Peroxisomal oxidation of thiazolidine carboxylates in firefly fat body, frog retina, and rat liver and kidney.

D-amino acid oxidase is a widely distributed peroxisomal enzyme whose principal natural substrates are still unknown. Thiazolidine carboxylates, their derivatives and relatives, and the intermediates in their metabolism are among the more plausible substrate candidates. Using a cytochemical procedure, we have explored the distribution of peroxide-generating enzymatic activity against two thiazolidine carboxylates. We find that these compounds are effective substrates for peroxisomal oxidation in a variety of tissues that contain peroxisomal D-amino acid oxidase. Reaction was seen in the "classical" peroxisomes of rat liver and kidney, the peroxisomes of the fat body of firefly and of Drosophila and the peroxisomes of frog retina. Interestingly, both with the thiazolidine compounds and with more traditional D-amino acid oxidase substrates, the fireflies' photocyte granules, which are peroxisomes, lack activity.     

Kinetic properties of rat kidney D-amino acid oxidase associated with peroxisomes

In contrast to hog kidney D-amino acid oxidase, the v vs s plots of D-amino acid oxidase in homogenized rat kidney did not have the form of a rectangular hyperbola, and showed an apparent negative cooperativity. After subcellular fractionation of rat kidney, both of the oxidases in the supernatant fraction and the peroxisomal fraction showed Michaelis-Menten type kinetics. The Km values for D-alanine and D-proline of the peroxisomal fraction were significantly lower than those of the supernatant fraction. The partially purified enzyme from the peroxisomal fraction showed the same kinetic properties as the supernatant fraction. These facts suggest that the two types of rat kidney D-amino acid oxidase were originally identical and that some interaction between the enzyme and peroxisomes is physiologically important for the function of the enzyme.     

Cytochemical and immunocytochemical study on the peroxisomes of rat liver after administration of a hypolipidemic drug, MLM-160

After administration of a hypolipidemic drug, MLM-160, to male rats, liver peroxisomes were studied by biochemical, cytochemical, and immunocytochemical methods. The activities of D-amino acid oxidase, glycolate oxidase, and urate oxidase increased 2 to 3-fold by the treatment. The increase of the oxidases was confirmed by immunoblotting analysis. By light microscopy, immunoreaction for catalase was present in the cytoplasmic granules of hepatocytes. The stained granules formed some clusters and overlapped each other after MLM-160 treatment. However, immunostaining for D-amino acid oxidase and urate oxidase was present in discrete fine granules which did not overlap each other. By electron microscopy, many peroxisomes showed ring-like extensions and cavitation of the matrix, often giving the appearance of a peroxisome-within-a-peroxisome. In many cases, these unusual peroxisomes seemed to be interconnected with each other. Within the peroxisomes, the catalase was localized in the matrix. Urate oxidase was associated with the crystalloid cores. D-amino acid oxidase was localized focally in a small part of the matrix where the catalase was mostly negative. In conclusion, the administration of MLM-160 to male rats induces some peroxisomal oxidases, accompanying the appearance of unusual peroxisomes. The precise localization of peroxisomal enzymes suggested that there are subcompartments within the liver peroxisomes as shown in rat kidney peroxisomes.     

D-aspartate oxidation by rat and bovine renal peroxisomes: an electron microscopic cytochemical study

D-amino acid oxidase, a peroxisomal enzyme, and D-aspartate oxidase, a potential peroxisomal enzyme, share biochemical attributes. Both produce hydrogen peroxide in flavin-requiring oxidative reactions. Such similarities suggest that D-aspartate oxidase may also be localized to peroxisomes. Definitive identification of D-aspartate oxidase as a peroxisomal enzyme depends, however, on visualization at the electron microscopic level. Using incubation conditions shown to be specific for the enzyme in biochemical studies, this report extends the cytochemical localization of D-amino acid oxidase to bovine renal peroxisomes, and shows that D-aspartate can be oxidized by rat and bovine renal peroxisomes. An unexpected finding was the sensitivity of both D-amino acid oxidase activity (proline specific) and D-aspartate oxidase activity to inhibition by agents used in biochemical studies to discriminate between the two enzyme activities. Therefore, it is possible that, in the cytochemical system used in this study, (a) either D-proline and D-aspartate are substrates for only one enzyme or (b) the two enzymes have additional overlapping biochemical properties.     

