Partial phenotypic suppression of a peroxisome-deficient animal cell mutant treated with aminoglycoside G418.

Certain enzymes normally associated with peroxisomes, such as the dihydroxyacetone phosphate (DHAP) acyltransferase involved in plasmalogen biosynthesis, are present at low levels in peroxisome-deficient mutants of Chinese hamster ovary (CHO) cells. We now show that the aminoglycoside G418 increases the residual DHAP acyltransferase in mutant ZR-82 by 60-fold. This is accompanied by a dose- and time-dependent restoration of the plasmalogen content. G418 treatment of ZR-82 also increases residual peroxisomal beta-oxidation activity by 3.8-fold. G418 does not affect wild-type CHO cells (CHO-K1) or a different peroxisome-deficient mutant, ZR-78.1. The effects of G418 on ZR-82 are transient, since plasmalogens and DHAP-acyltransferase decline to basal levels 5 days after G418 withdrawal. Other aminoglycosides and lysosomotropic agents do not alter plasmalogen levels in ZR-82. The subcellular distribution of catalase (an enzyme of the peroxisomal matrix which is present in normal amounts in peroxisome-deficient mutants but is mislocalized in the cytosol) is unaffected by G418 treatment of ZR-82, demonstrating that G418 does not restore peroxisomes. Localization of catalase by immunofluorescence microscopy confirms a total absence of intact peroxisomes in ZR-82, either before or after exposure to G418. This study is the first to demonstrate that some peroxisome-deficient mutants can be induced to accumulate functional DHAP acyltransferase and other peroxisomal enzymes, usually missing in the absence of peroxisomes. G418 may have some therapeutic value in selected patients with inborn errors of peroxisome assembly, such as Zellweger syndrome.     

Rapid isolation and characterization of CHO mutants deficient in peroxisome biogenesis using the peroxisomal forms of fluorescent proteins

We isolated and characterized CHO mutants deficient in peroxisome assembly using green fluorescent protein (GFP) and blue fluorescent protein (BFP) as the fluorescent probes to study the molecular mechanism of peroxisome biogenesis. We used stable transformants of CHO cells expressing GFP appending peroxisome targeting signal-1 (PTS1) and/or peroxisome targeting signal-2 (PTS2) as the parent strains for rapid isolation of the mutants. We have obtained six peroxisome-deficient mutants by visual screening of the mislocalizations of the peroxisomal GFPs. Mutual cell fusion experiments indicated that the six mutants isolated were divided into four complementation groups. Several of the mutants obtained possessed defective genes: the PEX2 gene was defective in SK24 and PT54; the PEX5 gene in SK32 and the PEX7 gene in PT13 and PT32. BE41, which belonged to the fourth complementation group, was not determined. When peroxisomal forms of BFP were transiently expressed in mutant cells, the peroxisomal BFPs appending both PTS1 and PTS2 appeared to bypass either the PTS1 or PTS2 pathway for localization in SK32. This observation suggested that other important machinery, in addition to the PTS1 or PTS2 pathway, could be involved in peroxisome biogenesis. Thus, our approach using peroxisomal fluorescent proteins could facilitate the isolation and analysis of peroxisome-deficient CHO mutants and benefit studies on the identification and role of the genes responsible for peroxisome biogenesis.     

Cloning and characterization of PAS5: a gene required for peroxisome biogenesis in the methylotrophic yeast Pichia pastoris

