, Himeji Institute of Technology, Kamigori, Hyogo 678-1297, Japan

    ABSTRACT
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INTRODUCTION
EXPERIMENTAL PROCEDURES
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The 70-kDa peroxisomal membrane protein (PMP70) is one of the major components of rat liver peroxisomal membranes and belongs to a superfamily of proteins known as ATP binding cassette transporters. PMP70 is markedly induced by administration of hypolipidemic agents in parallel with peroxisome proliferation and induction of peroxisomal fatty acid beta -oxidation enzymes. To characterize the role of PMP70 in biogenesis and function of peroxisomes, we transfected the cDNA of rat PMP70 into Chinese hamster ovary cells and established cell lines stably expressing PMP70. The content of PMP70 in the transfectants increased about 5-fold when compared with the control cells. A subcellular fractionation study showed that overexpressed PMP70 was enriched in peroxisomes. This peroxisomal localization was confirmed by immunofluorescence and immunoelectron microscopy. The number of immuno-gold particles corresponding to PMP70 on peroxisomes increased markedly in the transfectants, but the size and the number of peroxisomes were essentially the same in both the transfectants and the control cells. beta -Oxidation of palmitic acid increased about 2-3-fold in the transfectants, whereas the oxidation of lignoceric acid decreased about 30-40%. When intact peroxisomes prepared from both the cell lines were incubated with palmitoyl-CoA, oxidation was stimulated with ATP, but the degree of the stimulation was higher in the transfectants than in the control cells. Furthermore, we established three Chinese hamster ovary cell lines stably expressing mutant PMP70. In these cells, beta -oxidation of palmitic acid decreased markedly. These results suggest that PMP70 is involved in metabolic transport of long chain acyl-CoA across peroxisomal membranes and that increase of PMP70 is not associated with proliferation of peroxisomes.

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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
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DISCUSSION
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Peroxisomes are organelles bounded by a single membrane that are present in almost all eukaryotic cells. The peroxisomes are involved in a variety of metabolic processes including peroxide-based respiration, oxidative degradation of fatty acids and purine, and synthesis of plasmalogen and bile acids (1). Early studies on rat liver peroxisomes led to the concept that peroxisomes are freely permeable to compounds of low molecular weight (2, 3). However, Van Roermund et al. (4) suggested recently that some metabolites were unable to permeate the membrane of peroxisomes in Saccharomyces cerevisiae. The peroxisomal membrane in human fibroblasts has been also shown not to be freely permeable to at least one of the substrates of acyl-CoA:dihydroxyacetonephosphate acyltransferase, unless ATP is present (5). Therefore, the exchange of metabolites between peroxisomes and cytosol seems to require specific transporters.

The 70-kDa peroxisomal membrane protein (PMP70)1 is a major component of peroxisomal membranes and markedly induced by the administration of hypolipidemic agents, and its induction parallels peroxisome proliferation and induction of peroxisomal beta -oxidation enzymes (6, 7). We cloned and sequenced rat PMP70 and found that it was an ATP binding cassette (ABC) transporter (8). ABC transporters are a superfamily of membrane-bound proteins whose structure and function have been highly conserved from eubacteria to mammals and catalyze the ATP-dependent transmembrane translocation of a wide variety of substrates, including anti-tumor drugs and several kind of lipids (9, 10). They are composed of two homologous halves, each containing the following two parts: a domain containing six potential transmembrane segments and an ATP binding domain, which contains a particular type of nucleotide binding fold. PMP70 is half the size of an ABC transporter and seems to function as a dimer.

To date, four peroxisomal ABC transporters have been identified in mammalian peroxisomes: PMP70 (8, 11, 12), adrenoleukodystrophy protein (ALDP) (13), ALDP-related protein (ALDRP) (14, 15), and PMP70-related protein (P70R/PMP69) (16, 17). A defect in ALDP is known to be responsible for the X chromosome-linked neurodegeneration disorder adrenoleukodystrophy; this defect is an inborn error of peroxisomal beta -oxidation of very long chain fatty acids (18, 19). Mutations in the PMP70 gene have been identified in one complementation group (group 1) of Zellweger syndrome, an inborn error of peroxisome biogenesis, and it is suggested that PMP70 has an important role in peroxisome assembly (12). However, a recent study of complementation group 1 probands by Southern blotting and single-strand conformation polymorphism (SSCP) of reverse transcription-PCR fragments failed to detect PMP70 mutations (20). Therefore, it is not clear whether PMP70 is associated with biogenesis of peroxisomes. On the other hand, the fact that inducibility of PMP70 parallels peroxisome proliferation and induction of peroxisomal beta -oxidation enzymes suggests that PMP70 participates in proliferation of peroxisomal membranes and/or transport of substrates for peroxisomal beta -oxidation enzymes.

