Pumpkin peroxisomal ascorbate peroxidase is localized on peroxisomal membranes and unknown membranous structures

To investigate the roles of peroxisomal membrane proteins in the reversible conversion of glyoxysomes to leaf peroxisomes, we characterized several membrane proteins of glyoxysomes. One of them was identified as an ascorbate peroxidase (pAPX) that is localized on glyoxysomal membranes. Its cDNA was isolated by immunoscreening. The deduced amino acid sequence encoded by the cDNA insert does not have a peroxisomal targeting signal (PTS), suggesting that pAPX is imported by one or more PTS-independent pathways. Subcellular fractionation of 3- and 5-d-old cotyledons of pumpkin revealed that pAPX was localized not only in the glyoxysomal fraction, but also in the ER fraction. A magnesium shift experiment showed that the density of pAPX in the ER fraction did not increase in the presence of Mg(2+), indicating that pAPX is not localized in the rough ER. Immunocytochemical analysis using a transgenic Arabidopsis which expressed pumpkin pAPX showed that pAPX was localized on peroxisomal membranes, and also on a unknown membranous structure in green cotyledons. The overall results suggested that pAPX is transported to glyoxysomal membranes via this unknown membranous structure.     

Novel glyoxysomal protein kinase, GPK1, identified by proteomic analysis of glyoxysomes in etiolated cotyledons of Arabidopsis thaliana

Glyoxysomes are present in etiolated cotyledons and contain enzymes for gluconeogenesis, which constitutes the major function of glyoxysomes. However, 281 genes seemingly related to peroxisomal functions occur in the Arabidopsis genome, implying that many unidentified proteins are present in glyoxysomes. To better understand the functions of glyoxysomes, we performed glyoxysomal proteomic analysis of etiolated Arabidopsis cotyledons. Nineteen proteins were identified as glyoxysomal proteins, including 13 novel proteins, one of which is glyoxysomal protein kinase 1 (GPK1). We cloned GPK1 cDNA by RT-PCR and characterized GPK1. The amino acid sequence deduced from GPK1 cDNA has a hydrophobic region, a putative protein kinase domain, and a possible PTS1 motif. Immunoblot analysis using fractions collected on a Percoll density gradient confirmed that GPK1 is localized in glyoxysomes. Analysis of suborganellar localization and protease sensitivity showed that GPK1 is localized on glyoxysomal membranes as a peripheral membrane protein and that the putative kinase domain is located inside the glyoxysomes. Glyoxysomal proteins are phosphorylated well in the presence of various metal ions and [g-32P]ATP, and one of them is identified as thiolase by immunoprecipitation. Immuno-inhibition of phosphorylation in glyoxysomes suggested that GPK1 phosphorylates a 40-kDa protein. These results show that protein phosphorylation systems are operating in glyoxysomes.     

Identification of Peroxisome Membrane Proteins (PMPs) in Sunflower (Helianthus annuus L.) Cotyledons and Influence of Light on the PMP Developmental Pattern

Boundary membranes were recovered from glyoxysomes, transition peroxisomes, and leaf-type peroxisomes purified from cotyledons of sunflower (Helianthus annuus L.) at three stages of postgerminative growth. After membranes were washed in 100 mM Na2CO3 (pH 11.5), integral peroxisome membrane proteins (PMPs) were solubilized in buffered aminocaproic acid/dodecyl maltoside (0.63 M/1.5%) and analyzed by nondenaturing and sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis. Six prominent nondenatured PMP complexes and 10 prominent SDS-denatured polypeptides were identified in the membranes of the three types of peroxisomes. A nondenatured complex of approximately 140 kD, composed mainly of 24.5-kD polypeptides, decreased temporally, independently of seedling exposure to white, blue, or red light; only far-red light seemed to prevent its decrease. PMP complexes of approximately 120 and 70 kD, in contrast, were present at all stages and changed in polypeptide content. It remains to be determined whether these data reflect changes within in vivo complexes or within complexes formed following/during detergent solubilization. Conversion of glyoxysomes to leaf-type peroxisomes in white or red light after a 2-d dark period was accompanied by the appearance of three SDS-denatured PMPs: 27.5, 28, and 47 kD. The former two became part of the PMP120 and 70 complexes, as well as part of a new PMP130 complex that also possessed the PMP47. Growth of seedlings in blue or far-red light did not promote the appearance of PMPs 27.5 or 28. Blue light promoted the appearance of PMP47, and far-red light seemed to prevent its appearance. Chlorophyll likely is not the photoreceptor involved in accumulation of PMPs because the PMP composition is distinctly different in seedlings irradiated with red or blue light of comparable fluence rates. Several lines of evidence indicate that the synthesis and acquisition of membrane and all matrix proteins are not coupled. The data provide evidence for a change in PMP composition when sunflower or any other oilseed glyoxysomes are converted to leaf-type peroxisomes and suggest that the change is regulated by both photobiological and temporal mechanisms.     