The biogenesis and maintenance of cellular organelles is of fundamental importance in all eukaryotic cells. One such organelle is the peroxisome. The establishment of a genetic system to study peroxisome biogenesis in the methylotrophic yeast Pichia pastoris has yielded many different complementation groups of peroxisomal assembly (pas) or peroxisome-deficient (per) mutants. Each appears to be deficient in functional peroxisomes. One of these mutants, pas5, has been characterized, complemented, and the gene sequenced. Ultrastructural studies show that normal peroxisomes are not present in pas5, but aberrant peroxisomal structures resembling "membranous ghosts" are frequently observed. The "peroxisome ghosts" appear to be induced and segregated to daughter cells normally. Biochemical fractionation analysis of organelles of the pas5 mutant reveals that peroxisomal matrix enzymes are induced normally but are found mostly in the cytosol. However, purification of peroxisome ghosts from the mutant shows that small amounts (< 5%) of matrix enzymes are imported. The PAS5 gene was cloned and found to encode a 127-kD protein, which contains a 200-amino acid-long region of homology with PAS1, NEM- sensitive factor (NSF), and other related ATPases. Weak homology to a yeast myosin was also observed. The gene is not essential for growth on glucose but is essential for growth on oleic acid and methanol. The role of PAS5 in peroxisome biogenesis is discussed.     

Hydroxyeicosatetraenoic acid oxidation in Chinese hamster ovary cells: a peroxisomal metabolic pathway

To evaluate the peroxisomal requirement for beta-oxidation of hydroxyeicosatetraenoic acids (HETES), we tested 5-, 12- and 15-HETE oxidation in wild-type and mutant Chinese hamster ovary (CHO) cells. Mutant CHO cells contain peroxisomal ghosts, have random cytosolic localization of catalase and lack two of the enzymes necessary for peroxisomal beta-oxidation. Reverse-phase HPLC indicated that 33% of 12-HETE radioactivity was converted by wild-type CHO cells during a 2 h incubation to one major and several minor polar metabolites. Wild-type CHO cells also converted 15-HETE to one major and several minor polar metabolites. Neither 12- nor 15-HETE were converted to any metabolites by the mutant CHO cell lines, despite appreciable cellular uptake of these hydroxyeicosanoids. 5-HETE was not converted to any metabolic products by either the wild-type or the mutant CHO cells. Docosahexaenoic acid beta-oxidation was substantially reduced in the mutants as compared to the wild-type cells, palmitic acid beta-oxidation was reduced to an intermediate extent in the mutants, but octanoate beta-oxidation and citrate synthase activity were not impaired. Protein immunoblotting for mitochondrial manganese superoxide dismutase indicated a single band of identity at 20 kDa in both wild-type and mutant CHO cells. Since mutant CHO cells fail to convert 12- and 15-HETE to oxidative metabolites but contain normal mitochondrial enzymatic activities, intact peroxisomes appear to be the organelle responsible for HETE oxidation.     

Chinese hamster ovary cell mutants defective in peroxisome biogenesis. Comparison to Zellweger syndrome

We have previously reported the isolation of Chinese hamster ovary (CHO) cell mutants that are defective in the biosynthesis of plasmalogens, deficient in at least two peroxisomal enzymes (dihydroxyacetonephosphate (DHAP) acyltransferase and alkyl-DHAP synthase), and in which catalase is not found within peroxisomes (Zoeller, R. A., and Raetz, C. R. H. (1986) Proc. Natl. Acad. Sci. U.S.A. 83, 5170). We now provide further evidence that three such strains are more generally defective in peroxisome biogenesis. Electron microscopic cytochemistry revealed that the mutants did not contain recognizable peroxisomes. However, immunofluorescence microscopy using an antibody directed against peroxisomal integral membrane proteins revealed the presence of peroxisomal membrane ghosts resembling those seen in cells of patients suffering from one of the human peroxisomal disorders, Zellweger syndrome. Immunoblot analyses, using antibodies specific for peroxisomal matrix proteins, demonstrated deficiencies of peroxisomal proteins in the mutant CHO cells that were similar to those in Zellweger syndrome. Fusion of a CHO mutant with fibroblasts obtained from Zellweger patients resulted in restoration of peroxisomal dihydroxyacetonephosphate acyltransferase and peroxisomal acyl-coenzyme A oxidation activities. The hybrid cells also regained the ability to synthesize plasmenylethanolamine. Moreover, normal peroxisomes were seen by immunofluorescence in the hybrid cells. These results indicate that the hybrid cells have recovered the ability to assemble peroxisomes and that, although the mutant CHO cells are biochemically and morphologically very similar to cells from patients with Zellweger syndrome, the genetic lesions are distinct. Our somatic cell mutants should be useful in identifying factors and genes involved in peroxisome biogenesis and may aid the genetic categorization of the various peroxisomal disorders.     

