PEX11{alpha} Is Required for Peroxisome Proliferation in Response to 4-Phenylbutyrate but Is Dispensable for Peroxisome Proliferator-Activated Receptor Alpha-Mediated Peroxisome Proliferation

The PEX11 peroxisomal membrane proteins promote peroxisome divisionin multiple eukaryotes. As part of our effort to understandthe molecular and physiological functions of PEX11 proteins,we disrupted the mouse PEX11 ${alpha}$ gene. Overexpression of PEX11 ${alpha}$ issufficient to promote peroxisome division, and a class of chemicalsknown as peroxisome proliferating agents (PPAs) induce the expressionof PEX11 ${alpha}$ and promote peroxisome division. These observationsled to the hypothesis that PPAs induce peroxisome abundanceby enhancing PEX11 ${alpha}$ expression. The phenotypes of PEX11 ${alpha}$ ^-/- miceindicate that this hypothesis remains valid for a novel classof PPAs that act independently of peroxisome proliferator-activatedreceptor alpha (PPAR ${alpha}$ ) but is not valid for the classical PPAsthat act as activators of PPAR ${alpha}$ . Furthermore, we find that PEX11 ${alpha}$ ^-/-mice have normal peroxisome abundance and that cells lackingboth PEX11 ${alpha}$ and PEX11ß, a second mammalian PEX11 gene,have no greater defect in peroxisome abundance than do cellslacking only PEX11ß. Finally, we report the identificationof a third mammalian PEX11 gene, PEX11 ${gamma}$ , and show that it tooencodes a peroxisomal protein.

INTRODUCTION

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Introduction

Peroxisomes are single membrane-bound organelles that participatein a wide variety of metabolic pathways, such as ß-oxidizationof very-long-chain fatty acids (VLCFAs), ${alpha}$ - and ß-oxidizationof long branched-chain fatty acids, biosynthesis of plasmalogens,and H₂O₂ metabolism (45, 47, 48). These peroxisomal activitiesare crucial to human development, as evident from the many diseasesthat result from defects in peroxisomal enzymes or in peroxisomebiogenesis, most of which are lethal (12, 30, 47, 48). Not surprisingly,the abundance of peroxisomes and peroxisomal enzymes is regulatedin response to metabolic and environmental variables in a varietyof species (42).

The abundance of peroxisomes reflects the rates of peroxisomedestruction and peroxisome synthesis. Peroxisome destructioninvolves a specialized version of autophagy and many of theAPG/CVT genes that are involved in cytoplasm-to-vacuole transport(20). Although regulated peroxisome destruction has been describedfor methylotrophic yeast (4), there is as yet no evidence forregulated peroxisome destruction in other yeasts or in mammals.However, there is strong evidence for regulatory pathways thatcouple environmental, dietary, or hormonal signals to an increasedrate of peroxisome synthesis in both lower and higher eukaryotes(7, 32, 43).

The best-characterized examples of regulated peroxisome synthesisare the increases in peroxisome division that occur in yeastsin response to fatty acids (9, 27) and in mammals, notably rodents,in response to peroxisome proliferating agents (PPAs) (32).In yeast, fatty acids and/or fatty acid metabolism induces asignificant increase in peroxisome abundance as well as in theexpression of many genes encoding peroxisomal enzymes and peroxisomebiogenesis factors (also known as peroxins). The transcriptionaleffects are mediated by the PIP2/OAF1 heterodimeric transcriptionfactor (18, 34), but the molecular mechanism linking the increasedexpression of these enzymes, biogenesis factors (peroxins),and metabolic activities to increases in peroxisome formationremains obscure.

It is clear that peroxisomal metabolic activities can have aprofound effect on peroxisome abundance (7, 43), but it is alsoclear that overexpression of one peroxin, PEX11, can induceperoxisome abundance in the absence of extracellular stimulior peroxisome metabolism (23, 38). Cells lacking PEX11 displaythe normal transcriptional response to fatty acids but are unableto induce peroxisome synthesis (9, 27). Conversely, overexpressionof PEX11 leads to an elevated rate of peroxisome formation (9,27), even in the absence of exogenous fatty acids or peroxisomalfatty acid metabolism (23). More recently, Hoepfner et al. (13)identified the dynamin-like GTPase VPS1 as required for peroxisomedivision. Although overexpression of VPS1 does not induce peroxisomedivision, cells lacking VPS1 have even fewer peroxisomes thando pex11 mutants (13; X. Li and S. J. Gould, submitted for publication).

Similar observations have been derived from mammalian cell studies.In fact, the first observations of peroxisome proliferationwere obtained from studies of fibrate drugs in rodents (5, 32).Exposure of rats and mice to these hypolipidemic drugs causedperoxisome abundance to rise dramatically, particularly in theliver, and also increased the expression of many peroxisomalenzymes involved in fatty acid oxidation. These drugs bind tothe peroxisome proliferator-activated receptor alpha (PPAR ${alpha}$ )and stimulate the activity of a heterodimeric transcriptionfactor composed of PPAR ${alpha}$ and the 9-cis-retinoic acid receptor(RxR). The activation of PPAR ${alpha}$ /RxR leads to increased expressionof numerous lipid-metabolizing enzymes, including those of theperoxisomal fatty acid ß-oxidation pathway (32), andincreased expression of PEX11 ${alpha}$ (31, 38). Unlike yeasts, mammalshave multiple PEX11 genes and the expression of either PEX11 ${alpha}$ or PEX11ß is sufficient to induce peroxisome divisionin cultured cells. Peroxisome division in mammals also requiresa large dynamin-like GTPase, the dynamin-like protein 1 (DLP1)(Li and Gould, submitted), and is influenced by the metabolicstate of the peroxisome (7, 43). Thus, the regulation of peroxisomedivision follows similar themes in both yeast and mammaliancells, though there appear to be additional layers of complexityto the mammalian system.

Studies of PEX11 are concerned not only with its role in peroxisomeformation but also its potential metabolic and physiologicalroles. The yeast pex11 mutant and the PEX11ß-deficientmouse are both defective in certain aspects of peroxisome metabolism(22, 43). Furthermore, PEX11ß deficiency in mice cancause intrauterine growth defects, neonatal lethality, hypotonia,neuronal migration defects, and enhanced neuronal apoptosis(22). These phenotypes are extremely similar to those of Zellwegersyndrome mice and Zellweger syndrome patients, though they lackthe peroxisomal protein import defects and strong metabolicdefects of Zellweger syndrome and its mouse models (12). Asa result, it may be that the pathophysiology of Zellweger syndromeis caused by a more subtle metabolic defect than previouslyassumed and, hence, may be more amenable to therapeutic interventiononce the causative metabolic defect is identified. Whether thepathologically relevant metabolic defect in PEX11ß^-/-animals is due to a direct role for PEX11ß or is anindirect consequence of reduced peroxisome abundance remainsto be determined.