Unusual responses of rat hepatic and renal peroxisomes to RMI 14, 514, a new hypolipidemic agent.

RMI 14, 514 ([5-tetradecycloxy]-2-furancarboxylic acid) represents a new class of hypolipidemic agents which cause unusual ultrastructural changes in liver of male rats and in selected peroxisomal enzymes in liver and kidney of both sexes. Among the principal ultrastructural changes in peroxisomes of male rat liver were (a) cavitation and compartmentalization of the matrix, often giving the appearance of a peroxisome-within-a-peroxisome, and (b) narrow, dense extensions of canaliculi or cisterns from the periphery of the peroxisome, forming partial circlets or surrounding irregular areas of cytoplasm. The unusual enzyme responses were (a) elevation of catalase activity in liver and kidney in female rats, (b) increased activity of three hydrogen peroxide-producing oxidases (urate oxidase, L-alpha-hydroxy acid oxidase, and D-amino acid oxidase) in the liver of both sexes, and (c) elevation of activity of the last two oxidases in male kidney. The peculiar ultrastructural changes in liver peroxisomes combined with the responses of selected peroxisomal enzymes represent unusual modulations or adaptations of these organelles to a hypolipidemic agent, the effects of which have not been reported extensively.     

Enzymologic study of the structural organization of the matrix or rat liver peroxisomes]

The effect of ionic strength and pH on the release of some enzymes of the matrix of peroxisomes in rat's liver was studied. Catalase, L ALpha-hydroxy acid oxidase, isocitrate dehydrogenase, glycerophosphate dehydrogenase and lactate dehydrogenase were easily released from the particles during their lysis and treatment with 0.16 M KCl, whereas urate oxidase, NADH cytochrome c reductase and D-amino acid oxidase were not solubilized. After the solubilization of peroxisomal membrane by 0.2% Triton X-100, the remaining core contained about 50% amino acid oxidase activity, and had 1.28--1.30 g/cm3 density. These results suggest that D-amino acid oxidase associates with urate oxidase in the peroxisomal core.     

The involvement of fatty acid binding protein in peroxisomal fatty acid oxidation

Rat liver fatty acid-binding protein (FABP) can function as a fatty acid donor protein for both peroxisomal and mitochondrial fatty acid oxidation, since 14C-labeled palmitic acid bound to FABP is oxidized by both organelles. FABP is, however, not detected in peroxisomes and mitochondria of rat liver by ELISA. Acyl-CoA oxidase activity of isolated peroxisomes was not changed by addition of FABP or flavaspidic acid, an inhibitor of fatty acid binding to FABP, nor by disruption of the peroxisomal membranes. These data indicate that FABP may transfer fatty acids to peroxisomes, but is not involved in the transport of acyl-CoA through the peroxisomal membrane.     

Immunocytochemical localization of urate oxidase, fatty acyl-CoA oxidase, and catalase in bovine kidney peroxisomes

We investigated the localization of urate oxidase, peroxisomal fatty acyl-CoA oxidase, and catalase in bovine kidney by immunoblot analysis and protein A-gold immunocytochemistry, using the respective polyclonal monospecific antibodies raised against the enzymes purified from rat liver. By immunoblot analysis, these three proteins were detected in bovine kidney and bovine liver homogenates. Subcellular localization of these three enzymes in kidney was ascertained by protein A-gold immunocytochemical staining of Lowicryl K4M-embedded tissue. Peroxisomes in bovine kidney cortical epithelium possessed crystalloid cores or nucleoids, which were found to be the exclusive sites of urate oxidase localization. The limiting membrane, the marginal plate, and the matrix of renal peroxisomes were negative for urate oxidase staining. In contrast, catalase and fatty acyl-CoA oxidase were found in the peroxisome matrix. These results demonstrate that, unlike rat kidney peroxisomes which lack urate oxidase, peroxisomes of bovine kidney contain this enzyme as well as peroxisomal fatty acyl-CoA oxidase.     

