How proteins get into microbodies (peroxisomes, glyoxysomes, glycosomes)

Characterization of an in vitro assay for import of 3-phosphoglycerate kinase into the glycosomes of Trypanosoma brucei

Glycosomes are microbody organelles found in kinetoplastida, where they serve to compartmentalize the enzymes of the glycolytic pathway. In order to identify the mechanism by which these enzymes are targeted to the glycosome, we have modified the in vitro import assay developed by Dovey et al. (Proc. Natl. Acad. Sci. USA 85:2598-2602, 1988). This assay measures the uptake of in vitro-translated Trypanosoma brucei glycosomal 3-phosphoglycerate kinase (gPGK) by purified glycosomes. Up to 50% of the total 35S-gPGK in the glycosomal fraction was resistant to extraction by 3 M urea or treatment with proteinase K (500 micrograms/ml). The glycosome-associated 35S-gPGK could be chemically cross-linked to the endogenous glycosomal proteins to form a sodium dodecyl sulfate-resistant complex, suggesting that it is close to the intraglycosomal protein matrix. Deoxycholate solubilized the glycosome and thereby rendered the glycosome-associated 35S-gPGK fully susceptible to proteinase K. However, the glycosome-associated 35S-gPGK was not digested by proteinase K in the presence of Triton X-100, which cannot dissolve the glycosomal protein core. The 35S-gPGK synthesized in vitro was able to bind directly to protein cores, where it became resistant to urea extraction and proteinase K digestion. However, the 35S-gPGK-protein core complex exhibited a much higher density than the 35S-gPGK-glycosome complex and was readily separable in sucrose gradients. Thus, in our in vitro import assay, the 35S-gPGK appeared to associate with intact glycosomes, possibly reflecting import of protein into the organelle. Complete denaturation of the 35S-gPGK in 8 M urea prior to the assay enhanced the efficiency of its association with glycosomes. Native gPGK did not compete with the association of in vitro-translated gPGK unless it was denatured. The assay exhibited time and temperature dependence, but it did not require externally added ATP and was not inhibited by the nonhydrolyzable analogs adenosine-5'-(beta,gamma-imido)-triphosphate and gamma-S-ATP. However, the presence of 20 to 30 microM ATP inside the glycosome may fulfill the requirement for protein import.

Studies on peroxisomal membranes

The phospholipid/protein ratios of rat liver peroxisomes, mitochondria and microsomes were determined and found to be 257 +/- 26, 232 +/- 20 and 575 +/- 20 nmol.mg-1, respectively. After correction for the loss of soluble protein, a peroxisomal ratio of 153 nmol.mg-1 was calculated. Organelle fractions were treated with sodium carbonate, whereafter membrane fragments containing integral membrane proteins were pelleted. For the membrane fractions of peroxisomes, mitochondria and microsomes phospholipid/protein ratios of 1054 +/- 103, 1180 +/- 90 and 1050 +/- 50 nmol.mg-1 were found, whereas 26 +/- 2, 20 +/- 2 and 49 +/- 2% of the organelle protein was recovered in these membrane fractions, respectively. The phospholipid composition of the different organelle fractions were determined, but no large differences were obtained, except for cardiolipin that was found only in the mitochondrial fraction. After sodium carbonate treatment virtually all enzymatic activity of the enzymes tested was lost. Therefore Triton X-114 phase separation was used to obtain the peroxisomal membrane components. In this fraction 42.9 +/- 3.5% of the protein and 90.2 +/- 3.7% of the phospholipid was found. Enzymatic activity of two integral membrane proteins was recovered for over 90% in the membrane fraction, whereas activity of two matrix proteins was mainly found in the soluble fraction. Urate oxidase, the peroxisomal core protein, behaved differently and was recovered mainly with the membrane components. Recoveries of enzymatic activities after the Triton X-114 phase separation varied from 45 to 116%, and together with the good separation that was obtained between soluble proteins and integral membrane proteins this method provides a useful alternative for the isolation of membrane components.

Cloning and sequence determination of cDNA encoding a second rat liver peroxisomal 3-ketoacyl-CoA thiolase

3-Ketoacyl-coenzyme A thiolase (thiolase) catalyzes the final step of the fatty acid beta-oxidation pathway in peroxisomes. Thiolase is unique among rat liver peroxisomal enzymes in that it is synthesized as a precursor possessing a 26-amino acid (aa) N-terminal extension which is cleaved to generate the mature enzyme. To facilitate further examination of the synthesis, intracellular transport and processing of this enzyme, cDNA clones were selected from a lambda gt11 rat liver library using antiserum raised against peroxisomal thiolase. Upon sequencing several cDNA clones, it was revealed that there are at least two distinct thiolase enzymes localized to rat liver peroxisomes, one identical to the previously published rat liver peroxisomal thiolase (thiolase 1) [Hijikata et al., J. Biol. Chem. 262 (1987) 8151-8158] and a novel thiolase (thiolase 2). The THL2 cDNA possesses a single open reading frame of 1302 nucleotides (nt) encoding a protein of 434 aa (Mr 44790). The coding region of THL2 cDNA exhibits 94.6% nt sequence identity with THL1 and 95.4% identity at the level of aa sequence. Northern-blot analysis indicates that the mRNA encoding thiolase 2 is approx. 1.7 kb in size. The mRNA encoding thiolase 2 is induced approx. twofold upon treatment of rats with the peroxisome-proliferating drug, clofibrate. In contrast, the thiolase 1 mRNA is induced more than tenfold under similar conditions.