An Efficient Positive Selection Procedure for the Isolation of Peroxisomal Import and Peroxisome Assembly Mutants of Saccharomyces Cerevisiae

To study peroxisome biogenesis, we developed a procedure to select for Saccharomyces cerevisiae mutants defective in peroxisomal protein import or peroxisome assembly. For this purpose, a chimeric gene was constructed encoding the bleomycin resistance protein linked to the peroxisomal protein luciferase. In wild-type cells this chimeric protein is imported into the peroxisome, which prevents the neutralizing interaction of the chimeric protein with its toxic phleomycin ligand. Peroxisomal import and peroxisome assembly mutants are unable to import this chimeric protein into their peroxisomes. This enables the bleomycin moiety of the chimeric protein to bind phleomycin, thereby preventing its toxicity. The selection is very efficient: upon mutagenesis, 84 (10%) of 800 phleomycin resistant colonies tested were unable to grow on oleic acid. This rate could be increased to 25% using more stringent selection conditions. The selection procedure is very specific; all oleic acid non utilizing (onu) mutants tested were disturbed in peroxisomal import and/or peroxisome assembly. The pas (peroxisome assembly) mutants that have been used for complementation analysis represent 12 complementation groups including three novel ones, designated pas20, pas21 and pas22.     

Regulation of peroxisome size and number by fatty acid beta -oxidation in the yeast yarrowia lipolytica

The Yarrowia lipolytica MFE2 gene encodes peroxisomal beta-oxidation multifunctional enzyme type 2 (MFE2). MFE2 is peroxisomal in a wild-type strain but is cytosolic in a strain lacking the peroxisomal targeting signal-1 (PTS1) receptor. MFE2 has a PTS1, Ala-Lys-Leu, that is essential for targeting to peroxisomes. MFE2 lacking a PTS1 can apparently oligomerize with full-length MFE2 to enable targetting to peroxisomes. Peroxisomes of an oleic acid-induced MFE2 deletion strain, mfe2-KO, are larger and more abundant than those of the wild-type strain. Under growth conditions not requiring peroxisomes, peroxisomes of mfe2-KO are larger but less abundant than those of the wild-type strain, suggesting a role for MFE2 in the regulation of peroxisome size and number. A nonfunctional version of MFE2 did not restore normal peroxisome morphology to mfe2-KO cells, indicating that their phenotype is not due to the absence of MFE2. mfe2-KO cells contain higher amounts of beta-oxidation enzymes than do wild-type cells. We also show that increasing the level of the beta-oxidation enzyme thiolase results in enlarged peroxisomes. Our results implicate peroxisomal beta-oxidation in the control of peroxisome size and number in yeast.     

Role of peroxisomes in isoprenoid biosynthesis.

