The peroxisomal targeting signal of 3-oxoacyl-coA thiolase from Saccharomyces cerevisiae

All peroxisomal 3-oxoacyl-CoA thiolases identified so far do not contain the previously identified tripeptide peroxisomal targeting signal at their carboxy-termini. For the two rat thiolases it was shown that their peroxisomal targeting signals are localized within the amino-terminal region of the proteins and are cleaved upon import. This report demonstrates that the N-terminal region of the peroxisomal 3-oxoacyl-CoA thiolase from Saccharomyces cerevisiae is essential for its peroxisomal targeting, and that the N-terminal 16 amino acids of yeast thiolase are sufficient to target the otherwise cytosolic small subunit of ribulose-1,5-bisphosphate carboxylase to peroxisomes for import.     

Analysis of the peroxisomal acyl‐CoA oxidase gene product from Pichia pastoris and determination of its targeting signal

Acyl‐CoA oxidase (Pox1p) is involved in the β‐oxidation of fatty acids and is targeted to the peroxisomal matrix via the use of different signals in various organisms. In rat, mouse and human, Pox1p contains a canonical peroxisomal targeting signal 1 (PTS1), whereas in the yeasts Candida tropicalis, Saccharomyces cerevisiae, C. maltosa and Yarrowia lipolytica neither a PTS1 nor a PTS2 sequence is present, suggesting that Pox1p might be targeted to the peroxisomes via a third unknown pathway. Alternatively, since proteins lacking a PTS sequence can enter peroxisomes in association with other polypeptides containing a PTS, Pox1p might ‘piggy‐back’ its way into the peroxisomal matrix together with other proteins. To understand the mechanism of peroxisomal targeting of a yeast Pox1p, we cloned the Pichia pastoris POX1 gene to study the pathway of import of PpPox1p into peroxisomes. The gene was cloned by PCR, hybridization and plasmid rescue. The 2157 bp gene encodes a protein with a predicted molecular weight of 80 kDa. Antisera against PpPox1p detected a protein specifically induced on oleate with an apparent molecular weight of 72 kDa. Immunolocalization studies confirmed the peroxisomal localization of PpPox1p. The carboxy‐terminus of PpPox1p ends with a PTS1‐like sequence, APKI. The sequence PKI was necessary for transport of PpPox1p into peroxisomes and interacted with the PTS1 receptor, Pex5p. Furthermore, addition of the sequence APKI to the C‐terminus of the green fluorescent protein directed this fusion protein to the peroxisome. Therefore, PpPox1p uses the PTS1 pathway for its import into peroxisomes. Copyright © 1999 John Wiley & Sons, Ltd.     

Predicting the function and subcellular location of Caenorhabditis elegans proteins similar to Saccharomyces cerevisiae beta-oxidation enzymes

The role of peroxisomal processes in the maintenance of neurons has not been thoroughly investigated. We propose using Caenorhabditis elegans as a model organism for studying the molecular basis underlying neurodegeneration in certain human peroxisomal disorders, e.g. Zellweger syndrome, since the nematode neural network is well characterized and relatively simple in function. Here we have identified C. elegans PEX-5 (C34C6.6) representing the receptor for peroxisomal targeting signal type 1 (PTS1), defective in patients with such disorders. PEX-5 interacted strongly in a two-hybrid assay with Gal4p-SKL, and a screen using PEX-5 identified interaction partners that were predominantly terminated with PTS1 or its variants. A list of C. elegans proteins with similarities to well-characterized yeast beta-oxidation enzymes was compiled by homology probing. The possible subcellular localization of these orthologues was predicted using an algorithm based on trafficking signals. Examining the C termini of selected nematode proteins for PTS1 function substantiated predictions made regarding the proteins' peroxisomal location. It is concluded that the eukaryotic PEX5-dependent route for importing PTS1-containing proteins into peroxisomes is conserved in nematodes. C. elegans might emerge as an attractive model system for studying the importance of peroxisomes and affiliated processes in neurodegeneration, and also for studying a beta-oxidation process that is potentially compartmentalized in both mitochondria and peroxisomes.     