In vivo import of Candida tropicalis hydratase-dehydrogenase-epimerase into peroxisomes of Candida albicans

We present a system for studying peroxisomal protein targeting in Candida. We have expressed the Candida tropicalis gene encoding hydratase-dehydrogenase-epimerase (HDE) in Candida albicans. Immunoblot analyses of C. albicans transformants demonstrate the presence of oleic-acid inducible HDE (100 kDa) in peroxisomes of transformed cells, but not of control cells. Peroxisomes isolated from transformed cells show increased beta-hydroxyacyl-CoA dehydrogenase specific activity, indicating that HDE is imported into peroxisomes of C. albicans where it is enzymatically active. C. albicans provides a useful model for the study of protein targeting to peroxisomes in vivo.

Cloning and sequencing of the malate synthase gene from Hansenula polymorpha

We have cloned the MAS gene, encoding the microbody matrix enzyme malate synthase (EC 4.1.3.2.) from the methylotrophic yeast Hansenula polymorpha. The gene was isolated by screening of a genomic library with a mixed-sequence probe, based on the partial amino acid sequence of the purified enzyme. The nucleotide sequence of a 2.4-kilobase stretch of DNA covering the MAS gene was determined. The gene contains an open reading frame of 555 amino acids, amounting to a calculated molecular mass of 63,254 for the encoded protein. Comparison of the amino acid sequence with the malate synthase sequences of Escherichia coli, Brassica napus L. and Cucumis sativus L. clearly establishes the homology of all four proteins. Compared to the soluble enzyme from E. coli, the malate synthases from H. polymorpha and both plant species, which are located in the microbodies, have a short carboxy-terminal extension. In the plant malate synthases, the extension is probably involved in routing to the microbodies, since it contains the potential peroxisomal targeting signal, Ser-Arg/Lys-Leu, at the carboxy terminus. The H. polymorpha enzyme terminates with similar amino acids, but their sequence, Ser-Leu-Lys, does not conform to any of the known peroxisomal targeting signals.

Topogenesis of peroxisomal proteins

Molecular and biochemical analysis of the biogenesis of peroxisomes has made rapid progress in recent years. Research on the mechanism of targeting of peroxisomal proteins has revealed that many, but not all, peroxisomal proteins have a conserved tripeptide motif in their carboxy-terminal portions which is required for entry into peroxisomes; the topogenic signal mechanism thus differs in these instances from those employed in mitochondria and endoplasmic reticulum. Other factors involved in peroxisome biogenesis are also coming to light.

Trypanosoma brucei: two-dimensional gel analysis of the major glycosomal proteins during the life cycle

Kinetoplastid organisms possess a unique organelle, the glycosome, which compartmentalizes the Embden-Meyerhof segment of glycolysis and several other metabolic pathways. In Trypanosoma brucei many of the enzyme activities localized to the glycosome are stage regulated. Two-dimensional gel analysis was used to examine the characteristics, expression, and biosynthesis of the major glycosomal proteins. Two-dimensional gel maps of glycosomes from slender bloodforms and late intermediate-stumpy bloodforms (the precursors of procyclic forms) were indistinguishable, while those of procyclic form glycosomes showed extensive differences. Glycosomal phosphoenolpyruvate carboxykinase and malate dehydrogenase were identified to have subunit molecular weights of 60 and 34 kDa, respectively. We detected two hitherto undescribed glycosomal proteins, one of which is found only in bloodforms. All of the major proteins, except glucose phosphate isomerase, were highly basic. Stage regulation of glycosomal enzyme activities correlated with stage regulation of specific protein biosynthesis.

Permeability properties of peroxisomal membranes from yeasts

We have studied the permeability properties of intact peroxisomes and purified peroxisomal membranes from two methylotrophic yeasts. After incorporation of sucrose and dextran in proteoliposomes composed of asolectin and peroxisomal membranes isolated from the yeasts Hansenula polymorpha and Candida boidinii a selective leakage of sucrose occurred indicating that the peroxisomal membranes were permeable to small molecules. Since the permeability of yeast peroxisomal membranes in vitro may be due to the isolation procedure employed, the osmotic stability of peroxisomes was tested during incubations of intact protoplasts in hypotonic media. Mild osmotic swelling of the protoplasts also resulted in swelling of the peroxisomes present in these cells but not in a release of their matrix proteins. The latter was only observed when the integrity of the cells was disturbed due to disruption of the cell membrane during further lowering of the concentration of the osmotic stabilizer. Stability tests with purified peroxisomes indicated that this leak of matrix proteins was not associated with the permeability to sucrose. Various attempts to mimic the in vivo situation and generate a proton motive force across the peroxisomal membranes in order to influence the permeability properties failed. Two different proton pumps were used for this purpose namely bacteriorhodopsin (BR) and reaction center-light-harvesting complex I (RCLH1 complex). After introduction of BR into the membrane of intact peroxisomes generation of a pH-gradient was not or barely detectable. Since this pump readily generated a pH-gradient in pure liposomes, these results strengthened the initial observations on the leakiness of the peroxisomal membrane fragments.(ABSTRACT TRUNCATED AT 250 WORDS)

Isolation and characterization of Chinese hamster ovary cell mutants defective in assembly of peroxisomes

