Genomic and Chemical Diversity of Bacillus subtilis Secondary Metabolites against Plant Pathogenic Fungi

Kiesewalter, Heiko T.; Lozano-Andrade, Carlos N.; Wibowo, Mario; Strube, Mikael Lenz; Maróti, Gergely; Snyder, Dan; Jørgensen, Tue Sparholt; Larsen, Thomas Ostenfeld; Cooper, Vaughn S.; Weber, Tilmann; Kovács, Ákos T.

doi:10.1128/msystems.00770-20

Cited by 77 publications

(76 citation statements)

References 70 publications

(77 reference statements)

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“…The so-called dual-culture assay is among the most common screening methods to identify potent fungal inhibitors from microbial collections [17,21,30–32]. Typically, the assay is performed by inoculating potential biocontrol agents at a fixed distance from the pathogenic fungal inoculum on a petri dish as illustrated in Fig.…”

Section: Resultsmentioning

confidence: 99%

Development of quantitative high-throughput screening methods for identification of antifungal biocontrol strains

Kjeldgaard

Ar²,

Fonseca

et al. 2021

Preprint

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Large screens of bacterial strain collections to identify potential biocontrol agents are often time consuming, costly, and fail to provide quantitative results. In this study, we present two quantitative and high-throughput methods to assess the inhibitory capacity of bacterial biocontrol candidates against fungal phytopathogens. One method measures the inhibitory effect of bacterial culture supernatant components on the fungal growth, while the other accounts for direct interaction between growing bacteria and the fungus by co-cultivating the two organisms. The antagonistic supernatant method quantifies the culture components’ antifungal activity by calculating the cumulative impact of supernatant addition relative to a non-treated fungal control, while the antagonistic co-cultivation method identifies the minimal bacterial cell concentration required to inhibit fungal growth by co-inoculating fungal spores with bacterial culture dilution series. Thereby, both methods provide quantitative measures of biocontrol efficiency and allow prominent fungal inhibitors to be distinguished from less effective strains. The combination of the two methods shed light on the type of inhibition mechanisms and provide the basis for further mode of action studies. We demonstrate the efficacy of the methods using Bacillus spp. with different levels of antifungal activities as model antagonists and quantify their inhibitory potency against classic plant pathogens.ImportanceFungal phytopathogens are responsible for tremendous agricultural losses on annual basis. While microbial biocontrol agents represent a promising solution to the problem, there is a growing need for high-throughput methods to evaluate and quantify inhibitory properties of new potential biocontrol agents for agricultural application. In this study, we present two high-throughput and quantitative fungal inhibition methods that are suitable for commercial biocontrol screening.

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Section: Resultsmentioning

confidence: 99%

Development of quantitative high-throughput screening methods for identification of antifungal biocontrol strains

Kjeldgaard

Ar²,

Fonseca

et al. 2021

Preprint

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“…One class of metabolic features, which differed in later stages of interaction between S. plymuthica 4Rx13 and B. subtilis B2g belonged to compounds of the plipastatin family. Plipastatins are bioactive lipopeptides produced by isolates of Bacillus subtilis isolates (Nishikiori et al, 1986;Ongena et al, 2007;Hussein, 2019), mainly known for their striking antifungal activity (Kaspar et al, 2019;Kiesewalter et al, 2021). They occur as various isomers characterized by different structures (A1, A2, B1, and B2; Kaspar et al, 2019) of whom only specific isomers were increasingly produced by B. subtilis B2g in the cocultivation with S. plymuthica 4Rx13.…”

Section: S Plymuthica 4rx13 and B Subtilis B2gmentioning

confidence: 99%

Metabolic Profiling of Rhizobacteria Serratia plymuthica and Bacillus subtilis Revealed Intra- and Interspecific Differences and Elicitation of Plipastatins and Short Peptides Due to Co-cultivation