Peroxisome-deficient mutants of Hansenula polymorpha

As a first step in a genetic approach towards understanding peroxisome biogenesis and function, we have sought to isolate mutants of the methylotrophic yeast Hansenula polymorpha which are deficient in peroxisomes. A collection of 260 methanol-utilization-defective strains was isolated and screened for the ability to utilize a second compound, ethanol, the metabolism of which involves peroxisomes. Electron microscopical investigations of ultrathin sections of selected pleiotropic mutants revealed two strains which were completely devoid of peroxisomes. In both, different peroxisomal matrix enzymes were active but located in the cytosol; these included catalase, alcohol oxidase, malate synthase and isocitrate lyase. Subsequent backcrossing experiments revealed that for all crosses involving both strains, the methanol- and ethanol utilizing-deficient phenotypes segregated independently of each other, indicating that different gene mutations were responsible for these phenotypes. The phenotype of the backcrossed peroxisome-deficient derivates was identical: defective in the ability to utilize methanol but capable of growth on other carbon sources, including ethanol. The mutations complemented and therefore were recessive mutations in different genes.     

Regulation of peroxisomal proteins and organelle proliferation by multiple carbon sources in the methylotrophic yeast,Candida boidinii

A methylotrophic yeast, Candida boidinii, was grown on various combinations of peroxisome-inducing carbon source(s) (PIC(s)), i.e. methanol, oleate and d-alanine, and the regulation of peroxisomal proteins (both matrix and membrane ones) and organelle proliferation were studied. This regulation was followed (1) at the protein or enzyme level by means of the peroxisomal enzyme activity and Western analysis; (2) at the mRNA level by Northern analysis; and (3) at the organelle level by direct observation of peroxisomes under a fluorescent microscope. Peroxisomal proliferation was followed in vivo by using a C. boidinii strain producing a green fluorescent protein having peroxisomal targeting signal 1. When multiple PICs were used for cell growth, C. boidinii induced specific peroxisomal proteins characteristic of all PIC(s) present in the medium, responding to all PIC(s) simultaneously. Thus, these PICs were considered to induce peroxisomal proliferation independently and not to repress peroxisomes induced by other PICs. Next, the sensitivity of the peroxisomal induction to glucose repression was studied. While the peroxisomal induction by methanol or oleate was completely repressed by glucose, the d-alanine-induced activities of d-amino acid oxidase and catalase, Pmp47, and the organelle proliferation were not. These results indicate that peroxisomal proliferation in yeasts is not necessarily sensitive to glucose repression. Lastly, this regulation was shown to occur at the mRNA level. © 1998 John Wiley & Sons, Ltd.     

Peroxisomal amine oxidase of Hansenula polymorpha does not require its SRL-containing C-terminal sequence for targeting

Amine oxidase (AMO) is a peroxisomal matrix protein of Hansenula polymorpha, which is induced during growth of the yeast in media containing primary amines as a sole nitrogen source. The deduced amino acid sequence of the protein contains an SRL sequence at nine amino acids from the C-terminus. In this study, we have examined the possible role of the SRL motif in sorting of AMO to peroxisomes by mutating the corresponding gene sequence. For this purpose, we have developed a DNA construct that is specifically integrated into the AMO locus of the H. polymorpha genome, placing the mutant gene under the control of the endogenous AMO promoter and eliminating expression of the wild-type gene. Analysis of a stable transformant, containing the desired gene configuration, showed that mutation of the C-terminal sequence neither interfered with correct targeting of the protein into the peroxisome nor displayed significant effects on its activity. From this, it was concluded that the SRL-containing C-terminus is not essential for peroxisomal targeting of AMO in H. polymorpha.     

Deviant Pex3p Levels affect Normal Peroxisome Formation in Hansenula polymorpha: A Sharp Increase of the Protein Level Induces the Proliferation of Numerous,Small Protein-import Competent Peroxisomes