We made use of autoradiographic screening to isolate two Chinese hamster ovary (CHO) cell mutants deficient in peroxisomal dihydroxyacetonephosphate acyltransferase, a key enzyme for the biosynthesis of ether glycerolipids such as plasmalogens. Morphological analysis revealed no evidence of peroxisome in these mutants. Catalase was as active as in the normal cells but was not sedimentable. Pulse-chase radiolabeling experiments and cell-free translation of RNA demonstrated that acyl-CoA oxidase, the first enzyme of the peroxisomal beta-oxidation system, was synthesized as the 75-kD form but was not converted to 53- and 22-kD mature components that were present in the wild-type CHO cells; rather, degradation was apparent. Peroxisomal thiolase was synthesized as in normal cells but remained as a larger, 44-kD precursor, whereas maturation to the 41-kD enzyme was detected in the wild-type cells. The peroxisomal 70-kD integral membrane protein was also equally synthesized, as in the wild-type cells, and was not degraded. These results suggest that assembly of the peroxisomes is defective in the mutants, whereas the synthesis of peroxisomal proteins appears to be normal. Cell-fusion studies revealed that the two mutants are recessive to the wild-type CHO cells and belong to different complementation groups. Thus, these mutants presumably contain different lesions in gene(s) encoding factor(s) required for peroxisome assembly.

Homology between hydroxybutyryl and hydroxyacyl coenzyme A dehydrogenase enzymes from Clostridium acetobutylicum fermentation and vertebrate fatty acid beta-oxidation pathways

The enzymes NAD-dependent beta-hydroxybutyryl coenzyme A dehydrogenase (BHBD) and 3-hydroxyacetyl coenzyme A (3-hydroxyacyl-CoA) dehydrogenase are part of the central fermentation pathways for butyrate and butanol production in the gram-positive anaerobic bacterium Clostridium acetobutylicum and for the beta oxidation of fatty acids in eucaryotes, respectively. The C. acetobutylicum hbd gene encoding a bacterial BHBD was cloned, expressed, and sequenced in Escherichia coli. The deduced primary amino acid sequence of the C. acetobutylicum BHBD showed 45.9% similarity with the equivalent mitochondrial fatty acid beta-oxidation enzyme and 38.4% similarity with the 3-hydroxyacyl-CoA dehydrogenase part of the bifunctional enoyl-CoA hydratase:3-hydroxyacyl-CoA dehydrogenase from rat peroxisomes. The pig mitochondrial 3-hydroxyacyl-CoA dehydrogenase showed 31.7% similarity with the 3-hydroxyacyl-CoA dehydrogenase part of the bifunctional enzyme from rat peroxisomes. The phylogenetic relationship between these enzymes supports a common evolutionary origin for the fatty acid beta-oxidation pathways of vertebrate mitochondria and peroxisomes and the bacterial fermentation pathway.

Functional complementation of catalase-defective peroxisomes in a methylotrophic yeast by import of the catalase A from Saccharomyces cerevisiae

A mutant of the methanol-utilizing yeast Hansenula polymorpha defective in catalase was isolated. It lacks the ability to grow on methanol as the sole source of carbon and energy due to a loss of peroxisomal function that is required for the dissimilation and assimilation of this substrate. Growth of the mutant on glucose or glycerol was not impaired. Transformation of mutant cells with the gene coding for catalase A from Saccharomyces cerevisiae [Cohen, G., Fessl, F., Traczyk, J., Rytka, J. & Ruis, H. (1985) Mol. Gen. Genet. 200, 74-79] conferred constitutive expression of catalase activity. When the gene was placed under control of the regulatory methanol oxidase promoter from H. polymorpha, high levels of activity subject to glucose repression were obtained. In both cases efficient targeting of catalase A to the heterologous peroxisomes and assembly into an active form could be demonstrated. Concomitantly, growth on methanol was restored in the transformed mutant. The results are in line with a high conservation of transport signals on peroxisomal proteins. Expression of a cytosolic catalase in H. polymorpha did not confer the ability to grow on methanol. Therefore, proper localization of the catalase activity is a prerequisite for peroxisomal function.

Cytoplasmic requirement for peroxisome biogenesis in Chinese hamster ovary cells

Hybrids constructed by fusion of wild-type Chinese hamster ovary cells (CHO-K1) to peroxisome-deficient CHO mutants (ZR-78.1) contain normal peroxisomes, demonstrating that the mutation(s) are recessive. "Nuclear hybrids" prepared by fusion of CHO-K1 karyoplasts to mutant ZR-78.1 occasionally fail to regain intact peroxisomes (approximately 1/300 cells). These peroxisome-deficient nuclear hybrids closely resemble the original mutant cells by biochemical criteria, but their modal chromosome number is 36-38, the same as that of CHO hybrids generated from intact cells. When the peroxisome-deficient nuclear hybrids are fused to wild-type cytoplasts, a fraction of the fusion products (at least 70%) continue to propagate normal peroxisomes indefinitely. Peroxisome biogenesis cannot be reinitiated in cells of mutant ZR-78.1 by fusion to wild-type cytoplasts. Our results suggest that a wild-type nucleus by itself is necessary but not sufficient for restoration of normal peroxisome biogenesis and that a cytoplasmic component of wild-type cells, possibly a normal peroxisome, is also required.

