| Abstract: | 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. |