In an effort to improve our understanding of PEX11 functionin general, and the physiological roles of PEX11 ${alpha}$ in particular,we generated a mouse strain carrying a disruption of the PEX11 ${alpha}$ gene. Unlike PEX11ß-deficient mice, mice lacking PEX11 ${alpha}$ are externally indistinguishable from their wild-type (WT) andheterozygous littermates and follow a seemingly normal developmentalpattern. Furthermore, they have no detectable defect in constitutiveperoxisome division and, more surprisingly, display a normalperoxisome proliferation response when exposed to PPAR ${alpha}$ -activatingdrugs. However, cells lacking PEX11 are defective in peroxisomeproliferation induced by 4-phenylbutyrate (4-PBA), an atypicalPPA that acts independently of PPAR ${alpha}$ . We also report the phenotypesof mice lacking both the PEX11 ${alpha}$ and PEX11ß genes anddescribe a third PEX11 gene, PEX11 ${gamma}$ .

MATERIALS AND METHODS

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Materials and Methods

Generating mutant mice. A genomic DNA clone of the mouse PEX11 ${alpha}$ gene was identified byscreening a genomic DNA BAC library of 129J/Sv mice with thefull-length mouse PEX11 ${alpha}$ cDNA (38). Three continuous NheI-NheIfragments from this BAC clone, spanning an 18-kb genomic regioncontaining the PEX11 ${alpha}$ gene, were subcloned into the pLITMUS38vector (New England BioLabs, Beverly, Mass.) and sequenced.The deduced genomic structure of the PEX11 ${alpha}$ gene is shown inFig. 1A. The targeting vector (Fig. 1A), designed to disruptthe last two exons of the PEX11 ${alpha}$ gene, was generated by flankingthe 5' and 3' regions of the pgk-Neo^R cassette in the pGT-N28 vector (New England BioLabs) with a 3.6-kb ScaI-AatII fragment(5' untranslated region and exon 1) and a 3.0-kb NheI-PvuIIfragment (3' untranslated region) of the PEX11 ${alpha}$ gene, respectively.The resulting targeting vector (200 µg) was linearizedwith SwaI and electroporated into 6.5 x 10⁶ R1 embryonic stem(ES) cells as previously described (49). Transfected cells wereplated onto Neo^R, mitomycin C-inactivated primary embryonicfibroblasts. After 24 h of growth, the medium was supplementedwith 200 µg of G418/ml, and the cells were grown for anadditional 8 to 10 days in selective medium. G418-resistantclones were examined by Southern hybridization analysis of NheI-or EcoRI-digested genomic DNA, by using two flanking probes(probes A and B, Fig. 1B). Two independently generated PEX11 ${alpha}$ ^+/-ES cell clones were identified and injected into blastocystsof C57BL/6 host mice (Jackson Laboratory, Bar Harbor, Maine).Chimeric males derived from both PEX11 ${alpha}$ ^+/- ES cell lines wereintercrossed with C57BL/6 mice. Agouti offspring were testedfor the presence of the mutant PEX11 ${alpha}$ allele by Southern blotting(37). Heterozygous F₁ mice were either intercrossed to producehomozygous PEX11 ${alpha}$ ^-/- animals or backcrossed with C57BL/6 micefive times prior to generating PEX11 ${alpha}$ ^-/- animals. Genotypes ofmice from generation F₂ and beyond were determined by PCR withthe following primers: primer 10, 5'-AATCAGGGACCTGTGCAACCTG-3';primer 11, 5'-AGTACAGCGTGGCTAATGAAGAGAC-3'; and Neo primer,5'-ATATTGCTGAAGAGCTTGGCGGC-3'. The WT allele was amplified byprimer 10 and primer 11 to yield a 556-bp product, while thetargeted allele was amplified by primer 10 and the Neo primerto yield a 907-bp product (Fig. 1C). An 0.1-µg amountof genomic DNA was used in a 25-µl reaction mixture.

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FIG. 1. Generation of PEX11 ${alpha}$ -deficient mice. (A) Schematic representation of the PEX11 ${alpha}$ WT locus (top), targeting vector (middle), and the targeted allele (bottom). Two flanking Southern blot probes, probes A and B, are indicated. (B) Southern blot analyses of the G418^R ES cell DNA with probe A (left) and probe B (middle) and the mouse tail DNA with probe A (right). Probe A detects a 10.4-kb NheI fragment in the WT allele and a 7.9-kb fragment in the targeted allele. Probe B detects a 12.0-kb EcoRI fragment in the WT allele and an 8.3-kb fragment in the targeted allele. (C) PCR analysis of mouse tail DNA. Positions of three primers are indicated. The WT allele product is 556 bp, and the targeted allele product is 907 bp. (D) Northern blot analysis of total liver RNA from WT (+/+), homozygous (-/-), and heterozygous (+/-) animals. The Northern blot was probed with a radioactively labeled murine PEX11 ${alpha}$ cDNA probe (upper panel), stripped, and probed with labeled PEX11ß cDNA (lower panel). Note that the expression level of PEX11ß was not elevated in the homozygous animals.

The generation of doubly homozygous PEX11 ${alpha}$ ^-/-/PEX11ß^-/-animals was accomplished both by crossing doubly heterozygousPEX11 ${alpha}$ ^+/-/PEX11ß^+/- animals and by crossing PEX11 ${alpha}$ ^-/-/PEX11ß^+/-animals. Typing the PEX11ß locus was accomplishedas described previously (22).

Northern analysis. Total RNA was isolated from mouse livers by using the PurescriptRNA isolation kit (Gentra Systems, Minneapolis, Minn.). RNA(10 µg/lane) was separated on formaldehyde-agarose gels(1.5%), transferred to GeneScreen Plus membranes (NEN Life ScienceProducts, Boston, Mass.), and hybridized according to standardprocedures (37). The expression patterns of PEX11 ${alpha}$ and PEX11 ${gamma}$ were analyzed by probing a mouse multitissue Northern blot [2µg of poly(A)⁺ mRNA/lane; Clontech, Palo Alto, Calif.]with the full-length mouse PEX11 ${alpha}$ or PEX11 ${gamma}$ cDNA. To study theeffect of PPAs on mice, 6- to 8-week-old control and PEX11 ${alpha}$ -deficientmale mice were fed with either standard chow or chow supplementedwith 0.0125% ciprofibrate (Sigma, St. Louis, Mo.) for 2 or 5weeks as indicated, and then total liver RNA was isolated andanalyzed as described above.

Immunoblotting. The expression of PEX11 ${alpha}$ protein in control and PEX11 ${alpha}$ ^-/- mouselivers was analyzed by extracting total protein from liver,separating the proteins by sodium dodecyl sulfate-polyacrylamidegel electrophoresis, transferring the proteins to polyvinylidenedifluoride membranes, and probing them with rabbit antibodiesgenerated against the C-terminal 12 amino acids of the mousePEX11 ${alpha}$ protein. These antibodies were generated by coupling thepeptide NH₂-TVVYPQLKLKAR-COOH to keyhole limpet hemocyanin (Pierce,Rockford, Ill.) and injecting it into four rabbits, one of whichgenerated a recognizable immune response. Proteins were extractedfrom livers of mice fed a normal chow diet as well as from animalsfed a normal chow diet that was supplemented with 0.0125% ciprofibratefor 2 weeks.