Our group and others have recently demonstrated that peroxisomes contain a number of enzymes involved in cholesterol biosynthesis that previously were considered to be cytosolic or located in the endoplasmic reticulum (ER). Peroxisomes have been shown to contain HMG-CoA reductase, mevalonate kinase, phosphomevalonate kinase, phosphomevalonate decarboxylase, isopentenyl diphosphate isomerase, and FPP synthase. Four of the five enzymes required for the conversion of mevalonate to FPP contain a conserved putative PTS1 or PTS2, supporting the concept of targeted transport into peroxisomes. To date, no information is available regarding the function of the peroxisomal HMG-CoA reductase in cholesterol/isoprenoid metabolism, and the structure of the peroxisomal HMG-CoA reductase has yet to be determined. We have identified a mammalian cell line that expresses only one HMG-CoA reductase protein, and which is localized exclusively to peroxisomes, to facilitate our studies on the function, regulation, and structure of the peroxisomal HMG-CoA reductase. This cell line was obtained by growing UT2 cells (which lack the ER HMG-CoA reductase) in the absence of mevalonate. The surviving cells exhibited a marked increase in a 90-kD HMG-CoA reductase that was localized exclusively to peroxisomes. The wild-type CHO cells contain two HMG-CoA reductase proteins, the well-characterized 97-kD protein localized in the ER, and a 90-kD protein localized in peroxisomes. We have also identified the mutations in the UT2 cells responsible for the lack of the 97-kD protein. In addition, peroxisomal-deficient Pex2 CHO cell mutants display reduced HMG-CoA reductase levels and have reduced rates of sterol and nonsterol biosynthesis. These data further support the proposal that peroxisomes play an essential role in isoprenoid biosynthesis.     

Characterization of a novel component of the peroxisomal protein import apparatus using fluorescent peroxisomal proteins.

Fluorescent peroxisomal probes were developed by fusing green fluorescent protein (GFP) to the matrix peroxisomal targeting signals PTS1 and PTS2, as well as to an integral peroxisomal membrane protein (IPMP). These proteins were used to identify and characterize novel peroxisome assembly (pas) mutants in the yeast Pichia pastoris. Mutant cells lacking the PAS10 gene mislocalized both PTS1-GFP and PTS2-GFP to the cytoplasm but did incorporate IPMP-GFP into peroxisome membranes. Similar distributions were observed for endogenous peroxisomal matrix and membrane proteins. While peroxisomes from translocation-competent pas mutants sediment in sucrose gradients at the density of normal peroxisomes, >98% of peroxisomes from pas10 cells migrated to a much lower density and had an extremely low ratio of matrix:membrane protein. These data indicate that Pas10p plays an important role in protein translocation across the peroxisome membrane. Consistent with this hypothesis, we find that Pas10p is an integral protein of the peroxisome membrane. In addition, Pas10p contains a cytoplasmically-oriented C3HC4 zinc binding domain that is essential for its biological activity.     

Localization of p21-Activated Kinase 1 (PAK1) to Pinocytic Vesicles and Cortical Actin Structures in Stimulated Cells

Pex mutants of the yeast Yarrowia lipolytica are defective in peroxisome assembly. The mutant strain pex16-1 lacks morphologically recognizable peroxisomes. Most peroxisomal proteins are mislocalized to a subcellular fraction enriched for cytosol in pex16 strains, but a subset of peroxisomal proteins is localized at, or near, wild-type levels to a fraction typically enriched for peroxisomes. The PEX16 gene was isolated by functional complementation of the pex16-1 strain and encodes a protein, Pex16p, of 391 amino acids (44,479 D). Pex16p has no known homologues. Pex16p is a peripheral protein located at the matrix face of the peroxisomal membrane. Substitution of the carboxylterminal tripeptide Ser-Thr-Leu, which is similar to the consensus sequence of peroxisomal targeting signal 1, does not affect targeting of Pex16p to peroxisomes. Pex16p is synthesized in wild-type cells grown in glucose-containing media, and its levels are modestly increased by growth of cells in oleic acid–containing medium. Overexpression of the PEX16 gene in oleic acid– grown Y. lipolytica leads to the appearance of a small number of enlarged peroxisomes, which contain the normal complement of peroxisomal proteins at levels approaching those of wild-type peroxisomes.     

Assembly of alcohol oxidase in peroxisomes of the yeast Hansenula polymorpha requires the cofactor flavin adenine dinucleotide.

