Evidence that Blastocladiella emersonii zoospore maintenance factor is a sulfhydryl group-containing cyclic ribotide

Blastocladiella emersonii zoospore maintenance factor (ZMF), released into the medium during zoospore production, mediates a reversible developmental block to zoospore encystment (Gottschalk, W. K., and Sonneborn, D. R. (1981) Exp. Mycol. 5, 1-14 and (1982) Dev. Biol. 93, 165-180). Crude ZMF and purified ZMF display indistinguishable sensitivities/insensitivities to inactivations by several different chemical or enzymatic treatments. Such data have provided additional support for the conclusion (Gottschalk, W. K., and Sonneborn, D. R. (1985) J. Biol. Chem. 260, 6588-6591) that ZMF biological activity resides in a single molecular species. The inactivation analyses have provided substantial evidence that ZMF is a newly discovered SH-containing cyclic ribotide. At least one SH-containing side group and at least one free amino group linked to an imidazole, as well as a ribosyl moiety containing a cyclic 3',5'-phosphate, a 2'-free hydroxyl, and a 1'-linkage to the imidazole, appear to be essential structural requirements for ZMF-mediated encystment blockage. The proposed structure of biologically functional ZMF is similar to that of a key intermediate in the de novo pathway of purine nucleotide biosynthesis (5'-phosphoribosyl-5-aminoimidazole-4-N-succino-carboxamide), except that ZMF, and not 5'-phosphoribosyl-5-aminoimidazole-4-N-succinocarboxamide, contains a cyclic phosphate and at least one reduced SH group.     

Regulation of attachment, germination, and appressorium formation by zoospores ofLagenidium giganteum and related oomycetes by chitin, chitosan, and catecholamines

Summary Lagenidium giganteum (Oomycetes: Lagenidiales), a facultative parasite of mosquito larvae, infects the larval stage of most species of mosquitoes and a very limited number of alternate hosts. Host infection by this and other members of Oomycetes is initiated by motile, laterally biflagellate zoospores. Chemical bases for the various degrees of host specificity exhibited by these parasites is not known, but presumably involves receptors on the zoospore surface recognizing compounds either secreted by or on the surface of their hosts. Surface topography had no detectable effect onL. giganteum encystment or appressorium formation. Scanning electron microscopy documented the detachment of flagella during zoospore encystment. Bulbous knobs at the basal end of the detached flagellum were interpreted as encysting zoospores dropping the axoneme and/or the basal body and associated structures to which flagella are attached. Multiple signals appear to be involved in the initial steps ofL. giganteum host invasion. Zoospores of this parasite did not encyst on powdered preparations of chitin or chitosan (deacetylated chitin). Upon dissolution of chitosan in dilute acid followed by drying these solutions to form thin, transparent films, zoospores readily encysted. The degree of reacetylation of these films and the spacing of acetylated and deacetylated residues had no significant effect on zoospore encystment. Zoospores of a strain ofLagenidium myophilum isolated from marine shrimp, that also infects mosquito larvae, encysted on chitosan films. No encystment of spores of the plant parasitePhytophthora capsici was observed on chitin or chitosan films. Simulation of cuticle sclerotization by incubating chitosan films with different catecholamines and tyrosinase significantly reduced zoospore encystment. Zoospores that encysted on chitosan films did not germinate in distilled water. Germination could be induced by adding microgram quantities of bovine serum albumin or proteins secreted by motile zoospores into the water, and to a lesser degree by some amino acids, but not by various cations. Zoospores encysted and germinated on the pupal stage of some mosquito species. Appressoria were occasionally formed, but most subsequently sent out another mycelial branch, apparently without attempting to pierce the pupal cuticle. Methylation of pupal exuviae with ethereal diazomethane or methanol/HCl significantly increased zoospore encystment. Modification of chitin by catecholamines, lipids and protein on the epicuticular larval surface all affected host invasion.Abbreviations BSA bovine serum albumin - CID collision-induced dissociation - DOPA 3,4-dihydroxyphenylalanine - ESI-MS electrospray mass spectrometry - ESI-MS/MS tandem electrospray mass spectrometry - SDS-PAGE sodium dodecyl sulphate polyacrylamide gel electrophoresis - WGA wheat germ agglutinin - ZAP zoospore aggregation pheromone     