Mouse fibroblasts, immunofluorescence microscopy, and transfections. Mouse embryonic fibroblasts (MEFs) were isolated from E14.5embryos as described elsewhere (14). For indirect immunofluorescence,cells were fixed for 20 min in 3% formaldehyde in Dulbecco'sphosphate-buffered saline (PBS; pH 7.1; Life Technologies, Bethesda,Md.), permeabilized for 5 min in 1% Triton X-100-Dulbecco'sPBS, and processed as described previously (7). Affinity-purifiedrabbit anti-human PEX14 antibody has been described previously(35), sheep anti-human catalase antibodies were obtained fromThe Binding Site (Birmingham, United Kingdom), anti-myc monoclonalantibodies were from the tissue culture supernatant of the hybridoma1-9E10 (10), and labeled secondary antibodies were obtainedfrom standard commercial sources. Transfections were done byelectroporation as described previously (6).

Histology and electron microscopy. Newborn mice (P0.5) were deeply anesthetized by ether and perfusedintracardially with 0.5 ml of physiological saline (150 mM NaCl,0.05% CaCl₂, pH 7.4), followed by 10 ml of 4% paraformaldehydein PBS, pH 7.4. The animals were then further fixed by immersionin the same fixative overnight at 4°C and paraffin embedded.Five-micrometer sagittal sections of whole mice were stainedwith hematoxylin and periodic acid-Schiff stain for histologicalanalysis of body tissues. For examination of 6- to 8-week-oldadult mice, animals were anesthetized with ether and perfusedthrough the hepatic portal vein with 10 ml of physiologicalsaline, followed by 50 ml of 4% paraformaldehyde in PBS buffer,pH 7.4. Livers were then embedded in paraffin, sectioned at5 µm, stained with hematoxylin and periodic acid-Schiffstain, and analyzed by light microscopy.

For electron microscopy, adult mice were anesthetized with etherand perfused through the hepatic portal vein first with 10 mlof physiological saline and then with 50 ml of 4% paraformaldehyde-0.05%glutaraldehyde-2% sucrose-0.05% CaCl₂, in 0.1 M piperazine-N,N'-bis(2-ethanesulfonicacid) (PIPES) buffer, pH 7.4. Livers were then removed, cutinto 100-µm sections, and postfixed for 15 min with 1.0%glutaraldehyde in 0.1 M PIPES buffer. Catalase cytochemistrywas performed with the alkaline diaminobenzidine (DAB) mediumaccording to the method of Fahimi (11). DAB-stained sectionswere postfixed with either aqueous or reduced osmium, embeddedin Epon 812, and examined by electron microscopy.

Measuring peroxisome abundance. To determine peroxisome abundance in mouse fibroblasts, fluorescenceimages were captured with an UltraVIEW confocal imaging system(Nikon) and analyzed with IPLab software (Scanalytics, Fairfax,Va.). Peroxisomes in the widest region of the cell, in 0.5-µm-thicksections, were automatically identified as segments comprisedof pixels with a limited range of intensity, and then the segmentsin each cell were automatically counted (peroxisomes per section).At least 100 randomly selected cells were examined for eachsample. To determine the peroxisome abundance in mouse livers,Epon-embedded alkaline DAB-stained mouse livers were sectionedat 0.5 µm, analyzed under an inverted Zeiss microscope(Axiovert 135 TV; Thornwood, N.Y.), and digitally photographed.For each experimental group, 50 to 80 independent fields (5,785µm² each) were photographed from four animals, and thenDAB-stained peroxisomes and the empty spaces between hepatocyteswere automatically measured with IPLab software. Peroxisomedensity was then obtained according to the following equation:D = P x 5,000/(A_field - A_empty), where D is the peroxisome density(peroxisomes/5,000 µm²), P is the peroxisome number ina 5,785-µm² field, A_field is the area of the photographfield (5,785 µm² in this study), and A_empty is the areaof the empty spaces between hepatocytes. Ciprofibrate-treatedanimals were fed normal chow supplemented with 0.0125% (wt/wt)ciprofibrate for 2 weeks, WY-14,643-treated animals were fednormal chow supplemented with 0.1% (wt/wt) WY-14,643 for 2 weeks,and diethylhexylphthalate (DEHP)-treated animals were fed normalchow supplemented with 2% (vol/wt) DEHP for 2 weeks.

4-PBA treatment of MEFs. To study the effect of 4-PBA on the peroxisome proliferationin PEX11 ${alpha}$ -deficient cells, control and PEX11 ${alpha}$ ^-/- MEFs were culturedin standard medium (39) supplemented with 5 mM 4-PBA for 10days and then fixed and processed for indirect immunofluorescencefor catalase and PEX14. Cell images were then taken under anormal immunofluorescence microscope and enlarged to count thenumber of peroxisomes in each cell with the aid of a colonycounter.

Biochemical assays. For lipid analysis in plasma and MEFs, total lipids in the plasmaand fibroblasts were extracted with choroform-methanol-water,converted to their methyl esters, dissolved in hexane at a concentrationof $~$ 1 µg/µl, and separated by gas chromatography(DB-1 and SP-2560 columns) as described previously (29). Fattyacid levels were normalized as the percentage of the total amountof lipids in the extracts. Oxidation assays for the branched-chainfatty acids phytanic acid and pristanic acid were carried outin cultured embryonic fibroblasts with [2,3-³H]phytanic acidor [1-¹⁴C]pristanic acid as substrate (50, 53). Fatty acid ß-oxidationassays were carried out with liver homogenates with [1-¹⁴C]palmiticacid (C_16:0) and [1-¹⁴C]lignoceric acid (C_24:0) as substrate(50). Plasmalogen synthesis activity was determined in the culturedMEFs by the double-substrate, double-isotope method (33).

Cloning the PEX11 ${gamma}$ gene. To identify the human cDNA with the potential to encode a proteinsimilar to the human PEX11 ${alpha}$ and PEX11ß proteins, wescanned the completed human genome sequence with the TBLASTNalgorithm (3) with the use of human PEX11ß as thequery. Although several regions in human chromosomes have beenidentified as encoding possible PEX11 homologs, only one ofthem (in chromosome 19) has two overlapping expressed sequencetags in the database of expression sequence tags. Iterativesearches led to the identification of human and mouse cDNA clonesin the I.M.A.G.E. Consortium that were likely to encode theentire open reading frame of this gene, which we designatedPEX11 ${gamma}$ . These cDNA clones were sequenced in their entirety (accessionnumbers are given below). To determine the subcellular distributionof the PEX11 ${gamma}$ gene product, the open reading frames of the humanand mouse cDNAs were amplified with oligonucleotides designedto append an Asp718 site upstream of the start codon (GGTACCATG)and a BamHI site (GGATCC) in place of their stop codon. Followingdigestion with the restriction enzymes Asp718 and BamHI, thesefragments were cloned into pcDNA3myc (52). An N-myc-tagged expressionvector, pcDNA3-mycPEX11 ${gamma}$ , was also generated. The inserts inthe resulting plasmids were sequenced to ensure the absenceof any mutations in the open reading frame.