Cloning and sequencing of the peroxisomal amine oxidase gene from Hansenula polymorpha

We have cloned the AMO gene, encoding the microbody matrix enzyme amine oxidase (EC 1.4.3.6) from the yeast Hansenula polymorpha. The gene was isolated by differential screening of a cDNA library, immunoselection, and subsequent screening of a H. polymorpha genomic library. The nucleotide sequence of a 3.6 kilobase stretch of DNA containing the amine oxidase (AMO) gene was determined. The AMO gene contains an open reading frame of 692 amino acids, with a relative molecular mass of 77,435. The 5' and 3' ends of the gene were mapped and show that the transcribed region measures 2134 nucleotides. The derived amino-acid sequence was confirmed by sequencing an internal proteolytic fragment of the purified protein. Amine oxidase contains the tripeptide sequence Ser-Arg-Leu, located 9 residues from the carboxy terminus, which may represent the topogenic signal for protein import into microbodies.

Isolation of peroxisome-deficient mutants of Saccharomyces cerevisiae

Two mutants of Saccharomyces cerevisiae affected in peroxisomal assembly (pas mutants) have been isolated and characterized. Each strain contains a single mutation that results in (i) the inability to grow on oleic acid, (ii) accumulation of peroxisomal matrix enzymes in the cytosol, and (iii) absence of detectable peroxisomes at the ultrastructural level. These lesions (pas1-1 and pas2) are shown to be nonallelic and recessive. Crossing of pas1-1 and pas2 strains resulted in diploid cells that had regained the ability to grow on oleic acid as sole carbon source and to form peroxisomes. These pas mutants may provide useful tools for future studies on the molecular mechanisms involved in peroxisomal assembly.

Biogenesis of peroxisomes: immunocytochemical investigation of peroxisomal membrane proteins in proliferating rat liver peroxisomes and in catalase-negative membrane loops

Treatment of rats with a new hypocholesterolemic drug BM 15766 induces proliferation of peroxisomes in pericentral regions of the liver lobule with distinct alterations of the peroxisomal membrane (Baumgart, E., K. Stegmeier, F. H. Schmidt, and H. D. Fahimi. 1987. Lab. Invest. 56:554-564). We have used ultrastructural cytochemistry in conjunction with immunoblotting and immunoelectron microscopy to investigate the effects of this drug on peroxisomal membranes. Highly purified peroxisomal fractions were obtained by Metrizamide gradient centrifugation from control and treated rats. Immunoblots prepared from such peroxisomal fractions incubated with antibodies to 22-, 26-, and 70-kD peroxisomal membrane proteins revealed that the treatment with BM 15766 induced only the 70-kD protein. In sections of normal liver embedded in Lowicryl K4M, all three membrane proteins of peroxisomes could be localized by the postembedding technique. The strongest labeling was obtained with the 22-kD antibody followed by the 70-kD and 26-kD antibodies. In treated animals, double-membraned loops with negative catalase reaction in their lumen, resembling smooth endoplasmic reticulum segments as well as myelin-like figures, were noted in the proximity of some peroxisomes. Serial sectioning revealed that the loops seen at some distance from peroxisomes in the cytoplasm were always continuous with the peroxisomal membranes. The double-membraned loops were consistently negative for glucose-6-phosphatase, a marker for endoplasmic reticulum, but were distinctly labeled with antibodies to peroxisomal membrane proteins. Our observations indicate that these membranous structures are part of the peroxisomal membrane system. They could provide a membrane reservoir for the proliferation of peroxisomes and the expansion of this intracellular compartment.

Nisin, a peptide antibiotic: cloning and sequencing of the nisA gene and posttranslational processing of its peptide product

Nisin produced by Streptococcus lactis is used as a food preservative and is the most important member of a group of antibiotics containing lanthionine bridges. To understand the genetic basis of these so-called lantibiotics (Schnell et al., Nature 333:276-278, 1988), we characterized the nisin structural gene, nisA, which is located on a plasmid and codes for a 57-amino-acid prepeptide. The prepeptide is processed posttranslationally to the pentacyclic antibiotic. Although nisin and the recently elucidated lantibiotic epidermin from Staphylococcus epidermidis are produced by different organisms, their gene organization is identical. As with epidermin, the nisin propeptide corresponds to the C-terminus of the prepeptide. The N-terminus of the prepeptide is cleaved at a characteristic splice site (Pro--2 Arg--1 Ile-+1). Remarkably, the N-terminus of prenisin shares 70% similarity with preepidermin, although the propeptide sequences are distinctly different. The structural similarities between these two lantibiotics are consistent with the fact that there is a common mechanism of biosynthesis of these lanthionine-containing antibiotics.

Mitochondrial protein import

Most mitochondrial proteins are synthesized as precursor proteins on cytosolic polysomes and are subsequently imported into mitochondria. Many precursors carry amino-terminal presequences which contain information for their targeting to mitochondria. In several cases, targeting and sorting information is also contained in non-amino-terminal portions of the precursor protein. Nucleoside triphosphates are required to keep precursors in an import-competent (unfolded) conformation. The precursors bind to specific receptor proteins on the mitochondrial surface and interact with a general insertion protein (GIP) in the outer membrane. The initial interaction of the precursor with the inner membrane requires the mitochondrial membrane potential (delta psi) and occurs at contact sites between outer and inner membranes. Completion of translocation into the inner membrane or matrix is independent of delta psi. The presequences are cleaved off by the processing peptidase in the mitochondrial matrix. In several cases, a second proteolytic processing event is performed in either the matrix or in the intermembrane space. Other modifications can occur such as the addition of prosthetic groups (e.g., heme or Fe/S clusters). Some precursors of proteins of the intermembrane space or the outer surface of the inner membrane are retranslocated from the matrix space across the inner membrane to their functional destination ('conservative sorting'). Finally, many proteins are assembled in multi-subunit complexes. Exceptions to this general import pathway are known. Precursors of outer membrane proteins are transported directly into the outer membrane in a receptor-dependent manner. The precursor of cytochrome c is directly translocated across the outer membrane and thereby reaches the intermembrane space. In addition to the general sequence of events which occurs during mitochondrial protein import, current research focuses on the molecules themselves that are involved in these processes.

