Peroxisomes in intestinal and gallbladder epithelial cells of the stickleback,Gasterosteus aculeatus L. (Teleostei)

Summary The occurrence of microbodies in the epithelial cells of the intestine and gallbladder of the stickleback, Gasterosteus aculeatus L., is described. In the intestine the organelles are predominantly located in the apical and perinuclear zone of the cells and may contain small crystalline cores. In gallbladder epithelial cells the microbodies are distributed randomly. The latter organelles are characterized by the presence of large crystalloids. Cytochemical and biochemical experiments show that catalase and D-amino acid oxidase are main matrix components of the microbodies in both the intestinal and gallbladder epithelia. These organelles therefore are considered peroxisomes. In addition, in intestinal mucosa but not in gallbladder epithelium a low activity of palmitoyl CoA oxidase was detected biochemically. Urate oxidase and L- hydroxy acid oxidase activities could not be demonstrated.     

Cytochemical localization of catalase and several hydrogen peroxide-producing oxidases in the nucleoids and matrix of rat liver peroxisomes

Synopsis The distribution of catalase, amino acid oxidase, -hydroxy acid oxidase, urate oxidase and alcohol oxidase was studied cytochemically in rat hepatocytes. The presence of catalase was demonstrated with the conventional diaminobenzidine technique. Oxidase activities were visualized with methods based on the enzymatic or chemical trapping of the hydrogen peroxide produced by these enzymes during aerobic incubations.All enzymes investigated were found to be present in peroxisomes. Catalase activity was found in the peroxisomal matrix, but also associated with the nucleoid. After staining for oxidase activities the stain deposits occurred invariably in the peroxisomal matrix as well as in the nucleoids. In all experiments the activity of both catalase and the oxidases was confined to the peroxisomes. The presence of a hydrogen peroxide-producing alcohol oxidase was demonstrated for the first time in peroxisomes in liver cells.The results imply that the enzyme activity of the nucleoids of rat liver peroxisomes is not exclusively due to urate oxidase. The nucleoids obviously contain a variety of other enzymes that may be more or less loosely associated with the insoluble components of these structures.     

Absence of CeCl3-detectable peroxisomal glycolate-oxidase activity in developing raphide crystal idioblasts in leaves of Psychotria punctata Vatke and roots of Yucca torreyi L.

Three peroxisomal enzymes, glycolate oxidase, urate oxidase and catalase were localized cytochemically in Psychotria punctata (Rubiaceae) leaves and Yucca torreyi (Agavaceae) seedling root tips, both of which contain developing and mature calcium-oxalate raphide crystal idioblasts. Glycolate-oxidase (EC 1.1.3.1) and catalase (EC 1.11.1.6) activities were present within leaftype peroxisomes in nonidioblastic mesophyll cells in Psychotria leaves, while urate-oxidase (EC 1.7.3.3) activity could not be conclusively demonstrated in these organelles. Unspecialized peroxisomes in cortical parenchyma of Yucca roots exhibited activities of all three enzymes. Reactionproduct deposits attributable to glycolate-oxidase activity were never observed in peroxisomes of any developing or mature crystal idioblasts of Psychotria or Yucca. Catalase localization indicates that idioblast microbodies are functional peroxisomes. The apparent absence of glycolate oxidase in crystal idioblasts of Psychotria and Yucca casts serious doubt that pathways involving this enzyme are operational in the synthesis of the oxalic acid precipitated as calcium-oxalate crystals in these cells.Abbreviations AMPD 2-amino-2-methyl-1,3-propandiol - CTEM conventional transmission electron microscopy - DAB 3,3-diaminobenzidine tetrahydrochloride - HVEM high-voltage electron microscopy     

Cytochemical localization of glycolate oxidase in microbodies (glyoxysomes and peroxisomes) of higher plant tissues with the CeCl3 technique