As an approach to determining the role of PMP70 in peroxisome assembly and function, we isolated CHO cells stably overexpressing PMP70 and its mutant forms. We found that PMP70 is involved in metabolic transport of long chain acyl-CoA across the peroxisomal membrane and is not required for proliferation of peroxisomes or peroxisome biogenesis.

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Materials-- 125I-Protein A (2.60-3.70 TBq/g), [1-14C]palmitic acid (1.85 GBq/mmol), [1-14C]lignoceric acid (1.92 GBq/mmol), and [1-14C]palmitoyl-CoA (1.46-2.22GBq/mmol) were purchased from ICN Biochemicals Inc. (Irvine, CA), Moravek Biochemicals Inc. (Brea, CA), CEA (Gif-Sur-Yvette, France), and NEN Life Science Products, respectively. Palmitoyl-CoA, coenzyme A, NAD+, and dithiothreitol were obtained from Sigma. Preparation of antibodies against the C-terminal 15 amino acids of rat PMP70 was as described in (21). Anti-rat liver catalase antibodies were raised in guinea pigs (22), and anti-rat liver acyl-CoA oxidase antibodies were raised in rabbits (23). Other reagents were of analytical grade.

Construction of PMP70 Expression Vector-- The plasmid pTZ18U/PMP70 in which the rat cDNA sequence encoding PMP70 was cloned into the EcoRI and HindIII sites of pTZ18U was described in (21). From this cDNA, a fragment containing the first 1971 bases of PMP70 was excised with EcoRI and recloned into pBluescript KS(+) at the EcoRI site. This was cut with HpaI and PstI, and the linear plasmid containing the N-terminal 35% of PMP70 was purified by agarose gel electrophoresis. A 1.3-kilobase fragment containing the C-terminal 65% of PMP70 was then excised from pTZ18U/PMP70 with HapI and EcoT22I and purified. The fragment was ligated into HapI and PstI sites of the above plasmid, encoding the N-terminal 35% of PMP70 and the construct designated pBluescriptKS(+)/PMP70. The pBluescript KS(+)/PMP70 was cut with XhoI and XbaI, and a 2.1-kilobase fragment encoding the full-length of PMP70 was subcloned into XhoI and XbaI sites of expression vector pME18S (24), which was then designated as pME18S/PMP70.

Construction of Mutant cDNAs-- A mutant version of PMP70 containing mutations in EAA-like motif, designated as PMP70 (E277D/E278D), was constructed by asymmetric PCR using pME18S/PMP70 as a template. Two oligonucleotides (the site of substitution is underlined), with 5'-660AAGCCATTTTTAGACATAGTTTTGTA685-3' and 5'-875GGCAATTTCTTCACTATTAGTAGTAAGCCG846-3' were used in the first step, and a 220-bp fragment was generated by PCR. The fragment and an oligonucleotide, 5'-1075TGAAGGTGTCGCGGATGCGCCAGGTC1050-3' was used in the second step, and a 400-base pair fragment generated by PCR was purified and digested with HpaI and KpnI. The fragment containing the mutations of E277D and E278D was ligated into the HpaI-KpnI sites of pME18S/PMP70. Another version containing a mutation in Walker A motif, designated as PMP70 (K479A), was constructed with QuikChangeTM site-directed mutagenesis kit (Stratagene) using pME18S/PMP70 as a template. Two oligonucleotides with substitution sites and a new restriction site of 1468NarI, 5'-1445CATTTGTGGTCCAAATGGCTGTGGCGCCAGCTCCCTCTTC1484-3' and 5'-1484GAAGAGGGAGCTGGCGCCACAGCCATTTGGACCACAAATG1445-3' were used. A deletion construct of PMP70 containing amino acids 1-575, designated PMP70(1-575), was made as follows. A mutation was generated by PCR with two oligonucleotides: 5'-660AAGCCATTTTTAGACATAGTTTTGTA685-3' and 5'-TTGGAAGCTTGAATTC-1763TCATTCTCCTCCGCTGAGT1745-3', using pTZ18U/PMP70 as template. The sequence of 5'-TTGGAAGCTTGAATTC-1763TCA-3' contained new restriction sites EcoRI and HindIII. The PCR-generated fragment of about 1.1-kilobases containing a termination codon and the new restriction sites was digested with HindIII and inserted into HindIII site of pTZ18U/PMP70. The plasmid was then digested with EcoRI and inserted into EcoRI site of pME18S/PMP70. The mutation in each construct was confirmed by DNA sequencing.

Transfection of PMP70 cDNAs and Selection of Cells Overexpressing PMP70-- Expression plasmids were stably transfected into CHO cells. CHO cells were cultured with Ham's F-12 medium (100 units/ml penicillin and 100 µg/ml streptomycin) and transfected with 5.0 µg of pME18S/PMP70 plus 0.5 µg of pSVneo, which had been mixed with Transfectam® (Promega). The procedure was essentially the same as described (25). Surviving isolated colonies were picked up by cylinder technique and subjected to immunoblot analysis of PMP70. Cells overexpressing PMP70 were further purified by repeating the limited dilution twice. The same procedure was carried out to obtain cells overexpressing mutant PMP70.

