Germination and parasitation of the resting sporangia ofSynchytrium endobioticum

Summary The cytoplasmic organization of the long-lived, thick walled resting stage of the sporangium ofSynchytrium endobioticum (Schilb.) Perc. is described. The cytoplasm of the resting sporangium contains a large number of closely packed lipid bodies and irregular electron dense bodies, which are interspaced with fine channels of cytoplasm. These ultrastructural observations are discussed in relation to the hypothesis ofBally (1912) andCurtis (1921) that zoospore primordia are already present during the resting stage. It is shown that the zoospore primordium is actually a lipid body and an osmiophilic body and the strands postulated to connect the individual zoospore primordia are actually the fine channels of cytoplasm.A new inner wall layer is laid down prior to the start of the germination. It is this wall layer which will protrude to form the vesicle in which sporogenesis takes place. The germination process observed, protrusion of a vesicle through a crack in the sporangial wall, the migration of the sporangial content into the vesicle, and the formation of a single, membrane-bound sporangium within this vesicle, is in full agreement with the recent light microscopic studies ofSharma andCammack (1976). These observations support the transfer ofS. endobioticum from the subgenusMesochytrium to the subgenusMicrosynchytrium (bothsensu Karling 1964).A major objective of the study, to obtain ultrastructural evidence for the location of the meiotic divisions in the life cycle, was not fulfilled.Three different fungi were observed to parasitize the resting sporangium ofS. endobioticum. These infections are discussed in relation to other mycoparasites of plant pathogenic fungi. The possibility of using a mycoparasite for the biological control of potato wart disease is considered to be without practical relevance.     

The endobiotic thallus ofPhysoderma maydis,the causal agent ofPhysoderma disease of maize

Summary The endobiotic thallus ofPhysoderma maydis is characterized by the presence of an extremely fine rhizomycelium which passes through the host cell wall, allowing the spread of the disease, and irregularly shaped turbinate cells, which may be septate or nonseptate and which are in close association with developing resting sporangia. The formation of the resting sporangium wall is first seen as localized depositions on the rounded surface of the sporangium and only later on the flattened surface of the sporangium which will form the operculum. The substructure of the resting sporangium wall is typical for members of theBlastocladiales. The resting sporangium is contiguous with the rhizomycelium during development and is finally sealed-off from the rhizomycelium by a further deposition of wall material. After the sealing-off of the resting sporangium from the rhizomycelium the content of the sporangium is compartmentalized and the two inner wall layers are deposited. The centre of the sporangium is filled with an electron dense accretion. At the periphery of the sporangium is a layer of lipid bodies. Between the lipid bodies and the central electron dense accretion is a thin layer of cytoplasm which contains the nuclei. The outer surface of the resting sporangium is smooth.     

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.     

Development of the resting sporangia ofSynchytrium endobioticum,the causal agent of potato wart disease

Summary An ultrastructural study of the development of the resting sporangium ofSynchytrium endobioticum (Schilb.) Perc. infecting potato cells is presented. The resting sporangium is found to have a single large, centrally placed nucleus with a prominent nucleolus through its entirein situ development. The cytoplasmic organization of the resting sporangium is further characterized by numerous membrane-bound lipid bodies and osmiophilic bodies. The latter have a characteristic sieve-like appearance, probably because certain storage components have been extracted during preparation for electron microscopy. Because of the similar location and appearance of these osmiophilic bodies it is suggested that they are identical to what has earlier (based on light microscopy) been described as chromatin granules; and the ultrastructural studies presented here show that nucleolar discharge which was described from light microscopic observations as leading to chromatin granules in the cytoplasm, and finally forming the nuclei of the zoospores (bally 1912,curtis 1921,percival 1910) simply does not occur.The appearance of dense fibrillar-like structures on the sporangial surface at an early stage of resting sporangium development ultrastructurally distinguishes the resting sporangium from the zoosporangium. The development of the layered portion of the thick sporangial wall is shown to be due to the fusion of vacuoles containing pre-made wall fibrils with the cell membrane. It is suggested that the inner compact wall layer which is essentially substructureless is formed by the membrane itself.The characteristic wings of the matureS. endobioticum resting sporangium originate from the potato host cell wall. Remnants of host cell organelles in the outermost layer of the resting sporangium wall show that degradation of the host cell cytoplasm contributes to wall formation of the parasite.     

