Interactions of Pex7p and Pex18p/Pex21p with the Peroxisomal Docking Machinery: Implications for the First Steps in PTS2 Protein Import

Peroxisomal PTS2-dependent matrix protein import starts withthe recognition of the PTS2 targeting signal by the import receptorPex7p. Subsequently, the formed Pex7p/cargo complex is transportedfrom the cytosol to the peroxisomal docking complex, consistingof Pex13p and Pex14p. In Saccharomyces cerevisiae, the latterevent is thought to require the redundant Pex18p and Pex21p.Here we mapped the Pex7p interaction domain of Pex13p to itsN-terminal 100 amino acids. Pex18p and Pex21p also interactedwith this region, albeit only in the presence of Pex7p. Expressionof an N-terminally deleted version of Pex13p in a pex13 ${Delta}$ mutantfailed to restore growth on fatty acids due to a specific defectin the import of PTS2-containing proteins. We further show byyeast two-hybrid analysis, coimmunoprecipitation, and in vitrobinding assays that Pex7p can bind Pex13p and Pex14p in theabsence of Pex18p/Pex21p. The PTS2 protein thiolase was shownto interact with Pex14p but not with Pex13p in a Pex7p- andPex18p/Pex21p-dependent manner, suggesting that only Pex14pbinds cargo-loaded PTS2 receptor. We also found that the cytosolicPex7p/thiolase-containing complex includes Pex18p. This complexaccumulated in docking mutants but was absent in cells lackingPex18p/Pex21p, indicating that Pex18p/Pex21p are required alreadybefore the docking event.

INTRODUCTION

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Introduction

Peroxisomes are ubiquitous organelles of eucaryotic cells andfulfill a number of biochemical functions, including the ß-oxidationof fatty acids (51). Peroxisome biogenesis is dependent on aclass of genes that is conserved among species, the PEX genes(19, 40). The corresponding gene products, the peroxins, areinvolved in specific aspects of peroxisome formation, peroxisomeproliferation, membrane protein insertion, and matrix proteinimport (14, 21). Most of the peroxins are required for matrixprotein import, which can occur via two different pathways,the peroxisomal targeting signal type 1 (PTS1)-dependent oneand the PTS2-dependent one. The majority of matrix proteinspossess a PTS1 signal, which is located at the extreme C terminusand is composed of the tripeptide SKL or conservative variantsthereof (18, 24). PTS2-containing proteins include 3-ketoacyl-coenzymeA thiolase, which in Saccharomyces cerevisiae is encoded bythe FOX3 gene. PTS2 targeting signals are located close to theN terminus and were proposed to follow the consensus sequenceH/R-L-X₅-H-L (47, 48).

The targeting signals are recognized in the cytosol by the PTS1-and PTS2-specific factors Pex5p and Pex7p, respectively, whichin turn deliver the cargo proteins to a docking complex at theperoxisomal membrane. Upon docking, the two pathways seem tomerge, as the components of the docking complex, Pex14p andPex13p, provide binding sites for both Pex5p and Pex7p (1, 16,32). In the case of Pex5p, interaction with Pex13p and Pex14phas been shown to be direct (2, 41, 50). Since Pex13p and Pex14pare nonredundant peroxins, it follows that they act either togetherin the same complex or in a consecutive fashion upon proteintranslocation. Evidence for Pex13p being in a complex that isdistinct from the Pex14p-containing complex was recently providedupon purification of both proteins from rat liver peroxisomes(35). In S. cerevisiae, Pex13p is required for the targetingof Pex14p to the peroxisomal membrane (16), and thus, some ofthe defects in PTS2-dependent import that are observed in pex13 ${Delta}$ mutant cells may in fact be due to the absence of peroxisomalPex14p from these cells.

PTS2 protein import specifically requires cytosolic factorsin addition to Pex7p. These include the redundant Pex18p/Pex21pin S. cerevisiae (34); Pex5pL, the long isoform of Pex5p inhigher eukaryotes (5, 31); and Pex20p of Yarrowia lipolytica(49). These PTS2-specific proteins possess only a weak overallsequence similarity, but recent reports suggest that they mightperform a similar function. Pex5pL and Pex18p/Pex21p are capableof interacting with Pex7p via a conserved short motif and arethought to deliver cargo-loaded receptor to the peroxisomalmembrane, whereas the binding of the PTS2 signal is accomplishedby Pex7p (7, 27, 30). Support for a conserved function of theseproteins was presented recently by the partial complementationof a pex18 ${Delta}$ pex21 ${Delta}$ mutant with Pex20p (8). However, Pex7p hasnot yet been identified in Y. lipolytica, and thus, Pex20p maycontain the activities of both Pex7p and Pex18p/Pex21p. ForY. lipolytica, it has been shown that Pex20p is involved inthe cytosolic oligomerization of thiolase, which seems to bea prerequisite for import. However, Pex20p might also be involvedin later events, as it can directly interact with the intraperoxisomalPex8p (46).

Here we present a functional analysis of the PTS2-specific peroxinsPex7p, Pex18p, and Pex21p and their docking factors Pex13p andPex14p. The Pex7p-binding domain in Pex13p was mapped to theextreme N terminus of Pex13p, which fails to interact with Pex5pand Pex14p. The physiological relevance of this domain for PTS2-dependentprotein import was addressed. We further demonstrate that Pex7pand not Pex18p/Pex21p actually docks to the peroxisomal dockingcomplex and provide evidence that Pex14p represents the initialdocking protein. The function of Pex18p and Pex21p will be addressed,and our findings will be discussed in terms of a sequence ofevents for the early steps in PTS2 protein import.

MATERIALS AND METHODS

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Materials and Methods

Strains, media, and general methods. Escherichia coli strain DH5 ${alpha}$ was used for all plasmid amplificationsand isolations, and E. coli strain C41 (DE3) (obtained fromJ. Walker, Medical Research Council, Cambridge, United Kingdom)was used for heterologous expression of recombinant fusion proteins.The yeast strains used in this study are listed in Table 1.PEX18 was deleted from strains HF7cpex21 ${Delta}$ and UTL-7Apex21 ${Delta}$ byusing a kanMX4-based disruption cassette that had been amplifiedfrom genomic DNA of strain HF7cpex18 ${Delta}$ with primer pair RE221/222.PEX14 was similarly deleted from strain yKat110 by amplifyinga LEU2-based cassette with primer pair RE87/88 and genomic DNAof strain UTL-7Apex14 ${Delta}$ as a template. The authenticity of eachgene deletion was confirmed by PCR. EcoRV-linearized pHPR131(expressing PTS2-DsRed) was stably integrated into the trp1locus of strains UTL-7A (yHPR251), UTL-7Apex7 ${Delta}$ (yHPR252), UTL-7Apex13 ${Delta}$ (yKAT92), and UTL-7Apex18 ${Delta}$ pex21 ${Delta}$ (yKat111). Plasmid pHPR132 (expressingDsRed) was similarly integrated into the trp1 locus of UTL-7A(yHPR255). PEX18 was genomically tagged with the TAP tag asdescribed previously (38). In brief, primer pair RE301/302 wasused to amplify the TAP tag cassette plus the Kluyveromyceslactis TRP1 marker gene from plasmid pBS1479. The resultingPCR product was then used to transform strains UTL-7Apex7 ${Delta}$ (yAS3)and UTL-7Apex21 ${Delta}$ (yAS4). Correct integration of the cassettewas verified by PCR.