Repeated zoospore emergence from isolated spore cysts ofAphanomyces astaci

Sporulation inA. astaci did not occur in a peptone-glucose growth medium, but was readily initiated when mycelia were transferred to distilled water or 1 mM CaCl₂. If 1 mM Ca²⁺ was added to isolated primary cysts, zoospores emerged in about 6–8 h. Zoospores could be encysted by vigorous shaking or by growth medium addition without causing germination, and these cysts were instead able to produce zoospores. With this technique it was possible to achieve three consecutive zoospore generations. If 50 mM CaCl₂ was added before ca. 10–15 min had elapsed after initiating encystment, the cysts germinated. Addition of calcium after this period did not induce germination. Calcium addition to germination-competent spores resulted in a sharp increase in protein synthesis, whereas addition to noncompetent cysts gave no such increase.     

Encystment of Pythium aphanidermatum Zoospores is Induced by Root Mucilage Polysaccharides, Pectin and a Monoclonal Antibody to a Surface Antigen

The infection of roots by the pathogenic Oomycete Pythium aphanidermatuminvolves interactions between the fungal zoospores and rootsurface mucilage polysaccharides. After initial recognitionat the root surface the zoospores are triggered to encyst duringwhich adhesive glycoproteins are secreted followed by a fibrillarcyst wall. In this paper a simple in vitro assay has been usedto assess the ability of a variety of macromolecules to inducezoospore encystment. Mucilage polysaccharides of the cress rootsurface trigger encystment. Whole mucilage was fractionatedby gel filtration and a fraction low in uronic acid, containing5% fucose, was shown to be more effective in triggering encystmentthan a uronic acid-rich fraction. Encystment can also be inducedby commercial pectin. The lectin Con A, and PA1, one of a rangeof monoclonal antibodies specific for zoospore surface antigens,also triggered encystment. In Western blotting experiments PA1recognizes protein epitopes of a 75 kDa surface antigen. Theresults suggest that at least one mechanism of zoospore triggeringmay involve a specific zoospore surface receptor. Key words: Pythium aphanidermatum, recognition, encystment, zoospore, mucilage, root, monoclonal antibodies, polysaccharides     

Phospholipase D in Phytophthora infestans and its role in zoospore encystment

We show that differentiation of zoospores of the late blight pathogen Phytophthora infestans into cysts, a process called encystment, was triggered by both phosphatidic acid (PA) and the G-protein activator mastoparan. Mastoparan induced the accumulation of PA, indicating that encystment by mastoparan most likely acts through PA. Likewise, mechanical agitation of zoospores, which often is used to induce synchronized encystment, resulted in increased levels of PA. The levels of diacylglycerolpyrophosphate (DGPP), the phosphorylation product of PA, increased simultaneously. Also in cysts, sporangiospores, and mycelium, mastoparan induced increases in the levels of PA and DGPP. Using an in vivo assay for phospholipase D (PLD) activity, it was shown that the mastoparan-induced increase in PA was due to a stimulation of the activity of this enzyme. Phospholipase C in combination with diacylglycerol (DAG) kinase activity also can generate PA, but activation of these enzymes by mastoparan was not detected under conditions selected to highlight 32P-PA production via DAG kinase. Primary and secondary butanol, which, like mastoparan, have been reported to activate G-proteins, also stimulated PLD activity, whereas the inactive tertiary isomer did not. Similarly, encystment was induced by n- and sec-butanol but not by tert-butanol. Together, these results show that Phytophthora infestans contains a mastoparan- and butanol-inducible PLD pathway and strongly indicate that PLD is involved in zoospore encystment. The role of G-proteins in this process is discussed.     

Evidence that Blastocladiella emersonii zoospore chitin synthetase is located at the plasma membrane

Blastocladiella emersonii zoospores are not encased by a cell wall and do not detectably synthesize or contain chitin; accompanying de novo cell wall formation during zoospore encystment, chitin rapidly accumulates and is incorporated into the cell wall. Essential for understanding this abrupt change in chitin synthesis is the location of zoospore chitin synthetase. The enzyme has previously been reported to the sequestered with distinctive cytoplasmic organelles (gamma particles) characteristic for the zoospore cell type. Using similar differential and equilibrium density centrifugation procedures to those reported previously, we have observed the vast majority of zoospore homogenate chitin synthetase activity in fractions distinct from the gamma particle-enriched fractions. Over 90% of the homogenate enzyme activity could be recovered in a sucrose buoyant density region (1.14–1.18 g/ml) containing membranous elements and well separated from the region enriched for gamma particles (1.30–1.34 g/ml). When zoospores were surface-labelled with [³H]concanavalin A prior to homogenization, the buoyant density regions of radioactivity and of chitin synthetase activity exhibited nearly complete coincidence. At least the bulk of zoospore chitin synthetase appears to be located at the plasma membrane, rather than in gamma particles.     