THE DEVELOPMENT AND CYTOLOGY OF THE EPIBIOTIC PHASE OF PHYSODERMA PULPOSUM

Lingappa , Yamuna . (U. Michigan, Ann Arbor.) The development and cytology of the epibiotic phase of Physoderma pulposum. Amer. Jour. Bot. 46(3) : 145-150. Illus. 1959.—Physoderma pulposum, a chytrid parasite on Chenopodium album L. and Atriplex patula L., has a zoosporangial epibiotic phase. The latter consists of extramatrical sporangia and intramatrical bushy rhizoids, both enclosed in large protruding galls. The sporangia are subspherical, up to 350μ in diameter, and may produce hundreds of planospores. If planospores settle on the host surface, they develop narrow germ tubes which penetrate the epidermal cells and develop into rhizoids. The planospore body, however, remains on the host surface and develops into a mature epibiotic sporangium in about 20-25 days at 16°C., 12-15 days at 20-25°C., or 6-8 days at 30°C. During development, its nucleus and daughter nuclei divide mitotically with intranuclear spindles until the sporangium contains several hundred nuclei. This is followed by progressive cleavage which delimits the planospore rudiments. When mature sporangia are placed in fresh water, the planospores are quickly formed within 1 hr. at 25°C. and begin to swarm within the sporangia. They escape in large numbers through an opening formed by the deliquescence of a papillum in the sporangial wall. The planospores are subspherical or elongate, 3-5 × 4-6 μ, and each has an eccentric orange-yellow refractive globule and a flagellum 18-22 μ in length. The electron micrographs of the flagella indicate that the flagella are absorbed from tip backward during encystment of the planospores. By periodic inoculation of the host plants with planospores from epibiotic sporangia, as well as from germinating resting sporangia, generation after generation of epibiotic sporangia have been obtained for 4 years. This proves the existence of a eucarpic, epibiotic, ephemeral zoosporangial phase in P. pulposum. Field observations on the duration and sequence of development of the fungus indicate that the endobiotic resting sporangial phase always follows the epibiotic phase. The results of infection experiments also indicate that the epi- and endobiotic phases belong to one and the same fungus, P. pulposum.     

Studies on British chytrids XXVIII. Rhizophydium nobile sp. nov., parasitic on the resting spore of Ceratium hirundinella O.F.Müll. from the plankton

The life history of a new species of the Chytridiales Rhizophydium nobile is described. It occurs in the autumn on resting spores of the alga Ceratium hirundinella O.F.M. in Blelham Tarn, Windermere and Esthwaite Water, lakes in the English Lake District. The sporangium develops from the zoospore and possesses a branched rhizoidal system. The zoospores are fully formed in the sporangium. On dehiscence part of the sporangium content flows out surrounded by a vesicle which eventually bursts and liberates the zoospores. Only a few resting spores were seen associated with the sporangial stage. They were small spherical thick-walled bodies containing several globules. Further observations need to be made upon this stage.     