Nucleotide sequence accession number. The GenBank accession numbers for the sequenced cDNA clonesare BE616000 for the human PEX11 ${gamma}$ gene and BG176196 and AK007582for the mouse PEX11 ${gamma}$ gene.

RESULTS

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Results

Generation of PEX11 ${alpha}$ -deficient mice. To disrupt the PEX11 ${alpha}$ gene, we generated a targeting vector thatreplaced exons 2 and 3 of this gene with the pgk-Neo^R cassette(Fig. 1A). These two exons encode 227 of the 246 amino acidsin the PEX11 ${alpha}$ protein. After linearization, this targeting vectorwas electroporated into R1 ES cells and transfected cells wereselected with G418. G418-resistant ES clones were screened bySouthern hybridization of NheI- or EcoRI-digested ES cell genomicDNA with two flanking probes (probes A and B, Fig. 1A and B).PEX11 ${alpha}$ ^+/- ES cell clones were also examined with a probe specificfor the Neo^R gene, which also showed the expected genetic alteration(data not shown). Two independently derived PEX11 ${alpha}$ ^+/- ES cloneswere injected into blastocysts of C57BL/6 host mice, chimericmice were obtained, and these mice were crossed with C57BL/6mice. The heterozygous F₁ animals were either intercrossed toproduce homozygous PEX11 ${alpha}$ ^-/- animals or backcrossed with C57BL/6mice for five generations to obtain PEX11 ${alpha}$ ^-/- animals with arelatively homogeneous background.

PEX11 ${alpha}$ ^+/+, PEX11 ${alpha}$ ^+/-, and PEX11 ${alpha}$ ^-/- animals were obtained in theexpected Mendelian ratios (1:2:1) in numerous intercrosses betweenPEX11 ${alpha}$ ^+/- animals. PEX11 ${alpha}$ ^-/- animals lacked detectable PEX11 ${alpha}$ mRNA,as judged by Northern analysis (Fig. 1D). Mice of all genotypeswere similar, with no obvious external phenotypes. There wereno significant differences in body and liver weight betweenage-matched control and PEX11 ${alpha}$ ^-/- animals, and no obvious abnormalitieswere detected in the histological analysis of liver, kidney,adrenal gland, intestine, heart, lung, brown adipose tissue,brain, and bone of PEX11 ${alpha}$ ^-/- animals (data not shown).

PEX11 ${alpha}$ -deficient mice have normal peroxisome abundance. To determine whether loss of PEX11 ${alpha}$ affected peroxisome abundancein untreated cells, we examined mouse livers and cultured MEFs.Peroxisomes in mouse liver sections were detected cytochemicallyby DAB staining for the peroxisomal marker enzyme catalase,which generates an electron-dense precipitate over the organelle(Fig. 2). To detect peroxisomes in MEFs, the cells were fixed,permeabilized, and stained with antibodies specific for a peroxisomalintegral membrane protein, PEX14, and a matrix enzyme, catalase(Fig. 2). DAB-stained liver sections and fluorescence-labeledfibroblasts were then analyzed by microscopy, and peroxisomeabundance was determined by counting the number of distinctperoxisomal profiles. There was no statistically significantdifference in peroxisome abundance between PEX11 ${alpha}$ ^-/- mice andheterozygous and normal control animals in either liver or MEFs.Although the loss of PEX11 ${alpha}$ had no dramatic effect on peroxisomemorphology (Fig. 3), we did observe a tendency of peroxisomesto cluster in the absence of PEX11 ${alpha}$ (Fig. 2B and 3B).

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FIG. 2. Peroxisome abundance in the livers and fibroblasts of PEX11 ${alpha}$ -deficient mice. (A and B) Control and PEX11 ${alpha}$ ^-/- mouse livers were fixed and stained with alkaline DAB solution for peroxisomal maker enzyme catalase. Semithin (0.5-µm) Epon-embedded sections were then analyzed under a light microscope. (C and D) MEFs from control and PEX11 ${alpha}$ ^-/- animals were fixed, permeabilized with 1% Triton X-100, and processed for indirect immunofluorescence with antibodies to PEX14, a peroxisomal integral membrane protein. Peroxisomes present in 60 independent fields of semithin liver sections from four animals (E) and 100 randomly selected fibroblasts from three cell lines (F) were counted for each group. Results in panels E and F are presented as the average peroxisome abundances ± 1 standard deviation.

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FIG. 3. Ultrastructural analysis of PEX11 ${alpha}$ -deficient mouse livers. DAB-stained control (A) and PEX11 ${alpha}$ ^-/- (B) mouse liver sections were postfixed with aqueous osmium and analyzed under an electron microscope. Pictures are from the hepatic midzone. PO, peroxisome; Gly, glycogen.

Peroxisome metabolism is unaffected by PEX11 ${alpha}$ deficiency. To determine whether loss of PEX11 ${alpha}$ might cause a defect in peroxisomalmetabolic function, we examined major peroxisomal metabolicpathways, including fatty acid ${alpha}$ -oxidation, fatty acid ß-oxidation,and ether-lipid synthesis. Defects in peroxisomal fatty acidß-oxidation cause an approximately 10-fold increasein VLCFAs (C₂₂ to C₂₆) in both plasma and fibroblasts due toa proportional defect in the oxidation of VLCFAs (47). Theyalso cause a similar defect in the oxidation of a long branched-chainfatty acid, pristanic acid (19, 29, 47). PEX11 ${alpha}$ ^-/- mice had normallevels of VLCFAs in plasma and fibroblasts (Fig. 4A). The oxidationof pristanic acid in embryonic fibroblasts was the same in PEX11 ${alpha}$ ^-/-cells as in control cells (Fig. 4B), and the oxidation of palmiticacid (C_16:0) and lignoceric acid (C_24:0) in liver homogenateswas the same in PEX11 ${alpha}$ ^-/- mouse lysates as in control lysates(Fig. 4C). Peroxisomal fatty acid ${alpha}$ -oxidation was also normalin PEX11 ${alpha}$ ^-/- MEFs, as determined by measuring the rate of phytanicacid oxidation. In regard to peroxisomal ether-lipid synthesis,it is known that fibroblasts from patients defective in theperoxisomal plasmalogen synthesis pathway have 90 to 99% decreasesin plasmalogen level and plasmalogen synthesis activity (29).However, cultured PEX11 ${alpha}$ ^-/- fibroblasts had no significant defectin plasmalogen levels (Fig. 4D) or plasmalogen synthesis activity(Fig. 4E).

