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

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

Proteomic analysis of leaf peroxisomal proteins in greening cotyledons of Arabidopsis thaliana

Leaf peroxisomes are present in greening cotyledons and contain enzymes of the glycolate pathway that functions in photorespiration. However, only a few leaf peroxisomal proteins, that is hydroxypyruvate reductase (HPR), glycolate oxidase (GO) and alanine:glyoxylate aminotransferase 1 (AGT1), have been characterized, and other functions in leaf peroxisomes have not been solved. To better understand the functions of leaf peroxisomes, we established a method to isolate leaf peroxisomes of greening cotyledons. We analyzed 53 proteins by MALDI-TOF MS and then identified 29 proteins. Among them, five proteins are related to the glycolate pathway, four proteins function in scavenging of hydrogen peroxide and additionally 20 novel leaf peroxisomal proteins were identified. In particular, protein kinases and protein phosphatase were first identified as peroxisomal proteins suggesting that protein phosphorylation is one of the regulatory mechanisms in leaf peroxisomes. Novel leaf peroxisomal proteins contained five PTS1-like proteins that have sequences where one amino acid is substituted with another one in PTS1 sequences. The PTS1 motif was suggested to have novel PTS1 sequences.     

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

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

Developmental studies on microbodies in wheat leaves : I. Conditions influencing enzyme development

Catalase, glycolate oxidase, and hydroxypyruvate reductase, enzymes which are located in the microbodies of leaves, show different developmental patterns in the shoots of wheat seedlings. Catalase and hydroxypyruvate reductase are already present in the shoots of ungerminated seeds. Glycolate oxidase appears later. All three enzymes develop in the dark, but glycolate oxidase and hydroxypyruvate reductase have only low activities. On exposure of the seedlings to continuous white light (14.8 × 10³ ergs cm⁻² sec⁻¹), the activity of catalase is doubled, and glycolate oxidase and hydroxypyruvate reductase activities increase by 4- to 7-fold. Under a higher light intensity, the activities of all three enzymes are considerably further increased. The activities of other enzymes (cytochrome oxidase, fumarase, glucose-6-phosphate dehydrogenase) are unchanged or only slightly influenced by light. After transfer of etiolated seedlings to white light, the induced increase of total catalase activity shows a much longer lag-phase than that of glycolate oxidase and hydroxypyruvate reductase. It is concluded that the light-induced increases of the microbody enzymes are due to enzyme synthesis. The light effect on the microbody enzymes is independent of chlorophyll formation or the concomitant development of functional chloroplasts. Short repeated light exposures which do not lead to greening are very effective. High activities of glycolate oxidase and hydroxypyruvate reductase develop in the presence of 3-amino-1,2,4-triazole which blocks chloroplast development. The effect of light is not exerted through induced glycolate formation and appears instead to be photomorphogenetic in character.     

cDNA cloning and differential gene expression of three catalases in pumpkin

Three cDNA clones (cat1, cat2, cat3) for catalase (EC 1.11.1.6) were isolated from a cDNA library of pumpkin (Cucurbita sp.) cotyledons. In northern blotting using the cDNA-specific probe, the cat1 mRNA levels were high in seeds and early seedlings of pumpkin. The expression pattern of cat1 was similar to that of malate synthase, a characteristic enzyme of glyoxysomes. These data suggest that cat1 might encode a catalase associated with glyoxysomal functions. Furthermore, immunocytochemical analysis using cat1-specific anti-peptide antibody directly showed that cat1 encoding catalase is located in glyoxysomes. The cat2 mRNA was present at high levels in green cotyledons, mature leaf, stem and green hypocotyl of light-grown pumpkin plant, and correlated with chlorophyll content in the tissues. The tissue-specific expression of cat2 had a strong resemblance to that of glycolate oxidase, a characteristic enzyme of leaf peroxisomes. During germination of pumpkin seeds, cat2 mRNA levels increased in response to light, although the increase in cat2 mRNA by light was less than that of glycolate oxidase. cat3 mRNA was abundant in green cotyledons, etiolated cotyledons, green hypocotyl and root, but not in young leaf. cat3 mRNA expression was not dependent on light, but was constitutive in mature tissues. Interestingly, cat1 mRNA levels increased during senescence of pumpkin cotyledons, whereas cat2 and cat3 mRNAs disappeared during senescence, suggesting that cat1 encoding catalase may be involved in the senescence process. Thus, in pumpkin, three catalase genes are differentially regulated and may exhibit different functions.     