Microtubules,organelle movement,and cross-wall formation at the sporangial-rhizoidal interface in the fungus,Chytridium confervae

Summary Chytridium confervae is a eucarpic, monocentric chytrid. We have used light and electron microscopy to study the relationship between the nutrient absorbing rhizoids and the asexually reproductive sporangium during growth. We have also examined the induction of zoosporogenesis by starvation, and subsequent differentiation until zoospore release. During growth the cytoplasm of the rhizoids and the developing sporangium was continuous and similar. At the start of starvation a bundle of fibers that were visible with light microscopy appeared at the junction between the rhizoids and the sporangium. Two hours after initiation of starvation a wall, that was also visible with light microscopy, formed to separate the rhizoids from the sporangium. Electron microscopy revealed a large, ordered array of microtubules in the thallus at the same time that the fibers appeared, and a sharp difference in the density of ribosomes in the cytoplasm of the sporangium and that of the rhizoids that was apparent immediately after starvation. This cytoplasmic difference was preserved by the formation of a cross-wall that was penetrated by plasmodesmata. After the wall was formed the cytoplasm of the rhizoids senesced. Comparison ofC. confervae with other organisms that use arrays of microtubules to move organelles is made and speculation on the role of the microtubules in organelle movement and wall formation inC. confervae is offered.     

A light and electron microscopic study of sporulation in the myxomyceteStemonitis virginiensis

Summary The conversion of the plasmodium ofS. virginiensis into sporophores has been examined at both the light and electron microscopic levels. Particular attention has been paid to stalk and columella formation, capillitial formation, nuclear behavior during sporulation and spore formation. Both the stalk and columella are formed within the sporangial initial as intraprotoplasmic secretions. A portion of the capillitium arises directly from the columella while the remainder forms within an anastomosing system of tubular vacuoles. As spore cleavage begins the nuclei within the sporangium begin to divide mitotically. The protoplasmic content of the sporangium is first divided into small protospores which typically contain a single dividing nucleus. Following the completion of mitosis each of these segments cleaves into yet smaller segments which develop into spores. Meiosis occurs in the spores some 12–16 hours after cleavage.     

Rhinosporidium seeberi: Light,phase contrast,fluorescent and scanning electron microscopic study

Phase contrast microscopic study indicated the multilayered structure of the sporangial wall of R. seeberi while the scanning electronmicroscopic study revealed a trilaminated wall compared to a thick double walled light microscopic structure. The scanning electronmicroscopy revealed the spores of varying sizes which were found either discretely or in groups interconnected and seen attached to the inner aspect of the sporangial wall. Autofluorescence of sporangia and spores was observed under microscope. Acridine orange staining revealed the presence of DNA materials in the spore and sporangia.     

Development of the zoosporangia ofSynchytrium endobioticum,the causal agent of potato wart disease

Summary An ultrastructural study of zoosporangium development ofSynchytrium, endobioticum (Schilb.) Perc. is presented. Emphasis is placed on the location of the parasitic fungal thallus in the potato host cell, on the specific location of organelles in relation to the developing zoosporangial wall, and on the host cell reaction to the fungal infection. The cytoplasmic organization of the individual sporangia after division of the zoosporangium into a sorus of sporangia is characterized by numerous similarly sized nuclei, well developed dictyosomes, and the presence of many lipid bodies of variable size. Cytoplasmic microtubules are observed to flare out from the functional kinetosome both before and after zoospore cleavage.The ultrastructural details of zoosporangium development are used to revaluate the life cycle ofS. endobioticum as described from light microscopic observations made early in the century (Curtis 1921;Köhler 1923, 1932;Percival 1910).     

Autochory in ferns,not all spores are blown with the wind

Dispersal is a key process in plant population dynamics. In ferns, two successive vectors are needed: the sporangium catapulting mechanism, and wind or gravity. However, some rock ferns have a growth habit that suggests a kind of autochory by placing spores on the rock surface. Moreover, some ferns show modifications of the sporangial dehiscence. To determine the role of growth habit in spore dispersal, we checked the sporangial opening mechanism and explored the spatial distribution of plants on the walls. The presence of spores of Asplenium celtibericum, a rupicolous fern, in the rock surface was checked. In addition, its sporangial dehiscence, plant size and position in the wall were analysed. Spores and indehiscent sporangia were present on walls at each sampling moment. Their highest number was found close to the plants. There was a positive correlation between crack width and plant size. However, most plants occupy the upper half of the cliffs. The growth habit of A. celtibericum is instrumental to deposit the spores over the neighbouring rock surface, thus enhancing the probability of spores to find suitable crevices for germination. Furthermore, dispersal of indehiscent sporangia might promote intergametophytic mating, and the modified sporangial opening mechanism extends the dispersive period.     