Identification of peroxisomal targeting signals located at the carboxy terminus of four peroxisomal proteins

As part of an effort to understand how proteins are imported into the peroxisome, we have sought to identify the peroxisomal targeting signals in four unrelated peroxisomal proteins: human catalase, rat hydratase:dehydrogenase, pig D-amino acid oxidase, and rat acyl-CoA oxidase. Using gene fusion experiments, we have identified a region of each protein that can direct heterologous proteins to peroxisomes. In each case, the peroxisomal targeting signal is contained at or near the carboxy terminus of the protein. For catalase, the peroxisomal targeting signal is located within the COOH-terminal 27 amino acids of the protein. For hydratase:dehydrogenase, D-amino acid oxidase, and acyl-CoA oxidase, the targeting signals are located within the carboxy-terminal 15, 14, and 15 amino acids, respectively. A tripeptide of the sequence Ser-Lys/His-Leu is present in each of these targeting signals as well as in the peroxisomal targeting signal identified in firefly luciferase (Gould, S.J., G.-A. Keller, and S. Subramani. 1987. J. Cell Biol. 105:2923-2931). When the peroxisomal targeting signal of the hydratase:dehydrogenase is mutated so that the Ser-Lys-Leu tripeptide is converted to Ser-Asn-Leu, it can no longer direct proteins to peroxisomes. We suggest that this tripeptide is an essential element of at least one class of peroxisomal targeting signals.     

Localization of xanthine oxidase in crystalline cores of peroxisomes. A cytochemical and biochemical study

The ultrastructural cytochemical localization of xanthine oxidase activity in rat liver was investigated by the cerium technique. The reaction product was found in the cytoplasm of endothelial cells in liver sinusoids and, in addition, in crystalline cores of peroxisomes of liver parenchymal cells. Xanthine oxidase was also present in peroxisomal cores of beef liver and kidney, but not in rat kidney peroxisomes, which lack crystalline cores. The localization in peroxisomal cores of rat liver was confirmed also biochemically using highly purified peroxisomal fractions and subfractions containing exclusively the crystalline cores. Moreover, high levels of molybdenum were found in isolated peroxisomal cores by atomic absorption spectroscopy, thus corroborating the association of the molybdenum-containing enzyme with the cores. Since urate oxidase is also present within the same compartment of peroxisomes, it is possible that the crystalline cores harbor a complex of several enzymes involved in the purine metabolism.     

Studies on peroxisomes III. Further studies on the intraparticulate localization of peroxisomal components in the liver of the rat

The peroxisome-rich fraction prepared from rat liver homogenate was treated by various procedures and the behavior of the peroxisomal core on sucrose density gradient centrifugation was investigated.Peroxisomes were destroyed by various treatments, such as pH 9.0, VirTis blender, sonication and deoxycholate, resulting in the solubilization of catalase from the particles. Urate oxidase was not solubilized at all such treatments. Although D-amino acid oxidase was solubilized by treatments with deoxycholate and VirTis blender, this enzyme was found to be resistant to solubilization by treatment with pH 9.0 or sonication, in contrast to catalase.When the peroxisomal core was investigated, using urate oxidase activity as a marker, its density proved to be changed when submitted to various treatments. These results indicated that the peroxisomes consist of four compartments: a catalase-containing compartment (matrix), a urate oxidase containing compartment (core), a D-amino acid oxidase containing compartment and a low density compartment which is proposed for the first time in the present paper. Furthermore, it was also found that the last two compartments seem to be bound to the core, though the binding might be weak.     

