Cytological effects of cellulases in the parasitism of Phytophthora parasitica by Pythium oligandrum

The ubiquitous oomycete Pythium oligandrum is a potential biocontrol agent for use against a wide range of pathogenic fungi and an inducer of plant disease resistance. The ability of P. oligandrum to compete with root pathogens for saprophytic colonization of substrates may be critical for pathogen increase in soil, but other mechanisms, including antibiosis and enzyme production, also may play a role in the antagonistic process. We used transmission electron microscopy and gold cytochemistry to analyze the intercellular interaction between P. oligandrum and Phytophthora parasitica. Growth of P. oligandrum towards Phytophthora cells correlated with changes in the host, including retraction of the plasma membrane and cytoplasmic disorganization. These changes were associated with the deposition onto the inner host cell surface of a cellulose-enriched material. P. oligandrum hyphae could penetrate the thickened host cell wall and the cellulose-enriched material, suggesting that large amounts of cellulolytic enzymes were produced. Labeling of cellulose with gold-complexed exoglucanase showed that the integrity of the cellulose was greatly affected both along the channel of fungal penetration and also at a distance from it. We measured cellulolytic activity of P. oligandrum in substrate-free liquid medium. The enzymes present were almost as effective as those from Trichoderma viride in degrading both carboxymethyl cellulose and Phytophthora wall-bound cellulose. P. oligandrum and its cellulolytic enzymes may be useful for biological control of oomycete pathogens, including Phytophthora and Pythium spp., which are frequently encountered in field and greenhouse production.     

Oligandrin. A proteinaceous molecule produced by the mycoparasite Pythium oligandrum induces resistance to Phytophthora parasitica infection in tomato plants

A low-molecular weight protein, termed oligandrin, was purified to homogeneity from the culture filtrate of the mycoparasitic fungus Pythium oligandrum. When applied to decapitated tomato (Lycopersicon esculentum Mill. var. Prisca) plants, this protein displayed the ability to induce plant defense reactions that contributed to restrict stem cell invasion by the pathogenic fungus Phytophthora parasitica. According to its N-terminal sequence, low-molecular weight, acidic isoelectric point, ultraviolet spectrum, and migration profile, the P. oligandrum-produced oligandrin was found to share some similarities with several elicitins from other Phytophthora spp. and Pythium spp. However, oligandrin did not induce hypersensitive reactions. A significant decrease in disease incidence was monitored in oligandrin-treated plants as compared with water-treated plants. Ultrastructural investigations of the infected tomato stem tissues from non-treated plants showed a rapid colonization of all tissues associated with a marked host cell disorganization. In stems from oligandrin-treated plants, restriction of fungal growth to the outermost tissues and decrease in pathogen viability were the main features of the host-pathogen interaction. Invading fungal cells were markedly damaged at a time when the cellulose component of their cell walls was quite well preserved. Host reactions included the plugging of intercellular spaces as well as the occasional formation of wall appositions at sites of potential pathogen entry. In addition, pathogen ingress in the epidermis was associated with the deposition of an electron-opaque material in most invaded intercellular spaces. This material, lining the primary walls, usually extended toward the inside to form deposits that frequently interacted with the wall of invading hyphae. In the absence of fungal challenge, host reactions were not detected.     

