The primary and secondary spore cyst of Aphanomyces (Oomycetes, Saprolegniales)

The ultrastructural organization of the primary (1°) and secondary (2°) cysts of Aphanomyces astaci and A. laevis is extremely similar, and similar to that of the 1° and 2° cysts of A. eutekhes as presented earlier by Hoch and Mitchell. Synchronous populations of 2° cysts can be induced by mechanical shock and encystment appears to be essentially instantaneous. The cyst coat–wall appears to be formed extremely rapidly from material from the peripheral vesicles with flocculent content. After encystment the microtubule cytoskeleton found in the zoospore is maintained in the 1° and 2° cyst (i.e. the single microtubules which extend along the pyriform nucleus from the ki–netosomes–centrioles and the bundles of closely appressed microtubules are retained). The peripheral vesicles with granular content found in the zoospore are not seen in the 1° or 2° cyst. Multivesicular bodies and lomasomes are observed in the 1° and 2° cyst which are not found in the zoospore. The peripheral cisternae of the zoospore are lost upon encystment and may be formed from dictyosome–derived vesicles during excystment of the 1° and 2° cyst. The U–body of A. astaci has a paracrystalline content while the U–body of A laevis and A eutekhes has a tubular content. A microbody–lipid body complex (sensu Powell) is found in the 1° and 2° cysts of A laevis but not in A astaci or A eutekhes. The significance of the presence of a microbody–lipid body complex in a biflagellate zoospore is discussed.     

Ultrastructural observations of mature and encysting zoospores ofPythium proliferum de Bary

Summary The process of zoospore maturation and encystment inP. proliferum was studied by electron microscopy. General ultrastructural features of the mature, swimming zoospore were found to be similar to those previously described for other oomycetes in both the attachment and ultrastructure of the flagella as well as the type and distribution of cellular organelles. Associated with extensive areas of RER in the mature zoospores were unusual, electrondense, bar-like structures. These structures were found in the groove region of young zoospores and at the periphery of encysting zoospores. Their possible function is discussed. The five main types of vesicles observed during encystment, as seen grouped in this study, along with the vesicles described in previous studies of oomycete encystment, were in table form and individually discussed. Interesting correlations appear to exist in the types of vesicles that are present within the oomycetes studied thusfar.     

ZOOSPORE STRUCTURE OF THE MYCOPARASITIC CHYTRID CAULOCHYTRIUM PROTOSTELIOIDES OLIVE

The subcellular organization of zoospores released from sessile, parasitic sporangia of Caulochytrium protostelioides was studied with light and electron microscopy. A single flagellum is posteriorly directed but laterally inserted into the cylindrical motile zoospore. A striated rhizoplast attaches the proximal end of the kinetosome to a specialized region of the nuclear envelope. A system of rough endoplasmic reticulum, smooth endoplasmic reticulum, dictyosomes and bristle-coated vesicles are associated with the one to several pulsating vacuoles typically located near the flagellar apparatus. The microbody-lipid globule complex (MLC) comprises one to many lipid globules. An extensive microbody branches around each lipid globule and encloses a portion of the rhizoplast. A reticulum of smooth surfaced cisternae interdigitates among the branches of the complex microbody, and cisternae are opposed to the surface of lipid globules opposite the microbodies. Mitochondria with predominantly circular profiles are scattered throughout the zoospore body, but several are always adjacent to the microbody, and hence, are also part of the MLC. Ribosomes are uniformly distributed throughout the zoospore, and one to several cisternae of rough endoplasmic reticulum are adjacent to the nuclear envelope. Zoospores of C. protostelioides are similar to several other chytrid zoospores, which also have the same type of microbody-lipid globule complex, but yet are structurally distinct from any other chytrid zoospore.     

Electron microscopy of primary zoosporogenesis inPlasmodiophora brassicae

Primary zoosporogenesis in resting sporangia ofPlasmodiophora brassicae that had been incubated for 14 d in culture solution containing turnip seedlings was examined by transmission electron microscopy. A single zoospore differentiated within each sporangium, the differentiation being initiated by the emergence, of two flagella in the tight space formed by invagination of the plasma membrane within the sporangium. The differentiazing zoospore was similar in intracellular aspects to sporangia within clubroot galls. Then a deep groove formed on the zoospore cell body by further invagination of the plasma membrane. Two flagella appeared to coil around the zoospore cell body in parallel along this groove. Thereafter, the cell body lost the groove and became rounded following the protoplasmic condensation (contraction of cell body) during late development, and assumed an irregular shape at the stage of maturation. Intracellular features in, developing and mature zoospores were complicated, being characterized by electron-dense nuclei and mitochondria, microbodies, cored vesicles and various unidentified cytoplasmic vesicles and granules. A nucleolus-like region was observed only in the nucleus of the mature zoospore. A partially opened germ, pore was also seem in the sporangium containing the mature zoospore.     