Microbodies (Glyoxysomes and Peroxisomes) in Cucumber Cotyledons: Correlative Biochemical and Ultrastructural Study in Light- and Dark-grown Seedlings

The changes in activities of glyoxysomal and peroxisomal enzymes have been correlated with the fine structure of microbodies in cotyledons of the cucumber (Cucumis sativus L.) during the transition from fat degradation to photosynthesis in light-grown plants, and in plants grown in the dark and then exposed to light. During early periods of development in the light (days 2 through 4), the microbodies (glyoxysomes) are interspersed among lipid bodies and contain relatively high activities of glyoxylate cycle enzymes involved in lipid degradation. Thereafter, these activities decrease rapidly as the cotyledons expand and become photosynthetic, and the activity of glycolate oxidase rises to a peak (day 7); concomitantly the microbodies (peroxisomes) become preferentially associated with chloroplasts.     

Localization of Glyoxylate Cycle Enzymes in Glyoxysomes in Euglena*

SYNOPSIS. We demonstrated previously microbodies in Euglena gracilis grown in the dark on 2-carbon substrates. We have now established in Euglena the particulate nature of enzymes known in other organisms to be localized in microbodies (glyoxysomes and leaf peroxisomes). On a linear sucrose gradient the glyoxylate cycle enzymes band together at a nigner equilibrium density (1.20 g/cm3) than mitochondrial marker enzymes (1.17 g/cm3), establishing the existence in Euglena of glyoxysomes similar to those of higher plants. Glyoxylate (hydroxypyruvate) reductase and, under certain conditions, also glycolate dehydrogenase co-band with the glyoxylate cycle enzymes, suggesting that Euglena glyoxysomes, like those of higher plants, may contain peroxisomal-type enzymes. Catalase, an enzyme characteristic of microbodies from a variety of sources, was not detected in Euglena.     

Kinetin action on the development of microbody enzymes in sunflower cotyledons in the dark

Summary Removal of the roots from etiolated sunflower seedlings (Helianthus annuus L.) at various stages of development resulted in a premature or enhanced decline of the activities of catalase (E.C. 1.11.1.6) and isocitrate lyase (E.C. 4.1.3.1) (glyoxysomes), and hydroxypyruvate reductase (E.C. 1.1.1.26) and glycolate oxidase (E.C. 1.1.3.1) (leaf peroxisomes) in the cotyledons. Treatment of the cuttings with kinetin in the dark inhibited the loss of glyoxysomal enzyme activities and, at the same time, induced a three to fivefold increase in leaf-peroxisomal enzyme activities. The decline of glyoxysomal enzyme activities was also suppressed after application of both kinetin and cycloheximide (50 g/ml). The kinetin-mediated rise of leaf-peroxisomal enzyme activities was strongly curtailed in the presence of cycloheximide. The dose effect curves of kinetin action on the development of glyoxysomal and of leaf-peroxisomal enzyme activities were different, supporting the hypothesis that the mechanisms of kinetin action on the two microbody enzyme systems are different. Nitrogen nutrition of intact seedling effected the development of microbody enzyme activities in a pattern closely resembling that of kinetin action. Presumably endogenous cytokinins produced by the roots are involved in the regulation of microbody enzyme activities in cotyledons of dark-grown sunflower seedlings.     

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.     

NCS对离体萝卜子叶微体中酶活性及细胞超微结构的影响

研究了天然生物活性物质narciclasine(NCS)对离体萝卜子叶光下生长发育期间叶绿素含量变化、异柠檬酸裂解酶及羟基丙酮酸还原酶活性的影响;并对萝卜子叶细胞的超微结构变化进行了观察。结果表明,NCS明显抑制光下培养的离体萝卜子叶叶绿素含量及鲜重增加,对异柠檬酸裂解酶及羟基丙酮酸还原酶活性也显示出明显的抑制作用。电镜观察显示,NCS对蛋白体及脂质体的降解、叶绿体的发育也表现出强烈的抑制效应。NCS的各种抑制作用均随其浓度的增加而增加,而且高浓度的NCS(10^-5mol／L)基本上完全阻止了离体萝卜子叶的光下生长及其转绿。     

Changes in some enzymes of microbodies and plastid development in excised radish cotyledons: effect of narciclasine

Narciclasine (NCS), isolated from mucilage of Narcissus bulb, showed inhibitory effects on growth and plastid development of excised radish cotyledons. NCS (0.1 mumol/L) started to show inhibitory effects on isocitrate lyase and hydroxypyruvate reductase activities after 24 h incubation in light. When NCS concentration was increased to 10 mumol/L, the activities of both enzymes are completely inhibited. From ultrastructural studies, NCS markedly prevented the degradation of protein bodies and lipid bodies, as well as chloroplast formation of excised radish cotyledons. There was only little degradation of protein and lipid bodies, and almost no chloroplast formation in the excised radish cotyledon treated with 1 mumol/L NCS. Therefore, our results provide clear evidence that NCS inhibited the transition of glyoxysomes and peroxisomes, and chloroplast development.     