Phage-Displayed Peptides as Developmental Agonists for Phytophthora capsici Zoospores

As part of its pathogenic life cycle, Phytophthora capsici disperses to plants through a motile zoospore stage. Molecules on the zoospore surface are involved in reception of environmental signals that direct preinfection behavior. We developed a phage display protocol to identify peptides that bind to the surface molecules of P. capsici zoospores in vitro. The selected phage-displayed peptides contained an abundance of polar amino acids and proline but were otherwise not conserved. About half of the selected phage that were tested concomitantly induced zoospore encystment in the absence of other signaling agents. A display phage was shown to bind to the zoospore but not to the cyst form of P. capsici. Two free peptides corresponding to active phage were similarly able to induce encystment of zoospores, indicating that their ability to serve as signaling ligands did not depend on their exact molecular context. Isolation and subsequent expression of peptides that act on pathogens could allow the identification of receptor molecules on the zoospore surface, in addition to forming the basis for a novel plant disease resistance strategy.     

A monoclonal antibody and the lectin wheat germ agglutinin induce zoospore encystment in Pythium porphyrae, a marine microbial pathogen

Pythium porphyrae (Oomycota) is a microbial pathogen which causes red rot disease in the commercially cultivated red seaweed Porphyra. This disease is initiated by the motile zoospores of the fungus, which it has been suggested to recognize and process host specific signals by membrane bound receptors. Monoclonal antibodies (MAbs) were developed against the surface components of zoospores and cysts of this fungus in order to try and identify the putative receptor molecules involved in the zoospore encystment process. Screening of MAbs by immunofluorescence assays has revealed three different patterns of surface epitope binding, while labeling of zoospore and cysts components by FITC-conjugated lectins has identified different carbohydrate moieties. Of the MAbs and lectins tested, MAb 1A3 and wheat germ agglutinin have induced zoospore encystment under in vitro conditions. MAb 1A3 identified a 109 KDa band of a glycoprotein in western blot analysis which could be a putative receptor responsible for the induction of zoospore encystment.     

Reactivation of Ribonucleic Acid and Protein Synthesis During Germination of Blastocladiella Zoospores and the Role of the Ribosomal Nuclear Cap

Freshly harvested zoospores of Blastocladiella emersonii begin to germinate about 15 min after inoculation into a defined growth medium at a density of 10(6) zoospores per ml. Flagellum retraction accompanies encystment, and dispersal of the ribosomal nuclear cap takes place shortly thereafter. The primary rhizoid begins to emerge at 25 to 30 min and starts to branch at ca. 60 min. The first nuclear division occurs between 120 and 190 min. The dry weight per cell increases linearly after 60 min, whereas the deoxyribonucleic acid per cell doubles between 120 and 240 min. A linear increase in total ribonucleic acid (RNA) is detectable beginning at 40 to 45 min, and in total protein beginning at 80 min; neither process is interrupted during nuclear division. Encystment and nuclear cap disorganization are associated with a sharp rise in the rates of precursor incorporation into RNA and protein. Cycloheximide at 20 mug/ml prevents leucine incorporation at all stages and inhibits development beyond the earliest encystment stage. Actinomycin D at 25 mug to 50 mug/ml prevents uracil incorporation, but it has no effect on leucine incorporation or development until 40 to 45 min. At the latter stage, actinomycin D causes a sharp developmental arrest and begins to inhibit leucine incorporation. It is concluded that early protein synthesis must occur on the ribosomes formed during the prior growth phase and conserved through the zoospore stage in the nuclear cap. The results further indicate that this synthesis is dependent upon messenger RNA already present in the zoospore before germination.     