A putative DEAD-box RNA-helicase is required for normal zoospore development in the late blight pathogen Phytophthora infestans

The asexual multinucleated sporangia of Phytophthora infestans can germinate directly through a germ tube or indirectly by releasing zoospores. The molecular mechanisms controlling sporangial cytokinesis or sporangial cleavage, and zoospore release are largely unknown. Sporangial cleavage is initiated by a cold shock that eventually compartmentalizes single nuclei within each zoospore. Comparison of EST representation in different cDNA libraries revealed a putative ATP-dependent DEAD-box RNA-helicase gene in P. infestans, Pi-RNH1, which has a 140-fold increased expression level in young zoospores compared to uncleaved sporangia. RNA interference was employed to determine the role of Pi-RNH1 in zoospore development. Silencing efficiencies of up to 99% were achieved in some transiently-silenced lines. These Pi-RNH1-silenced lines produced large aberrant zoospores that had undergone partial cleavage and often had multiple flagella on their surface. Transmission electron microscopy revealed that cytoplasmic vesicles fused in the silenced lines, resulting in the formation of large vesicles. The Pi-RNH1-silenced zoospores were also sensitive to osmotic pressure and often ruptured upon release from the sporangia. These findings indicate that Pi-RNH1 has a major function in zoospore development and its potential role in cytokinesis is discussed.     

Production and modifications of extracellular structures during development of chytridiomycetes

Summary In development of the primitive fungi, chytridiomycetes, unwalled zoospores bearing single, posterior flagella are transformed into walled, round-cells which elaborate the thallus. Production, structural modification, or release of extracellular material are involved with each transition of developmental stage. This article reviews the variety and developmental changes of extracellular materials found at the cell surface of chytridiomycetes. A cell coat, produced from Golgi-derived vesicles during zoosporogenesis, is visible around free swimming zoospores of some chytridiomycetes. How the zoospore surface receives and transduces signals is not widely explored, but it is known that fenestrated cisternae and simple cisternae, which are integrated into the microbody-lipid globule complex, are spatially and structurally associated with the plasma membrane and flagellar apparatus. This spatial association, as well as the cytochemical localization of calcium in fenestrated cisternae, suggest a mechanism for signal transduction and for regulation of zoospore motility. Zoospores become encased in a new layer of extracellular material as the zoospore encysts. Among some chytrids the source of this material is preexisting vesicles which fuse with the plasma membrane. Among other zoospores, a readily identifiable population of encystment vesicles is not apparent, demonstrating that there is no single pattern or mechanism for zoospore encystment in chytridiomycetes. Encysted zoospores developing into thalli, typically produce cell walls with a microfibrillar substructure. Ultrastructural analysis of walls reveals distinctive architecture and remarkable sculpturing which have been used in systematics of some members of chytridiomycetes. Nothing is known as to underlying controls of cytoskeletal elements and plasma membrane enzyme complexes in wall biogenesis. Many changes in cell surface structures accompany thallus maturation. Septa, many traversed with plasmodesmata, are produced in most chytrid thallus types. As sporangia and resting spores prepare for the production and release of zoospores, additional extracellular layers of material are frequently produced. Polarized deposits of extracellular material become discharge plugs, discharge vesicles, or endoopercula. Interstitial material is also released into cleavage furrows. Circumscissile or localized digestion of walls produce operculate or inoperculate exit ports for zoospore release. Cryofixation preserves more extensive extracellular material than does conventional chemical fixation, and broader application of cryofixation may radically alter our current view of cell surface structure. Thus chytridiomycetes exhibit a range in patterns for the occurrence and subsequent modifications of extracellular materials, even for members within the same order. The most universally recognized role for these extracellular materials is protection. Although there is a reasonable view of the types of extracellular material involved in chytridiomycete development, we have only limited understandings of their biogenesis or roles in regulation and communication, areas awaiting more investigations.Abbreviations DIC Nomarski-differential contrast optics - TEM transmission electron microscopy     

Endocytosis of cationized ferritin by zoospores of the fungusAphanomyces euteiches

Summary Cationized ferritin, a marker for adsorptive endocytosis, was taken up by zoospores of the fungusAphanomyces euteiches. The probe was endocytosed into the numerous, often coated, vesicles surrounding the contractile vacuole. The vacuole itself contained very little ferritin. It is suggested that the contractile vacuole complex is the main area of membrane recycling in the zoospore. After zoospore encystment some of the ferritin was found in multivesicular bodies and the remnants of the contractile vacuole.     