Molecular analysis of peroxisomal beta-oxidation enzymes in infants with peroxisomal disorders indicates heterogeneity of the primary defect

Immunoblot analysis of peroxisomal beta-oxidation enzymes proteins was carried on liver samples from 15 patients with peroxisomal disorders in which accumulation of very long chain fatty acids was always observed in plasma. In 11 cases including 4 cerebro-hepatorenal syndrome (CHRS), 4 neonatal adrenoleukodystrophy (NALD) and 3 infantile Refsum's disease, the liver peroxisomes could not be detected by electron microscopy. Immunoblot analysis revealed the absence, or presence in weak amounts, of the 72-kDa subunit of acyl-CoA oxidase, and the complete absence of the 52-kDa and 21-kDa subunits which are processed from the 72-kDa. The bifunctional protein (78-kDa) was absent or very reduced, as was the mature form of peroxisomal 3-ketoacyl-CoA thiolase (41-kDa). Multiple defects of peroxisomal beta-oxidation enzymes may be caused by an absence of synthesis or an inability to import proteins into peroxisomes in these patients. One patient, diagnosed as NALD, had no detectable liver peroxisomes but the presence, in normal amounts, of the three peroxisomal beta-oxidation enzyme proteins suggests that the transport of these enzymes into "peroxisomal ghosts" was still intact. The last 3 patients, clinically diagnosed as NALD, had normal liver peroxisomes. One patient had an isolated deficiency of the bifunctional protein and the 2 others had normal amounts of the 3 peroxisomal beta-oxidation enzymes, as shown by immunoblotting. This suggests that import and translocation of some peroxisomal proteins had occurred and that a mechanism is therefore required to explain the defect in these patients.     

D-aspartate oxidase in rat, bovine and sheep kidney cortex is localized in peroxisomes.

D-Aspartate oxidase (EC 1.4.3.1) was assayed in subcellular fractions and in highly purified peroxisomes from rat, bovine and sheep kidney cortex as well as from rat liver. During all steps of subcellular-fractionation procedures, D-aspartate oxidase co-fractionated with peroxisomal marker enzymes. In highly purified preparations of peroxisomes, the enrichment of D-aspartate oxidase activity over the homogenate is about 32-fold, being comparable with that of the peroxisomal marker enzymes catalase and D-amino acid oxidase. Disruption of the peroxisomes by freezing and thawing released more than 90% of the enzyme activity, which is typical for soluble peroxisomal-matrix proteins. Our findings provide strong evidence that in these tissues D-aspartate oxidase is a peroxisomal-matrix protein and should be added as an additional flavoprotein oxidase to the known set of peroxisomal oxidases.     

Immunoelectron microscopic localization of the isozymes of L-alpha-hydroxyacid oxidase in renal peroxisomes of beef and sheep: evidence of distinct intraorganellar subcompartmentation

L-alpha-hydroxyacid oxidase (HAOX), a peroxisomal marker enzyme in mammals, exists in two isozymic forms, HAOX A (EC 1.1.3.1) and HAOX B (EC 1.3.4.2), which differ in their substrate specificity. In rat tissues HAOX A is found exclusively in hepatocyte peroxisomes and HAOX B in renal peroxisomes. Recently we found enzymatic evidence that highly purified peroxisome preparations from beef and sheep kidney cortex contain both isozymes. In situ, the peroxisomes in the proximal tubule cells of both species exhibit peculiar angular outlines apparently due to the presence of multiple marginal plates. Marginal plates are plate-like crystalline matrix inclusions which are apposed to the inner aspect of the peroxisomal membrane. In this study monospecific antibodies against HAOX A and B proteins purified from rat liver and kidney, respectively, were raised in rabbits and used to study the intraorganellar localization of each isozyme in beef and sheep kidney cortex peroxisomes. Incubation of ultra-thin sections of LR White-embedded tissue with anti-HAOX A or B followed by protein A-gold revealed that in both species HAOX A is present diffusely in the peroxisomal matrix, whereas HAOX B is localized almost exclusively in the membrane associated marginal plates. This is the first report on the in situ immunocytochemical characterization of marginal plates, which are the most common inclusions in the matrix of renal peroxisomes.     