Pex3p has been implicated in the biosynthesis of the peroxisomal membrane of the yeast Hansenula polymorpha. Here we show that in the initial stages of a sharp increase in Pex3p levels, induced in batch cultures of cells of a constructed H. polymorpha strain, which contained seven copies of PEX3 under control of the alcohol oxidase promoter (WT::P_AOX.PEX3^7x), strongly interfered with normal peroxisome proliferation. Ultrastructural studies demonstrated that in such cells numerous small peroxisomes had developed, which were absent in wild-type controls. These organelles, which contained typical peroxisomal matrix and membrane proteins (alcohol oxidase, catalase, Pex3p, Pex10p and Pex14p), showed a relatively low density (1·18 g cm⁻³) after sucrose gradient centrifugation of WT::P_AOX.PEX3^7x homogenates, compared to normal peroxisomes (1·23 g cm⁻³). We furthermore demonstrated that these early induced, small peroxisomes were protected against glucose-induced proteolytic degradation and did not fuse to form larger organelles. Remarkably, the induction of these small peroxisomes was paralleled by a partial defect in matrix protein import, reflected by the mislocalization of minor amounts of alcohol oxidase protein in the cytosol. However, when the cells were subsequently placed under conditions in which the synthesis of a new matrix enzyme (amine oxidase) was induced while simultaneously the excessive proliferation was repressed (by repression of the P_AOX), amine oxidase protein was selectively incorporated into these organelles. This indicated that the small peroxisomes had regained a normal protein import capacity. Based on these results we argue that peroxisome proliferation and matrix protein import are coupled processes in H. polymorpha. © 1997 John Wiley & Sons, Ltd.     

Antibodies directed against a yeast carboxyl-terminal peroxisomal targeting signal specifically recognize peroxisomal proteins from various yeasts.

The carboxyl-terminal tripeptide Ala-Lys-Ile is essential for targeting Candida tropicalis trifunctional enzyme (hydratase-dehydrogenase-epimerase) to peroxisomes of both Candida albicans and Saccharomyces cerevisiae (Aitchison,J.D., Murray, W.W. and Rachubinski, R. A. (1991).J. Biol. Chem. 266, 23197-23203). We investigated the possibility that this tripeptide may act as a general peroxisomal targeting signal (PTS) for other proteins in the yeasts C. tropicalis, C. albicans, Yarrowia lipolytica and S. cerevisiae, and in rat liver. Anti-AKI antibodies raised against the carboxyl-terminal 12 amino acids of trifunctional enzyme were used to search for this PTS in proteins of these yeasts and of rat liver. The anti-AKI antibodies reacted exclusively with multiple peroxisomal proteins from the yeasts C. tropicalis, C. albicans and Y. lipolytica. There was a weak reaction of the antibodies with one peroxisomal protein from S. cerevisiae and no reaction with peroxisomal proteins from rat liver. Antibodies directed against a synthetic peptide containing a carboxyl-terminal Ser-Lys-Leu PTS (Gould, S. J., Krisans, S., Keller, G.-A. and Subramani, S. (1990). J. Cell Biol. 110,27-34) reacted with multiple peroxisomal proteins of rat liver and with peroxisomal proteins of yeast distinct from those identified with anti-AKI antibodies. These results provide evidence that several peroxisomal proteins of different yeasts contain a PTS antigenically similar to that of C. tropicalis trifunctional enzyme and that this signal is absent from peroxisomal proteins from at least one mammalian system, rat liver.     

Rapid identification and characterization of peroxisomal assembly mutants in Yarrowia lipolytica

We describe the isolation and characterization of p eroxisomal a ssembly mutants in the genetically manipulable yeast Y arrowia lipolytica (pay mutants). These mutants were initially identified as oleic acid-non-utilizers by their inability to grow on oleic acid, the utilization of which requires peroxisomal β-oxidation enzymes. Identification of a subset of oleic acid-non-utilizers as pay mutants was obtained by a rapid immunofluorescence procedure using antibodies to the peroxisomal targeting signal Ser-Lys-Leu-CO₂H. Punctate structures characteristic of peroxisomes were not detected in pay mutants using this technique. This rapid identification by immunofluorescence should be generally applicable to the selection of peroxisomal assembly mutants in other yeasts. To take advantage of the pay mutant system, we constructed a genomic library in the autonomously replicating vector pINA445 and developed an efficient and rapid electroporation procedure for the functional complementation of these mutants. We have been successful in functionally complementing two independent pay mutants. Molecular analysis of these and other complementing genes will allow for characterization of some of the cellular elements involved in peroxisomal assembly.     