Lipid turnover during morphogenesis in the water mold Blastocladiella emersonii

The lipid content of $\text{Blastocladiella emersonii}$ zoospores is 5 pg/cell or about 13% of dry weight. Within the first few minutes of germination 60–70% of total zoospore lipid is lost, with neutral lipid, glycolipid and phospholipid fractions decreasing to about the same extent. These changes in lipid content precede the breakdown during germination of the complex and extensive membrane system of zoospores. During growth, which immediately follows germination, net phospholipid synthesis resumes so that total lipid is maintained at 6% of dry weight, but net synthesis of neutral and glycolipid does not begin until induction of sporulation. During sporulation the phospholipid level decreases so that the distribution of lipid among the three fractions approaches that found in zoospores. These changes in lipid content suggest that zoospore membranes containing neutral and glycolipids are synthesized $\text{de novo}$ during spore formation.     

Flow cytometric determination of zoospore DNA content and population DNA distribution in cultured Pfiesteria spp. (Pyrrhophyta)

The relative cellular DNA content from 23 different clonal cultures of Pfiesteria spp. zoospores was determined using a DNA fluorochrome and flow cytometry. Significant differences between Pfiesteria piscicida and P. shumwayae were detected, both in mean zoospore DNA content and population cell cycle DNA distribution. Intraspecific differences in DNA content were found between clonal zoospore cultures established from different geographical regions. Long-term cultures (years) of P. piscicida were available for testing, and a negative correlation was observed between zoospore DNA content and time in culture. Zoospore cell cycle-related DNA distributions were also markedly different between the two species in these clonal cultures. In most cultures tested, P. piscicida zoospores exhibited bimodal DNA flow histograms with G1-S-G2+M distributions, typical of eukaryotic asynchronously cycling cells. In contrast, cultures of P. shumwayae zoospores exhibited one DNA peak distribution, indicative of synchronized cells. The data are consistent with the hypothesis that P. shumwayae zoospores are interphasic cells, and mitosis in zoospore cultures of this species predominantly occurs as benthic or adherent non-motile division cysts. Light microscopy observations of the nuclear condition of electrostatically sorted zoospores of each Pfiesteria species also support this hypothesis. If highly conserved, this disparity in modes of vegetative reproduction would ramify the population dynamics of the two Pfiesteria species.     

Production of monoclonal antibodies against peripheral-vesicle proteins in zoospores of Phytophthora nicotianae

Summary. A coimmunisation protocol using microsomal fractions from Phytophthora nicotianae cells has enhanced the production of monoclonal antibodies directed towards proteins produced during asexual sporulation. Over 40% of the antibodies targeted three categories of zoospore peripheral vesicles. Five antibodies label the contents of dorsal vesicles, with three of these reacting with two P. nicotianae polypeptides with a relative molecular mass of approximately 100 kDa. Two antibodies label the contents of large peripheral vesicles and react with two very high-molecular-weight polypeptides in extracts of P. nicotianae cells. These antibodies cross-react with the contents of large peripheral vesicles in P. cinnamomi zoospores. Ten antibodies label the contents of P. nicotianae zoospore ventral vesicles and react with a single polypeptide with a relative molecular mass of 230 kDa. A number of these antibodies against the contents of ventral vesicles in P. nicotianae zoospores cross-react with ventral-vesicle proteins in P. cinnamomi cells in immunofluorescence and immunoblot assays. The study illustrates the value of the coimmunisation protocol and has produced antibodies that could be instrumental in the cloning of genes encoding peripheral-vesicle proteins.Correspondence and reprints: Plant Cell Biology Group, Research School of Biological Sciences, Australian National University, GPO Box 475, Canberra, ACT 2601, Australia.     