et al. 2021

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Rhizobacteria live in diverse and dynamic communities having a high impact on plant growth and development. Due to the complexity of the microbial communities and the difficult accessibility of the rhizosphere, investigations of interactive processes within this bacterial network are challenging. In order to better understand causal relationships between individual members of the microbial community of plants, we started to investigate the inter- and intraspecific interaction potential of three rhizobacteria, the S. plymuthica isolates 4Rx13 and AS9 and B. subtilis B2g, using high resolution mass spectrometry based metabolic profiling of structured, low-diversity model communities. We found that by metabolic profiling we are able to detect metabolite changes during cultivation of all three isolates. The metabolic profile of S. plymuthica 4Rx13 differs interspecifically to B. subtilis B2g and surprisingly intraspecifically to S. plymuthica AS9. Thereby, the release of different secondary metabolites represents one contributing factor of inter- and intraspecific variations in metabolite profiles. Interspecific co-cultivation of S. plymuthica 4Rx13 and B. subtilis B2g showed consistently distinct metabolic profiles compared to mono-cultivated species. Thereby, putative known and new variants of the plipastatin family are increased in the co-cultivation of S. plymuthica 4Rx13 and B. subtilis B2g. Interestingly, intraspecific co-cultivation of S. plymuthica 4Rx13 and S. plymuthica AS9 revealed a distinct interaction zone and showed distinct metabolic profiles compared to mono-cultures. Thereby, several putative short proline-containing peptides are increased in co-cultivation of S. plymuthica 4Rx13 with S. plymuthica AS9 compared to mono-cultivated strains. Our results demonstrate that the release of metabolites by rhizobacteria alters due to growth and induced by social interactions between single members of the microbial community. These results form a basis to elucidate the functional role of such interaction-triggered compounds in establishment and maintenance of microbial communities and can be applied under natural and more realistic conditions, since rhizobacteria also interact with the plant itself and many other members of plant and soil microbiota.

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“…Furthermore, studying biofilms is of special interest due to their detrimental impact in clinical and industrial settings (Di Pippo et al, 2018; Stewart, 2002) as well as their promising potential within the biotechnology industry (Blake et al, 2021; Singh et al, 2006). Regarding the latter, the gram‐positive bacterium Bacillus subtilis has in the last two decades gained interest due to its promising potential as a biocontrol agent within agriculture (Kiesewalter et al, 2021; Ongena & Jacques, 2008). In its natural habitat, the soil‐dwelling bacterium colonizes plants by forming a biofilm on the root (Bais et al, 2004; Beauregard et al, 2013; Chen et al, 2012).…”

Section: Introductionmentioning

confidence: 99%

“…Regarding the latter, the gram-positive bacterium Bacillus subtilis has in the last two decades gained interest due to its promising potential as a biocontrol agent within agriculture (Kiesewalter et al, 2021;Ongena & Jacques, 2008). In its natural habitat, the soildwelling bacterium colonizes plants by forming a biofilm on the root (Bais et al, 2004;Beauregard et al, 2013;Chen et al, 2012).…”

Section: Introductionmentioning

confidence: 99%

Deletion of Rap‐Phr systems in Bacillus subtilis influences in vitro biofilm formation and plant root colonization

et al. 2021

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Natural isolates of the soil‐dwelling bacterium Bacillus subtilis form robust biofilms under laboratory conditions and colonize plant roots. B. subtilis biofilm gene expression displays phenotypic heterogeneity that is influenced by a family of Rap‐Phr regulatory systems. Most Rap‐Phr systems in B. subtilis have been studied independently, in different genetic backgrounds and under distinct conditions, hampering true comparison of the Rap‐Phr systems’ impact on bacterial cell differentiation. Here, we investigated each of the 12 Rap‐Phr systems of B.subtilis NCIB 3610 for their effect on biofilm formation. By studying single ∆ rap ‐ phr mutants, we show that despite redundancy between the cell–cell communication systems, deletion of each of the 12 Rap‐Phr systems influences matrix gene expression. These Rap‐Phr systems therefore enable fine‐tuning of the timing and level of matrix production in response to specific conditions. Furthermore, some of the ∆ rap ‐ phr mutants demonstrated altered biofilm formation in vitro and colonization of Arabidopsis thaliana roots, but not necessarily similarly in both processes, indicating that the pathways regulating matrix gene expression and other factors important for biofilm formation may be differently regulated under these distinct conditions.

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Genomic and Chemical Diversity of Bacillus subtilis Secondary Metabolites against Plant Pathogenic Fungi

Cited by 77 publications

References 70 publications

Development of quantitative high-throughput screening methods for identification of antifungal biocontrol strains

Development of quantitative high-throughput screening methods for identification of antifungal biocontrol strains

Metabolic Profiling of Rhizobacteria Serratia plymuthica and Bacillus subtilis Revealed Intra- and Interspecific Differences and Elicitation of Plipastatins and Short Peptides Due to Co-cultivation

Deletion of Rap‐Phr systems in Bacillus subtilis influences in vitro biofilm formation and plant root colonization

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