OBSERVATIONS ON CHYTRIDIACEOUS PARASITES OF PHANEROGAMS. XIV. PHYSODERMA CALAMI

Physoderma calami, a chytrid (Phycomycetes), has not been studied or apparently even collected in Europe since 1895 and has never been recorded in this hemisphere. Material widely distributed in herbaria indicated it was a Physoderma but no details save color, shape, and size of resting spores were known. A study of living material from Vermont indicates resting spore germination occurs by dehiscence of a lid and production of a sporangium with zoospores. The latter may form either an epibiotic or “ephemeral” sporangial stage and zoospores, or an endobiotic one, with extensive polycentric thallus bearing turbinate cells along the rhizoids, and, as outgrowths of these turbinate cells, straw-colored, thick-walled resting spores. The latter stage produces dark-brown spots on infected parts of the host.     

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.     

Zoosporic fungi of Oceania. VI. Species with biflagellate zoospores

Summary Several species of the Plasmodiophoraceae, Olpidiopsidaceae and Lagenidiaceae were isolated on various substrata from the soils of Oceania. Among these were two parasites of rotifer eggs,Lagenidium septatum andMyzocytium fijiensis. The former species is characterized primarily by septation of the thallus into segments which develop into resting spores without sexual fusions.Mycozytium fijiensis resembles somewhatM. zophthorium but differs from it by smaller zoospores which are delimited outside of the sporangium.     

Observations on chytridiaceous parasites of Phanerogams

Summary A reexamination of Physoderma maculare Wallroth the type species of the genus, on Alisma, confirms Clinton's (1902) account of the production of an epibiotic stage from resting spore zoospores. The latter on mature host tissue may also give rise to the endobiotic stage which bears resting spores. On seedlings, however, resting spore zoospores produce only epibiotic sporangia. The fungus could not successfully infect Sagittaria, a closely related host.Contribution No. 1152     

MORPHOLOGY AND THERMAL DEATH POINT OF OLPIDIUM BRASSICAE

The morphology of single-sporangial isolates of lettuce, tomato, mustard, and oat Olpidium brassicae (Wor.) Dang. growing in their respective hosts as well as in cowpea were compared in situ and after extraction from the roots. The sporangia, zoospores, and resting spores of all isolates were within the established limits of the species. Single exit tubes or pores predominated which means that these isolates should not be transferred to the genus Pleotrachelus. A satisfactory assay for the presence of resting spores was developed by air-drying of the roots for a week or longer. This treatment killed zoospores and vegetative sporangia, but not resting spores. Factors affecting resting spore formation were investigated unsuccessfully. The thermal death point of zoospores of mustard isolates that did not form resting spores was between 40 and 45 C for 10 min.     

The development, ultrastructural cytology, and molecular phylogeny of the basal oomycete Eurychasma dicksonii, infecting the filamentous phaeophyte algae Ectocarpus siliculosus and Pylaiella littoralis

The morphological development, ultrastructural cytology, and molecular phylogeny of Eurychasma dicksonii, a holocarpic oomycete endoparasite of phaeophyte algae, were investigated in laboratory cultures. Infection of the host algae by E. dicksonii is initiated by an adhesorium-like infection apparatus. First non-walled, the parasite cell developed a cell wall and numerous large vacuoles once it had almost completely filled the infected host cell (foamy stage). Large-scale cytoplasmic changes led to the differentiation of a sporangium with peripheral primary cysts. Secondary zoospores appeared to be liberated from the primary cysts in the internal space left after the peripheral spores differentiated. These zoospores contained two phases of peripheral vesicles, most likely homologous to the dorsal encystment vesicles and K-bodies observed in other oomycetes. Following zoospore liberation the walls of the empty cyst were left behind, forming the so-called net sporangium, a distinctive morphological feature of this genus. The morphological and ultrastructural features of Eurychasma were discussed in relation to similarities with other oomycetes. Both SSU rRNA and COII trees pointed to a basal position of Eurychasma among the Oomycetes. The cox2 sequences also revealed that the UGA codon encoded tryptophan, constituting the first report of stop codon reassignment in an oomycete mitochondrion.     

The influence of phosphorus limitation of the diatomAsterionella Formosa on the zoospore production of its fungal parasiteRhizophydium Planktonicum

The influence of phosphorus limitedAsterionella on the zoospore production of its fungal parasiteRhizophydium planktonicum was measured, using laboratory cultures of host and parasite. At saturated phosphorus concentrations the host reached a specific growth rate of 0.95.d^–1. Growing on these host cells, the mean parasite zoospore production was 26 spores per sporangium, and the mean development time of a sporangium was 45 hours. Growing on phosphorus limited hosts, the zoospore production decreased to less then 9 spores per sporangium, and the development time decreased to 40 hours. On phosphorus limited hosts, zoospores were produced at a slower rate. The algal growth rate was reduced to a greater extent than the fungal growth rate. Therefore, it could be concluded that phosphorus limitation ofAsterionella will facilitate the development of an epidemic of its parasiteRhizophidium, at least at high diatom densities, when possible differences in infectability of the algae play a minor role.     