THE SECRET LIFE OF KELPS: PLANKTONIC PROCESSES AND POPULATION DYNAMICS

Understanding spatio‐temporal variability in recruitment is vital to studies of kelp population dynamics. Research on settlement and post‐settlement processes has suggested that arrival of kelp zoospores to suitable substrate is important in limiting kelp recruitment, yet the role of planktonic processes in kelp population dynamics has not been studied due to difficulties in sampling and identifying zoospores. I developed a method to estimate kelp zoospore abundance from in situ plankton samples and used it to study various processes regulating the availability of giant kelp (Macrocystis pyrifera) zoospores for settlement. My studies focused on (1) identifying temporal scales over which zoospore abundance is most variable, (2) describing physical and biological processes that regulate this variability, and (3) determining the relationship between zoospore abundance and settlement. I found that short‐term variability in zoospore abundance (<24 hrs) was not due to changes in supply but rather dispersion, caused by oscillating hydrodynamic forces (e.g. waves). Long‐term variability in zoospore abundance, however, was best explained by the size and density of reproductive adult plants, with zoospore abundance being most variable at the scale of days to months. Changes in adult reproductive condition caused rapid changes in zoospore abundance suggesting that the supply of kelp zoospores is sensitive to environmental regulation of adult physiology. Thus, unlike with marine animals, these results indicate that variability in kelp propagule supply, over scales most likely to affect subsequent settlement and recruitment, is more tightly coupled to demographic and reproductive mechanisms than to physical transport processes.     

Ultrastructural changes during sporangium formation and zoospore differentiation in Blastocladiella Emersonii

Samples from synchronized cultures of Blastocladiella emersonii were examined by electron microscopy from the late log phase to the completion of zoospore differentiation. Log-phase plants contain the usual cytoplasmic organelles but also have an unusual system of large tubules ca. 45 mμ diam that ramify in organized bundles throughout the protoplast. After induction, zoosporangium differentiation requires a 2-hr period in which the nuclei divide, a cross wall forms to separate the basal rhizoid region, and an apical papilla is produced. Nuclear division in B. emersonii is intranuclear with a typical microtubular spindle apparatus and paired, unequal, extranuclear centrioles at each pole. The papilla is formed by a process of localized cell wall breakdown and deposition of the papilla material by secretory granules. Differentiation of zoospores begins when one of the two centrioles associated with each nucleus elongates to form a basal body. The flagella fibers arise from the basal body and elongate into an expanding vesicle formed by the fusion of small secondary vesicles. The cleavage planes are formed by fusion of vesicles similar to those associated with flagellum initiation. When cleavage is complete, each sporangium contains ca. 250–260 uninucleate spore units with their flagella lying in the cleavage planes. Probable fusion of mitochondria to produce the single mitochondrion of the zoospore occurs after cleavage; the mitochondrion does not take its position around the basal body and rootlets until just before zoospore release. The ribosomal nuclear cap is organized and enclosed by a membrane formed through fusion of many small vesicles during a short period near the end of differentiation.     

LET THERE BE LIGHT (BUT NOT TOO MUCH): MOLECULAR EVOLUTION OF LIGHT-HARVESTING COMPLEXES

Understanding spatio-temporal variability in recruitment is vital to studies of kelp population dynamics. Research on settlement and post-settlement processes has suggested that arrival of kelp zoospores to suitable substrate is important in limiting kelp recruitment, yet the role of planktonic processes in kelp population dynamics has not been studied due to difficulties in sampling and identifying zoospores. I developed a method to estimate kelp zoospore abundance from in situ plankton samples and used it to study various processes regulating the availability of giant kelp ( Macrocystis pyrifera ) zoospores for settlement. My studies focused on (1) identifying temporal scales over which zoospore abundance is most variable, (2) describing physical and biological processes that regulate this variability, and (3) determining the relationship between zoospore abundance and settlement. I found that short-term variability in zoospore abundance (<24 hrs) was not due to changes in supply but rather dispersion, caused by oscillating hydrodynamic forces (e.g. waves). Long-term variability in zoospore abundance, however, was best explained by the size and density of reproductive adult plants, with zoospore abundance being most variable at the scale of days to months. Changes in adult reproductive condition caused rapid changes in zoospore abundance suggesting that the supply of kelp zoospores is sensitive to environmental regulation of adult physiology. Thus, unlike with marine animals, these results indicate that variability in kelp propagule supply, over scales most likely to affect subsequent settlement and recruitment, is more tightly coupled to demographic and reproductive mechanisms than to physical transport processes.     