Encystment of zoospores of the fungus,Phytophthora cinnamomi,is induced by specific lectin and monoclonal antibody binding to the cell surface

Summary Only two of a number of macromolecules that bind to the surface of zoospores of the dieback fungus,Phytophthora cinnamomi, induce encystment when added to a suspension of actively swimming zoospores. One, the lectin Concanavalin A (ConA), binds to the entire surface of the zoospores including the surface of both flagella. Within 10 minutes more than 70% of the cells have encysted in the presence of 5 g/ml ConA. This encystment is inhibited by preincubation of the lectin with its hapten sugar, -methyl-D-mannoside. The other effective molecule, a monoclonal antibody designated Zf-1, is one of 35 that have been raised to components on the surface of zoospores and cysts ofP. cinnamomi. The antigen for Zf-1 occurs only on the surface of the two flagella. Purified Zf-1 at 15 g/ml causes encystment of 75% of the zoospores in 13minutes. To show that the induction of encystment by these two probes is not due simply to the presence of protein either in solution or bound to the zoospore a number of other proteins were tested, including other antibodies that bind to the zoospore surface. None of these other molecules caused encystment even at concentrations greater than 200 g/ml. The results are consistent with the surface components that bind ConA and Zf-1 being involved in the critical step of triggering encystment at the surface of a potential host during infection.     

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.     

Cyst wall formation and endogenous carbohydrate utilization during synchronous encystment of Phytophthora palmivora zoospores

Summary Vigorous agitation caused the zoospores of Phytophthora palmivora to undergo rapid synchronous encystment. The rate of encystment was determined by counting the number of cells with an alkali-resistant cyst wall. 50% of the zoospores formed an alkali-resistant cyst wall within 60 sec of agitation; after 120 sec, essentially all zoospores had encysted. The rate of spontaneous encystment in nonagitated suspensions was much slower. The flagella of nearly all zoospores disappeared within 30 sec of agitation, i.e. prior to the formation of an alkali-resistant cyst wall. Zoospores depend on internal reserves for synthesizing their cyst walls. Approximately 70% of the total carbohydrate in motile zoospores was extracted with water after treating the cells with 70% éthnol. During synchronous encystment, this carbohydrate fraction composed largely of glucans decreased markedly while the insoluble carbohydrate fraction (cyst wall glucan) increased correspondingly. Clearly, the conversion of cytoplasmic glucan into wall glucan plays a major role in zoospore encystment.     

Different life cycle strategies of the dinoflagellates Fragilidium duplocampanaeforme and its prey Dinophysis acuminata may explain their different susceptibilities to the infection by the parasite Parvilucifera infectans

Some marine dinoflagellates form ecdysal cyst (=temporary cysts) as part of their life cycle or under unfavorable growth conditions. Whether the dinoflagellates form ecdysal cysts or not may influence susceptibility to parasitism. In this study, parasite prevalence relative to inoculum size of the parasitoid Parvilucifera infectans zoospores for two dinoflagellate hosts (i.e., Fragilidium duplocampanaeforme and Dinophysis acuminata), which have different life cycle strategies, was examined. Further, susceptibility of cysts to parasitism, encystment signal, duration of encystments, and effects of induced encystment on diel periodicity, using ecdysal cyst-forming F. duplocampanaeforme were explored. The percent hosts infected by P. infectans plotted as a function of inoculum size showed a sharp increase to a maximum in D. acuminata, but a gradual linear rise in F. duplocampanaeforme: while the parasite prevalence in D. acuminata increased to a maximum of 78.8 (±2.4%) by a zoospore:host ratio of 20:1, it in F. duplocampanaeforme only reached 8.9 (±0.3%), even at a zoospore:host ratio of 120:1. In F. duplocampanaeforme, infections were observed only in the vegetative cells and not observed in ecdysal cysts. When exposed to live, frozen, and sonicated zoospores and zoospore filtrate, F. duplocampanaeforme formed ecdysal cysts only when exposed to live zoospores, suggesting that temporary cyst formation in the dinoflagellate resulted from direct contact with zoospores. When the Parvilucifera zoospores attacked and struggled to penetrate F. duplocampanaeforme through its flagellar pore, the Fragilidium cell shed all thecal plates, forming a ‘thecal cloud layer’, in which the zoospores were caught and immobilized and thus could not penetrate anymore. The duration (35 ± 1.8 h) of ecdysal cysts induced with addition of zoospores was significantly longer than that (15 ± 0.8 h) of normally formed cysts (i.e., without addition of zoospores), thereby resulting in delayed growth as well as influencing the pattern of diel periodicity. The results from this study suggest that in addition to the classical predator-prey interaction and allelopathic interaction, parasitism and its accompanying defense can make the food web dynamics much more complicated than previously thought.     