Synchytrium solstitiale sp. nov. causing a false rust on Centaurea solstitialis in France

A new species of Synchytrium, S. solstitiale, infecting leaves of Centaurea solstitialis in France, is described and illustrated. Synchytrium solstitiale causes development of orange to red galls on the leaves and petioles of living plants. It differs microscopically from all previously described species of the genus mainly in having larger sporangia and zoospores and resting spores that are formed in succession without an evanescent prosoral stage.     

Moments of weaknesses – exploiting vulnerabilities between germination and encystment in the Phytomyxea

Attempts at management of diseases caused by protozoan plant parasitic Phytomyxea have often been ineffective. The dormant life stage is characterised by long-lived highly robust resting spores that are largely impervious to chemical treatment and environmental stress. This review explores some life stage weaknesses and highlights possible control measures associated with resting spore germination and zoospore taxis. With phytomyxid pathogens of agricultural importance, zoospore release from resting spores is stimulated by plant root exudates. On germination, the zoospores are attracted to host roots by chemoattractant components of root exudates. Both the relatively metabolically inactive resting spore and motile zoospore need to sense the chemical environment to determine the suitability of these germination stimulants or attractants respectively, before they can initiate an appropriate response. Blocking such sensing could inhibit resting spore germination or zoospore taxis. Conversely, the short life span and the vulnerability of zoospores to the environment require them to infect their host within a few hours after release. Identifying a mechanism or conditions that could synchronise resting spore germination in the absence of host plants could lead to diminished pathogen populations in the field.     

MORPHOLOGICAL AND ECOLOGICAL STUDY OF PHYSODERMA DULICHII

A new species of aquatic Phycomycete, Physoderma dulichii Johns, parasitic on the aquatic sedge Dulichium arundinaceum (L.) Britt., is described from northern Michigan. This parasite infects and kills the upper epidermal cells of the host leaves. Macroscopically, infection by P. dulichii is indicated by striking brown bands with irregular margins, at intervals on the upper surfaces of the leaves. Like other species of Physoderma, this organism's development includes two distinct phases, an epibiotic monocentric phase producing asexual zoospores and an endobiotic polycentric phase bearing thick-walled resting spores that germinate after an extensive period of maturation at low temperature to form zoospores. The morphology and development of the two phases and of resting spore germination are reported in detail. Only the immature leaves of the host are susceptible to infection, which may be initiated by the introduction of mature resting spores, zoospores from germinated resting spores, or zoospores from epibiotic sporangia. Resting-spore zoospores may also produce the endobiotic stage directly. Initiation of infection in nature requires that the terminal cluster of immature leaves on the host plant be submerged, but infection of subsequently formed leaves of emergent culms can be accomplished through the agency of zoospores from epibiotic sporangia on older leaves. The relation of infected stands of hosts to their environment is discussed and the importance of standing water to infection noted. The geographical distribution of the parasite shows correlation with the drainage basins of the Great Lakes, the St. Lawrence River, and the northern Atlantic Coastal Plain     

Life cycle and ultrastructure ofDucellieria chodati (Oomycetes)

Ducellieria chodati forms colourless, evidently plastid-lacking aggregates. For the first time, details of the reproduction cycle are reported: Biflagellate zoospores, released from the aggregates, infest coniferous pollen grains drifting on lake surfaces. The unicellular thallus growing inside the pollen grain develops into a sporangium. 10 to c. 60 spores are discharged, gather at the mouth of the discharge tube, and form new aggregates. After more than 30 cycles, the formation of aggregates ceases in favour of the direct production of zoospores which again infest pollen grains. If several zoospores infest the same grain, a resting spore can be produced, probably by a sexual process. It is evident from this complex life cycle thatDucellieria chodati is misplaced inChlorophyceae orXanthophyceae and needs to be grouped within theOomycetes. Dedicated to Prof. DrLothar Geitler on the occasion of his 90th birthday.     

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.     

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.     