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FIG. 4. PEX11 ${alpha}$ ^-/- mice have normal peroxisome metabolic activities. In all graphs, the black bar represents the average value obtained with control samples, the gray bar represents the average value obtained with PEX11 ${alpha}$ ^-/- mouse samples, and the brackets represent 1 standard deviation. (A) VLCFA levels in plasma and embryonic fibroblasts (MEFs) of the control and PEX11 ${alpha}$ ^-/- mice, expressed as a percentage of total fatty acids. (B) Peroxisomal branched-chain fatty acid ${alpha}$ - and ß-oxidation activities in cultured MEFs. (C) Activities of mitochondrial (C_16:0) and peroxisomal (C_24:0) fatty acid ß-oxidation in liver homogenates. (D) Plasmalogen levels in cultured MEFs, expressed as a percentage of total fatty acids. (E) Plasmalogen synthesis activities in cultured MEFs expressed as a ratio of the peroxisomal incorporation of [¹⁴C]hexadecanol and the microsomal incorporation of the [³H]hexadecyl-glycerol.

PEX11 ${alpha}$ is not required for PPA-mediated peroxisome proliferation. Like its rat ortholog, mouse PEX11 ${alpha}$ mRNA is expressed in a tissue-specificmanner, with highest levels in liver (Fig. 5A). Mouse PEX11 ${alpha}$ expression is also induced by ciprofibrate, a potent fibrateperoxisome proliferator, and we also detected a significantincrease in the levels of PEX11 ${alpha}$ protein following ciprofibratetreatment (Fig. 5B). As expected, we could not detect PEX11 ${alpha}$ mRNA or protein in PEX11 ${alpha}$ ^-/- animals, regardless of whether theanimals were fed a normal diet or the ciprofibrate-containingdiet (Fig. 5B). To test whether the loss of PEX11 ${alpha}$ had any effecton the transcriptional response to ciprofibrate, we also examinedthe expression of two other PPA-inducible genes, the genes forperoxisomal 3-ketoacyl-coenzyme A thiolase (PTL) and cytochromeP450 4A1 (CYP4A1). These two genes were induced by ciprofibratein both PEX11 ${alpha}$ ^-/- animals and control animals. Two constitutivelyexpressed genes, PEX11ß and the actin gene, were unaffectedby the loss of PEX11 ${alpha}$ and by ciprofibrate treatment (Fig. 5C).

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FIG. 5. PEX11 ${alpha}$ expression and role in PPA-mediated gene expression. (A) Abundance of PEX11 ${alpha}$ mRNA in mouse tissues. The mobilities of the 4.4- and 2.4-kb RNA standards are shown to the left of the blot. (B) PEX11 ${alpha}$ mRNA (top) and protein (bottom) are induced by ciprofibrate. The Northern blot was the same blot as in panel C. (C) Normal transcriptional responses of PEX11 ${alpha}$ ^-/- mice to ciprofibrate. Total RNA was isolated from control and PEX11 ${alpha}$ ^-/- mice fed either standard chow or chow supplemented with 0.0125% ciprofibrate for 2 weeks and then analyzed by Northern blotting with radioactively labeled PTL, CYP4A1, PEX11ß, and ß-actin cDNA probes as indicated.

The positive correlation between the abundance of PEX11 ${alpha}$ andperoxisome abundance indicates that PPA-mediated peroxisomeproliferation might be mediated by the increased expressionof PEX11 ${alpha}$ . To test this hypothesis, we measured peroxisome abundancein control and PEX11 ${alpha}$ ^-/- animals exposed to ciprofibrate for2 weeks. Liver sections were obtained for staining with DABto detect peroxisomal catalase activity, and peroxisome abundancein the hepatic central vein region was determined by light microscopy.Control and PEX11 ${alpha}$ ^-/- animals had similar peroxisome abundancebefore and after exposure to ciprofibrate (Fig. 6A). In controlanimals, peroxisome abundance rose from 1,160 ± 240 to2,080 ± 510 peroxisomes/5,000 µm² (1.6- to 4.5-fold;P < 0.001, Student's t test). In PEX11 ${alpha}$ ^-/- animals peroxisomeabundance rose from 1,140 ± 150 to 1,900 ± 540peroxisomes/5,000 µm² (1.1- to 4.0-fold; P < 0.001,Student's t test). These results are reflected in representativelight (Fig. 6B and C) and electron (Fig. 6D and E) microscopicimages of livers from ciprofibrate-fed animals. Similar resultswere obtained with animals fed with ciprofibrate for 5 weeks(data not shown). The peroxisome proliferator drugs are a diverseclass of compounds that includes WY-14,643 and the plasticizerDEHP in addition to ciprofibrate and many other compounds (5,32). PEX11 ${alpha}$ ^-/- animals exposed to these PPAs also displayed anormal peroxisome proliferation response (Fig. 6A).

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FIG. 6. Loss of PEX11 ${alpha}$ had no effect on PPA-mediated peroxisome proliferation. (A) Peroxisome abundance in the livers of control and PEX11 ${alpha}$ ^-/- mice. Control and PEX11 ${alpha}$ ^-/- mice were treated with ciprofibrate, WY-14,643, and DEHP as described in Materials and Methods for 2 weeks, and peroxisomes present in 50 to 80 fields surrounding the hepatic central veins in semithin liver sections were counted. Results here are presented as the peroxisome abundance distribution profile. Note that, after ciprofibrate, WY-14,643, and DEHP treatment, profile shifts in control and PEX11 ${alpha}$ ^-/- mice were comparable. (B to E) Peroxisome distribution and morphology in ciprofibrate-fed control (B and D) and PEX11 ${alpha}$ ^-/- (C and E) mice. Mice were fed with ciprofibrate as described in Materials and Methods for 2 weeks, fixed liver sections were stained with alkaline DAB and postfixed with reduced osmium, and then 0.5-µm semithin sections were analyzed under a light microscope (B and C) and ultrathin sections were analyzed under an electron microscope (D and E). All images are from hepatic central vein regions. There were no pronounced peroxisomal distribution and morphology differences between control and PEX11 ${alpha}$ -deficient mice.

Although loss of PEX11 ${alpha}$ had no effect on PPAR ${alpha}$ -mediated peroxisomeproliferation, PEX11 ${alpha}$ deficiency did lead to subtle changes ofmitochondrial morphology in scattered hepatocytes of ciprofibrate-fedPEX11 ${alpha}$ ^-/- animals (Fig. 7). A 2-week ciprofibrate diet led toproliferation of both mitochondria and peroxisomes in mousehepatocytes. In PEX11 ${alpha}$ ^-/- mouse livers, many mitochondria inmidzonal and periportal hepatocytes contained unusual parallelcristae (Fig. 7D), and many mitochondria appeared to be tightlyassociated with lipid droplets (Fig. 7B). Ciprofibrate feedingalso induced the association of mitochondria around lipid dropletsin control animals (Fig. 7A), but the degree of mitochondrialring formation was far lower than that in PEX11 ${alpha}$ ^-/- animals.Moreover, mitochondria with parallel cristae were very rarein hepatocytes of control animals (Fig. 7C).