Compartmentation studies on spinach leaf peroxisomes : evidence for channeling of photorespiratory metabolites in peroxisomes devoid of intact boundary membrane

In concurrence with earlier results, the following enzymes showed latency in intact spinach (Spinacia oleracea L.) leaf peroxisomes: malate dehydrogenase (89%), hydroxypyruvate reductase (85%), serine glyoxylate aminotransferase (75%), glutamate glyoxylate aminotransferase (41%), and catalase (70%). In contrast, glycolate oxidase was not latent. Aging of peroxisomes for several hours resulted in a reduction in latency accompanied by a partial solubilization of the above mentioned enzymes. The extent of enzyme solubilization was different, being highest with glutamate glyoxylate aminotransferase and lowest with malate dehydrogenase. Osmotic shock resulted in only a partial reduction of enzyme latency. Electron microscopy revealed that the osmotically shocked peroxisomes remained compact, with smaller particle size and pleomorphic morphology but without a continuous boundary membrane. Neither in intact nor in osmotically shocked peroxisomes was a lag phase observed in the formation of glycerate upon the addition of glycolate, serine, malate, and NAD. Apparently, the intermediates, glyoxylate, hydroxypyruvate, and NADH, were confined within the peroxisomal matrix in such a way that they did not readily leak out into the surrounding medium. We conclude that the observed compartmentation of peroxisomal metabolism is not due to the peroxisomal boundary membrane as a permeability barrier, but is a function of the structural arrangement of enzymes in the peroxisomal matrix allowing metabolite channeling.     

An activated-oxygen-mediated role for peroxisomes in the mechanism of senescence of Pisum sativum L. leaves

The possible involvement of peroxisomes and their activated-oxygen metabolism in the mechanism of leaf senescence was investigated in detached pea (Pisum sativum L.) leaves which were induced to senesce by incubation in complete darkness for up to 11 d. At days 0, 3, 8, and 11 of senescence, peroxisomes were purified from leaves and the activities of different peroxisomal and glyoxysomal enzymes were measured. Xanthine-oxidoreductase activity increased with senescence, especially the O ₂ ^{. -} -producing xanthine oxidase (EC 1.1.3.22). The activities of H₂O₂-generating Mn-superoxide dismutase (EC 1.15.1.1) and urate oxidase (EC 1.7.3.3) were also enhanced by senescence, whereas catalase (EC 1.11.1.6) activity was severely depressed. Hydrogen peroxide concentrations increased significantly in senescent leaf peroxisomes. During the progress of senescence, glycollate oxidase (EC 1.1.3.1) and hydroxypyruvate reductase (EC 1.1.1.81), two marker enzymes of photorespiratory metabolism, gradually decreased in activity and disappeared. At the same time, the activities of malate synthase (EC 4.1.3.2) and isocitrate lyase (EC 4.1.3.1), key enzymes of the glyoxylate cycle, which were undetectable in presenescent leaves, increased dramatically upon induction of senescence. Ultrastructural studies of intact leaves showed that the population of peroxisomes and mitochondria increased with senescence. Results indicate that peroxisomes could play a role, mediated by activated oxygen species, in the oxidative mechanism of leaf senescence, and further support the idea, proposed by other authors, that foliar senescence is associated with the transition of leaf peroxisomes into glyoxysomes.Abbreviation Mn-SOD (manganese-containing) superoxide dismutase The authors thank Dr. A.J. Sánchez-Raya (Unidad de Fisiología Vegetal, Estación Experimental del Zaidín, Granada, Spain) for his valuable help in measuring ethylene production, and Dr. G. Barja de Quiroga (Departamento de Biología Animal II, Universidad Complutense, Madrid, Spain) for carrying out the malondialdehyde determinations by HPLC. This work was supported by grant PB87-0404-01 from the DGICYT and the Junta de Andaluc'ia (Research Group # 3315), Spain.     

Effects of light fluence and wavelength on expression of the gene encoding cucumber hydroxypyruvate reductase.