Summary Alpha hydroxy acid oxidase activity (using glycolate as substrate) was demonstrated cytochemically in leaf-type peroxisomes, glyoxysomes, and unspecialized peroxisomes of higher plant tissues with the CeCl₃ technique in which cerous ions react with enzyme-generated H₂O₂ to form insoluble, electron-dense cerium perhydroxide. In all peroxisomes examined, reaction product was deposited throughout the matrices. None of the three types of microbody inclusions (crystals, amorphous nucleoids, or fibrillar, threadlike structures) observed in leaftype peroxisomes showed cytochemical reactivity. However, results with crystal-containing peroxisomes of guayule and tobacco leaves indicate an intimate association of glycolate oxidase with the crystals; reaction product was deposited in the spaces between the structural units of the crystal.Prolonged (18- versus 3-hour) incubation with glycolate and CeCl₃ were required for reliable cytochemical reactivity in glyoxysomes of castor bean endosperm and unspecialized peroxisomes of barley coleoptile, both of which contain relatively low enzyme activity. The CeCl₃ procedure may prove useful for helping identify microbodies observed with the electron microscope as peroxisomes. The lack of significant background deposits, and resolution of reaction product within crystals, illustrate qualities of the CeCl₃ procedure superior to those of the ferricyanide-reduction method, which was previously used to localize glycolate oxidase in higher plant microbodies.     

Induction of β-oxidation enzymes and microbody proliferation in Aspergillus nidulans

Aspergillus nidulans is able to grow on oleic acid as sole carbon source. Characterization of the oleate-induced β-oxidation pathway showed the presence of the two enzyme activities involved in the first step of this catabolic system: acyl-CoA oxidase and acyl-CoA dehydrogenase. After isopicnic centrifugation in a linear sucrose gradient, microbodies (peroxisomes) housing the β-oxidation enzymes, isocitrate lyase and catalase were clearly resolved from the mitochondrial fraction, which contained fumarase. Growth on oleic acid was associated with the development of many microbodies that were scattered throughout the cytoplasm of the cells. These microbodies (peroxisomes) were round to elongated, made up 6% of the cytoplasmic volume, and were characterized by the presence of catalase. The β-oxidation pathway was also induced in acetate-grown cells, although at lower levels; these cells lacked acyl-CoA oxidase activity. Nevertheless, growth on acetate did not cause a massive proliferation of microbodies in A. nidulans. Received: 8 March 1996 / Accepted: 5 August 1996     

Microbodies in fungi: a review

Summary Microbodies are ubiquitous organelles in fungal cells, occurring in both vegetative hyphae and spores. They are bounded by a single membrane and may contain a crystalloid inclusion with subunits spaced at regular intervals. Typically, they contain catalase which reacts with the cytochemical stain 3,3-diaminobenzidine to yield an electron-opaque product, urate oxidase,l--hydroxy acid oxidase andd-amino acid oxidase. Their fragility and the necessity to disrupt the tough fungal cell wall before isolating them make them difficult to isolate. Analysis of enzymes in purified or partially purified microbodies from fungi indicates that they participate in fatty acid degradation, the glyoxylate cycle, purine metabolism, methanol oxidation, assimilation of nitrogenous compounds, amine metabolism and oxalate synthesis. In organisms where microbodies are known to contain enzymes of the glyoxylate cycle, they are known as glyoxysomes; where they are known to contain peroxidatic activity, they are known as peroxisomes. In some cases microbodies contain enzymes for only a portion of a pathway or cycle. Thus, they must be involved in metabolic cooperation with other organelles, particularly mitochondria. The number, size and shape of microbodies in cells, their buoyant density and their enzyme contents may vary with the composition of the medium; their proliferation in cells is regulated by the growth environment. The isolation from the same organism of microbodies with different buoyant densities and different enzymes suggests strongly that more than one type of microbody can be formed by fungi.     

