A growing body of research indicates host plants impact root-associated microbial communities [28, 35, 51-52]. We conducted the multi-cycle plantings with infection by the fungal pathogen Rhizoctonia solani AG8 to reveal that successive plantings enhanced disease suppression on wheat and shaped the rhizosphere bacterial communities. Application of the pathogen AG8 further drove the differences of the wheat-associated bacterial communities. Moreover, the bacterial communities in the wheat rhizospheres from ‘Good’ (G) treatment (the least wheat root disease) gradually separated from those from ‘Bad’ (B) treatment (the worst wheat root disease) over the planting cycles. Most notably, some bacterial species were isolated from the wheat rhizospheres over multi-cycles growth and displayed antagonistic activities to soilborne fungal pathogens. Among them, a species of Janthinobacterium exhibited broad-spectrum antagonism against R. solani AG8, R. oryzae, and Pythium ultimum in a dual culture assay and against AG8 in soil. Overall, these findings suggest that repeated monocultures and AG8 infestation could change the root microbiome structure and recruit beneficial microbiota which promote plant growth and reduce soilborne pathogens, and eventually might induce disease-suppressive soils.
Multi-cycle wheat plantings accompanied by rhizosphere microbiota transfers reduced root rot disease caused by R. solani AG8 and the root disease suppression was enhanced over successive growth cycles. Soils suppressive to Rhizoctonia were similarly reported in our previous study [43] and in the agricultural fields in Australia and Pacific Northwest in USA [53-56]. Further studies of disease suppressive soil suggested that suppression resulted from the shifts in microbial community composition and activity, enhancing several groups of bacteria including Pantoea agglomerans, Exiguobacterium acetylicum, and Microbacteria [57]; Asaia spp. and Paenibacillus borealis [58]; and Flavobacterium, Chryseobacterium, and Chitinophaga [43]. In this study, some bacterial genera that have potential disease suppressive activities were significantly affected by the plant growth cycles. For example, bacteria within the genus Bacillus significantly increased with plant growth cycles without AG8 infection. It is well documented that Bacillus spp. secrete several metabolites not only to trigger plant growth but to inhibit pathogenic microbial growth in soil or kill pathogens through degrading the cell walls [59-61]. The abundance of Chitinophaga was significantly higher in AG8 infested wheat rhizosphere in cycle 9 than those in cycle 2 and cycle 1 (Fig. 7), which is consistent with our previous study [43]. In addition, bacterial species diversity and richness were observed to significantly decline with increasing growth cycle. This might be partially due to starting with cycle 2, in which pasteurized soil was used, which kills or removes some harmful microorganisms compared with the native Lind soil in control and cycle 1. However, the same pasteurization treatment was used for the second cycle and following cycles, and the reduction of bacterial species diversity was still observed over the growth cycles. This could be due to the shifts of bacterial communities driven by the plant and AG8 to favor certain bacterial species over others, leading to reduced bacterial diversity and more plant-specific communities.
Disease suppressive soils typically develop after a disease outbreak [55, 62-65]. This phenomenon is often attributed to plants changing the structure of the microbial community and recruiting protective microbiota in the rhizosphere in response to pathogen attack by producing chemical compounds. In our multi-cycle wheat planting selection system, the soilborne fungal pathogen AG8 was inoculated into soil. The bacterial communities recruited to the AG8 infected rhizosphere were distinct from those without AG8 infection. AG8 infection also enhanced bacterial community separation during cycling indicating the pathogen application modified changes in microbial community composition driven by successive plantings. Similar changes were reported in other studies [65]. For instance, tomato plants challenged with the pathogen Ralstonia solanacearum revealed that the soil microbial abundances were changed through the plant root exudation in infected plants [66]. Barley plants challenged with Fusarium graminearum enriched the rhizosphere microbiome with potentially antifungal microbes [41]. There is increasing evidence that plants produce compounds to attract beneficial microbes or stimulate the expression of antifungal genes to react to pathogen infection. Therefore, plants can acclimate to biotic stress [39, 41, 67].