The membrane proteins of the methanol-induced peroxisome of Candida boidinii. Initial characterization and generation of monoclonal antibodies

Peroxisomes are massively induced when methylotrophic yeasts are cultured on methanol as the sole carbon and energy source. An analysis of the protein composition of the peroxisomal membrane and the generation of probes against two peroxisomal membrane proteins (PMPs) have been undertaken. Peroxisomes from Candida boidinii were obtained from sucrose gradients as previously described or from a novel one-step purification of the organelle on a Percoll gradient. The protein composition of the membranes from these two preparations was virtually identical. About 10 proteins comprise nearly all of its protein mass. The most prominent proteins have molecular masses of 120, 100, 47, 31-32 (a triplet), and 20 kDa; significant amounts of alcohol oxidase and dihydroxyacetone synthase, the two abundant matrix proteins, also remain associated with the membrane. Glycosylation of the membrane proteins could not be detected. Exposure of the membrane to chaotropes shows that PMPs 100 and 20 are the most easily removable, whereas PMP 47 appears to be the most tightly associated. Mice were injected with peroxisomal membrane, and hybridoma lines were isolated that produced antibody against PMP 20, PMP 47, and dihydroxyacetone synthase. Indirect immunofluorescence with these monoclonal antibodies confirmed that all three proteins are localized to the peroxisomal cluster. Immunoblotting experiments demonstrated that peroxisomal membrane as well as matrix proteins are induced by methanol.     

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.     

Immunocytochemical Analysis Shows that Glyoxysomes Are Directly Transformed to Leaf Peroxisomes during Greening of Pumpkin Cotyledons

The functional transition of glyoxysomes to leaf peroxisomes occurs during greening of germinating pumpkin cotyledons (Cucurbita sp. Amakuri Nankin). The immunocytochemical protein A-gold method was employed in the analysis of the transition using glyoxysomal specific citrate synthase immunoglobulin G and leaf peroxisomal specific glycolate oxidase immunoglobulin G. The labeling density of citrate synthase was decreased in the microbodies during the greening, whereas that of glycolate oxidase was dramatically increased. Double labeling experiments using different sizes of protein A-gold particles show that both the glyoxysomal and the leaf peroxisomal enzymes coexist in the microbody of the transitional stage indicating that glyoxysomes are directly transformed to leaf peroxisomes during greening.     

The 70-kDa peroxisomal membrane protein (PMP70) an ATP-binding cassette transporter

The 70-kDa peroxisomal membrane protein (PMP70) is one of major components of peroxisomal membranes. In rodents, PMP70 is markedly induced by administration of hypolipidemic agents in parallel with peroxisome proliferation and the induction of peroxisomal fatty acid β-oxidation enzymes. PMP70 is an ATP-binding cassette transporter, identified for the first time in intracellular membranes of eukaryotic cells. The authors' recent studies suggest that PMP70 is synthesized on free polysomes and posttranslationally inserted into peroxisomal membranes, and assembles as dimeric or oligomeric forms on peroxisomal membranes. PMP70 is suggested to be involved in metabolic transport of long-chain acyl-CoA across peroxisomal membranes.     

Transport of chimeric proteins that contain a carboxy-terminal targeting signal into plant microbodies