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FIG. 7. Mitochondrial morphology defects in portal hepatocytes of ciprofibrate-fed PEX11 ${alpha}$ ^-/- mice. Control (A and C) and PEX11 ${alpha}$ ^-/- (B and D) mice were fed with ciprofibrate as described in Materials and Methods for 2 weeks, fixed liver sections were stained with alkaline DAB and postfixed with reduced osmium, and then ultrathin sections were analyzed under an electron microscope. All images were from the midzonal and periportal areas. In ciprofibrate-treated PEX11 ${alpha}$ ^-/- mouse livers (B and D), many mitochondria contained unusual parallel cristae (arrowheads in panel D) and were tightly ringed around lipid droplets (arrowheads in panel B).

PEX11 is required for 4-PBA-mediated peroxisome proliferation. Ciprofibrate, WY-14,643, and DEHP act by stimulating the transcriptionfactor PPAR ${alpha}$ /RxR (5, 32). Recent studies have shown that 4-PBAalso induces the expression of PEX11 ${alpha}$ and peroxisome proliferation(28, 51). However, 4-PBA differs from previously described PPAsin that it acts independently of PPAR ${alpha}$ (G.-X. Dong and K. D.Smith, unpublished data) and can induce peroxisome proliferationin cultured human and mouse fibroblasts. When MEFs from controland PEX11 ${alpha}$ ^-/- animals were examined for their response to 4-PBA,we found that the loss of PEX11 ${alpha}$ eliminated the peroxisome proliferationresponse to 4-PBA (Table 1).

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TABLE 1. Effect of 4-PBA on peroxisome proliferation in PEX11 ${alpha}$ -knockout (KO) MEFs^a

Phenotypes of PEX11 ${alpha}$ ^-/-/PEX11ß^-/- mice. Mammals express both a PEX11 ${alpha}$ and a PEX11ß gene (1,2, 31, 38). We previously reported that loss of PEX11ßreduces peroxisome abundance (though only about twofold), causesonly a very mild defect in peroxisomal fatty acid ß-oxidation(about 40%) and peroxisomal ether-lipid synthesis (about 20%),and has no effect on peroxisomal protein import (22). Nevertheless,PEX11ß^-/- mice display many of the pathological featuresof Zellweger syndrome, a disease that is typically associatedwith severe defects in peroxisomal protein import and virtuallyall peroxisomal metabolic functions (22). These pathologiesinclude an intrauterine growth defect, severe hypotonia, andneonatal lethality. Histological examination of PEX11ß^-/-animals revealed additional similarities to Zellweger syndromeand Zellweger syndrome mice, including a neuronal migrationdefect, enhanced neuronal apoptosis, and a tissue-specific patternof developmental delay (22).

To determine the effects of losing both the PEX11 ${alpha}$ and PEX11ßgenes, we generated doubly homozygous PEX11 ${alpha}$ ^-/-/ PEX11ß^-/-mice by crossing mice that were both (i) heterozygous for thePEX11ß lesion and (ii) either heterozygous or homozygousfor the PEX11 ${alpha}$ lesion. Like PEX11ß^-/- mice, doublyhomozygous PEX11 ${alpha}$ ^-/-/PEX11ß^-/- mice display an intrauterinegrowth defect, hypotonia, and neonatal or embryonic lethality(Table 2) but have only mild defects in peroxisomal metabolicfunctions (Fig. 8) and no defect in peroxisomal protein import(data not shown). As for peroxisome abundance, PEX11 ${alpha}$ ^-/-/PEX11ß^-/-cells had approximately half the numbers of peroxisomes of WTcontrol animals and the same numbers of peroxisomes as did PEX11ß^-/-cells (Fig. 9A).

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TABLE 2. Survival rates and sizes of newborn mice with different genotypes at the PEX11 ${alpha}$ and PEX11ß loci

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FIG. 8. Biochemical properties of PEX11 ${alpha}$ ^-/-/PEX11ß^-/- cells. In all graphs, the solid bar represents the average value obtained with control samples, the open bar represents the average value obtained with PEX11 ${alpha}$ ^-/-/PEX11ß^-/- samples, and the brackets represent 1 standard deviation. (A) VLCFA levels in MEFs of the control and PEX11 ${alpha}$ ^-/-/PEX11ß^-/- mice, expressed as a percentage of total fatty acids. (B) Plasmalogen levels in cultured MEFs, expressed as a percentage of total fatty acids. (C) Peroxisomal branched-chain fatty acid ${alpha}$ - and ß-oxidation activities in cultured MEFs. (D) Plasmalogen synthesis activities in cultured MEFs expressed as a ratio of the peroxisomal incorporation of [¹⁴C]hexadecanol and the microsomal incorporation of the [³H]hexadecyl-glycerol.

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FIG. 9. Peroxisome abundance in PEX11 ${alpha}$ ^-/-/PEX11ß^-/- cells. MEFs from control and PEX11 ${alpha}$ ^-/-/PEX11ß^-/- animals were fixed, permeabilized with 1% Triton X-100, and processed for indirect immunofluorescence with antibodies to PEX14, a peroxisomal integral membrane protein. Peroxisomes present in at least 100 randomly selected fibroblasts from four cell lines were counted for each group. Results in panel A are presented as the average peroxisome abundances ± 1 standard deviation. Representative images are shown for WT control cells (B), PEX11 ${alpha}$ ^-/- cells (C), PEX11ß^-/- cells (D), and PEX11 ${alpha}$ ^-/-/PEX11ß^-/- cells (E).

PEX11 ${gamma}$ , a third PEX11 gene of mammals. At the outset of this study, we hypothesized that mammals expressedtwo PEX11 proteins and that peroxisome division requires atleast one PEX11 protein (38). However, we recently identifieda third mammalian gene, PEX11 ${gamma}$ (Fig. 10A), which is expressedin both mice and humans (Fig. 10B). We performed a phylogeneticanalysis of the known PEX11 proteins, which suggests that thePEX11 ${gamma}$ gene defines a subfamily of PEX11 proteins that is distinctfrom the branch that includes the mammalian PEX11 ${alpha}$ and PEX11ßproteins (Fig. 11). Northern analysis revealed that the expressionof PEX11 ${gamma}$ was tissue specific, with very high levels in liverbut much lower levels in other tissues (Fig. 12A) and levelsbelow the limit of detection in MEFs (data not shown). Additionalexperiments revealed that PEX11 ${gamma}$ expression was not induced byciprofibrate (Fig. 12B). Furthermore, no change in PEX11 ${gamma}$ expressionwas detected in cells lacking either PEX11 ${alpha}$ or PEX11ß(Fig. 12C).