Peroxisomal oxidases: cytochemical localization and biological relevance

(1) alpha-HAOX has a broad substrate specificity. In rat kidney, the enzyme reacts with aliphatic and aromatic alpha-hydroxy acids, in rat liver, however, only with aliphatic ones. (2) The best substrate for the demonstration of alpha-HAOX activity in rat and human liver is glycolate. (3) alpha-hydroxy butyric acid is the best substrate in the luminometric assay for the demonstration of alpha-HAOX activity in the rat kidney, whereas glycolate is not catalysed by the enzyme. (4) In the proximal tubulus epithelial cells of the rat kidney alpha-HAOX is concentrated in the peripheral matrix of the peroxisomes.

Molecular immunocytochemistry of the CuZn superoxide dismutase in rat hepatocytes

The distribution of CuZn superoxide dismutase (SOD) molecules in subcellular organelles in rat liver hepatocytes was studied using integrated biochemical, stereological, and quantitative immunocytochemical techniques. A known concentration of purified CuZn SOD in 10% gelatin was embedded alongside the liver tissue for the calculation of CuZn SOD concentrations in hepatocyte organelles and total CuZn SOD in the rat liver. Most of the CuZn SOD was located in the cytoplasmic matrix (73.1%) and in the nucleus (11.9%) with concentrations of 1.36 and 0.71 mg/cm3, respectively. Lysosomes contained the highest concentration (5.81 mg/cm3). Only low concentrations were measured in mitochondria (0.21 mg/cm3). Membrane-bound spaces of rough endoplasmic reticulum (ER), smooth ER, and the Golgi system did not contain significant concentrations of the enzyme. By adding up the concentrations in all subcellular compartments, a total liver content of CuZn SOD was established from the immunocytochemical measurements (0.386 +/- 0.028 mg/gm liver) that agreed closely with those obtained by biochemical assays (0.380 +/- 0.058 mg/gm liver). The average distances between two CuZn SOD molecules can be calculated from enzyme concentrations. It was determined that CuZn SOD molecules in the cytoplasmic matrix and nucleus were 34 and 42 nm apart, respectively. In peroxisomes and mitochondria, average intermolecular distance increased to approximately 60 nm and increased to 136 nm in smooth ER. CuZn SOD is a relatively abundant protein in the cytosol of hepatocytes and its distribution overlaps with major sites of O2- production. The efficiency of protection CuZn SOD can provide to cytosolic proteins from attacks by superoxide anion depends on the rate of O2- production, distribution of CuZn SOD relative to cytosolic proteins, and the relative reaction rates between O2- with both cytosolic proteins and CuZn SOD. Future studies of these substrate-enzyme relationships in vivo can lead to a greater understanding of how cells handle oxidant stress.

Alcohol oxidase expressed under nonmethylotrophic conditions is imported, assembled, and enzymatically active in peroxisomes of Hansenula polymorpha

We have introduced into Hansenula polymorpha an extra copy of its alcohol oxidase gene. This gene which is under the control of the Saccharomyces cerevisiae phosphoglycerate kinase promoter is integrated in a chromosome different from the one containing the endogenous gene. Cells with the extra alcohol oxidase gene, grown on glucose or ethanol as the sole carbon source, express enzymatically active alcohol oxidase. However, other enzymes characteristic for methylotrophic growth conditions are absent or present at low levels. Most of the alcohol oxidase occurs in the octameric state and immuno- and cytochemical evidence shows that it is located in a single enlarged peroxisome per cell. Such peroxisomes show crystalloid inclusions which are lacking in the peroxisomes present in glucose grown control cells. Our results suggest that import into peroxisomes of H. polymorpha, assembly and activation of alcohol oxidase is not conditionally dependent on adaptation to methylotrophic growth conditions and that proliferation of peroxisomes is a well-programmed process that is not triggered solely by overproduction of a peroxisomal protein.

Peroxisomal disorders: clinical commentary and future prospects

Recent progress in the classification, biochemistry, and molecular biology of peroxisomal disorders is reviewed from a clinical perspective. Diseases such as Zellweger syndrome, neonatal adrenoleukodystrophy, infantile Refsum disease, hyperpipecolic acidemia, chondrodysplasia punctata, and Leber amaurosis share a common phenotype and involve deficiency of multiple peroxisomal enzymes. These disorders are associated with diverse metabolic abnormalities which are useful in pre- or postnatal diagnosis and distinguish these disorders from others such as X-linked adrenoleukodystrophy, adult Refsum disease, hyperoxaluria type I, and acatalasemia. Peroxisome structure is difficult to quantify histologically, since recent studies emphasize its developmental variability and tissue heterogeneity. The ability to manipulate this structure by dietary or pharmaceutical means provides a novel approach to therapy. At the molecular level, deficiency of peroxisomal enzymes responsible for fatty acid beta-oxidation or ether lipid synthesis reflects enhanced protein degradation due to abnormal peroxisomes; messenger RNA for the beta-oxidation enzymes is transcribed normally in peroxisomal disorders and can be increased by peroxisome proliferators. At least one integral structural protein of the peroxisome is synthesized normally in Zellweger syndrome. Hypotheses for the basic defect include defective regulation, uptake, or coenzyme stimulation of imported proteins, as well as defective biosynthesis. One clue to this defect may be a similar evolutionary history of peroxisomes and mitochondria which would explain their common alteration in Zellweger syndrome.