The flagellar apparatus and striated rhizoplast of the zoospore ofOlpidium brassicae

Summary The flagellar apparatus and its associated structures of the zoospore ofOlpidium brassicae are described and compared with observations of other zoospores of the uniflagellatePhycomycetes. The zoospore ofO. brassicae is shown to have an extensive cone-shaped rhizoplast fused to both the functional and the vestigial kinetosomes. Three-dimensional reconstructions were made of the kinetosomal region. The vestigial kinetosome differs from the functional, as it only has triplet bundles of microtubules and it lacks a system of props. The proximal termination of the central pair of flagellar microtubules occurs within the axoneme. No terminal plate is observed. The occurrence of dictyosomes in theChytridiales, Monoblepharidales, andHyphochytriales is discussed and it is concluded that a dictyosome may be present in the encysting zoospore and the maturing zoosporangium ofO. brassicae but only vestiges of a dictyosome are to be found in the free-swimming zoospore.     

Characterization of zoospore and cyst surface structure in saprophytic and fish pathogenicSaprolegnia species (oomycete fungal protists)

Summary The importance of the surface structure and chemistry in zoospores and cysts of oomycetes is briefly reviewed and the organelle systems associated with encystment described. The surface structure and chemistry of primary and secondary zoospores and cysts ofSaprolegnia diclina (a representative saprophytic species) andS. parasitica (a representative salmonid fish pathogen) were explored using the lectins concanavilin A (Con A) and wheat germ agglutinin (WGA) and monoclonal antibodies (MAbs) raised against a mixed zoospore and cyst suspension ofS. parasitica. The binding of lectins and antibodies to spores was determined using immunofluorescence microscopy with fluorescein isothiocyanate-labelled probes and with electron microscopy with gold-conjugated probes applied to spore suspensions post-fixation. In both species Con A, which is specific for glucose and mannose sugars, bound to both the surface of primary and secondary zoospores (the surface glycocalyx) and their cyst coats and readily induced zoospore encystment. The binding to the cysts appeared to be mainly associated with the matrix material released from the primary and secondary encystment vesicles and which appeared to diminish with time. No binding to germ tube walls was observed with this lectin. The MAb labelling showed a generally similar binding pattern to the primary and secondary cysts to that observed with Con A, although the binding to zoospores was more variable. Primary zoospores bound the antibodies but secondary zoospores appeared less reactive. It is suggested that the MAbs share a common epitope with one or more of the Con A-binding components. In both species WGA, which is specific for amongst other things the sugar N-acetyl glucosamine, bound to localised apical patches on the primary zoospores. This lectin also binds to the ventral groove region of secondary zoospores ofS. diclina, which were induced to encyst by this lectin. In contrast secondary zoospores ofS. parasitica were not induced to encyst by the addition of WGA and showed a patchy dorsal binding with this lectin. WGA also binds to both the inner wall of discharged primary cysts and the young germ tube walls of both species. These observations are discussed both in relation to other oomycete spores and to their possible functional and ecological significance.Abbreviations BSA bovine serum albumin - Con A Concanavalin A - DBA Dolichos biflorus agglutinin - ELISA enzyme-linked immunosorbent assay - EM electron microscope - EV encystment vesicles - FCS foetal calf serum - FITC Fluorescein isothiocyanate - FV peripheral fibrillar vesicles - G+F 0.2% glutaraldehyde and 2.0% formaldehyde primary fixative solution - 2G 2% glutaraldehyde primary fixative - LM light microscopy - MAbs monoclonal antibodies - LPV large peripheral vesicles - PBS phosphate buffered saline - PCV flattened peripheral cisternae - PEV primary encystment vesicle - PIPES piperazine-N,N1-bis(2-ethane sulfonic acid) - PNA Ricinus communis agglutinin - RAM-FITC/Au_10–20 Fluorescein isothiocyanate/gold (10 or 20 nm) labelled rabbit anti-mouse immunoglobulin - RCA Ricinus communis agglutinin - SEM scanning electron micrograph - SBA soybean agglutinin - SEV secondary encystment vesicles - TEM transmission electron micrograph - UEA I Ulex europaeus agglutinin - WGA wheat germ agglutinin     

The meiospore ofAllomyces

Summary The arrangement of cellular organelles within the meiospore ofAllomyces macrogynus was found to be similar to the zoospore of this species, with the exception that the meiospore contains membrane enclosed electron dense reserve material which has the appearance of the gamma bodies observed in the zoospores ofBlastocladiella. The three dimensional structure of the side body complex is analyzed with serial sections and compared to homologous organelles in other members of theChytridiomycetes.     