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FIG. 10. Amino acid sequence analysis of mammalian PEX11 ${gamma}$ . (A) Amino acid sequence alignment of human PEX11 ${alpha}$ , PEX11ß, and PEX11 ${gamma}$ . Sequences were aligned by the CLUSTAL method. Boxes represent amino acids present in at least two of the three proteins. (B) Amino acid sequence alignment of human and mouse PEX11 ${gamma}$ proteins. Sequences were aligned by the CLUSTAL method, and boxes represent amino acids shared by these proteins.

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FIG. 11. Phylogram representation of amino acid sequence similarities among yeast and animal PEX11 proteins. Sequences are aligned by the Clustal W method, and an unrooted phylogram tree was generated with the PAUP program. These are based on the published sequences of human and mouse PEX11 proteins (38); rat PEX11 ${alpha}$ (31); Trypanosoma brucei TbPEX11 (24) and TbGIM5 (25) proteins; Saccharomyces cerevisiae ScPEX11 (9); and Candida boidinii PMP30, PMP31, and PMP32 proteins (36), as well as the database sequences for human and mouse PEX11 ${gamma}$ proteins, a splicing isoform of mouse PEX11 ${gamma}$ protein MmPEX11 ${gamma}$ 1 (GenBank accession no. BAB25302), Lycopersicon esculentum LePEX11 (AAF75750), Caenorhabditis elegans CePEX11 (CAB16857), Drosophila melanogaster DmPEX11.1 (AAF56119) and DmPEX11.2 (AAF58084), and Schizosaccharomyces pombe SpPEX11.1 (CAA93785 and CAB46672) and SpPEX11.2 (CAA93808).

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FIG. 12. Northern analysis of PEX11 ${gamma}$ expression. (A) Abundance of PEX11 ${gamma}$ mRNA in mouse tissues. A multitissue Northern blot filter was hybridized to a radiolabeled PEX11 ${gamma}$ -specific cDNA probe and exposed to X-ray film. (B) Total liver RNA from mice fed normal rodent chow (lanes 1 and 2) and mice fed for 2 weeks with ciprofibrate-supplemented normal chow (lanes 3 and 4) were separated by denaturing agarose gel electrophoresis, transferred to a membrane, hybridized to a radiolabeled PEX11 ${gamma}$ -specific cDNA probe, and exposed to X-ray film. (C) Total liver RNAs from control mice, PEX11 ${alpha}$ ^-/- mice, and PEX11ß^-/- mice were separated by denaturing agarose gel electrophoresis, transferred to a membrane, hybridized to a radiolabeled PEX11 ${gamma}$ -specific cDNA probe, and exposed to X-ray film.

To determine whether PEX11 ${gamma}$ encoded a peroxisomal protein, wemodified the PEX11 ${gamma}$ cDNA so that it encoded a myc epitope tagat the either the 5' or the 3' end of the open reading frame.The corresponding cDNAs were placed in a mammalian cell expressionvector, and the resulting plasmids (pcDNA3-mycPEX11 ${gamma}$ and pcDNA3-PEX11 ${gamma}$ myc)were transfected into the human fibroblast cell line 5756-TI.The cells were subsequently processed for immunofluorescencemicroscopy with antibodies to the myc epitope tag and to theperoxisomal marker protein PEX14 (Fig. 13). The colocalizationof PEX11 ${gamma}$ and PEX14 demonstrates that PEX11 ${gamma}$ , like PEX11 ${alpha}$ and PEX11ß,is a peroxisomal protein. Furthermore, the ability to detectthe myc epitope tag at both the N and C termini of PEX11 ${gamma}$ whenonly the plasma membrane is permeabilized and the peroxisomalmembrane is intact suggests that PEX11 ${gamma}$ is a peroxisomal membraneprotein with both its N and C termini exposed to the cytoplasm.As for the consequences of PEX11 ${gamma}$ overexpression, we did notobserve any increase in peroxisome abundance. In fact, if overexpressionof PEX11 ${gamma}$ myc had any effect, it was to induce the tubulation,enlargement, and clustering of peroxisomes (Fig. 13C, D, G,and H).

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FIG. 13. PEX11 ${gamma}$ encodes a peroxisomal membrane protein. Human skin fibroblast cells were transfected with pcDNA3-HsPEX11 ${gamma}$ myc or pcDNA3-mycHsPEX11 ${gamma}$ by electroporation. Two days after transfection the cells were processed for immunofluorescence microscopy with antibodies specific for the myc epitope tag (A, C, E, and G) and PEX14 (B, D, F, and H), a peroxisomal membrane protein. In these experiments, cells were fixed and then permeabilized with a limiting concentration of digitonin so that antibodies had access to cytoplasmically exposed epitopes but to not epitopes that resided within peroxisomes.

DISCUSSION

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Discussion

Previous studies have implicated PEX11 proteins as effectorsof peroxisome division (1, 2, 9, 23, 24, 27, 31, 36, 38) andestablished that PEX11 ${alpha}$ expression is induced by activation ofPPAR ${alpha}$ (31, 38), which also induces peroxisome division (5, 32).These and other observations led us in a previous paper to proposethat PEX11 ${alpha}$ plays an important role in the peroxisome proliferationresponse induced by activators of PPAR ${alpha}$ (38). Our analysis ofPEX11 ${alpha}$ ^-/- mice does not support this hypothesis but does showthat PEX11 ${alpha}$ is required for peroxisome proliferation in responseto 4-PBA, a drug that acts independently of PPAR ${alpha}$ .

PEX11 ${alpha}$ ^-/- mice had no change in peroxisome abundance when feda normal diet. In addition, each of three PPAR ${alpha}$ activators (ciprofibrate,WY-14,643, and DEHP) induced a normal peroxisome proliferationresponse in PEX11 ${alpha}$ ^-/- mice. The simplest explanation for thisresult is that PEX11 ${alpha}$ is not involved in this process. However,it is possible that cells compensate for the loss of PEX11 ${alpha}$ byincreasing PEX11ß and/or PEX11 ${gamma}$ activity. This doesnot appear to be likely, because PEX11ß and PEX11 ${gamma}$ mRNA levels were not elevated in PEX11 ${alpha}$ ^-/- mice, but the effectcould be mediated at some point other than mRNA abundance.

If PEX11 ${alpha}$ is not involved in the pathway of PPAR ${alpha}$ activation-mediatedperoxisome proliferation, what are some other possible mechanismsthat could link PPAR ${alpha}$ activation to peroxisome proliferation?One possibility is that it involves a nontranscriptional activationof PEX11ß and/or PEX11 ${gamma}$ activity. Another is that itinvolves the activation of DLP1 (15, 16), a GTPase requiredfor peroxisome division in mammalian cells (Li and Gould, submitted).However, it is known that peroxisome abundance is under metaboliccontrol (7) and that activation of PPAR ${alpha}$ affects numerous metabolicpathways (32), raising the possibility that this peroxisomeproliferation pathway is mediated through some type of metaboliccontrol (7).