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TABLE 1. S. cerevisiae strains used

Standard media for the cultivation of yeast and bacterial strainswere prepared as described previously (10, 42). For the inductionof peroxisomes, cells were grown in synthetic dextrose medium(SD) containing 0.3% glucose to mid-log phase, shifted intooleic acid medium (YNO), and incubated for 13 h. YNO contained0.1% oleic acid, 0.05% Tween 40, 0.1% yeast extract, 0.67% yeastnitrogen base, and amino acids as required and was adjustedto pH 6.0 with KOH. For induction of the CUP1 promoter, 25 mgof CuSO₄/liter was added to the YNO medium. Oleic acid plateswere prepared as described previously and contained 0.1% (wt/vol)oleic acid, 0.5% (wt/vol) Tween 80, 0.1% yeast extract, 0.67%yeast nitrogen base, amino acids, and 0.5% potassium phosphatebuffer (pH 6). Standard recombinant DNA techniques, includingenzymatic modification of DNA, transformation, and cultivation,were performed essentially as described previously (42). Yeastwhole-cell extracts were prepared from 30 mg of cells accordingto a published protocol (55).

Plasmids and oligonucleotides. The plasmids and oligonucleotides used are listed in Tables2 and 3, respectively. Unless otherwise stated, all PCRs wereperformed with genomic DNA of a wild-type strain as a templateand products were subcloned into EcoRV-cut pBluescript SK(+)(Stratagene, La Jolla, Calif.). To construct the PEX13-GFP fusions,the complete PEX13 open reading frame and a truncated form (representingamino acids [aa] 151 to 386) were amplified with primer pairsRE 432/435 and RE 550/435, respectively, cut with BamHI andEcoRI, and cloned into the appropriately digested pUG35 (29),resulting in pMS9 and pKAT136.

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TABLE 2. Plasmids used

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TABLE 3. Oligonucleotides used

Expression of full-length and truncated Pex13p from the PEX13promoter was achieved as follows. The PEX13 promoter (base pairs-363 to +6) was amplified (RE 98/99) and cloned as a BamHI/EcoRIfragment into pSK(+) (pKat46). The complete PEX13 open readingframe, amplified with primer pair RE 421/423, and the truncatedversion (representing aa 56 to 386), amplified with primer pairRE 422/423, were digested with SphI/HindIII and cloned intothe SphI/HindIII-digested pKat46, resulting in pKat111 and pKat112.The assembled constructs were excised from pKat111 and pKat112with BamHI/HindIII and ligated into the appropriately cut yeastexpression vector pRS-FOXP-TERM (C. Clayton, Heidelberg, Germany),resulting in pKat113 and pKat122, respectively.

The PTS2-DsRed expression construct (pHPR131) was cloned byassembling the following fragments into XbaI/PstI-cut YIplac204(15): the ADH2 promoter, excised from plasmid pADH2PIP2, asan XbaI/NdeI fragment (3); the amino-terminal 16 aa of Fox3p,obtained from pPTS2-GFP-prA (unpublished) by using primer pairRE 188/189, as an NdeI/NcoI fragment; and DsRed, amplified frompDsRed (Clontech, Palo Alto, Calif.) with primer pair RE 197/198and subcloned into pBluescript SK(+) (pHPR126), as an NcoI/PstIfragment. The DsRed expression vector lacking a PTS2 (pHPR132)was similarly assembled in EcoRI/PstI-cut YIplac204 by usingthe DsRed-containing NcoI/PstI fragment of pHPR126 and the ADH2promoter from pADH2-OAF1 as an EcoRI-NcoI fragment (39).

For the bacterial expression of a synthetic PTS2 protein (pRB107),PTS2-GFP-prA was amplified from pPTS2-GFP-prA with primer pairRE 188/415 and cloned as a BamHI/EcoRI fragment into pGEX4T-2(Amersham Pharmacia, Freiburg, Germany). To express Pex7p inE. coli, PEX7 was amplified with primer pair RE 79/80 and clonedas a SacI/PstI fragment into the appropriately cut pQE31 (Qiagen,Hilden, Germany) or pMAL-c2X (New England Biolabs, Beverly,Mass.), yielding QE31-PEX7 and pKat128, respectively. To generatea His₆-Pex14p fusion construct (QE31-PEX14), PEX14 was amplifiedwith primer pair RE 87/88 and cloned into pQE31 as a BamHI/PstIfragment. The GST-Pex13p_1-100 construct (pKat118) was clonedby amplifying the Pex13p-encoding fragment with primer pairRE 298/379 and ligating the resulting EcoRI/XbaI fragment intopGEX4T-1.

Yeast two-hybrid assays. The two-hybrid assay was based on the method of Fields and Song(12). Selected PEX genes or truncations thereof were fused tothe DNA-binding domain or transcription activation domain ofGal4p in the vectors pPC86 and pPC97 (6). To construct the Gal4p-AD-Pex13pfusions, EcoRI/SpeI fragments of the various PEX13 fragmentsthat had been amplified from genomic DNA were subcloned intothe appropriately cut pPC86 (Table 2). To construct the Gal4p-BD-Pex13pfusions, the PEX13 fragments were excised from the pPC86-PEX13constructs with SmaI/SpeI and subcloned into SmaI/SpeI-digestedpPC97 (Table 2). PEX18 and PEX21 were amplified from genomicDNA and subcloned into SalI/SacI-digested pPC86 and pPC97, respectively(Table 2). A SalI/SacI fragment of pPC97-FOX3 containing theFOX3 open reading frame was subcloned into an appropriatelycut pPC86, resulting in pPC86-FOX3 (pKat146). Cotransformationof two-hybrid plasmids into HF7c was performed according tothe method of Schiestl and Gietz (44). Double transformantswere selected on SD synthetic medium without tryptophan andleucine. Histidine auxotrophy of transformed HF7c was determinedby growth on selective plates lacking leucine, tryptophan, andhistidine but containing 1 or 5 mM 3-aminotriazole.

Antibodies and Western blotting. To generate polyclonal antibodies against Pex7p, a His₆-taggedPex7p was expressed in E. coli strain C41 (DE3) and purifiedunder denaturing conditions according to the manufacturer'sprotocol (Qiagen). This protein was subsequently used to immunizerabbits at Eurogentec (Seraing, Belgium). The raised antiserumwas specific, as it was able to detect Pex7p in whole-cell extractsfrom a wild type but not from the respective pex7 ${Delta}$ strain (Fig.9C, lower panel). The other antibodies used have been describedpreviously, namely, anti-Fox3p (9), anti-Cta1p (20), anti-Pex13p(16), anti-Pex14p (1), anti-maltose-binding protein (MBP; NewEngland Biolabs), anti-protein A (Sigma, St. Louis, Mo.), andanti-myc from 9E10 cell lines (16). Immunoblotting was performedaccording to standard protocols. Horseradish peroxidase-coupledanti-rabbit or anti-mouse immunoglobulin G (IgG), in combinationwith the ECL system (Amersham Pharmacia), was used to detectimmunoreactive complexes.