Interestingly, R. solani AG8 infection increased the abundance of some genera that have suppressive or antagonistic functions, such as Chitinophaga, Pseudomonas, Chryseobacterium, Flavobacterium, Serratia, and Rhodanobacter. Similar results were reported in our previous study [43]: Chitinophaga, Flavobacterium, and Chryseobacterium were more abundant in the rhizosphere of diseased plants infected by R. solani AG8 than those of healthy plants. Moreover, some strains of Flavobacterium and Chryseobacterium produce antimicrobial compounds and stimulate plant immune systems and have been used as bioremediation agents [68]. Most recently, Nishioka et al. [69] recovered Flavobacterium species from the rhizosphere soils of the Allium plants that suppressed Fusarium wilt on cucumber seedlings and demonstrated that the Flavobacterium isolates inhibited the multiplication of the pathogen in soil. Flavobacterium was also found to be one of the most abundant bacterial genera present in the soil of banana fields in which Fusarium wilt decline had occurred [70]. The genus Serratia belongs to the family Enterobacteriaceae within the Gammaproteobacteria. Serratia plymuthica is a ubiquitous gram-negative bacterium, most frequently associated with plants and used as a broad-spectrum biocontrol agent because it produces antimicrobial compounds [71-73] and was successfully developed as a commercial product called Rhizostar (produced by E-nema GmbH Raisdorf, Germany). Recently Serratia marcescens was found to produce several hydrolytic enzymes and showed antagonistic activity against eight fungal pathogens of tea [74]. In contrast, genera Bacillus, Duganella and Lysobacter were more highly abundant in the rhizosphere soil without AG8 infection. Some strains of Bacillus can suppress pathogen-derived microbe-associated molecular patterns (MAMPs)-triggered root immune responses and protect Arabidopsis against pathogens [75]. In a previous field study [43] Duganella was more abundant in diseased plant rhizospheres, indicating Duganella may have different behavior in specific conditions. Lysobacter is a chitinolytic bacterium and has a potential antagonistic activity against Rhizoctonia and nematodes [76-78]. Collectively, the data indicate that upon pathogen attack, pathogen-stressed plants may undergo changes in metabolic pathways and modulate the chemical composition of their rhizospheres, which recruit beneficial and antagonistic bacterial communities. The accumulation of antagonistic microbes can protect plants against the pathogens that initiated the recruitment. In addition, the abundance of other genera was also changed by AG8 infection in this study. Most of them are non-antagonistic bacteria or their biological functions are still unknown. Interestingly, Fujiwara et al. [79] reported that a community of seven non-antagonistic bacterial strains, including one Kaistia strain, suppressed the fungal phytopathogen Fusarium oxysporum and morphological observations showed the formation of swollen F. oxysporum cells in the presence of these bacterial pairs. It demonstrated that a complex interactions among apparently non-antagonistic bacteria can result in antagonism against pathogens. Thus, these uncharacterized emergent functions of bacterial consortia may also contribute to suppression activities but require further investigation. Taken together, our results provided further evidence that under the pressure of pathogen attack, plants can enrich beneficial microorganisms to suppress pathogens in the rhizosphere.