Synaptonemal complex formation and meiosis in the resting sporangium ofBlastocladiella emersonii

Summary Blastocladiella emersonii Cantino etHyatt (Phycomycetes, Blastocladiales) has aBrachyallomyces type of life cycle (sensu Emerson 1941) or aBlastocladiella type of life cycle (sensu Karling 1973), with a regular formation of zoosporangia and resting sporangia and no sexual stages.Synaptonemal complex formation (a characteristic stage in meiotic prophase—pachytene) occurs during development of the resting sporangium inB. emersonii.During resting sporangium germination, two meiotic nuclear divisions give rise to nuclei which have approximately one-fourth of the nuclear volume of the diplotene nucleus. The life cycle ofBlastocladiella emersonii resembles that ofCatenaria anguillulae. The time of diploidization (n2 n) has not been determined.     

Allomyces neo-moniliformis gametogenesis

Summary InAllomyces neo-moniliformis meiosis takes place during resting sporangium germination. The meiospores are characteristically binucleate and biflagellate as described byEmerson (1938) andTeter (1944). A variation in the number of nuclei and flagella per meiospore from two is correlated with germination of the resting sporangia under reduced oxygen tension. The meiospores are extremely poor swimmers and are typically amoeboid. At encystment the gamma bodies of the cell are mobilized and appear involved in cyst wall synthesis. A single mitotic division of each nucleus gives rise to four nuclei. Gamete cleavage is as described for spore cleavage inBlastocladiella (Lessie andLovett 1968). The assembly of the nuclear cap and side body complex of the spore are extremely late processes in gametogenesis. The gametes are released when the single papilla dissolves. The gametes fuse in pairs and after zygote formation the cell is uninucleate with two flagella. The biflagellate zygote is an active swimming cell. The presence of homothallism or hetero-thallism inA. neo-moniliformis is discussed.     

Coelomomyces psorophorae vartasmaniensis Couch+Laird (1988) (Coelomomycetaeceae: Blastocladiales), a fungal pathogen of the mosquitoAedes australis

The germination of sporangia inCoelomomyces psorophorae vartasmaniensis (C. p. tas.) is uncoordinated and thus there is a mixture of developmental stages in any given population. Continuous urografin gradients separated out the critical stages of germinating sporangia giving four bands, each band representing a consecutive stage of germination. These stages were investigated for changes in the sporangial wall using Transmission Electron Microscopy (TEM). The sporangia have a typical two-layered wall, an electron dense outer layer which can be divided into three distinct sub-layers D1, D2, and D3 and an inner electron transparent secondary wall. Stage 3 sporangia have an intact D1 layer on their outer wall. In the subsequent stages (4 & 4b) there is a progressive breakdown of this layer.     