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FIG. 9. Pex18p binds Fox3p only via Pex7p. (A) Fox3p was tested in a two-hybrid assay for interaction with Pex18p (upper panel) and Pex7p (lower panel) in the HF7c wild type as well as the pex18 ${Delta}$ pex21 ${Delta}$ and pex7 ${Delta}$ strains. (B) Binding of Pex7p to a synthetic PTS2 protein in vitro. Equal amounts of MBP-Pex7p were loaded onto affinity columns and incubated with soluble extracts of bacterially expressed GST-PTS2-GFP-prA (GST-PTS2; right lane in each panel) or GST (left lane). The right panel shows a Coomassie blue stain of the loaded fractions. The retention of GST-containing proteins was analyzed by immunoblotting (upper-left panel). The lower panel shows the presence of MBP-Pex7p in both eluates. (C) Coimmunoprecipitation of Fox3p with Pex18p. Strains pex7D PEX18-TAP (yAS3), pex21D PEX18-TAP (yAS4), and the untransformed UTL7-A wild type were induced in oleic acid-containing medium and analyzed for the presence of Pex7p and Fox3p in the precipitate of Pex18p-TAP by immunoblotting (upper panel). The upper and lower panels show 33% of the immunoprecipitated samples and 0.2% of the total cell lysates, respectively.

Coimmunoprecipitation. Coimmunoprecipitation of myc-Pex7p was performed essentiallyas described previously (36), with the exception that breakageof the copper-induced cells was achieved by vortexing a suspensionof 1 g of cells, 3 volumes of solution A (50 mM Tris-HCl [pH7.5], 50 mM NaCl, 0.2% Triton X-100) that contained the Completeprotease inhibitor cocktail (Roche, Mannheim, Germany), and3 volumes of glass beads (diameter, 0.5 mm; Sigma) for 30 minat 4°C on an IKA-Vibrax VXR (Vibrax, Staufen, Germany).To precipitate Pex18p-TAP, soluble extracts obtained from 3g of cells (suspended in 2.5 volumes of solution A) were incubatedwith IgG Sepharose (Amersham Pharmacia) followed by three washingsteps with solution A. At that point, aliquots of each samplewere removed for analysis of bound Pex18p-TAP. The remainderof the samples were adjusted to 10 mM dithiothreitol and 1 mMEDTA and incubated with 3 U of recombinant tobacco etch virus(TEV) protease (Life Technologies, Karlsruhe, Germany) for 2h at room temperature with gentle agitation to release Pex18pfrom the matrix. The resulting eluates were analyzed for thepresence of Pex7p and Fox3p.

In vitro binding assays. To analyze the Pex7p-Pex14p interaction, the soluble fractionof bacterially expressed His₆-Pex14p (QE31-PEX14) was incubatedwith nickel-nitrilotriacetic acid (Ni-NTA) matrix (Invitrogen,De Schelp, The Netherlands) for 2 h at 4°C. After beingwashed with column buffer (50 mM NaH₂PO₄, 300 mM NaCl, 20 mMimidazole [pH 8]) in a column, equal amounts of the solublefractions of bacterially expressed MBP-Pex7p (pKat128) or MBPalone (pMAL-c2X) were added to the column and incubated withthe matrix for 1 h. After being washed with column buffer, theproteins were eluted with elution buffer (50 mM NaH₂PO₄, 300mM NaCl, 500 mM imidazole [pH 8]). The eluted samples were analyzedby Coomassie brilliant blue staining or immunoblot analysis.

The in vitro binding of Pex7p to Pex13p was analyzed as follows.The soluble fractions of glutathione S-transferase (GST) andGST-Pex13p_1-100 that had been expressed in C41 (DE3) from plasmidspGEX4T-1 and pKat118, respectively, were bound for 2 h at 4°Con a glutathione Sepharose 4B matrix (Amersham Pharmacia). Afterwashing the matrix with 1x phosphate-buffered saline (137 mMNaCl, 2.7 mM KCl, 4.3 mM Na₂HPO₄ · 7H₂O, 1.4 mM KH₂PO₄),the soluble fraction of bacterially expressed His₆-Pex7p (QE31-PEX7)was added and incubated with the matrix for 1 h at 4°C withgentle rotation. Alternatively, equal amounts of yeast lysatesfrom myc-Pex7p-expressing UTL-7A or UTL-7Apex18 ${Delta}$ pex21 ${Delta}$ cells wereadded. After washing the matrix with 1x phosphate-buffered saline,the proteins were eluted with 10 mM glutathione in 50 mM Tris-HCl(pH 8). The eluted samples were analyzed by Coomassie brilliantblue staining or immunoblot analysis.

The binding of PTS2 protein to Pex7p was tested by loading solubleextracts containing either GST-PTS2 protein (pRB107) or GST(pGEX4T-2) onto MBP-Pex7p that had been purified by using thepMAL purification system from New England Biolabs. After beingwashed with 10 bed volumes of column buffer (20 mM Tris-HCl[pH 7.4], 200 mM NaCl, 1 mM EDTA), MBP-Pex7p was eluted withcolumn buffer containing 10 mM maltose. The eluates were analyzedfor the presence of GST-containing proteins by immunoblottingwith an antibody directed against GST-Pex14p (1).

Miscellaneous. The analysis of live cells for DsRed and green fluorescent protein(GFP) fluorescence was performed according to the method ofWestermann and Neupert (53). ß-Galactosidase activitieswere assayed according to manufacturer's instructions and expressedas micromoles of CPRG (chlorophenol red-ß-D-galactopyranoside)hydrolyzed per minute per cell (Clontech).

RESULTS

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Results

Pex7p interacts with the cytoplasmic N-terminal domain of Pex13p. We have shown previously that Pex13p functionally interactswith the PTS2 cargo receptor Pex7p (16). To further characterizethe binding of Pex7p to Pex13p, a series of N- and C-terminaldeletion constructs of Pex13p were tested in a yeast two-hybridassay for interaction with Pex7p. The full-length Pex13p (aa1 to 386) as well as the two C-terminal truncations that lackedpart of the SH3 domain (aa 1 to 340) or the complete domain(aa 1 to 310) were able to interact with Pex7p (Fig. 1), therebydemonstrating that the SH3 domain of Pex13p is dispensable forthe interaction of Pex13p with Pex7p. Interaction was also observedfor even shorter Pex13p variants that lacked the cytosolicallyoriented C-terminal domain in total, with or without transmembranedomain 2 (TMD 2; aa 1 to 280 and 1 to 264, respectively). Byfurther removing the internal loop (aa 1 to 166) and TMD 1 (aa1 to 151) of Pex13p, binding to Pex7p remained proficient. Onthe other hand, removing these 151 N-terminal amino acids fromPex13p (aa 151 to 386) abolished its interaction with Pex7p.In accordance with this observation, all Pex13p fragments thatharbored even larger N-terminal truncations also tested negativefor Pex7p binding (Fig. 1). Thus, the N-terminal domain of Pex13p,which is exposed to the cytosol (16), is the only binding sitefor Pex7p. This novel protein interaction module was also testedfor interaction with Pex5p and Pex14p, the other known bindingpartners of Pex13p. However, these proteins failed to bind aa1 to 151 of Pex13p in a two-hybrid assay (Fig. 2A).