Interaction of the mycoparasite Pythium oligandrum with other Pythium species

Interactions of Pythium oligandrum and four plant‐pathogenic Pythium spp. (P. ultimum, P. vexans, P. graminicola and P. aphanidermatum,) were studied in vitro by (i) video microscopy of hyphal interactions on water agar films, (ii) counting of host and mycoparasite propagules in different regions of opposing colonies on sunflower‐seed extract agar films and (Hi) ability of P. oligandrum to overgrow plates of potato‐dextrose agar previously colonized by Pythium spp. Pythium oligandrum typically coiled round the hyphae of Pythium hosts and penetrated the host hyphae after approximately 50 min from the hyphal coils, causing disruption of host hyphal tips up to 1.2 mm ahead of contact points. The relative growth rates of mycoparasite and host hyphae, timing of penetration and distance (sub‐apical) at which penetration led to host tip disruption were used to assess the potential of mycoparasitism by P. oligandrum to prevent the growth of Pythium hosts. P. aphanidermatum was unique among the ‘host’ Pythium spp. in being largely unaffected by P. oligandrum and in antagonizing the mycoparasite by coiling and penetrating the mycoparasite hyphae. Other host Pythium spp. apparently differed in susceptibility, the most susceptible being P. vexans and P. ultimum, whereas P. graminicola was more resistant. The results are discussed in relation to the role of P. oligandrum as a biocontrol agent, especially for limiting the ability of other Pythium spp. to increase their propagule populations in crop residues.     

Biological Control of Phoma and Pythium Damping-Off of Sugar-Beet with Pythium oligandrum

Flooding freshly harvested oospores in sterile distilled water (SDW) for several days enhanced germination in 3 out of 4 isolates of Phythium oligandrum. Treatment of SDW-flooded oospores with myo-inositol increased germinability during the first 20 days of storage at 15°C. Seed dressing with oospores of P. oligandrum controlled pre- and post-emergence damping-off of sugar-beet caused by soil-borne P. ultimum and seed-borne Phoma betae. For some isolates, flooded oospores in SDW and treatment with myo-inositol increased efficacy of the seed dressing. However, no significant control of damping-off caused by Rhizoctonia solani was observed. On corn-meal agar, P. oligandrum coiled around and penetrated hyphae of P. ultimum and R. solani, but did not interfere with Ph. betae.     

生防真菌寡雄腐霉原生质体的制备及再生

寡雄腐霉Pythium oligandrum是一种对动、植物和环境无害,兼具杀菌和增产效果的生防真菌。本研究以0.8mol/L甘露醇与25mmol/L CaCl_2和10mmol/L Tris-HCl作为渗透压稳定剂,使寡雄腐霉菌丝体在含有裂解酶、纤维素酶、破壁酶的复合酶系中酶解得到其原生质体。此原生质体通过液体振荡培养的途径恢复再生1d后涂于平板上可生长为成熟菌体。本研究所述方法制备得到的寡雄腐霉原生质体数量超过1×10~9CFU/m L,活性超过80%;通过液体培养再生途径使得寡雄腐霉原生质体再生率达32.9%。此方法操作简便,稳定性好,获得的寡雄腐霉原生质体品质高、数量多,完全能够满足后期基因遗传转化、细胞融合培养等研究应用。     

Use of Oospore Formulations of Pythium oligandrum for Biological Control of Pythium Damping-off in Cress

Oospore preparations of Pythium oligandrum produced by liquid and solid-substrate fermentations were evaluated for biocontrol activity against Pythium damping-off in cress in artificially infested sand and naturally infested soil. Oospore biomass preparations from liquid fermentation of six isolates of P. oligandrum were equally effective in reducing damping-off in sand when tested as seed-coatings, whereas this type of preparation of a single isolate formulated as a kaolin dust, on Perlite and as alginate pellets incorporated into sand gave little or no control. None of the formulations containing oospores produced by solid-substrate fermentation incorporated into sand had any effect. In soil, a formulation containing oospores produced in a barley-Perlite solid-substrate fermentation and all oospore-biomass formulations which were prepared increased seedling survival, but none of these were as effective as a propamocarb HCl drench.     