Subcellular Fractionation of CHO Cells-- CHO cells were grown with Ham's F-12 medium containing 10%(v/v) fetal calf serum and cell homogenate and a postnuclear supernatant fraction were prepared with the same procedure described (21). Then a fraction combining both heavy and light mitochondrial fractions was obtained by centrifugation at 16,000 × g for 20 min. This fraction (~10 mg of protein in 0.5 ml) was further subjected to equilibrium density centrifugation in a 10.6-ml linear sucrose gradient (1.10-1.20 g/ml) in a Hitachi RP55VF rotor. The gradient rested on 1.0 ml of 1.25 g/ml sucrose. All solutions contained 1 mM EDTA, 3 mM imidazole, and 0.1%(v/v) ethanol. Centrifugation was carried out at 50,000 rpm (193,000 × g) for 90 min at 4 °C. Fractions of approximately 1.0 ml were collected in preweighed Eppendorf tubes, and the density of each fraction was determined by refractometry.

Immunofluorescence-- CHO cells were seeded on LAB-TEK®II Chamber SlideTM System that mounted 4 chambers on a glass slide (Nalge Nunc) in Ham's F-12 medium with 10%(v/v) fetal calf serum. After 18-24 h, the medium was replaced by a serum-free medium, and the culture was continued for an additional 15-18 h (22). Immunostaining microscopy was performed as described (26).

Immunoelectron Microscopy-- CHO cells were fixed with 4%(w/v) paraformaldehyde, 0.2%(w/v) glutaraldehyde in 0.15 M cacodylate buffer, pH 7.4, for 1 h at room temperature. After washing with phosphate-buffered saline, the cells were dehydrated with graded dimethylformamide at -20 °C and embedded in LR White. Polymerization of the resin was performed under UV light at -20 °C for 24 h. Thin sections were cut with a diamond knife equipped with a Ultramicrotome (Amersham Pharmacia Biotech). Catalase was visualized by combination of guinea pig anti-catalase with a 15-nm protein A-gold probe applied to one side of the thin sections, and PMP70 was detected by rabbit anti-PMP70 antibody with a 3-nm protein A-gold probe applied to another side of the sections.

beta -Oxidation Assay in Cultured Cells-- beta -Oxidation assay was done essentially as described (27). The cells cultured in 6-well flasks were preincubated for 1 h in Ham's F-12 medium without fetal calf serum. Fatty acid oxidation reaction was initiated by adding 4 nmol of [1-14C]palmitic acid or 4 nmol of [1-14C]lignoceric acid to the freshly prepared Ham's F-12 medium without fetal calf serum. Radioactive palmitic and lignoceric acid dissolved in ethanol was evaporated under a stream of nitrogen and dissolved in a solution of 0.1 M Tris-HCl, pH 8.0, containing 10 mM alpha -cyclodextrin. After incubation for 0-120 min, the dishes were placed on ice, 0.15 ml of 10%(w/v) bovine serum albumin and 0.2 ml of 3 M perchloric acid were added to the medium, and the preparation was incubated for 30 min on ice. The medium was centrifuged, and the unreacted fatty acids in the supernatant were removed by extraction 3 times with 3 ml of hexane. The acid-soluble radioactivity such as in acetate and citrate in the medium was measured by a scintillation counter.

beta -Oxidation Assay Using Isolated Peroxisomes-- Peroxisomal palmitoyl-CoA oxidation was measured with some modification of the methods in (28, 29). The oxidation was measured in a final volume of 100 µl of 10 µM [1-14C]palmitoyl-CoA, 2 mM MgCl2, 0.5 mM coenzyme A, 2 mM NAD+, 2 mM KCN, 2 mM dithiothreitol, 0.1%(w/v) bovine serum albumin, 0.25 M sucrose, 10 mM Tris-HCl, pH 7.4, with or without 2 mM ATP. In some experiments, peroxisomes were disrupted with 0.1%(v/v) of Triton X-100. After incubation for 10 min at 37 °C, reactions were terminated by adding 700 µl of ice-cold H20, 0.15 ml of 10% (w/v) bovine serum albumin, and 0.2 ml of 3 M perchloric acid to the reaction mixture, and the mixture was incubated for 30 min on ice. The mixture was centrifuged, and the supernatant was extracted 3 times with 3 ml of hexane. The acid-soluble radioactivity in the medium was measured by the scintillation counter.

Other Methods-- Protein, catalase, N-beta -D-glucosaminidase, cytochrome c oxidase, and NADPH cytochrome c reductase were assayed as described previously (21). Immunoblotting was done by the method of Small et al. (30).