Malate synthase is a glyoxysome-specific enzyme. The carboxy-terminal tripeptide of the enzyme is Ser—Arg—Leu (SRL), which is known to function as a peroxisomal targeting signal in mammalian cells. To analyze the function of the carboxy-terminal amino acids of pumpkin malate synthase in plant cells, a chimeric gene was constructed that encoded a fusion protein which consisted of β-glucuronidase and the carboxyl terminus of the enzyme. The fusion protein was expressed and accumulated in transgenic Arabidopsis that had been transformed with the chimeric gene. Immunocytochemical analysis of the transgenic plants revealed that the carboxy-terminal five amino acids of pumpkin malate synthase were sufficient for transport of the fusion protein into glyoxysomes in etiolated cotyledons, into leaf peroxisomes in green cotyledons and in mature leaves, and into unspecialized microbodies in roots, although the fusion protein was no longer transported into microbodies when SRL at the carboxyl terminus was deleted. Transport of proteins into glyoxysomes and leaf peroxisomes was also observed when the carboxy-terminal amino acids of the fusion protein were changed from SRL to SKL, SRM, ARL or PRL. The results suggest that tripeprides with S, A or P at the −3 position, K or R at the −2 position, and L or M at the carboxyl terminal position can function as a targeting signal for three kinds of plant microbody.     

Integral membrane polypeptides of rat liver peroxisomes: topology and response to different metabolic states

Rats were treated with clofibrate, a hypolipidemic drug, and with thyroxine. Both drugs which are known to cause peroxisome proliferation, and a concomitant increase in peroxisomal fatty acid beta-oxidation activity in liver increased one of the major integral peroxisomal membrane polypeptides (PMPs), with apparent molecular mass of 69-kDa, six- and twofold, respectively. On the other hand hypothyroidism caused a decrease in peroxisomal fatty acid beta-oxidation activity and considerably lowered the concentration of PMP 69 in the peroxisomal membrane. Two other PMPs with apparent molecular masses of 36 and 22 kDa were not influenced by these treatments. The PMPs with apparent molecular masses of 42, 28, and 26 kDa were shown to be derived from the 69-kDa polypeptide by the activity of a yet uncharacterized endogenous protease during isolation of peroxisomes. Limited proteolysis of intact peroxisomes using proteinase K and subtilisin further substantiated that some portion of the 69-kDa polypeptide extends into the cytoplasm. The 36- and the 22-kDa polypeptides were accessible to proteolytic attack to a much lower extent and, therefore, are supposed to be rather deeply embedded within the peroxisomal membrane. It is demonstrated that peroxisomal acyl-CoA synthetase, an integral PMP extending partially into the cytoplasm, and PMP 69 are not identical polypeptides. Comparison of the peroxisomal membrane with that of mitochondria and microsomes revealed that the 69- and 22-kDa polypeptides as well as the bifunctional protein of the peroxisomal fatty acid beta-oxidation pathway were specifically located only in peroxisomes. Considerable amounts of a polypeptide cross-reacting with the antiserum against the 36-kDa polypeptide were found in mitochondria.     

Immunoelectron microscopic evidence for organ differences in the composition of peroxisome-specific membrane polypeptides among three rat organs: liver, kidney, and small intestine

We examined the distribution of peroxisome-specific membrane polypeptides (PMPs) among peroxisomes of the liver, renal cortex, and jejunal mucosa, using antibodies for 70 KD, 26 KD and 22 KD PMPs. Immunoblot analysis showed signals for 70 KD polypeptide in all three kinds of tissue, but for the other two only in the liver and renal cortex, with neither being detected in jejunal mucosa. The total amounts of PMPs increased in all three organs with DEHP (di-(2-ethylhexyl)phthalate) administration. By immunoelectron microscopic analysis using protein A-gold, the three PMPs were localized along the peroxisomal membrane. Quantitation of the gold particles associated with the peroxisomal membrane showed an increase in the density of 70 KD and 26 KD PMPs but a decrease in 22 KD PMP with the administration of DEHP. The presence of tissue-specific localizations of PMPs suggest the 70 KD PMP is a common constituent of peroxisomes of these three tissues, whereas 26 KD and 22 KD PMPs are absent in microperoxisomes of jejunal mucosal epithelium.     