Impact of auxin-compounds produced by the antagonistic fungus Pythium oligandrum or the minor pathogen Pythium group F on plant growth

Plant growth promotion induced by the antagonistic fungus, Pythium oligandrum, is the result of a complex interaction which includes an indirect effect through control of pathogens in the rhizosphere and/or a direct one mediated by plant-induced resistance. The present study shows an increased plant growth associated with direct interaction between P. oligandrum and roots, which is mediated by a fungus-produced auxin compound, tryptamine (TNH₂). In vitro experiments provided evidence that P. oligandrum metabolised specifically indole derivatives, such as tryptophan and indole-3-acetaldehyde, to produce THN₂ through the tryptamine pathway. When P. oligandrum grew in sterile root exudates, it also produced an auxin-like compound. Additional experiments on P. oligandrum–root interaction showed that, in amended nutrient solution of plants, the antagonist metabolised Trp into TNH₂ and that root absorption of this newly formed auxin-compound in appropriate concentrations was associated with enhancement of plant growth. This phenomenon was observed only when nutrient solution was amended with low tryptophan (Trp) concentrations, i.e. 0.05 and 0.1 mM; higher concentration (0.5 and 1 mM Trp) induced abnormal root development. Similar experiments were performed with Pythium group F, a minor pathogen known for its ability to produce auxin-compounds through the tryptamine pathway. In this case, irregular root development was always noticed with all Trp concentrations added to the nutrient solution of plants. Moreover, Pythium group F colonization of roots was associated with leakage of auxin-compounds in the nutrient solution. Our results, therefore, highlight that the production of similar auxin-compounds by two Pythium species has contrary effects on plant development.     

Biocontrol of black scurf on potato by seed tuber treatment with Pythium oligandrum

The biological control activity of Pythium oligandrum against black scurf of potato caused by Rhizoctonia solani AG-3 was evaluated in field experiments after treatment of potato seed tubers with P. oligandrum. Seed tubers infected with black scurf sclerotia were dipped for a few seconds in a suspension of 10³, 10⁴ or 10⁵ mL^?1 P. oligandrum oospores and were then air-dried. Each level of P. oligandrum-treatment significantly reduced the disease rates of stolon at a level similar to that achieved by chemical control. When P. oligandrum populations adherent to the surface of seed tubers were determined, oospore counts on tubers treated with 10⁴ or 10⁵ oospores mL^?1 were about 540/cm² or about 22,000/cm² just after dipping and decreased to about 170/cm² or 2900/cm² after a 3-week incubation, respectively. Confocal laser scanning microscopic observation with an immuno-enzymatic staining procedure showed that P. oligandrum hyphae had colonized the sclerotia and established close contact by coiling around the R. solani hyphae present on the surface of seed tubers, in a manner similar to that observed in the dual-culture test. Quantification of R. solani DNA by PCR indicated that the R. solani population was reduced on the seed tubers treated with P. oligandrum compared to untreated tubers. Furthermore, the ability of P. oligandrum to induce resistance against black scurf was determined using a potato tuber disk assay. Treatment of tuber disks with the cell wall protein fraction of P. oligandrum enhanced the expression of defense-related genes such as 3-deoxy-d-arabino-heptulosonate 7-phosphate synthase, lipoxygenase and basic PR-6 genes, and reduced disease severity upon challenge with R. solani compared with untreated controls. These results suggest that biocontrol mechanisms employed by P. oligandrum against black scurf involve both mycoparasitism and induced resistance.     