The peroxisomal flavoprotein alcohol oxidase (AO) is an octamer (600 kDa) consisting of eight identical subunits, each of which contains one flavin adenine dinucleotide molecule as a cofactor. Studies on a riboflavin (Rf) auxotrophic mutant of the yeast Hansenula polymorpha revealed that limitation of the cofactor led to drastic effects on AO import and assembly as well as peroxisome proliferation. Compared to wild-type control cells Rf-limitation led to 1) reduced levels of AO protein, 2) reduced levels of correctly assembled and activated AO inside peroxisomes, 3) a partial inhibition of peroxisomal protein import, leading to the accumulation of precursors of matrix proteins in the cytosol, and 4) a significant increase in peroxisome number. We argue that the inhibition of import may result from the saturation of a peroxisomal molecular chaperone under conditions that normal assembly of a major matrix protein inside the target organelle is prevented.     

Differential protein import deficiencies in human peroxisome assembly disorders

Two peroxisome targeting signals (PTSs) for matrix proteins have been well defined to date. PTS1 comprises a COOH-terminal tripeptide, SKL, and has been found in several matrix proteins, whereas PTS2 has been found only in peroxisomal thiolase and is contained within an NH2- terminal cleavable presequence. We have investigated the functional integrity of the import routes for PTS1 and PTS2 in fibroblasts from patients suffering from peroxisome assembly disorders. Three of the five complementation groups tested showed a general loss of PTS1 and PTS2 import. Two complementation groups showed a differential loss of peroxisomal protein import: group I cells were able to import a PTS1- but not a PTS2- containing reporter protein into their peroxisomes, and group IV cells were able to import the PTS2 but not the PTS1 reporter into aberrant, peroxisomal ghostlike structures. The observation that the PTS2 import pathway is intact only in group IV cells is supported by the protection of endogenous thiolase from protease degradation in group IV cells and its sensitivity in the remaining complementation groups, including the partialized disorder of group I. The functionality of the PTS2 import pathway and colocalization of endogenous thiolase with the peroxisomal membranes in group IV cells was substantiated further using immunofluorescence, subcellular fractionation, and immunoelectron microscopy. The phenotypes of group I and IV cells provide the first evidence for differential import deficiencies in higher eukaryotes. These phenotypes are analogous to those found in Saccharomyces cerevisiae peroxisome assembly mutants.     

Peroxisome remnants in pex3delta cells and the requirement of Pex3p for interactions between the peroxisomal docking and translocation subcomplexes

During peroxisomal matrix protein import, the peroxisomal targeting signal receptors recognize cargo in the cytosol and interact with docking and translocation subcomplexes on the peroxisomal membrane. Using immunoprecipitations of multiple protein components, we show that in Pichia pastoris the docking subcomplex consists of the unique peroxins Pex13p, Pex14p and Pex17p, whereas the putative translocation subcomplex has all three RING-finger peroxins, Pex2p, Pex10p and Pex12p, as unique constituents. We identify Pex3p as a shared component of both subcomplexes. In pex3Δ cells, the unique constituents of the docking subcomplex interact as they do in wild-type cells, but the assembly of the translocation subcomplex is impaired and its components are present at reduced levels. Furthermore, several interactions detected in wild-type cells between translocation and docking subcomplex components are undetectable in pex3Δ cells. Contrary to previous reports, pex3Δ cells have peroxisome remnants that pellet during high-speed centrifugation, associate with membranes on floatation gradients and can be visualized by deconvolution microscopy using antibodies to several peroxins which were not available earlier. We discuss roles for Pex3p in the assembly of specific peroxisomal membrane protein subcomplexes whose formation is necessary for matrix protein import.     

Mutations in the three largest subunits of yeast RNA polymerase II that affect enzyme assembly.