In our multi-cycle selection system, wheat seedlings with roots showing relatively more or less disease to R. solani AG8 were screened from each cycle and used as rhizosphere inoculants for the following cycle, thus forming the two groups, ‘Good’ (G) (the least wheat root disease) treatment and ‘Bad’ (B) (the worst wheat root disease) treatment. In the first two cycles, wheat displayed severe stunting. Starting from the cycle 3, suppressiveness to AG8 gradually developed and was notable by cycle 5, but the disease severity was still variable among four replicates from ‘Good’ or ‘Bad’ treatments. To achieve uniform disease symptoms among replicates, the planting was continued and by the 9th cycle all wheat plants of two treatments were tolerant to AG8 infection, but the ‘Good’ treatment showed slightly less disease symptoms than the ‘Bad’ treatment. Consistent with the disease phenotype, sequence analysis found that the microbial communities separated gradually over the growth cycles. The different quantities of diseased roots likely affect the microbial community composition, but other factors may also contribute. Although care was taken to water the plant containers equally, those with more severe root disease had reduced root systems and typically retained more moisture towards the end of the cycles. Thus, water content may influence soil microbiomes and the development of suppressive soils, something which should be addressed further. Furthermore, DESeq2 analysis found that some OTUs were differentially abundant in the rhizosphere soil between ‘Good’ (G) and ‘Bad’ (B) treatment in both cycle 2 and cycle 9. Interestingly, the ‘Good’ treatment in cycles 2 and 9 were highly enriched the antagonistic microbe OTU19 belonged to genera Flavobacterium [69]. In addition, a group of plant growth-promoting (PGP) microbes, including Rhizobium, Pedobacter, and Variovorax, were highly abundant in the rhizosphere soil from ‘Good’ (G) treatment in cycle 9. PGP microbes have shown potential to promote plant growth at different stages via a wide variety of mechanisms [80]. For example, Rhizobium is a gram-negative soil bacterium and promotes plant growth through establishing nitrogen-fixing symbiosis with leguminous plants and increasing soil fertility [81]. Another PGP microbe, Pedobacter is also capable of colonizing roots of many crops, such as oilseed rape, potato, and strawberry, and could be used as a biofertilizer [82-84]. Variovorax is a metabolically diverse genus of plant growth-promoting rhizobacteria which belongs to the family Comamonadaceae. Variovorax sp. promoted plant growth via producing plant growth substances and enzymes such as siderophores and ACC deaminase [86]. These results suggest that both antagonistic and PGP microbes might contribute to improve wheat growth and tolerance to AG8. It is widely accepted that root exudates play a crucial role in the establishment of the root microbiome [87-88] and different root exudates are thought to secrete chemical compounds to select specific microbial populations. In our study, although the same wheat cultivar was used, continuous screening of wheat with more tolerance or susceptibility to AG8 might change the components or amounts of chemical compounds or root signals which attract favorite microorganisms [33, 89]. Further efforts to analyze root exudate composition of each cycle may greatly improve our understanding of the role of plants on the changes of microbial communities and elucidate the mechanisms underlying the recruitment of antagonistic bacteria by plant, and eventually lead to the development of eco-friendly soilborne pathogens management strategies.
In vitro bacterial isolation and antifungal capability testing found that eleven of 35 bacterial species inhibited the growth of R. solani AG8 in vitro. Six of them suppressed R. oryzae and only one for Pythium ultimum. Testing further indicated that AG8 infection is a major driver for the colonization of those antagonistic isolates. Most of them, such as Pseudomonas, Streptomyces, and Chryseobacterium, have been well-documented as pathogen suppressive [43, 52, 62]. Interestingly, a Janthinobacterium produces a dark-purple compound, violacein [85]. More dark-purple colonies were observed in the rhizosphere from ‘Good’ (G) treatment (the least disease rhizosphere soil) than those from ‘Bad’ (B) treatment (the worst disease rhizosphere soil), indicating Janthinobacterium was more highly associated with rhizospheres of plants more tolerant to AG8. Janthinobacterium is a gram-negative aerobic bacterium, which belong to the family Oxalobacteraceae of the Class Betaproteobacteria and commonly exist in soil and aquatic habitats. As a secondary metabolite, violacein has been reported to have antifungal effects [90-91]. However, Haack et al. [92] revealed that violacein was not the primary cause of the fungal growth inhibition by expressing violacein encoded gene vioABCDE in E. coli which had no significant inhibition on Fusarium graminearum growth and further observed that the fungal growth inhibition was independent of the amount of violacein. Our antifungal capabilities test showed that Janthinobacterium has a broad-spectrum antagonism against soilborne pathogens R. solani AG8, R. oryzae, and Pythium ultimum. Further greenhouse assays discovered that Janthinobacterium has antagonistic activity against AG8 in soil. Microbial communities have many potential applications in agriculture and medicine, such as pathogen suppression and environmental remediation. With more antagonistic and plant growth promoting (PGP) microbes being discovered and isolated, synthetic microbial communities might provide plants with stronger disease resistance and growth promotion than single species, thus become more powerful biotechnological tools to improve the sustainability of agro-ecosystems [93]. Our results will provide valuable resources for the development and testing of synthetic microbial consortia in the future.