We have investigated the regulation of cucumber (Cucumis sativus) hydroxypyruvate reductase mRNA abundance in response to white-, red-, and far-red-light treatments. Following irradiation of dark-adapted cucumber seedlings with 15 min to 4 h of either white or red light and return to darkness, the mRNA level for the gene encoding hydroxypyruvate reductase (Hpr) in cotyledons peaks in the darkness 16 to 20 h later. The response of the Hpr mRNA level to total fluence of white light depends more directly on irradiation time than on fluence rate. In addition to this time-dependent component, a phytochrome-dependent component is involved in Hpr regulation in dark-adapted green cotyledons as shown by red-light induction and partial far-red-light reversibility. Parallel measurements of mRNA levels for the ribulose bisphosphate carboxylase/oxygenase small subunit and for the chlorophyll a/b-binding protein show that Hpr is the most responsive to short (about 60 min) white- and red-light treatments and that each mRNA has a characteristic pattern of accumulation in dark-adapted cotyledons in response to light.     

Isolation of microbodies from plant tissues

Specialized microbodies have previously been isolated and characterized from fatty seedling tissues (glyoxysomes) and leaves (leaf peroxisomes). We have now examined 11 other plant tissues, including tubers, fruits, roots, shoots, and petals, and find that all contain particulate catalase, a distinctive common enzyme component of microbodies. On linear sucrose gradients the catalase activity peaks sharply at a higher equilibrium density (1.20 to 1.25 gram per cm³ in the various tissues) than the mitochondria (1.17 to 1.20). Only small amounts of protein are recovered in the fractions containing catalase, although a definite band is visible in preparations from some tissues, e.g., potato. As in the preparations from castor bean endosperm and spinach leaves for which comparable data are provided, the distribution of glycolate oxidase and uricase follows closely that of catalase on the gradients. The preparations from potato lack glyoxylate reductase and the transaminases, typical enzymes of leaf peroxisomes, and the distinctive enzymes of glyoxysomes are missing. Nonspecialized microbodies with limited enzyme composition can thus be isolated from a variety of plant tissues.     

Catalase Synthesis and Turnover during Peroxisome Transition in the Cotyledons of Helianthus annuus L

Based on measurements of total catalase hematin and the degradation constants of catalase hematin, zero order rate constants for the synthesis of catalase were determined during the development of sunflower cotyledons (Helianthus annuus L.). Catalase synthesis reached a sharp maximum of about 400 picomoles hematin per day per cotyledon at day 1.5 during the elaboration of glyoxysomes in the dark. During the transition of glyoxysomes to leaf peroxisomes (greening cotyledons, day 2.5 to 5) catalase synthesis was constant at a level of about 30 to 40 picomoles hematin per day per cotyledon. In the cotyledons of seedlings kept in the dark (day 2.5 to 5) catalase synthesis did not exceed 10 picomoles hematin per day per cotyledon. During the peroxisome transition in the light, total catalase hematin was maintained at a high level, whereas total catalase activity rapidly decreased. In continuous darkness, total catalase hematin decreased considerably from a peak at day 2. The results show that both catalase synthesis and catalase degradation are regulated by light. The turnover characteristics of catalase are in accordance with the concept that glyoxysomes are transformed to leaf peroxisomes as described by the one population model and contradict the two population model and the enzyme synthesis changeover model which both postulate de novo formation of the leaf peroxisome population and degradation of the glyoxysome population.     

Investigation of the glyoxysome-peroxisome transition in germinating cucumber cotyledons using double-label immunoelectron microscopy

Microbodies in the cotyledons of cucumber seedlings perform two successive metabolic functions during early postgerminative development. During the first 4 or 5 d, glyoxylate cycle enzymes accumulate in microbodies called glyoxysomes. Beginning at about day 3, light-induced activities of enzymes involved in photorespiratory glycolate metabolism accumulate rapidly in microbodies. As the cotyledonary microbodies undergo a functional transition from glyoxysomal to peroxisomal metabolism, both sets of enzymes are present at the same time, either within two distinct populations of microbodies with different functions or within a single population of microbodies with a dual function. We have used protein A-gold immunoelectron microscopy to detect two glyoxylate cycle enzymes, isocitrate lyase (ICL) and malate synthase, and two glycolate pathway enzymes, serine:glyoxylate aminotransferase (SGAT) and hydroxypyruvate reductase, in microbodies of transition-stage (day 4) cotyledons. Double-label immunoelectron microscopy was used to demonstrate directly the co-existence of ICL and SGAT within individual microbodies, thereby discrediting the two-population hypothesis. Quantitation of protein A- gold labeling density confirmed that labeling was specific for microbodies. Quantitation of immunolabeling for ICL or SGAT in microbodies adjacent to lipid bodies, to chloroplasts, or to both organelles revealed very similar labeling densities in these three categories, suggesting that concentrations of glyoxysomal and peroxisomal enzymes in transition-stage microbodies probably cannot be predicted based on the apparent associations of microbodies with other organelles.     