Although PEX11 ${alpha}$ is not required for peroxisome proliferationin response to PPAR ${alpha}$ activation, it is required for peroxisomeproliferation in response to 4-PBA. 4-PBA induces peroxisomeabundance approximately twofold in both human and mouse fibroblastcells, induces a similar increase in the abundance of PEX11 ${alpha}$ mRNA, and elevates the peroxisomal fatty acid ß-oxidationactivity (28, 51). A recent study has established that 4-PBA-mediatedperoxisome proliferation is unaffected in MEFs from mice lackingthe PPAR ${alpha}$ -encoding gene (Dong and Smith, unpublished), indicatingthat the mechanism of peroxisome proliferation in response to4-PBA is distinct from that used by activators of PPAR ${alpha}$ . Herewe find some support for this hypothesis by showing that PEX11 ${alpha}$ is required for the peroxisome proliferation response to 4-PBA.4-PBA might raise peroxisome abundance solely by its effectson PEX11 ${alpha}$ expression, but this conclusion is preliminary, giventhat 4-PBA alters the transcriptional profile of many genesand affects many processes (8, 17).

In addition to assessing peroxisome abundance and PPA-mediatedperoxisome proliferation, we also tested whether the loss ofPEX11 ${alpha}$ had any discernible effect on peroxisomal metabolic activities.The three most important peroxisomal metabolic functions arethe ß-oxidation of fatty acids, the ${alpha}$ -oxidation offatty acids, and the synthesis of ether-linked lipids (46, 48).The loss of PEX11 ${alpha}$ had no effect on these pathways. The relativelybenign nature of PEX11 ${alpha}$ deficiency stands in sharp contrast tothe severe consequences of PEX11ß deficiency, whichcauses a significant reduction in peroxisome abundance and aseries of pathologies similar to those of Zellweger syndrome(22).

The identification of a role for PEX11 ${alpha}$ in the response to 4-PBA,as well as our observation that it is not required for the responseto more classical PPAs, broadens our understanding of this genebut does not provide a comprehensive understanding of its physiologicalroles. Likewise, our understanding of how PEX11 proteins participatein peroxisome division is only partly enlightened by the presentstudy. However, it is useful to compare the process of peroxisomedivision to paradigms of vesicle budding in other organellesystems (21). Studies of COPII-mediated budding from the endoplasmicreticulum, COPI-mediated budding from the Golgi complex, andclathin-mediated budding from the trans-Golgi network and plasmamembrane suggest that there are two general classes of organelledivision factors. One class includes the proteins that are essentialfor division and directly execute the vesicle budding event,while the other class represents the recruitment factors thathelp bring the division machinery to the organelle membrane.In the case of peroxisomes, two sets of proteins have been implicatedin peroxisome division: the PEX11 proteins and the VPS1/DLP1GTPases. These differ considerably in their properties. Theloss of the VPS1/DLP1 GTPases appears to block peroxisome divisioncompletely, but their overexpression has no stimulatory effecton division (13; Li and Gould, submitted). In contrast, lossof any or all PEX11 proteins has a less severe effect on peroxisomeabundance but PEX11 overexpression strongly promotes peroxisomedivision (23; Li and Gould, submitted). Based on these limitedresults, one might predict that the VPS1/DLP1 GTPases are componentsof the peroxisome division machinery whereas PEX11 proteinsmight act by recruiting this and other components of the putativeperoxisome division machinery to the organelle. This model isonly valid if there are multiple recruitment mechanisms. Theseclearly exist for other organelle division processes (21), andthe presence of multiple PEX11 genes in mammals also lends supportto this notion. Our results add a small level of support tothis model of peroxisome division by showing that PEX11 is requiredfor the peroxisome proliferation response to 4-PBA. However,a direct test of this model remains to be performed.

At the outset of this study we hoped that we could eliminatePEX11 proteins from mice by disrupting the PEX11 ${alpha}$ and PEX11ßgenes. Our identification of a third PEX11 gene, PEX11 ${gamma}$ , makesit clear that we are still far from generating mice and murinecell lines that lack all PEX11 proteins. However, PEX11 ${gamma}$ differsfrom PEX11 ${alpha}$ and PEX11ß in that its overexpression doesnot induce peroxisome proliferation, its expression is not detectablein fibroblasts, and its expression is altered neither by classicalPPAs nor by the loss of PEX11 ${alpha}$ or PEX11ß. Thus, itmay be that the phenotypes of PEX11 ${alpha}$ ^-/-/PEX11ß^-/- fibroblastsare the same as those that we will see for PEX11 ${alpha}$ ^-/-/PEX11ß^-/-/PEX11 ${gamma}$ ^-/-fibroblasts.

The hypothesis that PEX11 proteins act to recruit peroxisomedivision factors is not new. Its original form, proposed byPassreiter et al. (31), was based on their report that rat PEX11 ${alpha}$ recruited the COPI vesicle coat to peroxisome membranes andthat increased levels of PEX11 ${alpha}$ caused an increased rate of COPI-dependentvesicle budding from peroxisomes (31). In support of this hypothesisare the observations that the COPI-binding motif, KXKXX, isa conserved feature of mammalian PEX11 ${alpha}$ proteins, is presentin PEX11 proteins from some lower eukaryotes (24, 38), and bindsCOPI in vitro (31) and that overexpression of PEX11 ${alpha}$ is sufficientto promote peroxisome division (31, 38). Against this hypothesisare the facts that many PEX11 proteins do not contain a COPIrecruitment motif (35), that disruption of the KXKXX motif atthe C terminus of PEX11 proteins has little or no effect ontheir ability to induce peroxisome proliferation (26, 38), andthat brefeldin A, which disrupts COPI-mediated vesicle transport,has no effect on peroxisome biogenesis (40, 41, 44). Our resultsadd the fact that loss of PEX11 ${alpha}$ has no effect on PPAR ${alpha}$ -mediatedperoxisome proliferation. While it is not possible to concludethat COPI plays no role in peroxisome division, we can concludethat it plays at best an ancillary role in mammalian cells.However, we may find that peroxisome division is promoted bymany factors, all of which are important but only a few of whichare essential.

ACKNOWLEDGMENTS

We thank Ann and Hugo Moser for use of their laboratory forbiochemical experiments and Stephanie Mihalik and Paul Watkinsfor help in determining ${alpha}$ - and ß-oxidation activitiesin fibroblasts and liver homogenates.

This work was supported by grants from the NIH to S.J.G. (DK59479and HD10981) and D.V. (HD10981). D.V. is an investigator ofthe HHMI. E.B. was supported by a Max Kade Scholarship (MaxKade Foundation, New York, N.Y., and Deutsche Forschungsgemeinschaft,Germany).

FOOTNOTES

* Corresponding author. Mailing address: Department of Biological Chemistry, The Johns Hopkins University School of Medicine, 725 North Wolfe S., Baltimore, MD 21205. Phone: (410) 955-3424. Fax: (410) 955-0215. E-mail: sgould{at}jhmi.edu.

REFERENCES

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