The ultrastructure of zoospores ofAphanomyces euteiches and of their encystment and subsequent germination

Summary The ultrastructure ofAphanomyces euteiches during the periods of zoospore motility, encystment, and germination has been studied. The motile spore has two heterokont flagella inserted laterally into the groove of the zoospore body where each is attached to a kinetosome. The kinetosomes and flagella are anchored into the zoospore body by rootlets comprised of two rows of microtubules with up to 12 microtubules in the outer row and are attached by fine threads to a striate fiber bundle. Secondary microtubules are attached at right angles at regular intervals along the rootlets. An unidentified body, 1.25m in diameter, containing helical fibers 16 nm in diameter is present in each zoospore. This body is situated near the two kinetosomes on the side of the pyriform nucleus opposite the contractile vacuole. The Golgi complex is between the nucleus and the contractile vacuole. The latter is surrounded by a 0.5–1.0m wide zone of Golgi proliferated vesicles. Ribosomes are generally absent from this region. Endoplasmic reticulum containing tubules within the expanded cisternae are also present. Vesicles with striated electron opaque inclusions and vesicles containing a granular cortex and center that developed in previous stages of zoosporogenesis were also present. During encystment of the zoospore the latter vesicles disappear. The two flagella are shed at this time leaving a membrane-bounded granular knob protruding from each of the kinetosome terminal plates. The contractile vacuole becomes disorganized and the zoospore assumes a spherical shape. Cyst wall deposition begins immediately and is completed in 30 minutes. The spore begins to germinate 1 hour following initiation of encystment with the appearance of a bulge in the cyst wall which elongates into a germ tube. Mitotic nuclear division follows.Research supported by the College of Agricultural and Life Sciences Station Project No. 1281.Research assistant and Professor. The advice and assistance of G. A. deZoeten, G. R.Gaard, and S.Vicen are most gratefully acknowledged.     

The zoospore of Pseudoperonospora cubensis, the causal agent of cucurbit downy mildew

The zoospore of Pseudosporonospora cubensis is typical of the secondary zoospore of the Peronosporales. The reniform zoospore contains a central nucleus with a prominent beak-like extension to the kinetosomes on the lateral side of the spore in the groove region. "Fuzzy" vesicles derived from dictyosomes surround and fuse with the contractile vacuole. Mitochondria and microbodies are located in the peripheral cytoplasm of the zoospore but the latter are confined to the groove region of the spore. The microbodies usually contain a laminate inclusion and the microbodies are not in a fixed position in relation to the peripheral cisternae. Neither a microbody-lipid body complex nor a "U-body" were observed.
The kinetosomes of the spore are almost perpendicular to each other at the distal end of the beak-like extension of the nucleus. A complex system of cytoplasmic microtu-bules flare out from the kinetosomes to surround the nucleus and bundles of cytoplasmic microtubules extend under the plasmalemma of the spore. The zoospore contain numerous vesicles with osmiophilic inclusions which are finely striated; these are the so-called finger-print vesicles.     

Ultrastructure and isolation of glyoxysomes (microbodies) in zoospores of the fungusentophlyctis sp.

Summary A correlative approach, involving light and electron microscopic, cytochemical, and biochemical techniques, was used to study the structure and function of microbodies in zoospores ofEntophlyctis sp. The same population of microbodies already existing in the zoosporangium appeared to be segregated into zoospore initials during cytoplasmic cleavage. Microbodies laid at the anterior end of zoospores and were part of an organized assemblage of organelles, the microbody-lipid globule complex. In the microbody-lipid globule complex, endoplasmic reticulum occurred on the surface of the lipid globules toward the zoospore's exterior, and the microbody, subtended by mitochondria, was appressed to the opposite surface of the lipid globule. The organization of the microbody-lipid globule complex changed as the zoospore swam and encysted. As lipid globules coalesced, the microbody-lipid globule complex became disorganized. After lipid globule coalescence was completed, the microbody-lipid globule complex regained its order, and several microbodies were clustered adjacent to a single lipid globule. The microbodies persisted even in the encysted zoospore, but they were found on all sides of the lipid globule.Microbodies isolated from zoospores contained catalase as well as malate synthase and isocitrate lyase, two enzymes of the glyoxylate cycle. When zoospores encysted greater activities of these glyoxylate cycle enzymes could be detected. The presence of glyoxylate cycle enzymes and the close association between the microbody and lipid globule suggest that microbodies function as glyoxysomes in zoospores and encysted zoospores. The functional significance of the morphological organization of the microbody-lipid complex is discussed in terms of energy production and the conversion of storage lipid into structural components of the cell.