Ultrastructure and distribution of microbodies in leaves of grasses with and without CO2-photorespiration

Summary A comparative study was made of the ultrastructure, distribution and abundance of leaf microbodies in four species of temperate grasses with high and four tropical grasses with low CO₂-photorespiration. The temperate grasses were all festucoid; the tropical grasses included two panicoid species and two chloridoid. Comparisons of relative abundance were made by computing the average numbers of microbody profiles per cell section.Although microbodies were present in the green parenchymatous leaf cells in all grasses examined, their average number per cell was in general severalfold greater in the grasses with high CO₂-photorespiration than in those with low. Furthermore, whereas in the grasses with high CO₂-photorespiration the microbodies were distributed through the mesophyll, in those with low CO₂-photorespiration they were concentrated in the vascular-bundle-sheath cells and were smaller and relatively scarce in the mesophyll cells. The leaf microbodies of the eight grass species resembled one another in general morphology, but differed to some extent in regard to size and type of inclusion. Microbodies of all four festucoid species contained numerous fibrils with a discernible substructure. Those of the two panicoid species contained clusters of round bodies with transparent cores. The equivalence of the microbodies to peroxisomes as biochemically defined was shown cytochemically by employing 3,3-diaminobenzidine for the localization of catalase, a marker enzyme for the peroxisome. This reaction was blocked by the catalase inhibitor, aminotriazole.The observations on the relative abundance and distribution of peroxisomes in leaves of grasses with high CO₂-photorespiration versus those with low are consistent with the published biochemical data on the levels and distribution of peroxisomal enzymes in representatives of plants with high and low CO₂-photorespiration, and may help explain the differences in apparent photorespiratory levels between these two groups of plants.     

Proliferation and function of microbodies in the nematophagous fungus Arthrobotrys oligospora during growth on oleic acid or d-alanine as the sole carbon source

Abstract The nematophagous fungus Arthrobotrys oligospora is able to grow on oleic acid or d-alanine as the sole carbon source. During growth on oleic acid, activities of enzymes of the β-oxidation pathway, but not catalase, were induced. In the presence of d-alanine, both d-amino acid oxidase and catalase activities were enhanced. Biochemically and cytochemically, the activities of the above enzymes were assigned to microbodies. The significance of these results in relation to the function of microbodies in trophic hyphae, which are formed during nematode infection, is discussed.     

Isolation of peroxisomes from the dog kidney cortex.

The present study was undertaken to separate peroxisomes of the dog kidney cortex by the methods of discontinuous sucrose density gradient and zonal centrifugation. The separation of subcellular particles was evaluated by measuring the activities of reference enzymes, beta-glycerophosphatase for lysosomes, succinate dehydrogenase for mitochondria, glucose-6-phosphatase for microsomes, and catalase and D-amino acid oxidase for peroxisomes. The activities of D-amino acid oxidase and catalase were mainly observed in fractions 1 and 2 (1.6 and 1.7 M sucrose) obtained by discontinuous sucrose density-gradient centrifugation. Small amounts of acid phosphatase and succinate dehydrogenase contaminated these fractions. Considerably higher activity of catalase was determined in the supernatant, while D-amino acid oxidase showed a lower activity. By the method of zonal centrifugation, the highest specific activities of catalase and D-amino acid oxidase were found in fraction 50 (1.73 M sucrose) with no succinate dehydrogenase, acid phosphatase or glucose-6-phosphatase activity. These results suggested that peroxisomes of dog kidney cortex were clearly separated in 1.73 M sucrose from mitochondria, lysosomes and microsomes by zonal centrifugation.     

Cytochemical localization of a D-amino acid oxidizing enzyme in peroxisomes of Drosophila melanogaster

A peroxide generating oxidase is demonstrated cytochemically in the peroxisomes of adult and larval Drosophila melanogaster, Oregon R and Rosy-506 strains. This enzyme activity is demonstrable using D-pipecolate or D-proline, but not L-proline, as substrate and is inhibited by kojic acid. Thus this enzyme shares cytochemical characteristics with vertebrate D-amino acid oxidase.     

Particles resembling microbodies in normal and neoplastic perianal glands of dogs

Summary By electron microscopy, the parenchymal cells of the perianal glands of dogs contain granules which have the morphological features of microbodies (peroxisomes) including marginal plates and, occasionally, dense nucleoids. Like microbodies, they are occasionally attached to the endoplasmic reticulum. Histochemical evidence is presented suggesting that they contain at least one of the peroxisomal enzymes, L--hydroxy acid oxidase. The granules of a perianal gland adenoma showed abnormal morphologic variations.Mrs. Murtie Still, Mrs. Bertha McClure and Mr. Bob White gave valuable technical assistance.     