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FIG. 1. Identification of the Pex7p-binding region in Pex13p. (A) Known features of PEX13. The cytosolically exposed SH3 domain (checked box) of the S. cerevisiae peroxisomal membrane protein Pex13p (386 aa) is bound by Pex5p and Pex14p at distinct sites as indicated by the arrows. The two predicted TMDs are marked in dark gray. (B) Analysis of PEX13 fragments for interaction with PEX7 in the yeast two-hybrid assay. The indicated regions of PEX13 were fused to the GAL4 activation domain of plasmid pPC86 and cotransformed with a pPC97-derived plasmid expressing a GAL4 DNA-binding domain-PEX7 fusion into the wild-type strain HF7c. The resulting prototrophs on histidine dropout plates containing 5 mM aminotriazole were considered positive for interaction (+). Numbers flanking the bars indicate the Pex13p amino acid residues that delimit the fragments.

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FIG. 2. Only the PTS2-specific peroxins interact with the N terminus of Pex13p. (A) Analysis of Pex5p and Pex14p for their interaction with Pex13p_1-151. The interaction of Pex7p with Pex13p_1-151 in a two-hybrid assay is indicated by the histidine prototrophy of two independent clones of the respective transformant. The corresponding PEX5 and PEX14 transformants failed to grow on the same plate. (B) Pex18p and Pex21p interaction with Pex13p_1-151. Coexpression of PEX18 and PEX21 fusions to the GAL4 activation domain (AD) with the Pex13p_1-151 GAL4 DNA-binding domain (BD) fusion resulted in the formation of histidine prototrophs.

Pex18p, Pex21p, and Pex7p interact with the same region in Pex13p. Translocation of proteins with a PTS2 targeting signal specificallyrequires, in addition to Pex7p, the redundant, largely cytosolicPex18p and Pex21p (34). In the absence of both proteins, PTS2-dependentimport is abolished. Both proteins can interact with Pex7p andare thought to target cargo-loaded Pex7p to the peroxisomalmembrane (34). We therefore tested whether Pex18p and Pex21pare able to contact the Pex7p interaction domain of Pex13p.When fused to the Gal4p DNA-binding domain, both proteins exhibitedautoactivity in the two-hybrid assay (data not shown). However,the respective activation domain fusions of Pex18p and Pex21pcaused growth of the tester strain only when coexpressed withthe amino terminus of Pex13p (Fig. 2B). This result indicatedthat Pex18p and Pex21p can also interact with the N terminusof Pex13p. To narrow down the binding regions in the Pex13pN terminus for the PTS2-specific proteins, smaller fragmentsof Pex13p were tested in the two-hybrid assay (Fig. 3A). Aminoacids 1 to 100 proved even more efficient than aa 1 to 151 inbinding the three proteins, while the amino-terminal 55 aa ofPex13p were efficiently recognized only by Pex7p. The constructcomprising aa 55 to 100 of Pex13p failed to give rise to a positivesignal with any of the proteins analyzed (Fig. 3A).

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FIG. 3. Pex18p and Pex21p contact Pex13p and Pex14p only in the presence of Pex7p. (A) Confinement of the Pex13p-binding region for Pex7p, Pex18p, and Pex21p. The indicated fragments of Pex13p were tested in a two-hybrid assay for interaction with Pex7p, Pex18p, and Pex21p in the HF7c wild-type strain. (B) Dependence of the Pex13p_1-100 interactions with Pex7p, Pex18p, and Pex21p on endogenous PEX7 and PEX18/PEX21. The assays with Pex13p_1-100 were repeated in the otherwise isogenic HF7c strains pex7 ${Delta}$ and pex18 ${Delta}$ pex21 ${Delta}$ . Histidine prototrophs were not observed for Pex18p/Pex21p in the absence of Pex7p. (C) Dependence of the Pex7p-Pex14p two-hybrid interaction on endogenous PEX18/PEX21. The respective Pex7p and Pex14p fusions were transformed into HF7c and the corresponding pex18 ${Delta}$ pex21 ${Delta}$ strain. In both strains, coexpression of Pex7p and Pex14p caused growth on histidine dropout plates.

Pex13p_1-100 and Pex13p_1-55 interacted more strongly with Pex7pthan with Pex18p or Pex21p, as the Pex7p-containing strainsgrew faster on histidine dropout plates than those containingPex18p and Pex21p (data not shown). This result was also verifiedby quantification of the two-hybrid data by means of a ß-galactosidaseassay in the strain background of PJ69-4A, which harbors a sensitiveGAL7 promoter-lacZ reporter gene. Activities were about threefoldhigher in the strain expressing Pex7p-Pex13p_1-100 (2,509 ±123 U) than in those expressing Pex7p-Pex13p_1-55 (811 ±137 U), whereas in the strain harboring Pex7p and Pex13p_55-100,activities reached only background levels (<50 U). None ofthe Pex18p/Pex21p-containing strains turned out to yield activitiesabove the detection limit of the assay (<50 U). These datawere interpreted to mean that despite the N-terminal 55 aa ofPex13p being essential for the Pex7p interaction, a somewhatlarger region of Pex13p, possibly up to its first 100 aa, constitutesthe full interaction site for Pex7p. The association of Pex18p/Pex21pwith this optimal site could be explained by the assumptionof a Pex7p-mediated interaction of Pex18p/Pex21p with Pex13p.

Pex18p and Pex21p bind Pex13p via Pex7p. The resemblance in binding sites opened the possibility thatPex18p and Pex21p bound to Pex13p in a complex with Pex7p. Thiswas addressed by testing the interaction of Pex7p with Pex13p_1-100in a strain devoid of both Pex18p and Pex21p (Fig. 3B). Theinteraction was unaffected, suggesting that Pex7p forms contactswith Pex13p that are independent of Pex18p/Pex21p. In contrast,the presence of Pex7p was important for the Pex18p/Pex21p interactionwith Pex13p_1-100 (Fig. 3B), thereby supporting the notion thatPex7p serves a bridging protein for the interaction of Pex18p/Pex21pwith Pex13p.

We then analyzed the possibility that Pex18p and Pex21p arerequired for the binding of Pex7p to the other docking protein,Pex14p, but this binding event occurred in the pex18 ${Delta}$ pex21 ${Delta}$ mutantbackground (Fig. 3C). Pex18p/Pex21p interacted only very weaklywith Pex14p, and this interaction depended on Pex7p (data notshown), suggesting that these redundant factors do not contactPex14p directly, either.