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Overexpression of PMP70 in CHO Cells-- The expression vector pME18/PMP70 was co-transfected with pSVneo into CHO cells, and stable transformants were selected based on Geneticin resistance. The clones were examined for the expression of PMP70 by immunoblot analysis. Several cell lines transfected with pME18S/PMP70 showed strong expression of a 70-kDa protein corresponding to PMP70 (Fig. 1). Cells transfected with pSVneo alone (Neo cells) or untransfected cells (Cont cells) showed weak expression of PMP70. The amount of PMP70 increased about 5-fold in the cells transfected with pME18S/PMP70 compared with Cont and Neo cells. To examine whether the overexpression of PMP70 affects the amount of other peroxisomal proteins in CHO cells, immunoblot analysis was carried out using #19 and #31 cells. As shown in Fig. 2, amounts of catalase, acyl-CoA oxidase, hydratase-dehydrogenase, and thiolase in these cells were essentially the same as those in Cont and Neo cells.


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Fig. 1.   Overexpression of PMP70 in stable CHO cells expressing the PMP70 cDNA. Cell homogenates prepared from Geneticin-resistant and control CHO cells were subjected to immunoblot analysis of PMP70. Rat Liver epsilon  fraction, post-mitochondrial supernatant fraction prepared from rat liver (50 µg of protein). Cont, wild type CHO cells (150 µg of protein). Neo, CHO cells transfected with pSVneo (150 µg of protein). #19~#55, CHO cells co-transfected with pME18S/PMP70 and pSVneo (150 µg of protein). The amount of PMP70 was quantitated by BAS 1500 imaging analyzer. The arrowhead indicates the position of PMP70.


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Fig. 2.   Immunoblot analysis of several peroxisomal enzymes in control CHO cells and CHO cells overexpressing PMP70. Cell homogenates (150 µg of protein) prepared from wild type CHO cells (Cont), the cells transfected with pSVneo (Neo), and the cells co-transfected with pME18S/PMP70 and pSVneo (#19 and #31) were analyzed with anti-catalase (Cat) (A), anti-acyl-CoA oxidase (AOx; a and b mean subunits a and b, respectively) (B), anti-hydratase-dehydrogenase (HD) (C), and anti-thiolase (D).

Subcellular Localization of PMP70-- To investigate the roles of PMP70 in biogenesis and function of peroxisomes, we first examined whether PMP70 was enriched in peroxisomes in the cells overexpressing PMP70. When isolated subcellular fractions such as mitochondrial, light mitochondrial, microsomal, and cytosolic fractions were subjected to immunoblot analysis, a band corresponding to PMP70 was enriched in the light mitochondrial fraction in Cont, Neo, #19, and #31 cells (data not shown).

The subcellular distribution of PMP70 was further determined by equilibrium density centrifugation. In Neo cells, peroxisomes were well separated from mitochondria, endoplasmic reticulum, and lysosomes (Fig. 3A). The PMP70 was mainly recovered in fractions 10-11 on the sucrose gradient, which corresponded to the position of peroxisomes as shown by the catalase distribution (Fig. 3B). For #19 cells, peroxisomes were also separated from other organelles (Fig. 3A). The PMP70 was mainly recovered in fractions 9-10, and the distribution of PMP70 was similar to that of catalase (Fig. 3B). These results suggest that overexpressed PMP70 is enriched in peroxisomes of CHO cells. The distribution of PMP70 in #31 cells is essentially the same as that of #19 cells (data not shown).


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Fig. 3.   Subcellular localization of PMP70 in Neo and #19 cells. A, heavy and light mitochondrial fractions from Neo and #19 cells were fractionated by equilibrium density centrifugation on sucrose. The marker enzyme distributions are plotted as described previously (21); the recoveries varied between 70 and 120%. Catalase, cytochrome c oxidase (Cyt Ox), NADPH cytochrome c reductase (Cyt Red), and N-acetyl-beta -D-glucosaminidase (NAGase) were measured as marker enzymes of peroxisomes, mitochondria, microsomes, and lysosomes, respectively. Distribution of PMP70 was quantitated by BAS 1500 imaging analyzer. B, immunoblot analysis of PMP70. An aliquot of each fraction from the top (1) to the bottom (12) of the sucrose gradient was analyzed by immunoblotting. One hundred µl of each fraction was used in the case of Neo cells and 25 µl was used in that of #19 cells.

Localization of PMP70 to peroxisomes in Neo, #19, and #31 cells was also examined by immunofluorescence microscopy. As shown in Fig. 4, PMP70 exhibited a punctulate staining pattern in Neo cells. This pattern was completely superimposable on the distribution of catalase in the same cells (A and B). PMP70 also exhibited a punctulate structure with high intensity of fluorescence in #19 and #31 cells, and this pattern was also superimposable on the distribution of catalase on the same cells, although the intensity of cytosolic catalase increased (D and F). We observed cytosolic catalase activity increased slightly after digitonin permeabilization of these cells (data not shown). In immunoelectron microscopy (Fig. 5), gold particles corresponding to PMP70 were observed on peroxisomes, and their number increased in #19 and #31 cells (B and C) as compared with Neo cells (A). However the size of peroxisomes seems to be similar between Neo, #19, and #31 cells.