One-step measurement of firefly luciferase activity in yeast

Firefly luciferase is often used as a sensitive genetic reporter in various cell types. The pitfall in yeast, however, has been the need to break down the rigid cells in order to measure the enzyme activity. In this study we have removed the peroxisomal targeting codons from the Photinus pyralis luciferase gene (luc) and shown that in the yeast Saccharomyces cerevisiae this modified luciferase gives high levels of light emission that is easy to measure from intact living cells. Furthermore, cells with the modified luciferase grew essentially faster than those with the wild-type luciferase, indicating that peroxisomal targeting of a foreign enzyme puts some constraints to cellular viability. As a model system we used two different reporter constructs. In the first, expression of the luciferase gene is under control of CUP1-promoter, a well known yeast promoter that is inducible by copper ions. In the second, luciferase activity is dependent on activation of the human oestrogen receptor and its interaction with oestrogen-responsive elements incorporated in a yeast promoter. The luciferase activity measurement could be done on a 96-well plate by simple addition of the substrate, D-luciferin, at a moderately acidic pH of 5.0. The ease of use of the non-peroxisomal luciferase makes it an interesting alternative for reporter genes that are conventionally used in yeast, such as lacZ.     

Selective inactivation of alcohol oxidase in two peroxisome-deficient mutants of the yeast Hansenula polymorpha.

We have studied selective inactivation of alcohol oxidase (AO) in two peroxisome-deficient (PER) mutants of the yeast Hansenula polymorpha. In these mutants high activities of cytosolic AO are induced by different growth conditions. At enhanced expression rates AO is arranged in large crystalloids in the cytosol, whereas smaller crystalloids are often observed inside the nucleus. Transfer of cells of the PER mutant 125-2E, which completely lacks peroxisomes, to glucose-excess conditions did not lead to degradative inactivation of AO and catalase as observed in wild-type (WT) cells used as a control. The gradual decrease in enzyme activities in the PER mutant could be accounted for by dilution of existing enzyme into newly formed cells as a result of growth. Morphologically, degradation of the cytosolic crystalloids was also not observed. Similar results were obtained with a second PER mutant (strain 124-2D), impaired in the import of peroxisomal matrix proteins. This mutant is characterized by the presence of small peroxisomes and large cytosolic AO crystalloids. Upon a shift of cells to glucose-excess conditions only part of the small peroxisomes present in these cells were degraded by mechanisms similar to those observed in WT cells placed under identical conditions. These results indicate that degradative inactivation of AO in H. polymorpha is strictly dependent on the localization of the enzyme inside peroxisomes and furthermore suggests that the mechanisms triggering this process are not directed against AO protein, but instead, to the membrane surrounding the organelle. Transfer of cells to methanol- or ethanol-containing media both resulted in modification inactivation of AO.(ABSTRACT TRUNCATED AT 250 WORDS)     

Isolation and characterization of peroxisomal protein import (Pim−) mutants of Hansenula polymorpha

In the course of our studies on the molecular mechanisms involved in peroxisome biogenesis, we have isolated several mutants of the methylotrophic yeast Hansenula polymorpha impaired in the import of peroximal matrix proteins. These mutants are characterized by the presence of small intact peroxisomes, while the bulk of the peroxisomal matrix protein is not imported and resides in the cytosol (Pim^? phenotype). Genetic analysis of back-crossed mutants revealed five different complementation groups, which were designated PERI–PER5. Mapping studies to determine the linkage relationships indicated that the observed Pim^? phenotypes were determined by single recessive nuclear mutations. The different mutants had comparable phenotypes: (i) they were impaired to utilize methanol as the sole source of carbon and energy but grew well on various other compounds, including nitrogen sources, the metabolism of which is known to be mediated by peroxisome-borne enzymes in wild-type cells; (ii) all peroxisomal enzymes tested were induced, assembled and activated as in wild-type cells although their activities varied between the different representative mutants; (iii) all peroxisomal proteins, whether constitutive or inducible, were found both in the cytosol and in the small peroxisomes. These results suggest that a general, major import mechanism is affected in all mutants.     

Molecular characterization of the PEX5 gene encoding peroxisomal targeting signal 1 receptor from the methylotrophic yeast Pichia methanolica

In this study, we describe the molecular characterization of the PEX5 gene encoding the peroxisomal targeting signal 1 (PTS1) receptor from the methylotrophic yeast Pichia methanolica. The P. methanolica PEX5 (PmPEX5) gene contains a open reading frame corresponding to a gene product of 646 amino acid residues, and its deduced amino acid sequence shows a high similarity to those of Pex5ps from other methylotrophic yeasts. Like other Pex5ps, the PmPex5p possesses seven repeats of the TPR motif in the C-terminal region and three WXXXF/Y motifs. A strain with the disrupted PEX5 gene (pex5Delta) lost its ability to grow on peroxisome-inducible carbon sources, methanol and oleate, but grew normally on glucose and glycerol. Disruption of PmPEX5 caused a drastic decrease in peroxisomal enzyme activities and mislocalization of GFP-PTS1 and some peroxisomal methanol-metabolizing enzymes in the cytosol. Expression of the PmPEX5 gene was regulated by carbon sources, and it was strongly expressed by peroxisome-inducible carbon sources, especially methanol. Taken together, these findings show that PmPex5p has an essential physiological role in peroxisomal metabolism of P. methanolica, including methanol metabolism, and in peroxisomal localization and activation of methanol-metabolizing enzymes, e.g. AOD isozymes, DHAS and CTA.     