Characterisation of the water expulsion vacuole inPhytophthora nicotianae zoospores

Summary The water expulsion vacuole (WEV) in zoospores ofPhytophthora nicotianae and other members of the Oomycetes is believed to function in cell osmoregulation. We have used videomicroscopy to analyse the behaviour of the WEV during zoospore development, motility and encystment inP. nicotianae. After cleavage of multinucleate sporangia, the WEV begins to pulse slowly but soon attains a rate similar to that seen in motile zoospores. In zoospores, the WEV has a mean cycle time of 5.7 ± 0.71 s. The WEV continues to pulse at this rate until approximately 4 min after the onset of encystment. At this stage, pulsing slows progressively until it becomes undetectable. The commencement of WEV operation in sporangia coincides with the reduction of zoospore volume prior to release from the sporangium. Disappearance of the WEV during encystment occurs as formation of a cell wall allows the generation of turgor pressure in the cyst. As in other organisms, the WEV inP. nicotianae zoospores consists of a central bladder surrounded by a vesicular and tubular spongiome. Immunolabelling with a monoclonal antibody directed towards vacuolar H⁺-ATPase reveals that this enzyme is confined to membranes of the spongiome and is absent from the bladder membrane or zoospore plasma membrane. An antibody directed towards plasma membrane H⁺-ATPase shows the presence of this ATPase in both the bladder membrane and the plasma membrane over the cell body but not the flagella. Analysis of ATPase activity in microsomal fractions fromP. nicotianae zoospores has provided information on the biochemical properties of the ATPases in these cells and has shown that they are similar to those in true fungi. Inhibition of the vacuolar H⁺-ATPase by potassium nitrate causes a reduction in the pulse rate of the WEV in zoospores and leads to premature encystment. These results give support to the idea that the vacuolar H⁺-ATPase plays an important role in water accumulation by the spongiome in oomycete zoospores, as it does in other protists.Abbreviations BMM butyl methylmethacrylate - F fix 4% formaldehyde fixation - GF fix 4% formaldehyde and 0.2% glutaraldehyde fixation - V-ATPase vacuolar H⁺-ATPase - WEV water expulsion vacuole     

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     

Attraction and attachment of zoospores of the parasitic chytridRozella allomycis in response to host-dependent factors

Summary This study examined the behavior of populations of zoospores of the obligately parasitic, endobiotic chytridRozella allomycis towards young, vegetative thalli of various saprophytic fungi, in order to identify host-dependent factors which control the development ofRozella. An inverted microscope was employed for continuous observation of parasite-host interaction in petri dishes of broth or agar medium. Two factors appear to control the initial stages of invasion byRozella of both susceptible and resistant species of the host genus,Allomyces: (i) a soluble exudate which attractsRozella zoospores, (ii) a receptor on the cell-wall surface which causesRozella zoospores to adhere, and to encyst and to germinate immediately thereafter. A related, nonsusceptible species,Blastocladiella emersonii, also attractsRozella zoospores, but supports very limited attachment.Rozella zoospores neither accumulate around, nor adhere to young thalli of non-blastocladialean fungi. This host-specific behavior pattern is compared with that of saprophytic and facultatively parasitic Phycomycetes, whose zoospores show nonspecific chemotactic responses and require no receptor for attachment, encystment and germination.     

Life cycle and mode of infection of Leptolegnia chapmanii (Oomycetes) parasitizing Aedes aegypti

The life cycle and mode of infection of mosquito larvae by Leptolegnia chapmanii (Oomycetes: Saprolegniales) were determined. The life cycle is typical of saprolegniaceous fungi, as the species is dimorphic producing diplanetic biflagellate zoospores. Sexual reproduction is by means of gametangial contact and results in the production of a characteristic papillate oogonium containing a subcentric or eccentric oospore. L. chapmanii is capable of infecting Aedes aegypti larvae both by germination of encysted secondary zoospores on the exterior cuticle and by germination of ingested zoospore cysts in the larval midgut. Once the fungus is established in the host, the disease, a coelomomycosis, is fatal. The encystment pattern of secondary zoospores on the larval cuticle appcars preferential. Scanning electron microscopy indicates that mechanical pressure is not the sole force utilized by the fungus for cuticle penetration.     