A Survey of Plants for Leaf Peroxisomes

Leaves of 10 plant species, 7 with photorespiration (spinach, sunflower, tobacco, pea, wheat, bean, and Swiss chard) and 3 without photorespiration (corn, sugarcane, and pigweed), were surveyed for peroxisomes. The distribution pattern for glycolate oxidase, glyoxylate reductase, catalase, and part of the malate dehydrogenase indicated that these enzymes exist together in this organelle. The peroxisomes were isolated at the interface between layers of 1.8 to 2.3 m sucrose by isopycnic nonlinear sucrose density gradient centrifugation or in 1.95 m sucrose on a linear gradient. Chloroplasts, located by chlorophyll, and mitochondria by cytochrome c oxidase, were in 1.3 to 1.8 m sucrose.In leaf homogenates from the first 7 species with photorespiration, glycolate oxidase activity ranged from 0.5 to 1.5 mumoles x min(-1) x g(-1) wet weight or a specific activity of 0.02 to 0.05 mumole x min(-1) x mg(-1) protein. Glyoxylate reductase activity was comparable with glycolate oxidase. Catalase activity in the homogenates ranged from 4000 to 12,000 mumoles x min(-1) x g(-1) wet weight or 90 to 300 mumoles x min(-1) x mg(-1) protein. Specific activities of malate dehydrogenase and cytochrome oxidase are also reported. In contrast, homogenates of corn and sugarcane leaves, without photorespiration, had 2 to 5% as much glycolate oxidase, glyoxylate reductase, and catalase activity. These amounts of activity, though lower than in plants with photorespiration, are, nevertheless, substantial.Peroxisomes were detected in leaf homogenates of all plants tested; however, significant yields were obtained only from the first 5 species mentioned above. From spinach and sunflower leaves, a maximum of about 50% of the marker enzyme activities was found to be in these microbodies after homogenization. The specific activity for peroxisomal glycolate oxidase and glyoxylate reductase was about 1 mumole x min(-1) x mg(-1) protein; for catalase. 8000 mumoles x min(-1) x mg(-1) protein, and for malate dehydrogenase, 40 mumoles x min(-1) x mg(-1) protein. Only small to trace amounts of marker enzymes for leaf peroxisomes were recovered on the sucrose gradients from the last 5 species of plants. Bean leaves, with photorespiration, had large amounts of these enzymes (0.57 mumole of glycolate oxidase x min(-1) x g(-1) tissue) in the soluble fraction, but only traces of activity in the peroxisomal fraction. Low peroxisome recovery from certain plants was attributed to particle fragility or loss of protein as well as to small numbers of particles in such plants as corn and sugarcane.Homogenates of pigweed leaves (no photorespiration) contained from one-third to one-half the activity of the glycolate pathway enzymes as found in comparable preparations from spinach leaves which exhibit photorespiration. However, only traces of peroxisomal enzymes were separated by sucrose gradient centrifugation of particles from pigweed. Data from pigweed on the absence of photorespiration yet abundance of enzymes associated with glycolate metabolism is inconsistent with current hypotheses about the mechanism of photorespiration.Most of the catalase and part of the malate dehydrogenase activity was located in the peroxisomes. Contrary to previous reports, the chloroplast fractions from plants with photo-respiration did not contain a concentration of these 2 enzymes, after removal of peroxisomes by isopycnic sucrose gradient centrifugation.     

Peroxisomes in the Alga Vaucheria are Neither of the Leaf Peroxisomal Nor of the Glyoxysomal Type*,1

Microbodies were isolated from the freshwater alga Vaucheria sessilis as well as from a marine Vaucheria. The organelles equilibrated on sucrose gradients at densities 1.23 g . cm^?3 and 1.24g . cm^?3, respectively. On electron micrographs they showed an ovoid or spheroid shape with a diameter of 0.5 to 0.8 μm. Besides catalase, the peroxisomes of both algae possess glycolate oxidase and glutamate-glyoxylate aminotransferase, but no other leaf-peroxisomal enzymes. Instead, the enzymes malate synthase and isocitrate lyase, which are markers of glyoxysomes in higher plants, are constituents of the peroxisomes in the marine as well as in the freshwater alga. Citrate synthase, aconitase, malate dehydrogenase and enzymes of the fatty acid β-oxidation pathway are located exclusively in the mitochondria. Therefore, the peroxisomes from Vaucheria do not belong to either the type of leaf peroxisomes or to the type of glyoxysomes.