Transcending the impenetrable: how proteins come to terms with membranes

In the living cell, proteins are efficiently sorted to a whole range of subcellular compartments. In many cases, sorting specificity is mediated by short 'sorting signals' attached either permanently or transiently to the protein. At long last, a fairly coherent picture of the design and function of many such sorting signals is beginning to emerge.

Genetic heterogeneity in the cerebrohepatorenal (Zellweger) syndrome and other inherited disorders with a generalized impairment of peroxisomal functions. A study using complementation analysis

We have used complementation analysis after somatic cell fusion to investigate the genetic relationships among various genetic diseases in humans in which there is a simultaneous impairment of several peroxisomal functions. The activity of acyl-coenzyme A:dihydroxyacetonephosphate acyltransferase, which is deficient in these diseases, was used as an index of complementation. In some of these diseases peroxisomes are deficient and catalase is present in the cytosol, so that the appearance of particle-bound catalase could be used as an index of complementation. The cell lines studied can be divided into at least five complementation groups. Group 1 is represented by a cell line from a patient with the rhizomelic form of chondrodysplasia punctata. Group 2 consists of cell lines from four patients with the Zellweger syndrome, a patient with the infantile form of Refsum disease and a patient with hyperpipecolic acidemia. Group 3 comprises one cel line from a patient with the Zellweger syndrome, group 4 one cell line from a patient with the neonatal form of adrenoleukodystrophy, and group 5 one cell line from a patient with the Zellweger syndrome. We conclude that at least five genes are required for the assembly of a functional peroxisome.

Kinetics of the assembly of peroxisomes after fusion of complementary cell lines from patients with the cerebro-hepato-renal (Zellweger) syndrome and related disorders

We have recently identified four complementation groups in fibroblasts from patients deficient in peroxisomes. Here we describe a kinetic analysis of the complementation process. The kinetics of peroxisome assembly was assessed in heterokaryons of complementary cell lines by measuring the rate of incorporation of catalase, initially present in the cytosol, into particles. In two combinations of cell lines assembly was rapid and insensitive to cycloheximide. Thus the components required for peroxisome assembly must have been present in the parental cell lines, at least one of which presumably contained peroxisomal ghosts. In three other combinations of cell lines assembly of peroxisomes was slow and sensitive to cycloheximide.

Characterization of two forms of the multifunctional protein acting in fatty acid beta-oxidation

The enzymatic apparatus of fatty acid beta-oxidation in peroxisomes and glyoxysomes includes a multifunctional protein. Two forms of this protein were detected in extracts from cotyledons of germinating cucumber seeds and separated on hydroxylapatite. The two proteins purified to apparent homogeneity possessed enoyl-CoA hydratase, 3-hydroxyacyl-CoA epimerase, and 3-hydroxyacyl-CoA dehydrogenase activity; the proteins are therefore trifunctional. Analysis of molecular structures and kinetic parameters of the two enzyme forms revealed significant differences in size and amino acid composition. The two proteins were characterized as monomers exhibiting molecular weights of 74,000 and 76,500. Likewise, the data obtained with limited proteolysis proved the occurrence of two independent proteins. Immunological comparisons were performed with antibodies raised against the 76.5-kDa protein. They indicated a weak relationship between the two proteins. From that we conclude that within one type of organelle, i.e., glyoxysome, two isoenzymes with multiple functions are located.

Purification and biosynthesis of cottonseed (Gossypium hirsutum L.) catalase

As part of our research on peroxisome biogenesis, catalase was purified from cotyledons of dark-grown cotton (Gossypium hirsutum L.) seedlings and monospecific antibodies were raised in rabbits. Purified catalase appeared as three distinct electrophoretic forms in non-denaturing gels and as a single protein band (with a subunit Mr of 57,000) on silver-stained SDS/polyacrylamide gels. Western blots of crude extracts and isolated peroxisomes from cotton revealed one immunoreactive polypeptide with the same Mr (57,000) as the purified enzyme, indicating that catalase did not undergo any detectable change in Mr during purification. Synthesis in vitro, directed by polyadenylated RNA isolated from either maturing seeds or cotyledons of dark-grown cotton seedlings, revealed a predominant immunoreactive translation product with a subunit Mr of 57,000 and an additional minor immunoreactive product with a subunit Mr of 64000. Labelling studies in vivo revealed newly synthesized monomers of both the 64000- and 57,000-Mr proteins present in the cytosol and incorporation of both proteins into the peroxisome without proteolytic processing. Within the peroxisome, the 57,000-Mr catalase was found as an 11S tetramer; whereas the 64,000-Mr protein was found as a relatively long-lived 20S aggregate (native Mr approx. 600,000-800,000). The results strongly indicate that the 64,000-Mr protein (catalase?) is not a precursor to the 57,000-Mr catalase and that cotton catalase is translated on cytosolic ribosomes without a cleavable transit or signal sequence.