The effect of clofibrate on amphibian hepatic peroxisomes.

Liver peroxisomes of two anuran amphibian species, Rana esculenta and Xenopus laevis, were studied in untreated and in clofibrate-treated adults by means of complementary technical approaches, ie, ultrastructural cytochemistry, cell fractionation and marker enzyme activity assays. In untreated adults, hepatic peroxisomes were found to be very scarce in Xenopus when compared to Rana. Activities of catalase, D-amino acid oxidase and of the three first enzymes of the peroxisomal beta-oxidation system were detected in the light mitochondrial fractions enriched in peroxisomes and prepared from livers of both species. Administration of clofibrate at a daily dose level of 60 mg (Rana) and 90 mg (Xenopus) during ten days induced a drastic peroxisome proliferation in Rana hepatocytes but had no visible effect on the hepatic peroxisomal population of Xenopus. The catalase activity and the peroxisomal beta-oxidation system of liver cells were enhanced in Rana as well as in Xenopus. The hepatic D-amino acid oxidase specific activity was increased in Rana whereas it remained rather constant in Xenopus. Taking advantage of the behaviors of Rana and Xenopus hepatic peroxisomes, the molecular mechanisms of clofibrate induction are now investigated in the target liver cells of the two amphibian species.     

Immunoelectron microscopic study of a new D-amino acid oxidase-immunoreactive subcompartment in rat liver peroxisomes.

We report the presence of a new subcompartment in rat liver peroxisomal matrix in which only D-amino acid oxidase is localized and other matrix enzymes are absent. By electron microscopic observation, the rat liver peroxisome has generally been considered to consist of a single limiting membrane, an electron-dense crystalline core, and a homogeneous matrix. Immunohistochemical staining for D-amino acid oxidase by the protein A-gold technique revealed the presence of a small area in the matrix that was immunoreactive for the enzyme and was less electron-dense than the surrounding matrix. The localization of D-amino acid oxidase in this small area of the peroxisomal matrix was confirmed by immunoelectron microscopy on freeze-substituted tissues processed without chemical fixation. To analyze the characteristics of the electron-lucent area, immunoreactivity for various peroxisomal enzymes, including catalase, acyl-CoA oxidase, enoyl-CoA hydratase/3-hydroxyacyl-CoA dehydrogenase bifunctional protein, 3-ketoacyl-CoA thiolase, L-alpha-hydroxy acid oxidase (isozyme B), and glycolate oxidase (isozyme A), was assayed. The electron-lucent area was negative for all of these. By double staining for D-amino acid oxidase and catalase, using colloidal gold particles of different sizes, these enzymes were shown to be located in separate areas in the matrix.     

Determination of the cross-points of rat liver peroxisomes, peroxisomal core and the core components by cross-partition.

The cross-points of rat liver peroxisomes, peroxisomal core and the core components were determined by means of cross-partition in two phase systems. The partitions were carried out in the systems containing 6% (w/w) Dextran T 500 and 6% (w/w) polyethyleneglycol 4000 in sodium salts. The same cross-point, pH 5.6, was obtained in peroxisomal marker enzymes in light mitochondrial fraction of liver homogenate, such as catalase, D-amino acid oxidase and urate oxidase. The cross-point as determined by cross-partition of purified peroxisomal core was 6.7. The cross-points of urate oxidase and framework protein fractions obtained by alkali treatment on the purified core were 7.8 and 4.2, respectively, and the ratio of the proteins of urate oxidase to framework protein was 2 : 1. The theoretical value of cross-point of the core calculated from from the relationship between the cross-point and protein ratio of each component of the core coincided with the experimental value obtained by this method.     