Development of a Defined Medium for Pythium oligandrum Oospore Production

Complex and defined media have been previously proposed for production of oospores of Pythium oligandrum , a fungal mycoparasite of several disease-causing fungi. However, oospore production in synthetic media requires long periods of incubation and yields lower oospore numbers than in complex media. Moreover, although complex media produce high oospore yields, these yields are not reproducible because of the variability in the composition of complex nutrient sources. In the present study, the average composition of molasses reported in the literature was utilized as a base to develop a new defined medium for P. oligandrum oospore production. Forty-two substrates defined in nine stock solutions: carbohydrates, vitamins, sterols, non nitrogenous acids, amino acids, minerals, nucleic acid bases, CaCl 2 and MgSO 4 were tested at two levels (present or absent) in two fractional factorial designs. Each of these nine variables had a significant main effect on oospore production. Furthermore, the effect of each variable, except for vitamins, depended on the level of each other variable, expressed by two-variable interactions. The maximal predicted oospore production was calculated from the polynomial regressions associated with the two fractional factorial designs. Oospore productions were 1.3 and 2 ×10 6 oospores mL -1 from the first and second designs. In order to optimize the oospore production, the two levels of each variable were modified and all variables were experimented in a selection of a complete factorial design (Plackett and Burman design). A fitted first-order polynomial regression equation provided the combination of levels of variables for optimal oospore production. A defined medium, based on this combination of levels, was used for P. oligandrum growth. The optimized oospore production after 7 days growth was 4 ×106 oospores mL -1 as predicted by the polynomial regression. Oospore yields, biomass produced from oospores and oospore freeze-drying tolerance were similar when P. oligandrum was previously grown in molasses or in the new defined medium.     

Genetic transformation of the plant pathogens Phytophthora capsici and Phytophthora parasitica.

Phytophthora capsici and P.parasitica were transformed to hygromycin B resistance using plasmids pCM54 and pHL1, which contain the bacterial hygromycin B phosphotransferase gene (hph) fused to promoter elements of the Ustilago maydis heat shock hsp70 gene. Enzymes Driselase and Novozyme 234 were used to generate protoplasts which were then transformed following exposure to plasmid DNA and polyethylene glycol 6000. Transformation frequencies of over 500 transformants per micrograms of DNA per 1 x 10(6) protoplasts were obtained. Plasmid pCM54 appears to be transmitted in Phytophthora spp. as an extra-chromosomal element through replication, as shown by Southern blot hybridization and by the loss of plasmid methylation. In addition, transformed strains retained their capacity of infecting Serrano pepper seedlings and Mc. Intosh apple fruits, the host plants for P.capsici and P.parasitica, respectively.     

Retraction of flagella by Phytophthora parasitica var. nicotiana zoospores

Summary Light and electron microscope evidence is presented to show that retraction of flagella may occur in Phytophthora parasitica zoospores during encystment.     

Antagonism of Rhizoctonia spp. to Pythium oligandrum and Damping-Off Fungi

In paired cultures on corn-meal agar, Rhizoctonia solani, R. cerealis and R. fragariae caused vacuolation, disappearance of cytoplasm, and apparent lysis of hyphae of Pythium oligandrum, P. ultimum, and Aphanomyces cochlioides. Hyphae of Phoma betae were not injured by the Rhizoctonia spp. When sugar-beet seeds dressed with mycelium of R. cerealis, R. fragariae, or an isolate of R. solani nonpathogenic to sugar-beet were planted in soil naturally infested with P. ul-timum, the level of biological control of damping-off was similar to that obtained with captan dressing. In soil artificially infested with P. ultimum, biological dressings were slightly less efficacious than the chemical dressing.     

Influence of Pythium oligandrum Biocontrol on Fungal and Oomycete Population Dynamics in the Rhizosphere