Predominant localization of non-specific lipid-transfer protein of the yeast Candida tropicalis in the matrix of peroxisomes

PXP-18 is a 14-kDa major peroxisomal protein of the yeast Candida tropicalis and a homologue of the non-specific lipid-transfer protein (nsLTP) of mammals. Mammalian nsLTP is thought to facilitate the contact of membranes, to stimulate lipid-transfer between them. If PXP-18 functions like nsLTP, it must be present on organelle membranes. Immunoelectron microscopy of C. tropicalis cells indicated that gold particles, which visualized PXP-18, localized exclusively in the matrix of peroxisomes. Subcellular fractionation followed by Western blotting revealed the association of PXP-18 with peroxisomes in C. tropicalis cells. An enzyme-linked immunosorbent assay revealed that almost all the PXP-18 associated with peroxisomes was detectable after the solubilization of the organelle but not before, implying the predominance of PXP-18 inside peroxisomes. This differential assay was applied to the intracellular import of the intact and truncated PXP-18s expressed in Saccharomyces cerevisiae cells. Most of the intact PXP-18 was shown to be imported into the matrix of host-cell peroxisomes, whereas the truncated PXP-18, which lacked the C-terminal tripeptide Pro-Lys-Leu, no longer targeted peroxisomes. These results are consistent with the view that PXP-18 is the matrix protein of peroxisomes and must function in a system other than that of lipid transfer.     

Excessive membrane development following exposure of the methylotrophic yeast Hansenula polymorpha to oleic acid-containing media

We studied the physiological responses of Hansenula polymorpha during adaptation of cells to oleic acid-containing media. Growth experiments indicated that the organism was unable to use oleic acid as the sole source of carbon and energy. However, upon incubation of glucose-grown cells in mineral media containing oleic acid, activities of various enzymes of the β-oxidation pathway were induced. These enzymes were localized in microbodies together with alcohol oxidase. Furthermore, a drastic increase in phospholipid content of the cells was observed; this was due to a rapid proliferation of membranes. These consisted of a variable number of membranous layers which were continuous with the peroxisomal membrane. Upon continued incubation, the membrane proliferations extended and large compartments were formed. This process was dependent on the presence of peroxisomes in the cells since it was not observed in peroxisome-deficient mutant strains of H. polymorpha. The newly formed membranous compartments differed from peroxisomes since they did not contain peroxisomal matrix proteins; these were confined to the single enlarged organelle which was incorporated in the membranous structure and characterized by a large alcohol oxidase crystalloid. The membranous compartments are considered to be whole entities since they could not be separated from the peroxisomes by common cell fraction methods; also they were degraded entirely after a shift of cells to glucose-excess condition. Freeze fracturing reveled that the substructure of the membranes greatly resembled that of normal peroxisomal membranes. Since a distinct enhancement of different peroxisomal membrane proteins was observed during the initial hours after the shift, we assume that exposure of H. polymorpha to acid lead to a drastic overproduction of peroxisomal membranes.     

Pichia pastoris Pex14p, a phosphorylated peroxisomal membrane protein, is part of a PTS-receptor docking complex and interacts with many peroxins

The peroxisomal protein import machinery plays a central role in the assembly of this organelle in all eukaryotes. Genes encoding components of this machinery, termed peroxins or Pex proteins, have been isolated and characterized in several yeast species and in mammals, including humans. Here we report on one of these components, Pex14p, from the methylotrophic yeast Pichia pastoris. Work in other organisms has shown that Pex14p is located on the cytoplasmic surface of the peroxisomal membrane and binds peroxisomal targeting signal (PTS) receptors carrying proteins bound for the peroxisomal matrix, results that have led to the hypothesis that Pex14p is a receptor-docking protein. P. pastoris Pex14p (PpPex14p) behaves like an integral membrane protein, with its C-terminus exposed on the cytosolic side of the peroxisomal membrane. PpPex14p complexes with many peroxins, including Pex3p (Snyder et al., 1999b), Pex5p, Pex7p, Pex13p, Pex17p, itself, and a previously unreported peroxin, Pex8p. A portion of Pex14p is phosphorylated, but both phosphorylated and unphosphorylated forms of Pex14p interact with several peroxins. The interactions between Pex14p and other peroxins provide clues regarding the function of Pex14p in peroxisomal protein import.     