Potential role for Pex19p in assembly of PTS-receptor docking complexes

Human Pex19p binds a broad spectrum of peroxisomal membrane proteins (PMPs). It has been proposed that this peroxin may: (i) act as a cycling PMP receptor protein, (ii) facilitate the insertion of newly synthesized PMPs into the peroxisomal membrane, or (iii) function as a chaperone to associate and/or dissociate complexes comprising integral PMPs already in the peroxisomal membrane. We previously demonstrated that human Pex19p binds peroxisomal integral membrane proteins at regions distinct from their sorting sequences. Here we demonstrate that a mutant of Pex13p that fails to bind to Pex19p nevertheless targets to and integrates into the peroxisomal membrane. In addition, through in vitro biochemical analysis, we show that Pex19p competes with Pex5p and Pex13p for binding to Pex14p, supporting a role for this peroxin in regulating assembly/disassembly of membrane-associated protein complexes. To further examine the molecular mechanism underlying this competition, six evolutionarily conserved amino acids in the Pex5p/Pex13p/Pex19p binding domain of Pex14p were subjected to site-directed mutagenesis and the corresponding mutants functionally analyzed. Our results indicate that the physically overlapping binding sites of Pex14p for Pex5p, Pex13p, and Pex19p are functionally distinct, suggesting that competition occurs through induction of structural changes, rather than through direct competition. Importantly, we also found that amino acid substitutions resulting in a strongly reduced binding affinity for Pex13p affect the peroxisomal localization of Pex14p.     

Leaf peroxisomes are directly transformed to glyoxysomes during senescence of pumpkin cotyledons

Summary After the functional transition of glyoxysomes to leaf peroxisomes during the greening of pumpkin cotyledons, the reverse microbody transition of leaf peroxisomes to glyoxysomes occurs during senescence. Immunocytochemical labeling with protein A-gold was performed to analyze the reverse microbody transition using antibodies against a leaf-peroxisomal enzyme, glycolate oxidase, and against two glyoxysomal enzymes, namely, malate synthase and isocitrate lyase. The intensity of labeling for glycolate oxidase decreased in the microbodies during senescence whereas in the case of malate synthase and isocitrate lyase intensities increased strikingly. Double labeling experiments with protein A-gold particles of different sizes showed that the leaf-peroxisomal enzymes and the glyoxysomal enzymes coexist in the microbodies of senescing pumpkin cotyledons, indicating that leaf peroxisomes are directly transformed to glyoxysomes during senescence.     

Immunological analysis of aconitase in pumpkin cotyledons: the absence of aconitase in glyoxysomes

Aconitase (EC 4.2.1.3) was purified by column chromatography and SDS-PAGE. Specific antibodies for aconitase were prepared after affinity purification of the antiserum with purified aconitase. The antibodies reacted with purified pumpkin aconitase, and with the 98 kDa protein band after electrophoretic fractionation of extracts of pumpkin cotyledons. Immunoblot analysis revealed a protein with similar molecular mass in extracts of several plants. The intensity of the 98 kDa band increased as pumpkin cotyledons developed in darkness, and decreased thereafter upon illumination. Aconitase activity showed a similar pattern. Anion exchange chromatography of a homogenate of pumpkin cotyledons, followed by western blotting, displayed the presence of immunoreactive protein bands only in fractions showing aconitase activity. The results indicate that the antibodies were specific for aconitase. When we investigated the presence of immunoreactive bands after sucrose gradient fractionation, aconitase was detected in the supernatant fractions and in mitochondria, while a very low amount was found in glyoxysomes. These data provide additional proof that aconitase is not localized in glyoxysomes.     

Saccharomyces cerevisiae pex3p and pex19p are required for proper localization and stability of peroxisomal membrane proteins

The mechanisms by which peroxisomal membrane proteins (PMPs) are targeted to and inserted into membranes are unknown, as are the required components. We show that among a collection of 16 Saccharomyces cerevisiae peroxisome biogenesis (pex) mutants, two mutants, pex3Delta and pex19Delta, completely lack detectable peroxisomal membrane structures and mislocalize their PMPs to the cytosol where they are rapidly degraded. The other pexDelta mutants contain membrane structures that are properly inherited during vegetative growth and that house multiple PMPs. Even Pex15p requires Pex3p and Pex19p for localization to peroxisomal membranes. This PMP was previously hypothesized to travel via the endoplasmic reticulum (ER) to peroxisomes. We provide evidence that ER-accumulated Pex15p is not a sorting intermediate on its way to peroxisomes. Our results show that Pex3p and Pex19p are required for the proper localization of all PMPs tested, including Pex15p, whereas the other Pex proteins might only be required for targeting/import of matrix proteins.     