Biogenesis of glycosomes of Trypanosoma brucei: an in vitro model of 3-phosphoglycerate kinase import

Glycosomes are intracellular, membrane-bound microbody organelles of trypanosomes and leishmania. Nine glycolytic enzymes are the major protein components of the glycosomes of Trypanosoma brucei long-slender bloodstream forms. Glycosomal proteins are believed to be synthesized in the cytoplasm and inserted across the glycosomal membrane posttranslationally. We have developed an in vitro protein import assay for the study of glycosomal biogenesis in T. brucei. All nine glycosomal glycolytic enzymes were detectable by immunoprecipitation and gel analysis of radiolabeled products derived from in vitro translation of total mRNA. Radiolabeled translational products were incubated with purified glycosomes isolated from bloodstream forms and digested with protease to remove proteins not imported into glycosomes. Gel analysis of reisolated glycosomes revealed that glyceraldehyde-3-phosphate dehydrogenase (EC 1.2.1.12) and 3-phosphoglycerate kinase (PGK) (EC 2.7.2.3) were apparently imported intact into the glycosome. Specificity of the protein import assay was verified by using translational products derived from cloned genes encoding T. brucei glycosomal PGK and its 95% homologous cytosolic isozyme. Glycosomal PGK was inserted into the glycosome in vitro with a 27.6% efficiency, but no imported cytosolic PGK was detectable. Preliminary data suggest that certain sequences between the N terminus and residue 123 may be important for import of glycosomal PGK. Our assay, combined with the potential use of genetically altered substrate proteins, may provide the opportunity to explore the recognition systems involved in glycosome biogenesis.

Gene response upon illumination in forming mRNA encoding peroxisomal glycollate oxidase

Glycollate oxidase is a constituent of leaf peroxisomes. Its biosynthesis is, like the biosynthesis of many chloroplastic proteins, controlled by light, via phytochrome. The level of mRNA coding for glycollate oxidase was determined at different stages of greening of etiolated plant cells. The appearance of glycollate oxidase mRNA in the cytoplasm was measured by hybridization with cDNA containing part of the coding sequence for glycollate oxidase. cDNA was prepared from enriched mRNA, inserted into the Pst I site of pBR 322, and cloned in Escherichia coli DH-1. By differential colony hybridization and hybrid selection, a clone containing a 670 bp sequence complementary to mRNA encoding glycollate oxidase was selected and identified. Northern blot hybridization was used to investigate mRNA levels induced by light. It was found that continuous light affected the formation of glycollate oxidase mRNA. When a large population of microbodies was present in the cells being induced, the immediate mRNA increase was very pronounced, and was detectable as little as 20 min after the beginning of the light treatment. In contrast, a lag period in the mRNA increase was observed when the induction was performed with etiolated leaves which are characterized by the occurrence of a rather small population of microbodies. For comparison, we measured the time-course of formation of mRNA coding for a light-induced chloroplastic protein, i.e., a protein of the light-harvesting complex. The time-courses of levels of the two mRNAs indicate that the program of gene expression differs between the two particular proteins destined either for chloroplasts or for peroxisomes. The formation of glycollate oxidase mRNA could also be stimulated by a short pulse of light, a treatment of 15 s being a sufficient trigger.

Most proteins, including fructose bisphosphate aldolase, are stable in the procyclic trypomastigote form of Trypanosoma brucei

Procyclic Trypanosoma brucei were labelled with [35S]methionine, then incubated for up to 2 days in medium containing excess unlabelled methionine under conditions suitable for exponential growth. Neither fructose bisphosphate aldolase, a glycosomal enzyme, nor any of the major labelled proteins showed any detectable degradation.

Peroxisomal integral membrane proteins in livers of patients with Zellweger syndrome, infantile Refsum's disease and X-linked adrenoleukodystrophy

Livers from seven patients with peroxisome disorders, three with Zellweger syndrome, one with infantile Refsum's syndrome and three with X-linked adrenoleukodystrophy, were analysed by immunoblotting. The bifunctional protein catalysing two peroxisomal beta-oxidation reactions was deficient in all Zellweger livers and in the infantile Refsum's liver, consistent with the absence of morphologically recognizable peroxisomes. Three peroxisomal integral membrane proteins (IMPs) (69, 53 and 22 kDa) were present in normal amounts in all the Zellweger and adrenoleukodystrophy samples and they sedimented in a membrane fraction. These membrane proteins were also present in the infantile Refsum's liver. We suggest, on the basis of these results, that aberrant peroxisomal membranes may be present in Zellweger syndrome and that the defect is in the transport of matrix proteins into the organelle.

Cytosolic epoxide hydrolase

Epoxide hydrolase activity is recovered in the high-speed supernatant fraction from the liver of all mammals so far examined, including man. For some as yet unexplained reason, the rat has a very low level of this activity, so that cytosolic epoxide hydrolase is generally studied in mice. This enzyme selectively hydrolyzes trans epoxides, thereby complementing the activity of microsomal epoxide hydrolase, for which cis epoxides are better substrates. Cytosolic epoxide hydrolase has been purified to homogeneity from the livers of mice, rabbits and humans. Certain of the physicochemical and enzymatic properties of the mouse enzyme have been thoroughly characterized. Neither the primary amino acid, cDNA nor gene sequences for this protein are yet known, but such characterization is presently in progress. Unlike microsomal epoxide hydrolase and most other enzymes involved in xenobiotic metabolism, cytosolic epoxide hydrolase is not induced by treatment of rodents with substances such as phenobarbital, 2-acetylaminofluorene, trans-stilbene oxide, or butylated hydroxyanisole. The only xenobiotics presently known to induce cytosolic epoxide hydrolase are substances which also cause peroxisome proliferation, e.g., clofibrate, nafenopin and phthalate esters. These and other observations indicate that this enzyme may actually be localized in peroxisomes in vivo and is recovered in the high-speed supernatant because of fragmentation of these fragile organelles during homogenization, i.e., recovery of this enzyme in the cytosolic fraction is an artefact. The functional significance of cytosolic epoxide hydrolase is still largely unknown. In addition to deactivating xenobiotic epoxides to which the organism is exposed directly or which are produced during xenobiotic metabolism, primarily by the cytochrome P-450 system, this enzyme may be involved in cellular defenses against oxidative stress.