Mutations in the three largest subunits of yeast RNA polymerase II (RPB1, RPB2, and RPB3) were investigated for their effects on RNA polymerase II structure and assembly. Among 23 temperature-sensitive mutations, 6 mutations affected enzyme assembly, as assayed by immunoprecipitation of epitope-tagged subunits. In all six assembly mutants, RNA polymerase II subunits synthesized at the permissive temperature were incorporated into stably assembled, immunoprecipitable enzyme and remained stably associated when cells were shifted to the nonpermissive temperature, whereas subunits synthesized at the nonpermissive temperature were not incorporated into a completely assembled enzyme. The observation that subunit subcomplexes accumulated in assembly-mutant cells at the nonpermissive temperature led us to investigate whether these subcomplexes were assembly intermediates or merely byproducts of mutant enzyme instability. The time course of assembly of RPB1, RPB2, and RPB3 was investigated in wild-type cells and subsequently in mutant cells. Glycerol gradient fractionation of extracts of cells pulse-labeled for various times revealed that a subcomplex of RPB2 and RPB3 appears soon after subunit synthesis and can be chased into fully assembled enzyme. The RPB2-plus-RPB3 subcomplexes accumulated in all RPB1 assembly mutants at the nonpermissive temperature but not in an RPB2 or RPB3 assembly mutant. These data indicate that RPB2 and RPB3 form a complex that subsequently interacts with RPB1 during the assembly of RNA polymerase II.     

A novel pex2 mutant: catalase-deficient but temperature-sensitive PTS1 and PTS2 import

We searched for Chinese hamster ovary (CHO) cell mutants defective in peroxisome biogenesis by using peroxisome targeting sequence (PTS) of Pex3p (amino acid residues 1-40)-fused enhanced green fluorescent protein (EGFP). From mutagenized wild-type CHO-K1 cells stably expressing rat Pex2p and Pex3p(1-40)-EGFP, cell colonies resistant to the 9-(1(')-pyrene)nonanol/ultraviolet treatment were examined for intracellular location of peroxisomal proteins, including EGFP chimera, catalase, and matrix proteins with PTS types 1 and 2. One clone, ZPEG309, showed a distinct phenotype: import defect of catalase, but normal transport of PTS1 and PTS2 proteins at 37 degrees C. PTS1 and PTS2 import was abrogated when ZPEG309 was cultured at 39 degrees C. Genetic defect of ZPEG309 was a nonsense point mutation in a codon for Arg50 in CHO PEX2 and a mutation resulting in a C-terminal truncation of the introduced rat Pex2p. Therefore, ZPEG309 is a novel pex2, catalase-deficient mutant with temperature-sensitive PTS1 and PTS2 import.     

Peroxisomal Targeting, Import, and Assembly of Alcohol Oxidase in Pichia pastoris

Alcohol oxidase (AOX), the first enzyme in the yeast methanol utilization pathway is a homooctameric peroxisomal matrix protein. In peroxisome biogenesis-defective (pex) mutants of the yeast Pichia pastoris, AOX fails to assemble into active octamers and instead forms inactive cytoplasmic aggregates. The apparent inability of AOX to assemble in the cytoplasm contrasts with other peroxisomal proteins that are able to oligomerize before import. To further investigate the import of AOX, we first identified its peroxisomal targeting signal (PTS). We found that sequences essential for targeting AOX are primarily located within the four COOH-terminal amino acids of the protein leucine-alanine-arginine-phenylalanine _COOH (LARF). To examine whether AOX can oligomerize before import, we coexpressed AOX without its PTS along with wild-type AOX and determined whether the mutant AOX could be coimported into peroxisomes. To identify the mutant form of AOX, the COOH-terminal LARF sequence of the protein was replaced with a hemagglutinin epitope tag (AOX–HA). Coexpression of AOX–HA with wild-type AOX (AOX-WT) did not result in an increase in the proportion of AOX–HA present in octameric active AOX, suggesting that newly synthesized AOX–HA cannot oligomerize with AOX-WT in the cytoplasm. Thus, AOX cannot initiate oligomerization in the cytoplasm, but must first be targeted to the organelle before assembly begins.     