Pex7p docking in the absence of Pex18p and Pex21p. To obtain independent evidence for our results, we set out coimmunoprecipitationexperiments with a myc-tagged version of Pex7p. The same proteinhas previously been used to demonstrate Pex7p binding to Pex13pin the absence of Pex5p and Pex14p (16). The tagged proteinwas expressed in wild-type and pex18 ${Delta}$ and pex18 ${Delta}$ pex21 ${Delta}$ mutantbackgrounds and also in the docking protein mutants pex13 ${Delta}$ andpex14 ${Delta}$ . Expression levels of myc-Pex7p were comparable in allstrains (Fig. 4). When myc-Pex7p was immunoprecipitated fromwhole-cell extracts of the wild-type strain, Pex13p and Pex14pwere also found in the precipitate (Fig. 4). As anticipated,in the absence of Pex14p, Pex13p was still found in a complexwith Pex7p. Since this was also the case in the pex18 ${Delta}$ pex21 ${Delta}$ double mutant (Fig. 4), this result demonstrated that bindingof Pex7p to the docking complex does not require the presenceof Pex18p and Pex21p.

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FIG. 4. Docking of Pex7p in the absence of Pex18p and Pex21p. The wild-type strain UTL-7A as well as the indicated, otherwise isogenic set of myc-Pex7p-expressing strains was induced in oleic acid-containing medium and analyzed for the presence of Pex13p and Pex14p in the immunoprecipitate of myc-Pex7p (upper panel). The upper and lower panels show 10% of the immunoprecipitated samples and 0.5% of the cell lysates, respectively, that had been subjected to immunoblotting with antisera against the myc epitope, Pex13p, and Pex14p.

Pex7p binds to Pex14p in vitro. The ability of Pex7p to bind Pex14p in the absence of Pex18p/Pex21pwas also analyzed with bacterially expressed proteins. A His₆-taggedversion of Pex14p was purified on Ni-NTA affinity columns ontowhich soluble extracts were loaded that contained either MBPor an MBP-Pex7p fusion protein. After washing, His₆-Pex14p waseluted from the columns and the eluates were analyzed for thepresence of coeluted MBP-Pex7p. Coomassie brilliant blue stainingrevealed that Pex7p coeluted with His₆-Pex14p (Fig. 5, upperpanel, lane 3) whereas MBP did not (lane 4). To ensure thatthe indicated bands in the Coomassie blue-stained gels indeedrepresented the MBP fusion protein, the same samples were diluted20-fold and subjected to immunoblot analysis with an antibodydirected against MBP (Fig. 5, lower panel). MBP-Pex7p was clearlydetectable (lane 3), whereas little MBP was detected (lane 4).Thus, heterologously expressed Pex7p specifically interactedwith Pex14p, demonstrating that these two peroxins can bindeach other in a direct manner.

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FIG. 5. Direct binding of Pex7p to Pex14p. Bacterially expressed His₆-tagged Pex14p was purified on Ni-NTA affinity columns. Subsequently, soluble extracts containing equal amounts of MBP (lane 1) or MBP-Pex7p (lane 2) were loaded onto these columns. After being washed, the eluates of His₆-Pex14p were analyzed for retained MBP-Pex7p (lane 3) or MBP (lane 4) by Coomassie blue staining (upper panel). The same samples were diluted 20-fold and subjected to immunoblot analysis with anti-MBP antibodies (lower panel).

Pex7p binds to Pex13p_1-100 in vitro. To analyze the Pex7p-Pex13p interaction in vitro, the first100 aa of Pex13p were expressed as a GST fusion protein in E.coli and subsequently purified on GST affinity columns. Subsequently,yeast lysates of wild-type or pex18 ${Delta}$ pex21 ${Delta}$ mutant cells expressingmyc-tagged Pex7p were added, and bound GST proteins were visualizedby Coomassie blue staining (Fig. 6A, lower panel). myc-Pex7pwas detected immunologically by using anti-myc antibodies (Fig.6A, upper panel). The tagged Pex7p was specifically retainedin the presence of Pex13p_1-100 even when expressed in cellsdevoid of Pex18p and Pex21p (lanes 2 and 3). When lysate froman untransformed wild-type strain was applied to the Pex13p_1-100-GST-loadedcolumn, no signal was obtained (lane 1). Similarly, GST alonealso failed to bind myc-Pex7p (lanes 4 and 5). Thus, it couldbe inferred that the amino-terminal 100 aa of Pex13p are indeedthe binding site for Pex7p and that Pex18p/Pex21p are not requiredfor Pex7p binding to Pex13p_1-100.

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FIG. 6. Direct binding of Pex7p to Pex13p_1-100. (A) Yeast myc-Pex7p specifically interacts with GST-Pex13p_1-100. Equal amounts of GST or GST-Pex13p_1-100 were loaded onto affinity columns and incubated with total cell lysates of a wild-type strain or the myc-Pex7p-expressing wild-type or pex18 ${Delta}$ pex21 ${Delta}$ strains. After the columns were washed, bound proteins were eluted and analyzed by immunoblotting for the presence of myc-Pex7p (upper panel). The presence of GST and GST-Pex13p_1-100 in these eluates was determined by Coomassie blue staining (lower panel). (B) Binding of Pex7p to Pex13p in vitro. Equal amounts of GST or GST-Pex13p_1-100 were loaded onto affinity columns and incubated with soluble extracts of bacterially expressed His₆-tagged Pex7p (+) or a mock-transformed E. coli strain (-). The retention of His₆-Pex7p was analyzed by immunoblotting (upper panel). The lower panel shows the presence of GST and GST-Pex13p_1-100 in these eluates.

To exclude the possibility that another yeast protein contributedto the observed binding of Pex7p to Pex13p, both proteins werebacterially expressed and subjected to in vitro binding studies.When expressed as a His₆-tagged version, a large fraction ofPex7p was found in inclusion bodies. Nevertheless, we couldobtain a small fraction of His₆-Pex7p that was soluble. Thisfraction was loaded onto columns containing purified GST-Pex13p_1-100or GST (Fig. 6B). Anti-Pex7p antibodies were then used to detectbound Pex7p by immunoblot analysis. His₆-Pex7p was only retainedin the presence of Pex13p_1-100 (Fig. 6B, lane 3), thereby demonstratingthat Pex7p can directly bind to the N-terminal region of Pex13p.

The N terminus of Pex13p is required for PTS2-dependent import. To elucidate the physiological relevance of the Pex7p-bindingregion in Pex13p, full-length Pex13p as well as a truncatedvariant of Pex13p lacking the N-terminal 55 aa were expressedfrom the native PEX13 promoter in a pex13 ${Delta}$ strain and analyzedfor their capability to complement the mutant phenotype. Immunoblotanalysis demonstrated that truncated Pex13p_56-386 was stablyexpressed, although to a lower degree than full-length Pex13p(Fig. 7A). However, in contrast to full-length Pex13p, Pex13p_56-386was not able to restore the growth defect of a pex13 ${Delta}$ mutanton fatty acids as a sole carbon source (Fig. 7B), indicatingthat the N-terminal region is important for the function ofPex13p.