Fungal and oomycete populations and their dynamics were investigated following the introduction of the biocontrol agent Pythium oligandrum into the rhizosphere of tomato plants grown in soilless culture. Three strains of P. oligandrum were selected on the basis of their ability to form oospores (resting structures) and to produce tryptamine (an auxin-like compound) and oligandrin (a glycoprotein elicitor). Real-time PCR and plate counting demonstrated the persistence of large amounts of the antagonistic oomycete in the rhizosphere throughout the cropping season (April to September). Inter-simple-sequence-repeat analysis of the P. oligandrum strains collected from root samples at the end of the cropping season showed that among the three strains used for inoculation, the one producing the smallest amount of oospores was detected at 90%. Single-strand conformational polymorphism analysis revealed increases in the number of members and the complexity of the fungal community over time. There were no significant differences between the microbial ecosystems inoculated with P. oligandrum and those that were not treated, except for a reduction of Pythium dissotocum (ubiquitous tomato root minor pathogen) populations in inoculated systems during the last 3 months of culture. These findings raise interesting issues concerning the use of P. oligandrum strains producing elicitor and auxin molecules for plant protection and the development of biocontrol.In soilless cultures, the recycling of drainage water within a system is the consequence of new laws concerning water saving and limitation of pollution. Such closed systems minimize costs by conserving water and reducing fertilizer input; however, they may favor the dissemination of pathogens (13). When pathogens manage to enter recirculation systems, they are rapidly disseminated and may cause disease epidemics, particularly during periods of stress, e.g., stress due to high temperatures and/or to low levels of dissolved oxygen in the nutrient solution. Thus, numerous facultative pathogens commonly found in conventional cultures may become economically significant (53). Several of them, e.g., Pythium spp. and Phytophthora spp., are well adapted to the aquatic environment of hydroponic systems: they produce flagellate zoospores which enable them to swim in the nutrient solution, facilitating the spread of infection (18, 21, 36, 54, 61).Various methods are used to reduce the risks to plant health. Over recent years, the disinfection of nutrient solutions by physical or chemical treatments, e.g., ozonization, UV irradiation, chlorination, and thermo-disinfection, has been developed (13, 38). These methods effectively destroy pathogenic microorganisms but are harmful to species liable to benefit the plant, to be used as biocontrol agents, or both. Indeed, recirculation of nutrient solutions in closed hydroponic systems favors the establishment of a potentially suppressive microflora besides the pathogenic microflora (16, 28, 39, 41). The development of a beneficial microflora may thus be impeded by treatments used to destroy pathogenic microorganisms. Consequently, interest has been focused on the management of microorganisms in soilless cultures (12). Postma and coworkers (40) found that the extent of root disease is increased by the use of autoclaved rock wool. Tu and coworkers (59) observed that root rot disease was less severe in closed hydroponic systems than in open cultures and suggested that the difference was due to a higher density of bacteria in the closed systems. According to Paulitz (34), the diversity of microorganisms in soilless cultures is more limited than that in conventional soil cultures, such that conditions are more suitable for beneficial microorganisms, and consequently for effective biological control, in soilless than in conventional soil cultures.Biocontrol strategies are promising (7, 35). However, both biotic and abiotic factors may affect the performance of biocontrol methods. Relevant biotic factors include interactions with nontarget microorganisms (6), poor implantation of the biocontrol agent due to nonadaptation to the hydroponic system or resistance from the native microflora, shelf life and formulation, and host plant species and cultivar effects. Abiotic factors include climatic, chemical, and physical conditions of the soil or rhizosphere.Despite the limitations, various studies report evidence of the suppression of disease following the inoculation of hydroponic systems with antagonistic microorganisms. In particular, Pythium oligandrum is an effective biocontrol agent (2, 14, 49, 64). This oomycete colonizes roots without damaging the host plant cells (24, 45) and survives in the rhizosphere, where it exerts its biocontrol (57). P. oligandrum acts through both direct effects (mycoparasitism, antibiosis, and competition for nutrients and space) and indirect effects (stimulation of plant defense reactions and plant growth promotion) (49). The operating effects seem to depend on the type of pathogenic fungi being controlled (3, 48, 49). Le Floch and coworkers suggested that mycoparasitism is not the main mode of action (23). Root colonization by P. oligandrum may induce systemic resistance associated with the synthesis of elicitors protecting the plant from its aggressors (4, 17, 31, 37, 56). Several studies have investigated formulations of P. oligandrum oospores applied to soil or seeds, and their production and use, to optimize the efficacy of biocontrol (9, 30).Effective biocontrol by P. oligandrum may be limited by its heterogeneous implantation in the rhizosphere (46). Therefore, enhanced implantation and persistence of P. oligandrum in the rhizosphere should improve plant protection. We report an investigation of the persistence of P. oligandrum and its impact on the native fungal microflora of the roots. Three strains with characteristic traits were selected to constitute an inoculum applied to tomato plant roots. The characteristics of the strains were the production of oospores to allow root colonization and favor persistence, the synthesis of tryptamine, a plant growth enhancer (22), and the production of oligandrin, a plant-protective elicitor (37). The inoculated rhizospheres were monitored to evaluate the persistence of the strains and their effects on the microflora. The populations of the common tomato root pathogen P. dissotocum (endemic in the studied systems) and of P. oligandrum were both assessed by plate counting and real-time PCR. The strain(s) of P. oligandrum responsible for the colonization of the rhizosphere was identified by inter-simple-sequence-repeat (ISSR) methodology. Single-strand conformational polymorphism (SSCP) investigations were used to study the effects of P. oligandrum on the fungal populations colonizing the rhizosphere and the fungal dynamics throughout the cropping season.     