Information transfer in biological systems: targeting of proteins to specific organelles or to the extracellular environment (secretion)

Orderliness is the salient characteristic of living systems. Cells are intolerant of disorder. They express this by rapidly eliminating or degrading out-of-place molecules. When cells are broken apart and their constituent organelles separated and analysed, the same types of macromolecules are always associated with the same subcellular structures. One finds, for example, the same proteins in mitochondria time after time, and these differ from the sets of proteins found in nuclei, secretory granules, or plasma membranes. The information necessary to target each protein to its appropriate intracellular destination is determined primarily by the gene for that protein. Encoded within the DNA structure of genes are signals that specify where each protein molecule belongs. Thus, it is the transfer of information from one macromolecule to another that maintains the integrity and orderliness of living cells.

Import of fructose bisphosphate aldolase into the glycosomes of Trypanosoma brucei

The glycolytic enzymes of Trypanosomatids are compartmentalized within peroxisome-like microbodies called glycosomes. Fructose bisphosphate aldolase is synthesized on free polysomes and imported into glycosomes within 5 min. Peptide mapping reveals no primary structural differences between the in vivo-synthesized protein and that made in vitro from a synthetic template. However, native aldolase from glycosomes is partially protease resistant, whereas the in vitro translation product is not. Pulse-chase results indicate that aldolase in bloodstream trypanosomes has a much longer half-life than in the procyclic tsetse fly form.

Efficient association of in vitro translation products with purified stable Candida tropicalis peroxisomes

Newly synthesized peroxisomal proteins enter preexisting peroxisomes posttranslationally in vivo, generally without proteolytic processing. An efficient reconstitution of this process in vitro together with cloned DNAs for peroxisomal proteins would make possible investigation of the molecular information that targets proteins to peroxisomes. We have previously reported the isolation of clones for Candida tropicalis peroxisomal proteins; here we describe the association (and possible import) of peroxisomal proteins with peroxisomes in vitro. C. tropicalis was grown in a medium containing Brij 35, resulting in the induction of a moderate number of medium-sized peroxisomes. These peroxisomes, isolated in a sucrose gradient, had a catalase latency of 54% and were sufficiently stable to be concentrated and used in an import assay. The reticulocyte lysate translation products of total RNA from oleate-grown cells were incubated with the peroxisomes at 26 degrees C in the presence of 50 mM KCl, protease inhibitors, 0.5 M sucrose, 2.5 mM MOPS (morpholinepropanesulfonic acid) (pH 7.2), and 0.5 mM EDTA. Ten major translation products (which could be immunoprecipitated with antiserum against peroxisomal protein) became progressively associated with the peroxisomes during the first 30 min of incubation (some up to approximately 70%). These include acyl coenzyme A oxidase and the trifunctional protein hydratase-dehydrogenase-epimerase. This association did not occur at 4 degrees C nor did it occur if the peroxisomes were replaced with mitochondria.

Import of the carboxy-terminal portion of acyl-CoA oxidase into peroxisomes of Candida tropicalis

We report the sequence of a cDNA clone that codes for the carboxy-terminal portion of the peroxisomal protein, acyl-CoA oxidase, from the yeast, Candida tropicalis. This is a newly identified acyl-CoA oxidase sequence, most likely a second allele of POX4. The cDNA clone was expressed by in vitro transcription followed by translation. The major product, a 43-kD protein, associated with isolated peroxisomes in an in vitro import assay. More than half of the peroxisome-associated protein was protected from added protease, implying that it was internalized within the organelle. These findings indicate that there is sufficient information in the carboxy-terminal portion of the protein to target it to peroxisomes.

Molecular cloning and nucleotide sequence of full-length cDNA for sweet potato catalase mRNA

A nearly full-length cDNA clone for catalase (pCAS01) was obtained through immunological screening of cDNA expression library constructed from size-fractionated poly(A)-rich RNA of wounded sweet potato tuberous roots by Escherichia coli expression vector-primed cDNA synthesis. Two additional catalase cDNA clones (pCAS10 and pCAS13), which contained cDNA inserts slightly longer than that of pCAS01 at their 5'-termini, were identified by colony hybridization of another cDNA library. Those three catalase cDNAs contained primary structures not identical, but closely related, to one another based on their restriction enzyme and RNase cleavage mapping analyses, suggesting that microheterogeneity exists in catalase mRNAs. The cDNA insert of pCAS13 carried the entire catalase coding capacity, since the RNA transcribed in vitro from the cDNA under the SP6 phage promoter directed the synthesis of a catalase polypeptide in the wheat germ in vitro translation assay. The nucleotide sequencing of these catalase cDNAs indicated that 1900-base catalase mRNA contained a coding region of 1476 bases. The amino acid sequence of sweet potato catalase deduced from the nucleotide sequence was 35 amino acids shorter than rat liver catalase [Furuta, S., Hayashi, H., Hijikata, M., Miyazawa, S., Osumi, T. & Hashimoto, T. (1986) Proc. Natl Acad. Sci. USA 83, 313-317]. Although these two sequences showed only 38% homology, the sequences around the amino acid residues implicated in catalytic function, heme ligand or heme contact had been well conserved during evolution.