Sorting of peroxisomal membrane protein PMP47 from Candida boidinii into peroxisomal membranes of Saccharomyces cerevisiae

A gene encoding PMP47, a peroxisomal integral membrane protein of the methylotrophic yeast Candida boidinii, was isolated from a genomic library. DNA sequencing of PMP47 revealed an open reading frame of 1269 base pairs capable of encoding a protein of 46,873 Da. At least two membrane-spanning regions in the protein are predicted from the sequence. Since the 3 amino acids at the carboxyl terminus are -AKE, PMP47 lacks a typical peroxisomal sorting signal. No significant similarities in primary structure between PMP47 and known proteins were observed, including PMP70, a rat peroxisomal membrane protein whose sequence has recently been reported (Kamijo, K., Taketani, S., Yokota, S., Osumi, T., and Hashimoto, T. (1990). J. Biol. Chem. 265, 4534-4540). In order to study the import and assembly of PMP47 into peroxisomes by genetic approaches, the gene was expressed in the yeast Saccharomyces cerevisiae. When PMP47 was expressed in cells grown on oleic acid to induce peroxisomes, the protein was observed exclusively in peroxisomes as determined by marker enzyme analysis of organelle fractions. Most of the PMP47 co-purified with the endogenous peroxisomal membrane proteins on isopycnic sucrose gradients. Either in the native host or when expressed in S. cerevisiae, PMP47 was not extractable from peroxisomal membranes by sodium carbonate at pH 11, indicating an integral membrane association. These results indicate that PMP47 is competent for sorting to and assembling into peroxisomal membranes in S. cerevisiae.     

The 70 kDa peroxisomal membrane protein: an ATP-binding cassette transporter protein involved in peroxisome biogenesis

The 70 kDa peroxisomal membrane protein (PMP70) is a major component of peroxisomal membranes. cDNAs for human and rat PMP70 have been cloned and sequenced and the gene mapped to the human chromosome 1p21-22. The predicted amino acid sequence showed homology to members of the ATP-binding cassette transporter family. In humans, mutations in the PMP70 gene have been found in a subset of patients with Zellweger syndrome, a lethal inborn error of peroxisome biogenesis. These results suggest that PMP70 functions in transporting molecules or possibility peptides across the peroxisomal membrane and has an important role in peroxisome assembly.     

PEX19 binds multiple peroxisomal membrane proteins, is predominantly cytoplasmic, and is required for peroxisome membrane synthesis

Peroxisomes are components of virtually all eukaryotic cells. While much is known about peroxisomal matrix protein import, our understanding of how peroxisomal membrane proteins (PMPs) are targeted and inserted into the peroxisome membrane is extremely limited. Here, we show that PEX19 binds a broad spectrum of PMPs, displays saturable PMP binding, and interacts with regions of PMPs required for their targeting to peroxisomes. Furthermore, mislocalization of PEX19 to the nucleus leads to nuclear accumulation of newly synthesized PMPs. At steady state, PEX19 is bimodally distributed between the cytoplasm and peroxisome, with most of the protein in the cytoplasm. We propose that PEX19 may bind newly synthesized PMPs and facilitate their insertion into the peroxisome membrane. This hypothesis is supported by the observation that the loss of PEX19 results in degradation of PMPs and/or mislocalization of PMPs to the mitochondrion.     

Cytosolic Aconitase Participates in the Glyoxylate Cycle in Etiolated Pumpkin Cotyledons

Two different aconitases are known to be expressed after thegermination of oil-seed plants. One is a mitochondrial aconitasethat is involved in the tricarboxylic acid cycle. The otherparticipates in the glyoxylate cycle, playing a role in gluconeogenesisfrom stored oil. We isolated and characterized a cDNA for anaconitase from etiolated pumpkin cotyledons. The cDNA was 3,145bp long and capable of encoding a protein of 98 kDa. N-terminaland C-terminal amino acid sequences deduced from the cDNA didnot contain mitochondrial or glyoxysomal targeting signals.A search of protein databases suggested that the cDNA encodeda cytosolic aconitase. Immuno blotting analysis with a specificantibody against the aconitase expressed in Escherichia colirevealed that developmental changes in the amount of the aconitasewere correlated with changes in levels of other enzymes of theglyoxylate cycle during growth of seedlings. Further analysisby subcellular fractionation and immunofluorescence microscopyrevealed that aconitase was present only in the cytosol andmitochondria. No glyoxysomal aconitase was found in etiolatedcotyledons even though all the other enzymes of the glyoxylatecycle are known to be localized in glyoxysomes. Taken together,the data suggest that the cytosolic aconitase participates inthe glyoxylate cycle with four glyoxysomal enzymes. (Received December 1, 1994; Accepted March 17, 1995)