Plant-induced cell death in the oomycete pathogen Phytophthora parasitica

The activation of programmed cell death in the host during plant-pathogen interactions is an important component of the plant disease resistance mechanism. In this study we show that activation of programmed cell death in microorganisms also regulates plant-pathogen interactions. We found that a form of vacuolar cell death is induced in the oomycete Phytophthora parasitica--the agent that causes black shank disease in Nicotiana tabacum--by extracellular stimuli from resistant tobacco. The single-celled zoospores underwent cell death characterized by dynamic membrane rearrangements, cell shrinkage, formation of numerous large vacuoles in the cytoplasm and degradation of cytoplasmic components before plasma membrane disruption. Phytophthora cell death required protein synthesis but not caspase activation, and was associated with the production of intracellular reactive oxygen species. This characterization of plant-mediated cell death signalling in pathogens will enhance our understanding of the biological processes regulating plant-pathogen interactions, and improve our ability to control crop diseases.     

Synthesis of beta-D-glucose oligosaccharides from Phytophthora parasitica

The glucohexaose, beta-D-Glcp-(1-->3)-[beta-D-Glcp-(1-->3)-beta-D-Glcp-(1-->3)-beta-D-Glcp-(1-->6)]-beta-D-Glcp-(1-->3)-D-Glcp, was synthesized as its allyl glycoside via 3+3 strategy. The trisaccharide donor, 2,3,4,6-tetra-O-benzoyl-beta-D-glucopyranosyl-(1-->3)-2,4,6-tri-O-acetyl-beta-D-glucopyranosyl-(1-->3)-2,4,6-tri-O-acetyl-alpha-D-glucopyranosyl trichloroacetimidate (11), was obtained by 3-selective coupling of isopropyl 4,6-O-benzylidene-1-thio-beta-D-glucopyranoside (2) with 2,3,4,6-tetra-O-benzoyl-beta-D-glucopyranosyl-(1-->3)-2-O-acetyl-4,6-O-benzylidene-alpha-D-glucopyranosyl trichloroacetimidate (6), followed by hydrolysis, acetylation, dethiolation, and trichloroacetimidation. Meanwhile, the trisaccharide acceptor, allyl 2,3,4,6-tetra-O-benzoyl-beta-D-glucopyranosyl-(1-->3)-2-O-acetyl-beta-D-glucopyranosyl-(1-->3)-4,6-di-O-acetyl-2-O-benzoyl-alpha-D-glucopyranoside (14), was prepared by coupling of allyl 4,6-di-O-acetyl-2-O-benzoyl-alpha-D-glucopyranoside (12) with 6, followed by debenzylidenation. Condensation of 14 with 11, followed by deacylation, gave the target hexaoside. A beta-(1-->3)-linked tetrasaccharide 29 was also synthesized with methyl 2-O-benzoyl-4,6-O-benzylidene-beta-D-glucopyranosyl-(1-->3)-2,4,6-tri-O-acetyl-beta-D-glucopyranoside (25) as the acceptor and acylated beta-(1-->3)-linked disaccharide 21 as the donor.