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Fig. 4.   Immunofluorescence microscopy of Neo, #19, and #31 cells. Double immunostaining of Neo cells (A and B), #19 cells (C and D), and #31 cells (E and F). Distribution of PMP70 was visualized with a rabbit anti-PMP70 antibody and a fluorescein isothiocyanate-labeled secondary antibody (Chemicon) (A, C, and E). Distribution of catalase was visualized with a guinea pig anti-catalase antibody and a rhodamine-labeled secondary antibody (Cappel) (B, D, and F). Bar = 20 µm.


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Fig. 5.   Immunoelectron microscopy of Neo, #19, and #31 cells. A, Neo cells; B, #19 cells; C, #31 cells. A-C show double labeling for catalase (large gold particles) and PMP70 (small gold particles). Large gold particles are predominantly present in peroxisomes (P). Note that dots of PMP70 on peroxisomal membranes increased in #19 and 31 cells, but the size of peroxisomes in Neo, #19, and 31 cells are essentially the same. Magnification, ×62,000.

beta -Oxidation of Fatty Acids-- We have investigated the enzymatic beta -oxidation activity of Cont, Neo, #19, and #31 cells using radiolabeled [1-14C]palmitic and [1-14C]lignoceric acids. 14C-Labeled acid-soluble degradation products derived from both substrates increased linearly up to 2 h in all the cells. The rate of palmitic acid beta -oxidation in #19 and #31 cells increased about 2-3-fold compared with control and Neo cells (Fig. 6A). On the other hand, the beta -oxidation of lignoceric acid in these cells was reduced about 30-40% (Fig. 6B). However, when beta -oxidation activities of palmitic acid and lignoceric acid were measured with 2 mM KCN in the lysates, prepared by freezing and thawing or treatment of 0.01% (v/v) Triton X-100, these activities were unchanged and indistinguishable among these cells, Cont, #19, and #31 cells, under those conditions where peroxisomes were disrupted (data not shown).


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Fig. 6.   beta -Oxidation of [1-14C]palmitic acid and [1-14C]lignoceric acid in Neo, #19, and #31 cells. Cells in 3.5-cm dishes were incubated with [1-14C]palmitic acid and [1-14C]lignoceric acid for 30 min and 1 h, and 14C-labeled acid-soluble products were counted. The beta -oxidation rates in Neo cells were taken as reference (100%). A, rate of formation of acid-soluble products from [1-14C]palmitic acid and beta -oxidation in Neo cells was 1.90 pmol/h/100 µg of protein. B, rate of formation of acid-soluble products from [1-14C]lignoceric acid and beta -oxidation in Neo cells was 4.80 pmol/h/100 µg of protein. Values are the mean ±S.D. of three experiments.

To evaluate peroxisomal beta -oxidation, we measured beta -oxidation of palmitic acid in cultured CHO cells in the presence of 2-[5-(4-chlorophenyl)pentyl]oxirane-2-carboxylate (POCA), a potent inhibitor of mitochondrial carnitine palmitoyltransferase I (27, 31). However, POCA (50 µM) did not inhibit beta -oxidation of palmitic acid in any of the cells, although under the same conditions palmitic acid oxidation was inhibited about 70 and 80% in rat hepatoma H4IIE cells and human fibroblasts. In addition, when a combined fraction of both heavy and light mitochondrial fractions prepared from CHO cells was separated on sucrose gradient centrifugation, about 80% of the activity was recovered in peroxisomal fraction, and it was not inhibited with 2 mM KCN (data not shown). We show, therefore, that peroxisomes contribute mainly to the formation of acid-soluble labeled products in CHO cells under our experimental conditions.

ATP Stimulates Palmitoyl-CoA Oxidation in Light Mitochondrial Fraction-- As palmitic acid is activated to become palmitoyl-CoA outside of peroxisomes, we further examined whether overexpression of PMP70 on peroxisomal membranes stimulates beta -oxidation of palmitoyl-CoA using light mitochondrial fractions in the presence of KCN. In some experiments, peroxisomes were disrupted with Triton X-100. As shown in Fig. 7, when beta -oxidation was measured in the disrupted peroxisomes, the activity was essentially the same with or without ATP. On the other hand, if peroxisomes were intact, ATP stimulated beta -oxidation of palmitoyl-CoA, and the degree of the stimulation in #19 cells was higher than that in Neo cells. Latency of catalase in both cells was essentially the same (about 90%) (data not shown). In addition, in our incubation, the rate of hydrolysis of palmitoyl-CoA to palmitic acid and CoA was about 10% and was not changed by ATP (data not shown). These results suggest that PMP70 is involved in transport of long chain acyl-CoA across peroxisomal membranes. It is unlikely that extensive hydrolysis of palmitoyl-CoA during incubation decreased its concentration and that the stimulative effect of ATP on the beta -oxidation was because of reactivation of palmitate.