Host-specific plant signal and G-protein activator, mastoparan, trigger differentiation of zoospores of the phytopathogenic oomycete Aphanomyces cochlioides

We found that the gradient of a host-specific attractant, cochliophilin A (5-hydroxy-6,7-methylenedioxyflavone) isolated from the roots of spinach triggered encystment followed by germination of zoospores of Aphanomyces cochlioidesat a concentration less than micromolar order. This compound did not affect the growth and reproduction of this phytopathogen up to 10^–6 M concentration in the culture medium. We also observed that mastoparan, an activator of heterotrimeric G-protein could inhibit the motility of zoospores and then strikingly effect encystment followed by 60–80% germination of cysts. Concomitant application of cochliophilin A and mastoparan showed stronger encystment followed by 100% germination of cysts. In addition, we have observed that chemicals interfering with phospholipase C activity (neomycin) and Ca²⁺ influx/release (EGTA and loperamide) suppress cochliophilin A or mastoparan induced encystment and germination. These results suggest that G-protein mediated signal transduction mechanism may be involved in the differentiation of the A. cochlioides zoospores. This is the first report on the differentiation of oomycete zoospores initiated by a host-specific plant signal or a G-protein activator.     

Monoclonal antibodies to cell surface components of zoospores and cysts of the fungusPythium aphanidermatum reveal species-specific antigens

A panel of monoclonal antibodies (MAbs) designated PA1 to PA8 has been raised against cell surface components of zoospores and cysts of the pathogenic fungusPythium aphanidermatum. The antibodies were selected on the basis of binding assays using indirect immunofluorescence. Four binding patterns were observed: PA1 labeled the entire zoospore surface including both flagella, PA2 binding was restricted to the anterior flagellum, PA3–PA6 bound to the adhesive cell coat secreted by zoospores during encystment, and PA7 and PA8 labeled zoospores and the cyst cell wall. Electron microscopic immunogold labeling of zoospores showed that PA2 bound to the mastigonemes on the anterior flagellum. The MAbs were tested for binding to zoospores and cysts of several isolates ofP. aphanidermatum, and to zoospores and cysts of several species ofPythium, Phystophthora, Aphanomyces, andSaprolegnia. The results showed that the antigens recognized by MAbs PA1–PA6 were restricted toP. aphanidermatum, whereas those recognized by PA7 and PA8 occurred on all species tested.     

Zoosporangia survival,dehiscence and zoospore formation,and motility in the green alga<Emphasis Type="Italic">Rhizoclonium hieroglyphicum</Emphasis> as affected by different factors

Urea at 200 ppm (probably serving as a nitrogen source), liquid Bold's basal medium at pH 7.5, temperature of about 22 degrees C and light intensity of about 40 micromol m(-2) s(-1) for 16 h a day induced rapid and/or abundant zoospores formation and zoosporangia dehiscence and favored zoospore liberation, speed and motility time period in the green alga Rhizoclonium hieroglyphicum. However, factors such as water stress (2 and 4 % agarized media, liquid media with 0.2-0.4 mol/L NaCl, 5-60 min blot-dryness of filaments), pH extremes of liquid media (at < or =6.5 and > or =9.5), temperature shock in liquid media (5 and 35 degrees C for > or =5 min), UV exposure (0.96-3.84 kJ/m2), lack of all nutrients from liquid medium (double distilled water), darkness, and presence of "heavy" metals (1-25 ppm Cu, Fe, Zn, Hg, Ni, Co) or organic substances (200-600 ppm captan or DDT, 800 and 1000 ppm 2,4-D, 50 and 400 ppm indole-3-acetic acid (3-IAA), 1000 and 2000 ppm urea, 100 and 200 ppm thiourea) in liquid media decreased and/or delayed at various levels either zoosporangia survival, zoospore formation or zoosporangia dehiscence and/or the rate of zoospore liberation from zoosporangia, zoospore speed and time period of motility in the media or totally inhibited all these processes. 3-IAA at 50 and 400 ppm induced zoosporangial papilla to grow into a tube-like projection of about 30-120 microm in length. Zoosporangial dehiscence rather than zoospore formation or zoosporangia survival, and zoospore motility period rather than zoospore speed are probably more sensitive to various adverse environmental factors. The rate of zoospores liberation from zoosporangium (possibly related directly to some extent on the zoospore number inside) is probably independent of zoospore speed in the medium.