A correlative ultrastructural and enzymatic study of cotyledonary microbodies following germination of fat-storing seeds

Summary Sunflower, cucumber, and tomato cotyledons, which contain microbodies in both the early lipid-degrading and the later photosynthetic stages of post-germinative growth, were processed for electron microscopy according to conventional procedures and examined 1, 4 and 7 days after germination. Homogenates of sunflower cotyledons were assayed for enzymes characteristic of glyoxysomes and leaf peroxisomes (both of which are defined morphologically as microbodies) at stages corresponding to the fixations for electron microscopy. The particulate nature of these enzymes was demonstrated by differential and equilibrium density centrifugation, making it possible to relate them to the microbodies seen in situ.One day after germination, the microbodies are present as small organelles among large numbers of protein and lipid storage bodies; the cell homogenate contains catalase but no detectable isocitrate lyase (characteristic of glyoxysomes) or glycolic acid oxidase (characteristic of leaf peroxisomes). 4 days after germination, numerous microbodies (glyoxysomes) are in extensive and frequent contact with lipid bodies. The microbodies often have cytoplasmic invaginations. At this stage the cells are rapidly converting lipids to carbohydrates, and the homogenate has high isocitrate lyase activity. 7 days after germination, microbodies (peroxisomes) are appressed to chloroplasts and frequently squeezed between them in the green photosynthetic cells. The homogenate at this stage has substantial glycolic acid oxidase activity but a reduced level of isocitrate lyase. It is yet to be determined whether the peroxisomes present at day 7 are derived from preexisting glyoxysomes or arise as a separate population of organelles.     

Electron microscopic cytochemical localization ofα-hydroxyacid oxidase in rat kidney cortex

Summary The substrate specificity of-hydroxyacid oxidase in the rat kidney has been investigated cytochemically by the cerium technique and biochemically with a luminometric assay applied to isolated renal peroxisomes. Rat kidneys were fixed by perfusion via the abdominal aorta with a low concentration (0.25%) of glutaraldehyde. Vibratome sections were incubated for 60 min at 37°C in a medium containing 3 mM CeCl₃, 100 mM NaN₃ and 5 mM of an-hydroxyacid in 0.1M Pipes or 0.1M Tris-maleate buffer both adjusted to pH 7.8. Ten aliphatic -hydroxyacids with chain lengths between 2 and 8 carbon atoms and two aromatic substrates were tested. The -hydroxyacid oxidase in the kidney exhibited a markedly different substrate specificity than the corresponding enzyme in the liver. Thus glycolate gave a negative reaction while two aromatic substrates, mandelic acid and phenyllactic acid, stained prommently. With aliphatic substrates a stronger reaction was obtained in Pipes than in theTris-maleate buffered incubation media. The best reaction in the kidney was obtained with hydroxybutyric acid. These cytochemical findings were confirmed by the luminometric determination of the oxidase activity in isolated purified peroxisome fractions. By electron microscopy the electron dense reaction product of cerium perhydroxide was found in the matrix of peroxisomes in the proximal tubules. The intensity of reaction varied markedly in neighbouring epithelial cells but also in different peroxisomes within the same cell. Thus heavily stained particles were seen next to lightly reacted ones. These observations establish the substrate specificity of -hydroxyacid oxidase in the rat kidney and demonstrate the marked heterogeneity in the staining of renal peroxisomes for this enzyme.     

Immobilization of yeast microbodies and the properties of immobilized microbody enzymes

Summary Yeast microbodies isolated from methanol-grown cells of Kloeckera sp. No. 2201 were immobilized by two types of entrapping techniques: photocrosslinking of liquid oligomers of suitable photosensitive resins and crosslinking of albumin molecules with glutaraldehyde. The apparent activities of catalase, alcohol oxidase, and D-amino acid oxidase in the gel-entrapped microbodies were 40–50, 70–80, and ca. 50% respectively as compared with those in the free microbodies. Alcohol oxidase in the immobilized microbodies, similarly to that in free ones, oxidized methanol, ethanol, n-propanol, n-butanol, n-amyl alcohol, and benzyl alcohol. Some properties of catalase and alcohol oxidase in the microbodies immobilized by the above-mentioned techniques were studied in comparison with those of the enzymes in the free microbodies.     