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Fig. 7.   Effect of ATP on beta -oxidation of [1-14C]palmitoyl-CoA in light mitochondrial fraction prepared from Neo and #19 cells. Light mitochondrial fractions containing intact or disrupted peroxisomes were incubated with [1-14C]palmitoyl-CoA in the absence or presence of ATP for 10 min at 37 °C, and acid-soluble products were counted. Rates of [1-14C]palmitoyl-CoA beta -oxidation are expressed as a percentage of the rates observed in disrupted peroxisomes in the presence of ATP. The activity in Neo cells and #19 cells was 2.07 nmol/h/mg of protein and 1.86 nmol/h/mg of protein, respectively.

Mutation of Conserved Motifs in PMP70 Inhibited beta -Oxidation of Palmitic Acid-- ABC transporters possess highly conserved regions such as an EAA-like motif and Walker A and B motifs. The EAA-like motif seems to be important for the function of ABC transporters (32, 33), and Walker A and B motifs seem to be important for ATP binding and hydrolysis (9, 34). As PMP70 is a half-sized ABC transporter and seems to function as a dimer, mutation of one of the conserved regions might cause loss of the PMP70 function. We chose to mutate the two glutamic acids (Glu277 and Glu278) in the EAA-like motif of PMP70 to aspartic acids (E277D/E278D), because aspartic acid resulting from a change of the corresponding glutamic acids (Glu291) in ALDP is known to be the site of mutation causing adrenoleukodystrophy. Concerning the Walker A motif, we changed the corresponding lysine (Lys479) to alanine, because it was shown that mutation of the lysine abolishes or markedly reduces ATP hydrolysis and inhibits the protein function of several ATPases (35, 36). In addition, we constructed PMP70 (1-575) minus 84 C-terminal amino acids including the Walker B motif, because recently, Gärtner et al. (12) suggested that the C-terminal sequence of PMP70 is important for the assembly of PMP70.

The three mutant cDNAs were transfected into CHO cells, and stably expressing cells were selected. In the cells overexpressing PMP70 (E277D/E278D and K479A), the amount of PMP70 increased about 2-3-fold compared with that in Neo cells (Fig. 8, A and B). In the cells overexpressing PMP70 (1-575), the band of 60 kDa corresponding to C-terminal-truncated PMP70 was detected, and the amount of the protein was increased ~2-fold over that of wild type PMP70 in Neo cells (Fig. 8C). Furthermore, the mutant PMP70s was found to be enriched in peroxisomes in E1, W10, and S15 cells (data not shown).


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Fig. 8.   Overexpression of mutant PMP70 in CHO cells and the beta -oxidation of [1-14C]palmitic acid and [1-14C]lignoceric acid in the cells. A-C, immunoblot analysis of PMP70. A, missense mutation of EEA-like motif (E1-E22). Neo, CHO cells transfected with pSVneo. B, missense mutation of Walker A motif (W5-W19). C, deletion mutation of C-terminal sequence including the Walker B motif (S1-S15). Cell homogenates (150 µg of protein) were subjected to immunoblot analysis. In the case of C-terminal-truncated PMP70, antibody against purified PMP70 from rat liver peroxisomes (37) was used. The arrowheads indicate the position of PMP70 and C-terminal-truncated PMP70, respectively. D-E, the beta -oxidation of palmitic acid (D) or lignoceric acid (E) in Neo and the mutant cells. Rates of fatty acid beta -oxidation are expressed as a percentage of the rates observed in Neo cells. The rate of formation of acid-soluble products from [1-14C]palmitic acid and [1-14C]lignoceric acid in Neo cells was 2.80 pmol/h/100 µg of protein and 4.50 pmol/h/100 µg of protein, respectively. Values are the mean ±S.D. of three experiments.

When we investigated the beta -oxidation of palmitic acid in the mutant cells, we found the rate of beta -oxidation markedly decreased compared with that of Neo cells (Fig. 8D). In the case of E1 and E21 cells, beta -oxidation of palmitic acid decreased almost 60-70%. These results support PMP70 involvement in beta -oxidation of long chain fatty acids, and furthermore, EAA-like and Walker A motifs, as well as the C-terminal segment including the Walker B motif, are essential to the function of PMP70.

Interestingly, the rate of lignoceric acid beta -oxidation decreased slightly in all the mutant cells (Fig. 8E) and cells overexpressing wild type PMP70 (Fig. 6B). It might be that overexpression of mutant as well as wild type PMP70 inhibited the function of ALDP, which is thought to be involved in beta -oxidation of very long chain fatty acids.

Overexpression of PMP70 Did Not Change the Number and Size of Peroxisomes in CHO Cells-- Administration of hypolipidemic agents in rats induces peroxisome proliferation (6, 7). For example, in the above conditions where the number of peroxisomes was increased ~5-fold, the amount of PMP70 increased ~10-fold (37). This observation suggested that PMP70 induces peroxisomal membranes and increases the number of peroxisomes. To address this issue we compared the number and the size of peroxisomes between Neo, #19, and #31 cells by immunofluorescence and immunoelectron microscopy.

