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 ultrastructure of cell wall formation and of gamma particles during encystment of Allomyces macrogynus zoospores

Structural changes during cell wall formation by populations of semisynchronously germinating zoospores were studied in the water mold Allomyces macrogynus. Fluorescence microscopy using Calcofluor white ST (which binds to -1,4-linked glycans) demonstrated that Calcofluor-specific material was deposited around most cells between 2–10 min after the induction of encystment (beginning when a wall-less zoospore retracts its flagellum and rounds up). During the first 15 min of encystment there was a progressive increase in fluorescence intensity. Ultrastructural analysis of encysting cells showed that within 2–10 min after the induction of encystment small vesicles 35–70 nm diameter were present near the spore surface, and some were in the process of fusing with the plasma membrane. The fusion of vesicles with the zoospore membrane was concomitant with the appearance of electron-opaque fibrillar material outside the plasma membrane. Vesicles similar to those near the spore surface were found within the gamma () particles of encysting cells. These particles had a crystalline inclusion within the electron-opaque matrix. During the period of initial cyst cell wall formation numerous vesicles appeared to arise at the crystal-matrix interface. Approximately 15–20 min was required for the cell wall to be formed. We suggest that the initial response of the zoospore to induction of encystment is the formation of a cell wall mediated by the fusion of cytoplasmic vesicles with the plasma membrane.Non-Standard Abbreviations GlcNac N-Acetylglucosamine - DS sterile dilute salts solution - PYG peptone-yeast extract-glucose broth     

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.     

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.     

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.     

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.     

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.     

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     

Cell surface antigens ofPhytophthora spores: biological and taxonomic characterization

Summary The oomycetes are a class of protists that produce biflagellate asexual zoospores. Members of the oomycetes have close phylogenetic affinities with the chromophyte algae and are widely divergent from the higher fungi. This review focuses on two genera,Phytophthora andPythium, which belong to the family Pythiaceae, and the order Peronosporales. These two genera contain many species that cause serious diseases in plants. Molecules on the surface of zoospores and cysts of these organisms are likely to play crucial roles in the infection of host plants. Knowledge of the properties of the surface of these cells should thus help increase our understanding of the infection process. Recent studies ofPhytophthora cinnamomi andPythium aphanidermatum have used lectins to analyse surface carbohydrates and have generated monoclonal antibodies (MAbs) directed towards a variety of zoospore and cysts surface components. Labelling studies with these probes have detected molecular differences between the surface of the cell body and of the flagella of the zoospores. They have been used to follow changes in surface components during encystment, including the secretion of an adhesive that bonds the spores to the host surface. Binding of lectin and antibody probes to the surface of living zoospores can induce encystment, giving evidence of cell receptors involved in this process. Freeze-substitution and immunolabelling studies have greatly augmented our understanding of the synthesis and assembly of the zoospore surface during zoosporogenesis. Synthesis of a variety of zoospore components begins when sporulation is induced. Cleavage of the multinucleate sporangium is achieved through the progressive extension of partitioning membranes, and a number of surface antigens are assembled onto the zoospore surface during cleavage. Comparisons of antibody binding to many isolates and species ofPhytophthora andPythium have revealed that surface components on zoospores and cysts exhibit a range of taxonomic specificities. Surface antigens or epitopes may occur on only a few isolates of a species; they may be species-specific, genus-specific or occur on the spores of both genera. Spore surface antigens thus promise to be of significant value for studies of the taxonomy and phylogeny of these protists, as well as for disease diagnosis.Abbreviations MAbs monoclonal antibodies - ConA Concanavalin A - SBA soybean agglutinin - WGA wheat germ agglutinin - gps glycoproteins     

Electron microscopy of zoospores and cysts of Phytophthora palmivora: Morphology and surface texture

Summary Scanning electron microscopy and transmission electron microscopy (carbon replicas) confirm the existence of a deep longitudinal groove on one side of the pyriform body of the zoospores of Phytophthora palmivora. Upon encystment the cell rounds off but the groove may be temporarily retained as a depression on the cyst surface. The carbon replicas revealed significant differences in outer surface texture: the zoospore surface is finely granular whereas the outer surface of both young and mature cysts are distinctly microfibrillar with only occasional patches of amorphous material.     

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     

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.     

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     

The secondary zoospore of Aphanomyces astaci and A. laevis (Oomycetes, Saprolegniales)

The ultrastructure of the secondary zoospores of Aphanomyces astaci and A. laevis was compared. The general appearance of the organelles and their compartmental–ization is the same, but some subtle differences were found. A. laevis has a less distinct distribution of fuzzy vesicles around the border of the water expulsion apparatus than A. astaci. The content of the U–body of the A. astaci zoospore is paracrystalline but the A. laevis U–body has a tubular content. In the peripheral cytoplasm of both species are seen vesicles with a granular content. Flattened cisternae are found in a narrow zone just below the plasmalemma. These two structures are confined to the zoospore stage of the fungi. The lipid–microbody complex of A. laevis cysts is not present in the zoospore. The ultrastructural organization of uniflagellate and bi–flagellate zoospores is compared.     