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FIG. 7. The Pex7p-binding region of Pex13p is important for its function. (A) Expression of a truncated Pex13p variant in pex13 ${Delta}$ cells. Whole-cell extracts of strain UTL-7Apex13 ${Delta}$ that had expressed plasmid-borne copies of either full-length Pex13p (Pex13p_1-386) or an N-terminally truncated version of Pex13p (Pex13p_56-386) were subjected to immunoblot analysis with antiserum against Pex13p. The asterisk denotes proteins that had cross-reacted with the antiserum. (B) Complementation analysis of pex13 ${Delta}$ with truncated Pex13p_56-386. The indicated strains were spotted as a series of 10-fold dilutions on an oleic acid plate and incubated for 5 days at 30°C.

To test whether truncated Pex13p was correctly targeted to peroxisomes,GFP was fused to the C terminus of full-length Pex13p (Pex13p_1-386)and to Pex13p that lacked the entire N-terminal cytosolic domain(Pex13p_151-386). The GFP fusions of both the truncated and thefull-length Pex13p were expressed in a wild-type strain, andtheir intracellular distribution was analyzed by fluorescencemicroscopy. Both Pex13p fusion proteins showed a punctate stainingpattern (Fig. 8A) that was reminiscent of clustered peroxisomes.This clustering did not affect peroxisomal function, as full-lengthPex13p-GFP was able to fully complement a pex13 ${Delta}$ strain (datanot shown). Moreover, the staining patterns of both the full-lengthand the truncated Pex13p coincided with that of the peroxisomalmarker protein PTS2-DsRed (Fig. 8A and B). It was thereforeconcluded that Pex13p_1-386 and Pex13p_151-386 are correctly targetedto the peroxisomal membrane. We then investigated whether truncatedPex13p_56-386 is still functional in peroxisomal matrix proteinimport. This was achieved by monitoring the subcellular distributionof fluorescent marker proteins for PTS1 and PTS2 import. GFP-SKLwas used for analyzing PTS1-dependent import, while PTS2-DsRed,composed of the 16 N-terminal amino acids of Fox3p and the redfluorescent protein DsRed, served as the PTS2 marker protein.This protein was imported into peroxisomes in a wild-type strainbut not in a pex7 ${Delta}$ or pex18 ${Delta}$ pex21 ${Delta}$ strain, and DsRed without thePTS2 signal remained cytosolic in a wild-type strain (Fig. 8B).As expected, both GFP-SKL and PTS2-DsRed caused diffuse stainingwhen expressed in the pex13 ${Delta}$ mutant, which is defective in bothimport pathways (Fig. 8C). Coexpression of full-length Pex13prestored matrix protein import, since both marker proteins ledto a punctate fluorescence staining pattern. Most interestingly,upon coexpression of the truncated Pex13p_56-386, PTS2-DsRedfluorescence remained diffuse, whereas GFP-SKL gave rise toa punctate staining pattern (Fig. 8C). These results clearlydemonstrate that in the absence of the N terminus of Pex13p,PTS1-dependent import can still proceed, while PTS2-dependentimport is blocked, probably because the binding of Pex7p tothis N-terminal domain is abolished.

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FIG. 8. Only PTS2-dependent import is blocked in the absence of the Pex13p-docking site for Pex7p. (A) Peroxisomal localization of Pex13p_151-386. The UTL-7A strains expressing PTS2-DsRed as well as Pex13p_1-386-GFP or Pex13p_151-386-GFP were examined for GFP (left panels) and DsRed (middle panels) fluorescence. Bright-field microscopy (BF) demonstrates the structural integrity of the cells. (B) Localization of the fluorescing PTS2-DsRed marker protein. The wild-type UTL-7A and the otherwise isogenic pex7 ${Delta}$ and pex18 ${Delta}$ pex21 ${Delta}$ strains expressing PTS2-DsRed were streaked on oleic acid plates. After 2 days, cells were examined for DsRed fluorescence. The expression of a PTS-less DsRed in a wild-type strain was also monitored. (C) Selective complementation of PTS1-dependent import by Pex13p_56-386. The pex13 ${Delta}$ strains coexpressing Pex13p_1-386 or Pex13p_56-386 in combination with GFP-PTS1 (pJR233) and PTS2-DsRed were streaked on oleic acid plates and examined after 2 days for staining patterns of the fluorescing PTS marker proteins.

Pex7p-dependent complex formation of Pex18p/Pex21p and Fox3p. To determine where in the translocation process Pex18p/Pex21pare required, we reinvestigated the two-hybrid interactionsof the PTS2 protein Fox3p with the PTS2-specific peroxins. Interactionof Fox3p with Pex7p was observed in wild-type, pex7 ${Delta}$ , and pex18 ${Delta}$ pex21 ${Delta}$ strains (Fig. 9A, lower panel). On the other hand, theinteraction between Fox3p and Pex18p or Pex21p (data not shown)was strictly dependent on Pex7p (Fig. 9A, upper panel), whichwas in accordance with previous findings (34). This result demonstratedthat Pex18p/Pex21p are also not required for the Pex7p-PTS2interaction. To exclude an involvement of other yeast proteinsin the PTS2 recognition event, an in vitro binding assay usingbacterially expressed MBP-Pex7p was set out. MBP-Pex7p was boundto an amylose resin onto which soluble extracts from E. colicells were loaded that had expressed either a synthetic PTS2protein fused to GST or GST alone. Subsequent analysis of theeluted MBP-Pex7p fractions revealed that the targeting signal-containingprotein was specifically retained (Fig. 9B). Thus, Pex7p alonewas sufficient to recognize the PTS2 targeting signal.

The apparent requirement for Pex7p in the formation of a complexbetween Pex18p and Fox3p was analyzed by coimmunoprecipitation.For that matter, Pex18p was chromosomally tagged with the TAPtag at its C terminus in pex21 ${Delta}$ and pex7 ${Delta}$ strains (Fig. 9C, lowerpanel). Expression of the fusion protein in a pex21 ${Delta}$ strain backgroundrevealed that Pex18p-TAP was fully functional, as this straingrew comparably to the wild-type strain on oleic acid plates(data not shown). This fusion protein could be specificallyprecipitated from whole-cell extracts via its TAP tag by usingIgG Sepharose (Fig. 9C, upper panel). The Pex18p-TAP precipitateswere released from the column by using TEV protease and analyzedfor the presence of Pex7p, which could be detected in the precipitateof the pex21 ${Delta}$ strain but not in those of the pex7 ${Delta}$ or untransformedwild-type strains (Fig. 9C, upper panel). The same precipitateswere also analyzed for the presence of Fox3p. While the PTS2cargo protein was found in the pex21 ${Delta}$ sample, it was absent fromthe precipitate derived from the pex7 ${Delta}$ strain (Fig. 9C, upperpanel). It was therefore concluded that Fox3p can indeed associatewith Pex18p in vivo, albeit only in the presence of Pex7p.