Studies on the Biology of Polymyxa betae, the Vector of Beet Necrotic Yellow Vein Virus

The development of Polymyxa betae within the roots of a sugar beet variety susceptible to Rhizomania was observed in hydroponic culture over a period of 10 days. Light microscope studies showed that at an average temperature of 20 °C the life cycle of the fungus, containing beet necrotic yellow vein virus (BNYW), was completed within 10 days. A change from the multiplication phase to the survival phase of P. betae became evident. At the beginning of the life cycle the fungus produced mainly zoospores whereas at a later stage plasmodia developed into resting spores. Zoospore density in the nutrient solution reached a maximum between the 5th and 7th day after inoculation and then declined to the initial concentration. The number of zoospores attached to the root surface increased progressively at 48 h intervals, correlated with a parallel increase in BNYW-content of the roots. Light- and fluorescence microscopy revealed that zoospores of P. betae often attach near the point of release and do not move very long distances. In addition it became evident that zoospores may attach to the thallus wall inside the zoosporangium that they have developed in.     

Life Cycle of <Emphasis Type="Italic">Plasmodiophora brassicae</Emphasis>

Plasmodiphora brassicae is a soil-borne obligate parasite. The pathogen has three stages in its life cycle: survival in soil, root hair infection, and cortical infection. Resting spores of P. brassicae have a great ability to survive in soil. These resting spores release primary zoospores. When a zoospore reaches the surface of a root hair, it penetrates through the cell wall. This stage is termed the root hair infection stage. Inside root hairs the pathogen forms primary plasmodia. A number of nuclear divisions occur synchronously in the plasmodia, followed by cleavage into zoosporangia. Later, 4–16 secondary zoospores are formed in each zoosporangium and released into the soil. Secondary zoospores penetrate the cortical tissues of the main roots, a process called cortical infection. Inside invaded roots cells, the pathogen develops into secondary plasmodia which are associated with cellular hypertrophy, followed by gall formation in the tissues. The plasmodia finally develop into a new generation of resting spores, followed by their release back into soil as survival structures. In vitro dual cultures of P. brassicae with hairy root culture and suspension cultures have been developed to provide a way to nondestructively observe the growth of this pathogen within host cells. The development of P. brassicae in the hairy roots was similar to that found in intact plants. The observations of the cortical infection stage suggest that swelling of P. brassicae-infected cells and abnormal cell division of P. brassicae-infected and adjacent cells will induce hypertrophy and that movement of plasmodia by cytoplasmic streaming increases the number of P. brassicae-infected cells during cell division.     

砂培体系中甜菜多粘菌生物学特性的研究

在改进的砂培体系中,甜菜多粘菌（Polymyxabetae）完成生活循环只需7天。利用砂培体系研究了多粘菌在不同pH值、光照、接种材料和接种量条件下,对寄主的侵染以及在其中繁殖的情况,研究了多粘菌完成侵染所需时间,侵染的游动孢子最初释放时间,游动孢子体外存活期和休眠孢子对温度的敏感性等生物学特性。     

Germination of surface-disinfected resting spores ofPlasmodiophora brassicae and their root hair infection in turnip hairy roots

Germination of surface-disinfected resting spores ofPlasmodiophora brassicae and its infection of turnip hairy root hairs were studied. Surface-disinfected resting spores showed higher germination than non-disinfected resting spores. Root hair infection was most frequent in the section of root formed 1 d before inoculation. Root hair infection began 4 d after inoculation, increased up to 6 d, and continued to increase more slowly until 10 to 12 d after inoculation. Growth ofP. brassicae in the root hair of hairy roots was observed serially. Most primary plasmodia differentiated to mature zoosporangia 8–10 d after inoculation. The secondary zoospores were initially released 6 d after inoculation.     

Zoospore development in the oomycetes

Oomycetes cause destructive diseases on both animals and plants. The epidemic spread of oomycete diseases is primarily based on rapid dispersal from host to host by free swimming zoospores. These single-nucleated spores are formed in sporangia and are only released in aqueous environments. Oomycetes are classified in the Kingdom of the Stramenopiles or Chromista, which is comprised of several organisms, including the golden brown algae. The unique shared attribute found in most Stramenopiles is the morphology of the zoospores and especially the structure of their two flagella. They have one tinsel flagellum, and one whiplash flagellum. Only the tinsel flagellum has distinctive flagellar hairs. Zoospore formation can occur within minutes and it is considered one of the fastest developmental processes in any biological system. Once released from the sporangium they are able to exhibit chemotactic responses, electrotaxis, and autotaxis or autoaggregation to target new hosts for infection. Here we discuss the latest discoveries in the development and biology of the oomycete zoospore.     

Studies on British Chytrids. XXX. On Podochytrium cornutum Sparrow

What is considered to be Podochytrium cornutum Sparrow is recorded from the plankton of Crosemere, Cheshire, where it parasitizes the diatom Stephanodiscus rotula (Kütz) Hendey. In the main essentials of its sporangial development and its rhizoidal system the Crosemere material agrees well with that of the type described from U.S.A. Observations concerning dehiscence and the structure of living zoospores, previously unknown, have been made and resting spores are described for the first time.