Pattern formation and the fine structure of the developing cell wall in colonies of Pediastrum boryanum

A single-layered disc of peripheral pronged cells and central prongless cells impart the typical gear shape to colonies of Pediastrum, while the walls of each cell have a characteristic reticulate triangular pattern. The two-layered wall forms in the cells during colony formation following zoospore aggregation and adhesion. The uniformly thin outer layer reflects contours resulting from differential thickening in the reticulate pattern of the inner, thicker, more fibrillar and granular wall layer. The reticulate pattern thus imparted to the outer wall layer persists in empty zoosporangia following the release of zoospores. Columns of electron-dense material extend through the outer wall layer except at the ridges and centers of the reticulum. Following mitosis and cleavage, the resulting zoospores are extruded within a vesicle membrane consisting of the inner wall layer. Separation of this membrane from the parent cell occurs in material of the inner layer adjacent to the outer wall. Vesicles containing swarming zoospores also contain a granular material which appears to become associated with the aggregating and adhering cells of new colonies. Microtubules occur in zoospores prior to adherence but are absent during wall deposition.     

Carbohydrate regulation of attachment, encystment, and appressorium formation by Pythium porphyrae (Oomycota) zoospores on Porphyra yezoensis (Rhodophyta)

Pythium porphyrae Takahashi et Sasaki, a facultative parasite of Porphyra spp., is the common microbial agent responsible for red rot disease of this red alga in Japan. Host infection by this species and other plant parasitic members of the Pythiaceae is initiated by motile biflagellate zoospores. Factors regulating host specificity and the initial steps involved in the infection process, consisting of attachment, encystment and appressorium formation, are not known. Zoospore encystment and appressorium formation of P. porphyrae were monitored by staining of the fungal cell walls using calcofluor. The zoospores infected only Porphyra spp. and Bangia atropurpurea (Roth) C. Agardh thalli, although they attached to, and encysted on, many other members of the Rhodophyceae (Stylonema alsidii[Zanardini] Drew, Gelidium elegans Kützing, Pterocladiella capillacea[Gmelin] Santelices et Hommersand, Carpopeltis affinis[Harvey] Okamura, Gloiosiphonia capillaris[Hudson] Carmichael in Berkeley, Grateloupia turuturu Yamada, Callophyllis adhaerens Yamada, Gracilaria spp., Lomentaria hakodatensis Yendo, Rhodymenia intricata[Okamura] Okamura, Griffithsia subcylindrica Okamura, Wrangelia tanegana Harvey, and Polysiphonia morrowii Harvey). No attachment or encystment was observed on the red alga Kappaphycus striatum (Schmitz) Doty ex Silva in Silva et al., the brown algae Undaria pinnatifida (Harvey) Suringar, Scytosiphon sp., and Sargassum thunbergii (Mertens ex Roth) Kuntze as well as members of the Ulvaceae (green algae). Sequential extraction of carbohydrates from Porphyra yezoensis Ueda thalli and the addition of diverse monosaccharides, polysaccharides, and amino acids to zoospore suspensions indicated that encystment and appressorium formation were induced only by sulfated galactans (porphyran, commercial agar, agarose, and carrageenans). Zoospore attachment and encystment on thalli of P. yezoensis was abolished by periodate oxidation of the thallus surface and was reduced by 80–90% after enzymatic removal of sulfated galactan (porphyran). It appears that the interaction of zoospore surface receptors with sulfated galactan (porphyran) determinants on the thallus surface induced specific attachment and encystment on Porphyra spp. thalli. Zoospores encysted, germinated, and formed appressoria on sulfated galactan films and in suspensions of this carbohydrate. Attachment and encystment were induced on commercial agar and agarose films, but appressoria were not induced on agarose films. Supplementation of agarose media with both cold and hot water fractions and with porphyran from P. yezoensis–induced appressoria implicated sulfated galactans (porphyran) in appressorium formation.     

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.     

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.     

Adhesion of Phytophthora palmivora zoospores: detection and ultrastructural visualization of concanavalin A-receptor sites appearing during encystment.

The binding of concanavalin A (Con A) to the cell surface of zoospores and cysts of Phytophthora palmivora was studied by radiometry (125I-Con A), ultraviolet microscopy (fluorescein-Con A) and electron microscopy peroxidase-diaminobenzidine technique). Zoospores were found to secrete during the early stages of encystment a Con A-binding material susceptible to trypsin digestion. This glycoprotein is contained in the so-called peripheral vesicles and is probably responsible for the adhesion of the encysting zoospores to solid surfaces.     

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.