As shown in Fig. 9, a number of punctulate structures with high intensity of fluorescence representing acyl-CoA oxidase were detected in Neo, #19, and #31 cells. The number of fluorescent dots in #19 and #31 cells was similar or slightly decreased compared with that in Neo cells. In immunoelectron micrographs, the number of small gold particles corresponding to PMP70 located on peroxisomes in #19 and #31 cells markedly increased compared with that of Neo cells, but the size and the number of peroxisomes seemed to be similar between Neo cells and #19 and #31 cells. An increase in the size and number of peroxisomes as was observed in rat liver on the administration of hypolipidemic agents did not occur. Thus, it seems that overexpression of PMP70 is not associated with proliferation of peroxisomes.


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Fig. 9.   Distribution of acyl-CoA oxidase in Neo, #19, and #31 cells. Immunofluorescence staining of acyl-CoA oxidase using rabbit anti-acyl-CoA oxidase and Cy2-labeled secondary antibody (Amersham Pharmacia Biotech). A, Neo cells; B, #19 cells; C, #31 cells. The number of peroxisomal particles in #19 and #31 cells was the same as or slightly decreased compared with that of Neo cells.


    DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

In this study, we overexpressed PMP70 in CHO cells and examined roles of PMP70 in biogenesis and function of peroxisomes. First, subcellular localization of PMP70 overexpressed in CHO cells was investigated because information about peroxisomal localization is essential to the characterization of PMP70. The following findings suggest that the overexpressed PMP70 is enriched in peroxisomes. First, the distribution of overexpressed PMP70 in a sucrose gradient was similar to that of catalase (Fig. 3). Second, the numerous dots detected by immunofluorescent staining of PMP70 in #19 and #31 cells were superimposable on those stained with anti-catalase antibody (Fig. 4). Third, the enrichment of immunogold particles corresponding PMP70 on peroxisomes was shown in #19 and #31 cells by immunoelectron microscopy (Fig. 5). In light of these results, we further investigated roles of PMP70 in biogenesis and function of peroxisomes.

Function of PMP70-- An early study demonstrated that ATP stimulated overall beta -oxidation activity in isolated rat liver peroxisomes (29). In addition, it is well known that PMP70 is markedly induced by administration of hypolipidemic agents in parallel with the induction of peroxisomal fatty acid beta -oxidation enzymes (6, 7, 37). These observations suggest the presence of an ATP-dependent acyl-CoA carrier in the peroxisomal membranes and PMP70 may be a carrier of fatty acids or their CoA ester. If PMP70 is a transporter of long chain fatty acids or their CoA ester, its overexpression might stimulate the beta -oxidation in peroxisomes. On the other hand, as PMP70 is a half-sized ABC transporter, mutant PMP70 expressed in the cells might interact with wild type PMP70, resulting in the inhibition of peroxisomal beta -oxidation. In fact, the rate of beta -oxidation of palmitic acid in #19 and #31 cells increased ~2-3-fold (Fig. 6). On the other hand, the rate of beta -oxidation of palmitic acid was markedly decreased by overexpression of all the mutant PMP70 (Fig. 8). It seems unlikely that the increase of beta -oxidation activity in #19 and #31 cells is because of the induction of peroxisomal beta -oxidation enzymes or increase in the permeability of peroxisomal membranes because the amount of peroxisomal beta -oxidation enzymes was essentially the same in Neo, #19, and #31 cells (Fig. 2), as was the latency of catalase in isolated peroxisomes (data not shown). Furthermore, the rate of beta -oxidation of lignoceric acid decreased in CHO cells overexpressing wild type and mutant PMP70 (Figs. 6 and 8), supporting the idea that increase in nonspecific permeability of fatty acids across peroxisomal membranes did not occur.

Because the active site of long chain acyl-CoA synthetase is located outside of peroxisomes (38), the long chain fatty acids seem to be activated to change to acyl-CoA ester prior to beta -oxidation in cells. To define whether PMP70 is involved in the transport of long chain acyl-CoA, we studied beta -oxidation of palmitoyl-CoA using isolated peroxisomes prepared from Cont, #19, and #31 cells. Intact peroxisomes showed latency to palmitoyl-CoA oxidation. ATP stimulated the beta -oxidation of palmitoyl-CoA when intact peroxisomes were used. The degree of stimulation was higher in the CHO cells overexpressing PMP70 than that in the Neo cells (Fig. 7). The effect of ATP was lost when the peroxisomal membranes were disrupted by the use of Triton X-100 (Fig. 7). Based on these results, we suggest that PMP70 functions as a transporter of long chain acyl-CoA across peroxisomal membranes to serve substrates for beta -oxidation, and ATP facilitates the transport of the substrate by PMP70.