Pex7p- and Pex18p/Pex21p-dependent docking of Fox3p to Pex14p. We then analyzed whether Fox3p would be found in a complex withthe docking proteins Pex14p and Pex13p when either Pex7p orPex18p/Pex21p were absent. This was achieved by testing foran interaction of Fox3p with Pex14p and Pex13p in a two-hybridassay. Remarkably, a strong interaction between Fox3p and Pex14pwas observed in a wild-type strain, which was absent in a pex7 ${Delta}$ or pex18 ${Delta}$ pex21 ${Delta}$ mutant background (Fig. 10A). On the other hand,no interaction between Fox3p and Pex13p_1-100, a Pex13p fragmentthat strongly interacted with Pex7p, was detectable in a wild-typestrain or a pex18 ${Delta}$ pex21 ${Delta}$ strain (Fig. 10B). Even in a pex14 ${Delta}$ strain,where Pex7p binding to Pex13p is likely to increase, no interactionbetween Fox3p and Pex13p was detected (Fig. 10B). These findingsindicate that docking of the PTS2 cargo protein is criticallydependent on both Pex18p/Pex21p and Pex7p. They further suggestthat Pex14p represents the docking protein, whereas Pex13p isinvolved in the binding of the Pex7p-Pex18p/Pex21p complex withoutcargo protein.

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FIG. 10. Fox3p interacts with Pex14p in a Pex7p- and Pex18p/Pex21p-dependent manner. The docking proteins Pex14p (A) and Pex13p (B) were tested for interaction with Fox3p in a two-hybrid assay in the indicated strain backgrounds.

Pex18p and Pex21 promote the formation of an import-competent PTS2 substrate complex. In the absence of a functional docking or translocation machinery,immunoprecipitates of myc-Pex7p contain a drastically increasedamount of the PTS2 protein Fox3p (16, 37). This increased bindingwas interpreted to be due to the cytosolic accumulation of Fox3pin these mutants. Were Pex18p/Pex21p only to mediate the dockingof Fox3p to Pex14p, then such an apparent accumulation of cargo-loadedreceptor should also occur in a pex18 ${Delta}$ pex21 ${Delta}$ strain. As expected,the myc-Pex7p immunoprecipitates of a wild-type strain containedlittle Fox3p, whereas those of pex13 ${Delta}$ and pex14 ${Delta}$ strains showedan accumulation of Fox3p (Fig. 11A). However, in the pex18 ${Delta}$ pex21 ${Delta}$ strain, only very little Fox3p could be coprecipitated (Fig.11A).

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FIG. 11. The Pex7p-Fox3p-containing cytosolic complex does not accumulate in a pex18 ${Delta}$ pex21 ${Delta}$ mutant. (A) Accumulation of a Fox3p-Pex7p complex in peroxin mutants. The indicated myc-Pex7p-expressing strains were analyzed for the presence of Fox3p in the immunoprecipitate of myc-Pex7p (10% of total) by immunoblotting (upper panel). The lower panel shows an immunoblot of the cell lysates (0.5% of total) that were used for precipitation. (B) The effect of overexpressing Pex7p in a pex18 ${Delta}$ pex21 ${Delta}$ strain. Tenfold dilutions of the indicated strains were spotted on oleic acid-containing plates and incubated for 5 days at 30°C. (C) Epistatic analysis of PEX14 and PEX18/PEX21. Precipitation of myc-Pex7p from the indicated oleic acid-induced cells and subsequent analysis of precipitated Fox3p were performed as described for panel A.

Since Fox3p also did not accumulate in a wild-type strain, weanalyzed the possibility that in our experiment, ectopic expressionof myc-Pex7p suppressed the defect of the pex18 ${Delta}$ pex21 ${Delta}$ strain.In that case, growth of the pex18 ${Delta}$ pex21 ${Delta}$ mutant on oleic acidplates should be restored when it is transformed with the myc-Pex7pexpression plasmid. However, as can be seen in Fig. 11B, thisstrain (pex18 ${Delta}$ pex21 ${Delta}$ [myc-Pex7p]) remained deficient in utilizingoleic acid to a degree similar to that of the untransformedstrain (pex18 ${Delta}$ pex21 ${Delta}$ ).

Thus, Pex18p/Pex21p probably act in a step that precedes dockingof Pex7p to the membrane. In that case, the observed increaseof Fox3p bound to myc-Pex7p in a pex14 ${Delta}$ mutant would be abolishedby additionally deleting PEX18 and PEX21. The amount of coimmunoprecipitatedFox3p in a pex14 ${Delta}$ pex18 ${Delta}$ pex21 ${Delta}$ triple-mutant strain was thereforecompared to those of the pex14 ${Delta}$ , pex18 ${Delta}$ pex21 ${Delta}$ , and wild-type strains.Strikingly, an accumulation of Fox3p was not observed in thetriple-deletion strain (Fig. 11C). This result indicates thatthe accumulation of the Pex7p-Fox3p complex in a pex14 ${Delta}$ mutantis dependent on Pex18p/Pex21p and, as a consequence, that thefunction of Pex18p and Pex21p is already required in the importprocess prior to Pex14p and thus before the Fox3p-Pex7p-Pex18p/Pex21pcomplex docks at the peroxisomal membrane.

DISCUSSION

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Discussion

Despite the identification of probably all components of theperoxisomal matrix protein import machinery in recent years(40, 47), the mechanism underlying the translocation processis still largely unknown. In this report, we have shown thatS. cerevisiae Pex13p plays a direct role in PTS2-dependent peroxisomalprotein import and begun to unravel the function of the PTS2-specificperoxins in the early steps of this process.

After their synthesis, PTS2 proteins such as thiolase are specificallyrecognized by Pex7p (36, 56). The recognition of PTS2 by Pex7pdoes not require S. cerevisiae Pex18p/Pex21p, whereas the latterproteins interact with Fox3p only in the presence of Pex7p (34).Our demonstration of yeast Pex7p binding a synthetic PTS2 proteinin vitro goes beyond that of a previous report, where a Pex7pwas used that had been immunoprecipitated from wild-type yeastextracts and thus might have contained other yeast proteins(36). Our first attempts to study in vitro the influence ofPex18p on the Pex7p-PTS2 interaction failed because bacteriallyexpressed Pex18p did not bind Pex7p, even in the concomitantpresence of PTS2 protein (data not shown). However, we couldshow by immunoprecipitation that such a ternary complex of Pex18p,Pex7p, and Fox3p indeed exists, and we substantiated the requirementfor Pex7p in the formation of such a complex. Notwithstandingthat, we found that the Fox3p-Pex7p-containing complex thataccumulates in a pex14 ${Delta}$ strain vanished when PEX18 and PEX21were additionally deleted. S. cerevisiae thiolase is assembledinto its active dimeric form in the cytosol even in the absenceof its PTS2 sequence (17), arguing against an essential rolefor Pex18p/Pex21p in the assembly of enzymatically active Fox3p.Rather, these proteins are required to form an import-competentFox3p complex.