Evaluation of the role of the endoplasmic reticulum-Golgi transit in the biogenesis of peroxisomal membrane proteins in wild type and peroxisome biogenesis mutant CHO cells

Peroxisomes are thought to be formed by division of pre-existing peroxisomes after the import of newly synthesized proteins. However, it has been recently suggested that the endoplasmic reticulum (ER) provides an alternative de novo mechanism for peroxisome biogenesis in some cells. To test a possible role of the ER-Golgi transit in peroxisome biogenesis in mammalian cells, we evaluated the biogenesis of three peroxisomal membrane proteins (PMPs): ALDRP (adrenoleukodystrophy related protein), PMP70 and Pex3p in CHO cells. We constructed chimeric genes encoding these PMPs and green fluorescent protein (GFP), and transiently transfected them to wild type and mutant CHO cells, in which normal peroxisomes were replaced by peroxisomal membrane ghosts. The expressed proteins were targeted to peroxisomes and peroxisomal ghosts correctly in the presence or absence of Brefeldin A (BFA), a drug known to block the ER-Golgi transit. Furthermore, low temperature did not disturb the targeting of Pex3p-GFP to peroxisomes. We also constructed two chimeric proteins of PMPs containing an ER retention signal "DEKKMP": GFP-ALDRP-DEKKMP and myc- Pex3p-DEKKMP. These proteins were mostly targeted to peroxisomes. No colocalization with an ER maker was found. These results suggest that the classical ER-Golgi pathway does not play a major role in the biogenesis of mammalian PMPs.     

Newly identified Chinese hamster ovary cell mutants defective in peroxisome assembly represent complementation group A of human peroxisome biogenesis disorders and one novel group in mammals

We isolated peroxisome biogenesis-defective mutants from rat PEX2-transformed Chinese hamster ovary (CHO) cells, using the 9-(1'-pyrene)nonanol/ultraviolet method. A total of 18 mutant cell clones showing cytosolic localization of catalase were isolated. By complementation group (CG) analysis by means of PEX cDNA transfection and cell fusion, cell mutants, ZP124 and ZP126, were found to belong to two novel CGs of CHO mutants. Mutants, ZP135 and ZP167, were also classified to the same CG as ZP124. Further cell fusion analysis using 12 CGs fibroblasts from patients with peroxisome deficiency disorders such as Zellweger syndrome revealed that ZP124 belonged to human CG-A, the same group as CG-VIII in the United States. ZP126 could not be classified to any of human and CHO CGs. These mutants also showed typical peroxisome assembly-defective phenotypes such as severe loss of catalase latency and impaired biogenesis of peroxisomal enzymes. Collectively, ZP124 represents CG-A, and ZP126 is in a newly identified CG distinct from the 14 mammalian CGs previously characterized.     

Arabidopsis 22-kilodalton peroxisomal membrane protein. Nucleotide sequence analysis and biochemical characterization.

We sequenced and characterized PMP22 (22-kD peroxisomal membrane protein) from Arabidopsis, which shares 28% to 30% amino acid identity and 55% to 57% similarity to two related mammalian peroxisomal membrane proteins, PMP22 and Mpv17. Subcellular fractionation studies confirmed that the Arabidopsis PMP22 is a genuine peroxisomal membrane protein. Biochemical analyses established that the Arabidopsis PMP22 is an integral membrane protein that is completely embedded in the lipid bilayer. In vitro import assays demonstrated that the protein is inserted into the membrane posttranslationally in the absence of ATP, but that ATP stimulates the assembly into the native state. Arabidopsis PMP22 is expressed in all organs of the mature plant and in tissue-cultured cells. Expression of PMP22 is not associated with a specific peroxisome type, as it is detected in seeds and throughout postgerminative growth as cotyledon peroxisomes undergo conversion from glyoxysomes to leaf-type peroxisomes. Although PMP22 shows increased accumulation during the growth of young seedlings, its expression is not stimulated by light.