Another important point addressed by the present study is the functional domain of PMP70. All ABC transporters characterized so far contain the consensus sequence for an ATP binding site (Walker motifs A and B (34, 35)). Walker A is characterized by the simple motif GXXGXGK(T/S), and the lysine as a source of the positive charge is invariant. In the case of PMP70, mutation of this lysine to alanine resulted in marked inhibition of the palmitic acid beta -oxidation (Fig. 8D). The fact that the lysine479 is critical for the PMP70 function suggests that PMP70 possesses ATP binding and hydrolytic activity, which couples to the transport of palmitoyl-CoA. EAA-like motif is a conserved sequence located in the region between the fourth and fifth putative membrane-spanning domains of ABC transporters. Studies of prokaryotic ABC transporters suggest missense mutations, which alter conserved residues, cause loss of transporter function (32-34). Our mutant demonstrated that this motif is also critical for the PMP70 function.

Recently, two ABC transporters called Pat1p (Pxa2p) and Pat2p (Pxa1p) were identified on peroxisomal membranes of S. cerevisiae (39-43). Disruption of PAT1 and PAT2 resulted in impaired growth on oleic acid and reduced ability to oxidize long chain fatty acids such as oleic acid. Furthermore, a possibility that pat2p is involved in the transport of long chain acyl-CoA was suggested using digitonin-permeabilized yeast cells (44). Therefore, PMP70 seems to be a counterpart of yeast peroxisomal ABC transporter of Pat1p or Pat2p. However, the functional unit of PMP70 and yeast peroxisomal ABC transporters Pat1p and Pat2p seems to be different. Disruption of PAT1 or PAT2 in yeast cells resulted in impaired growth in oleic acid medium, suggesting that Pat1p and Pat2p function as heterodimers (43-46). On the other hand, overexpression of PMP70 alone in CHO cells induced beta -oxidation of palmitic acid, suggesting that PMP70 can function as homodimer.

Unexpectedly, overexpression of wild type as well as mutant PMP70 suppressed the beta -oxidation of lignoceric acid. We don't know the reason for this at present, but one possibility is that because of the overexpression of PMP70, a part of PMP70 may associate with ALDP, although the interaction might be weak and such a heterodimer might reduce the transport activity of lignoceric acids. This possibility is now under investigation.

Effect of Overexpression of PMP70 on Structure of Peroxisomes-- Proliferation of peroxisomes parallels induction of PMP70 (6, 7, 37). A subset of patients with Zellweger syndrome, a peroxisome biogenesis disorder (complementation group 1), has defects at the locus encoding PMP70 (12). This observation led us to examine whether PMP70 is involved in proliferation and biogenesis of peroxisomes. To answer this, we analyzed the number and the morphology of peroxisomes by immunofluorescence and immunoelectron microscopy using CHO cells overexpressing PMP70. The following results suggest that PMP70 is not involved in such a process. First, the number of punctulate structures corresponding to peroxisomes did not increase on overexpression of PMP70 (Fig. 9). Second, the number of gold particles against PMP70 located on peroxisomes was markedly increased by overexpression of PMP70, but the size and the number of peroxisomes did not increase (Fig. 5). Furthermore, CHO cells expressing C-terminal truncated PMP70 as well as the cells possessing missense mutations of EAA-like and Walker A motifs had morphologically normal peroxisomes (data not shown). Therefore, PMP70 seems not to be necessary for the biogenesis and proliferation of peroxisomes but to be required for the normal function of peroxisomes. Recently, it was revealed that peroxisomes in mammalian cells preferentially oxidized several kinds of lipids, prostanoids such as prostaglandin E2, F2alpha , and leukotriens (45, 46) and dicarboxylic acids (47), trihydroxycholestanic acid (48), and phytanic acid (49, 50). These substances must be transported into peroxisomes to be oxidized. It would be interesting to know whether PMP70 is involved in the transport of these substances.

In this study we found that PMP70 is involved in metabolic transport of long chain fatty acyl-CoA across the peroxisomal membrane and is not required for proliferation of peroxisomes or peroxisome biogenesis using CHO cells stably overexpressing wild and mutant type PMP70. The mechanism by which PMP70 transports long chain acyl-CoA will be the subject of further research.

    FOOTNOTES

* This research was supported by the Ministry of Education, Science, Sports, and Culture of Japan (grant-in-aid for scientific research on priority areas of ABC Proteins).The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

§ To whom correspondence should be addressed. Tel.: 81-764-34-2281 (ext. 2635); Fax: 81-764-34-4656; E-mail: imanaka{at}ms.toyama-mpu.ac.jp.

    ABBREVIATIONS

The abbreviations used are: PMP70, 70-kDa peroxisomal membrane protein; ABC, ATP binding cassette; ALDP, adrenoleukodystrophy protein; PCR, polymerase chain reaction; CHO, Chinese hamster ovary; POCA, 2-[5-(4-chlorophenyl)pentyl]oxirane-2-carboxylate.

    REFERENCES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
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