Separate peroxisomal oxidases for fatty acyl-CoAs and trihydroxycoprostanoyl-CoA in human liver

Fatty acyl-CoAs as well as the CoA esters of the bile acid intermediates di- and trihydroxycoprostanic acids are beta-oxidized in peroxisomes. The first reaction of peroxisomal beta-oxidation is catalyzed by acyl-CoA oxidase. We recently described the presence of two fatty acyl-CoA oxidases plus a trihydroxycoprostanoyl-CoA oxidase in rat liver peroxisomes (Schepers, L., P. P. Van Veldhoven, M. Casteels, H. J. Eyssen, and G. P. Mannaerts. 1990. J. Biol. Chem. 265: 5242-5246). We have now developed methods for the measurement of palmitoyl-CoA oxidase and trihydroxycoprostanoyl-CoA oxidase in human liver. The activities were measured in livers from controls and from three patients with peroxisomopathies. In addition, the oxidase activities were partially purified from control livers by ammonium sulfate fractionation and heat treatment, and the partially purified enzyme preparation was subjected to chromatofocusing, hydroxylapatite chromatography, and gel filtration. In earlier experiments this allowed for the separation of the three rat liver oxidases. The results show that human liver, as rat liver, contains a separate trihydroxycoprostanoyl-CoA oxidase. In contrast to the situation in rat liver, no conclusive evidence was obtained for the presence of two fatty acyl-CoA oxidases in human liver. Our results explain why bile acid metabolism is normal in acyl-CoA oxidase deficiency, despite a severely disturbed peroxisomal fatty acid oxidation and perhaps also why, in a number of other cases of peroxisomopathy, di- and trihydroxycoprostanic acids are excreted despite a normal peroxisomal fatty acid metabolism.     

Peroxisomal oxidases and catalase in liver and kidney homogenates of normal and di(ethylhexyl)phthalate-fed rats.

1. Activities of peroxisomal oxidases and catalase were assayed at neutral and alkaline pH in liver and kidney homogenates from male rats fed a diet with or without 2% di(2-ethylhexyl)phthalate (DEHP) for 12 days. 2. All enzyme activities were higher at alkaline than at neutral pH in both groups. 3. The effect of the DEHP-diet on the peroxisomal enzymes was different in kidney and liver. Acyl-CoA oxidase activity was raised three- and sixfold in kidney and liver homogenates, respectively. The activity of D-amino acid oxidase decrease in liver, but increased in kidney homogenates. In liver homogenates, urate oxidase activity was not affected by the DEHP diet. The catalase activity was twofold induced in liver, but not in kidney. 4. The differences suggest that the changes of peroxisomal enzyme activities by DEHP treatment are not directly related to peroxisome proliferation. 5. DEHP treatment caused a marked increase of total and peroxisomal fatty acid oxidation in rat liver homogenates. 6. In the control group the rate of peroxisomal fatty acid oxidation was higher at alkaline pH than at neutral pH. 7. This rate was equal at both pH values in the DEHP-fed group, in contrast to the acyl-CoA oxidase activity. These results indicate that after DEHP treatment other parameters than acyl-CoA oxidase activity become limiting for peroxisomal beta-oxidation.     

Insulin-degrading enzyme exists inside of rat liver peroxisomes and degrades oxidized proteins

Insulin-degrading enzyme (IDE) was detected by immunoblot analysis in highly purified rat liver peroxisomes. IDE in the peroxisomal fraction was resistant to proteolysis by trypsin and chymotrypsin under conditions where the peroxisomal membranes remained intact. After sonication of the peroxisomal fraction, IDE was recovered in the supernatant fraction. Further, the localization of IDE in the peroxisomes was shown by immunoelectron microscopy. In addition, IDE isolated from peroxisomes degraded insulin as well as oxidized lysozyme as a model substrate for oxidized proteins. These results suggest that IDE exists in an active form in the matrix of rat liver peroxisomes and is involved in elimination of oxidized proteins in peroxisomes.