Enzymes of beta-Oxidation in Different Types of Algal Microbodies

The algae Mougeotia and Eremosphaera were used for isolation of microbodies with the characteristics of leaf peroxisomes and unspecialized peroxisomes, respectively. In both types of organelles, the following enzymes of the β-oxidation pathway were determined: acyl-CoA oxido-reductase, enoyl-CoA hydratase, and 3-hydroxyacyl-CoA dehydrogenase. There are indications that the peroxisomal oxidoreductase of both algae is a H₂O₂-forming oxidase rather than a dehydrogenase.

The enzymes enoyl-CoA hydratase and acyl-CoA oxidoreductase are located also in the mitochondria from Eremosphaera but not from Mougeotia. The mitochondrial acyl-CoA oxidizing enzyme was found to be a dehydrogenase. The specific activities of acyl-CoA oxidase and enoyl-CoA hydratase are lower than in spinach leaf peroxisomes. However, the activity of 3-hydroxyacyl-CoA dehydrogenase in the peroxisomes of both algae is almost 2-fold higher. The capability for degradation of fatty acids is a common feature of all different types of peroxisomes from algae.

     

Cytochemical localization of glucose oxidase in peroxisomes of Aspergillus niger

Summary The subcellular localization of glucose oxidase (E.C. 1.1.3.4) in mycelia of Aspergillus niger has been investigated using cytochemical staining techniques. Mycelia from fermenter cultures, which produced gluconic acid from glucose, contained elevated levels of glucose oxidase and catalase. Both enzymes were located in microbodies. In addition, when the organism was grown on glucose with methylamine as a nitrogen source, amine oxidase activity was detected in the microbodies. These organelles can therefore be designated as peroxisomes.     

Biogenesis and cytochemistry of unspecialized peroxisomes in root cortical cells of Yucca torreyi L

Microbodies containing bipyramidal crystalline nucleoid inclusions occur within every cortical cell in roots of Yucca torreyi. Reaction product deposition attributable to catalase, glycolate oxidase, and urate oxidase activities are cytochemically localized to Yucca root microbodies and classifies them as unspecialized peroxisomes on the basis of their enzyme complement and tissue origin. Crystalline nucleoids do not stain for glycolate or urate oxidase activities, appearing as negatively-stained inclusions, but are apparently reactive for catalase activity. Development of unspecialized peroxisomes in Yucca roots is consistent with all evidence for glyoxysome and leaf-type peroxisome biogenesis from ER. Dilated ends of ER cisternae accumulate cytochemically detectable glycolate oxidase activity. After considerable dilation, paracrystalline precursors to nucleoids form within the bulge, and the inclusion enlarges to comprise the majority of peroxisomal volume. Peroxisomes that are not attached to ER are observed with high voltage electron microscopy and in serial thin sections, implying that eventually the budding peroxisomes are vesiculated. The functions of these unspecialized peroxisomes are suggested based upon cytochemical detection of their partial enzyme complement and their spatial and developmental timing relationships within developing Yucca root cortical parenchyma cells.     

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.     

Proliferation and metabolic significance of peroxisomes in Candida boidinii during growth on d-alanine or oleic acid as the sole carbon source

We have studied the induction of peroxisomes in the methylotrophic yeast Candida boidinii by d-alanine and oleic acid. The organism was able to utilize each of these compounds as the sole carbon source and grew with growth rates of =0.20 h^-1 (on d-alanine) or =0.43 h^-1 (on oleic acid). Growth was associated with the development of many peroxisomes in the cells. On d-alanine a cluster of tightly interwoven organelles was observed which made up 6.3% of the cytoplasmic volume and were characterized by the presence of d-amino acid oxidase and catalase. On oleic acid rounded to elongated peroxisomes were dominant which were scattered throughout the cytoplasm. These organelles contained increased levels of -oxidation enzymes; their relative volume fraction amounted 12.8% of the cytoplasmic volume.     

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.