Identification of peroxisomal membrane ghosts with an epitope-tagged integral membrane protein in yeast mutants lacking peroxisomes

Many yeast peroxisome biogenesis mutants have been isolate in which peroxisomes appear to be completely absent. Introduction of a wild-type copy of the defective gene causes the reappearance of peroxisomes, despite the fact that new peroxisomes are thought to form only from pre-existing peroxisomes. This apparent paradox has been explained for similar human mutant cell lines (from patients with Zellweger syndrome) by the discovery of peroxisomal membrane ghosts in the mutant cells (Santos, M. J., T. Imanaka, H. Shio, G. M. Small and P. B. Lazarow. 1988. Science 239 , 1536–1538). Introduction of a wild-type gene is thought to restore to the ghosts the ability to import matrix proteins, and thus lead to the refilling of the peroxisomes. It is vitally important to our understanding of peroxisome biogenesis to determine whether the yeast mutants contain ghosts. We have solved this problem by introducing an epitope-tagged version of Pas3p, a peroxisome integral membrane protein (that is essential for peroxisome biogenesis). Nucleotides encoding a nine amino acid HA epitope were added to the PAS3 gene immediately before the stop codon. The tagged gene (PAS3_HA) was inserted in the genome, replacing the wild-type gene at its normal locus. It was fully functional (the cells assembled peroxisomes normally and grew on oleic acid) but the expression level was too low to detect the protein with monoclonal antibody 12CA5. PAS3_HA was expressed in greater quantity from an episomal plasmid with the CUP1 promoter. The gene product, Pas3p_HA, was detected by immunogold labelling on the membranes of individual and clustered peroxisomes; the clusters appeared as large spots in immunofluorescence. PAS3_HA was similarly expressed in peroxisome biogenesis mutants peb2 and peb4, which lack morphologically recognizable peroxisomes. Gold-labelled membranes were clearly visible in both mutants: in peb2 the labelled membrane vesicles were generally much smaller than those in peb4, which resembled normal peroxisomes in size.     

Subcellular localization of fructosyl amino acid oxidases in peroxisomes of Aspergillus terreus and Penicillium janthinellum

Fructosyl amino acid oxidase (FAOD) is the enzyme catalyzing the oxidative deglycation of Amadori compounds, such as fructosyl amino acids, yielding the corresponding amino acids, glucosone, and H(2)O(2). In a previous report, we determined the primary structures of cDNAs coding for FAODs from two fungal strains Aspergillus terreus AP1 and Penicillium janthinellum and we found that both fungal FAODs included the putative peroxisome targeting signal 1 (PTS1) at the carboxyl terminal (Yoshida, N. et al., Eur. J. Biochem., 242, 499-505, 1996). In this study, we determined the intracellular localization of FAODs in these two fungi. Subcellular fractionation experiments and immuno-electronmicroscopic observations, together with the previous findings indicated that the FAODs were localized in peroxisomes of A. terreus AP1 and P. janthinellum. These FAODs were also found to belong to a new member of "peroxisomal sarcosine oxidase family protein" in eucaryotic cells.     

Purification and immunolocalization of the peroxisomal 3-oxoacyl-coA thiolase from Saccharomyces cerevisiae

A molecular understanding of peroxisome biogenesis depends upon the analysis of peroxisomal proteins. Here we describe the isolation of the 3-oxoacyl-CoA thiolase of the peroxisomal β-oxidation system from Saccharomyces cerevisiae as a dimer of identical subunits, each with a molecular mass of 45 kDa. Monospecific polyclonal antibodies were raised against the purified enzyme, and its peroxisomal origin was demonstrated by immunoblotting of subcellular fractions as well as by immunogold labelling. We also show that these antibodies could be suitable for an immunofluorescence microscopy screening of yeast mutants affected in peroxisome assembly.