A similar function in thiolase import was proposed for Y. lipolyticaPex20p. This protein binds thiolase autonomously, in a PTS2targeting signal-independent fashion. In fact, Pex20p formshetero-oligomers with Fox3p, an event that is probably mandatoryfor the generation of an import-competent complex (49). In analogyto Pex20p, Pex18p/Pex21p could physically contact Fox3p in thePex7p-bound conformation. In that case, the targeting signalwould be bound by Pex7p, while Pex18p/Pex21p would contact bothPex7p, via their conserved motif (7), and Fox3p, which wouldthen trigger higher-order oligomerization. Alternatively, Pex18p/Pex21pcould assist in forming a Fox3p-Pex7p-containing complex bystabilizing the binding between Pex7p and Fox3p, although theexisting two-hybrid data do not support this idea. Still, bothcases would explain why Pex20p was able to partially complementa pex18 ${Delta}$ pex21 ${Delta}$ mutant strain (8). Oligomerization as a requirementfor import is not just an idiosyncrasy of thiolase. Such a postulatewas already raised upon investigating the import of Candidaboidinii alcohol oxidase, which seemed to depend on the oligomerizationor aggregation at the cytoplasmic side of the peroxisomal membrane(4). Since then, the ability of peroxisomes to import foldedor even oligomeric proteins has been amply recorded (28, 52).

Our data also suggest that a complex is formed that contemporaneouslycontains membrane-associated Pex14p, Pex7p, Pex18p/Pex21p, andFox3p (Fig. 10A). In the absence of either Pex7p or Pex18p/Pex21p,Fox3p was no longer able to interact with Pex14p. On the otherhand, Fox3p failed to interact with the Pex7p-binding domainof Pex13p even in a wild-type strain (Fig. 10B). It is unlikelythat the lack of interaction was caused by a masking of theinteraction domain in Pex13p with the Gal4p moieties, as thesame fusion construct was very efficient in recognizing Pex7pand Pex18p/Pex21p, which in turn were able to interact withthe Fox3p fusion proteins. Thus, we believe that our data pointto a scenario where Pex14p is the initial docking site in PTS2-dependentprotein import. We also considered the possibility of Pex13pconstituting the initial docking site for the empty Pex5p andPex7p, which would only then bind their cargo proteins. However,this is hard to reconcile with the observed formation of a Pex7p-Pex18p/Pex21p-Fox3pcomplex in the pex13 ${Delta}$ mutant, where this complex must have formedin the cytosol. Future biochemical work will have to demonstratewhether cargo-loaded PTS2 receptor can indeed be found in acomplex with Pex14p but not with Pex13p. In mammalian cells,the Pex7p-Pex5pL-PTS2 substrate complex also likely contactsPex14p prior to Pex13p (30). It is worth noting that a similarconclusion was drawn for the PTS1 receptor Pex5p of Pichia pastoris,since substrate-loaded Pex5p bound Pex14p with higher affinitythan Pex5p alone, whereas the opposite was true for Pex13p (50).

In contrast to Fox3p, Pex7p does not require the presence ofPex18p/Pex21p to contact Pex14p (Fig. 3C). Our in vitro bindinganalysis showed that this binding event can even occur in theabsence of any other yeast protein. Pex7p also contacts Pex13pdirectly (Fig. 6), thereby ruling out the possibility of Pex18p/Pex21pbeing adapter proteins between Pex7p and the docking complex.Notably, Y. lipolytica Pex20p did bind S. cerevisiae Pex13pand Pex14p in the absence of Pex7p (8). Thus, in Y. lipolyticathe function of a putative Pex7p might be restricted to targetingsignal recognition, whereas Pex20p might be required to forman import-competent complex as well as to contact the dockingmachinery. Alternatively, Pex20p might contain the functionof both Pex18p/Pex21p and Pex7p. In mammals, the Pex18p-likefactor Pex5pL is able to interact with Pex14p via its diaromaticpentapeptide repeats (13, 41, 54). It is therefore imaginablethat Pex5pL mediates the docking of Pex7p to Pex14p. However,Shimizu and colleagues demonstrated direct binding of Pex7pto Pex14p (45). In this case, it is also possible that Pex5pL,in analogy to Pex18p, is involved in the formation of a PTS2cargo import-competent complex.

In light of our results, the role of Pex13p in PTS2 proteinimport could be substantiated. Deletion of the N-terminal domainof Pex13p, which specifically interacted with Pex7p, affectedPTS2-dependent import but left PTS1 protein import intact. Thelatter observation indicated that Pex14p was correctly targetedto the peroxisomal membrane. As a consequence, the role of Pex13pin PTS2 import is not restricted to the targeting of Pex14p.Rather, Pex13p fulfills an essential step in PTS2 import thatis distinct from that governed by Pex14p. This result also meantthat although the import of both PTS1 and PTS2 requires Pex13p,the two pathways utilize different regions within Pex13p andtherefore do not coincide at the stage of Pex13p in a more narrowsense. Mutations that specifically block one of the two routeshave also been found previously for Pex8p and Pex2p, two peroxinsthat are possibly involved in later steps of the import cascade(22, 25).

The steps following docking are less clear. Peroxisomal importdeviates considerably from the well-established import intomitochondria or the endoplasmic reticulum (43). An obvious proteintranslocation channel is lacking, and the ability to importfolded or even oligomeric proteins must also be taken into account.Interestingly, Pex18p and Pex21p are constantly degraded dueto ubiquitination, which is apparently restricted to the fractionof peroxisomally localized Pex18p/Pex21p (33). Although it remainsto be determined whether the observed degradation of Pex18p/Pex21pis physiologically relevant for PTS2-dependent protein import,it could be that Pex18p/Pex21p are required not only for theformation of an import-competent PTS2 cargo protein complexbut also for a step that follows docking.

ACKNOWLEDGMENTS

We are grateful to M. Nündel for excellent technical assistance.We thank X. Hong for plasmids His₆-PEX14 and His₆-PEX7, R. Bahadorifor plasmid pRB107, A. Hartig for plasmid pJR233, B. Seraphinfor plasmid pBS1479, H. Otto for anti-myc antibodies, and particularlyW. H. Kunau for the provision of plasmids, strains, and antibodies.

This work was supported by the Deutsche Forschungsgemeinschaft,grants ER178/2-3 and SFB449, and by the Fonds der DeutschenChem. Industrie. H.R. was supported by an EMBO long-term fellowship(ALTF255-2000).

FOOTNOTES

* Corresponding author. Mailing address: Freie Universität Berlin, Institut für Chemie/Biochemie, Thielallee 63, D-14195 Berlin, Germany. Phone: 43-30-838 52935. Fax: 43-30-838 52936. E-mail: ralferdm{at}zedat.fu-berlin.de.

REFERENCES

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