SPORANGIAL STRUCTURE AND ZOOSPOROGENESIS IN CHORDA TOMENTOSA (LAMINARIALES)1,2,3

Members of the genus Chorda represent the simplest form of sporophyte in the order Laminariales. The present study deals with reproduction in Chorda tomentosa, involving the initiation, growth, and structure of the sporangium and the process of zoosporogenesis. The simple tube-like sporophyte of Chorda tomentosa grows in diameter by means of repeated anticlinal divisions in a superficial meristematic layer known as the meristoderm. The onset of reproduction is marked by the conversion of the meristoderm from contributing cells to the vegetative plant body to producing 2 new cell types: paraphyses and sporangial mother cells. At the time of initiation, sporangial mother cells are crescent shaped and possess a densely staining cytoplasm. Sporangial mother cells increase in size, become ellipsoid, decrease in staining density, and undergo meiosis. After meiosis, sporangia increase in size while their nuclei undergo successive cycles of synchronous mitotic divisions. Sporangia increase to a maximum length of 120 μ;m at which time they possess the characteristic “cap” found in all members of the order studied thus far. At this stage the protoplast of the sporangium is organized into a peripheral layer of nucleus-chloroplast pairs and a central region of vacuoles. Cleavage furrows begin to form at the cell membrane and are met by furrows developing in the interior of the cytoplasm resulting in the division of the entire protoplast into separate units. Each unit is an individual zoospore. The biflagellate zoospores contain a nucleus, one chloroplast with eyespot, perinuclear Golgi, and several bodies of presumed storage carbohydrate. The occurrence of a small population of early developing sporangia is described. In essential details, the origin, development, and structure of sporangia in Chorda tomentosa are identical to all earlier observations in the Laminariales.     

Effect of seed exudates ofPinus resinosa on the germination of sporangia and on the population ofPythium irregulare in the soil

Summary Exudates from germinating seed ofP. resinosa stimulated the germination of sporangia and increased thePythium populations in soil. Sporangia ofP. irregulare did not germinate in natural soil and needed exogenous nutrition for their germination. Different components of the exudate, particularly glucose and asparagine, effectively stimulated sporangial germination. This is in agreement with an earlier finding withPythium ultimum ³.     

Synchytrium solstitiale: reclassification based on the function and role of resting spores

Studies were made about resting spores of Synchytrium solstitiale, a chytrid that causes false rust disease of yellow starthistle (YST). During evaluation of this fungus for biological control of YST, a protocol for resting spore germination was developed. Details of resting spore germination and study of long-term survival of the fungus were documented. Resting spores from dried leaves germinated after incubating them on water agar at least 7 d at 10-15 C. Resting spores were viable after storage in air-dried leaves more than 2 y at room temperature, suggesting they have a role in off-season and long-term survival of the fungus. Each resting spore produced a single sorus that contained a single sporangium, which on germination released zoospores through a pore. YST inoculated with germinated resting spores developed symptoms typical of false rust disease. All spore forms of S. solstitiale have been found to be functional, and the life cycle of S. solstitiale has been completed under controlled laboratory and greenhouse conditions. Resting spore galls differ from sporangial galls both morphologically and biologically, and in comparison, each sporangial gall cleaves into several sori and each sorus produces 5-25 sporangia that rupture during release of zoospores. For this reason S. solstitiale should be reclassified as diheterogallic sensu Karling (Am J Bot 42:540-545). Because resting spores function as prosori and produce an external sorus, S. solstitiale is best placed in into the subgenus Exosynchytrium.     

In vitro studies on the mechanisms of endospore release by Rhinosporidium seeberi

Studies of Rhinosporidium seeberi have demonstrated that this organism has a complex life cycle in infected tissues. Its in vivo life cycle is initiated with the release of endospores into a host's tissues from its spherical sporangia. However, little is known about the mechanisms of sporangium formation and endospore release since this pathogen is intractable to culture. We have studied the in vitro mechanisms of endospore release from viable R. seeberi's sporangia. It was found that watery substances visibly stimulates the mature sporangia of R. seeberi to the point of endospore discharge. The internal rearrangement of the endospores within the mature sporangia, the opening of an apical pore in R. seeberi's cell wall, and the active release of the endospores were the main features of this process. Only one pore per sporangium was observed. The finding of early stages of pore development in juvenile and intermediate sporangia suggested that its formation is genetically programed and that it is not a random process. The stimulation of R. seeberi's sporangia by water supports the epidemiological studies that had linked this pathogen with wet environments. It also explains, in part, its affinities for mucous membranes in infected hosts. The microscopic features of endospore discharge suggest a connection with organisms classified in the Kingdom Protoctista. This study strongly supports a recent finding that placed R. seeberi with organisms in the protoctistan Mesomycetozoa clade. This revised version was published online in June 2006 with corrections to the Cover Date.     

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.