Biocontrol of Bacterial Wilt Disease Through Complex Interaction Between Tomato Plant, Antagonists, the Indigenous Rhizosphere Microbiota, and Ralstonia solanacearum

Elsayed, Tarek; Jacquiod, Samuel; Nour, Eman; Sørensen, Søren J.; Smalla, Kornelia

doi:10.3389/fmicb.2019.02835

Cited by 82 publications

(45 citation statements)

References 65 publications

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“…For example, Arabidopsis roots in response to a leaf pathogen infection attract Bacillus subtilis into the rhizosphere 49 . In the current study, the most enrichment in IT20 samples was recorded for the genus Devosia affiliated to Gammaproteobacteria, it was previously described that this genus is increased in response to B. velezensis and P. fluorescens , involved in biocontrol activity against R. solanacearum on tomato 50 . Another increase in relative abundance was recorded for the genus Gallionella that was previously described as a member of the core microbiome of the wheat healthy plant 23 .…”

Section: Discussionsupporting

confidence: 56%

Streptomyces strains modulate dynamics of soil bacterial communities and their efficacy in disease suppression caused by Phytophthora capsici

Abbasi

Spor

Sadeghi

et al. 2021

Sci Rep

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The responses of rhizosphere bacterial communities of Streptomyces (SS14 and IT20 stains) treated-pepper plants following inoculation by Phytophthora capsici (PC) was investigated using Illumina MiSeq sequencing. Distinct modulation of the bacteriome composition was found for PC samples with the highest relative abundance (RA) of Chitinophaga (22 ± 0.03%). The RA of several bacterial operational taxonomic units (OTUs) was affected and caused changes in alpha and beta-diversity measures. In IT20, the RA of Cyanobacteria was enriched compared to SS14 (72%) and control samples (47%). Phylotypes belonging to Devosia, Promicromonospora, Kribbella, Microbacterium, Amylocolatopsis, and Pseudomonas genera in the rhizosphere were positively responding against the pathogen. Our findings show that the phosphate solubilizing strain IT20 has higher microbial community responders than the melanin-producing strain SS14. Also, positive interactions were identified by comparing bacterial community profiles between treatments that might allow designing synthetic bio-inoculants to solve agronomic problems in an eco-friendly way.

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Section: Discussionsupporting

confidence: 56%

Streptomyces strains modulate dynamics of soil bacterial communities and their efficacy in disease suppression caused by Phytophthora capsici

Abbasi

Spor

Sadeghi

et al. 2021

Sci Rep

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“…The treatments of P. fluorescens Pf3 + T. longibrachiatum UNS11 were recorded highest wilt protection of 62% as compared to control treatment (97%). Our research outcomes authenticate earlier reports that in the control of bacterial wilt, the use of beneficial microbes in combination treatments was more effective than individual agents (Thilagavathi et al 2007 andElsayed et al 2020). The present results agreed with the R. solanacearum wilt disease reduction in tomato plants by treatment with Bacillus sp.…”

Section: Effect Of Seed Treatment Combination With Pgpr and Trichodersupporting

confidence: 89%

Efficacy of indigenous plant growth-promoting rhizobacteria and Trichoderma strains in eliciting resistance against bacterial wilt in a tomato

Konappa

Krishnamurthy

Arakere

et al. 2020

Egypt J Biol Pest Control

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Bacterial wilt of tomato caused by Ralstonia solanacearum is a serious threat to tomato production worldwide. For eco-friendly management of bacterial wilt of tomato, the rhizospheric microorganisms belonging to the genera Bacillus (6 isolates), Brevibacillus (1 isolate), Pseudomonas (3 isolates), and Trichoderma (8 isolates) were studied for their ability to induce innate immunity in tomato, individually and in combination against R. solanacearum in greenhouse and field studies. In laboratory studies, maximum germination percent of 93%, vigor index of 1609 was noted in seed bacterization with P. fluorescens Pf3, followed by 91% germination, vigor index of 1593 in treatment with T. asperellum T8 over control. Under greenhouse conditions, protection against bacterial wilt in individual treatments with PGPRs ranged from 38 to 43% and Trichoderma sp. ranged from 39 to 43% in comparison to control. In comparison to individual seed treatment, among different combinations, maximum seed germination percent of 97% was recorded with combination P. fluorescens Pf3 + T. longibrachiatumUNS11. In greenhouse studies' combination seed treatment with P. fluorescens Pf3 + T. longibrachiatumUNS11 offered an impressive 62% protection against bacterial wilt over control. Similarly, under field conditions, seed treatment with P. fluorescens Pf3 + T. longibrachiatumUNS11 resulted in 61% protection. The innate immunity triggered by eco-friendly seed treatment was analyzed by expression to defense-related enzymes such as peroxidase, phenylalanine ammonialyase, and polyphenol oxidase in comparison to control. This study indicated that the potential benefits of using combination treatments of beneficial microorganisms in effectively inducing resistance are possible for dual benefits of enhanced plant growth, tomato yield, and pathogen suppression.

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“…However, the majority of studies revealed only transient establishment or low abundance of the microbial inoculants during plant growth ( Scherwinski et al, 2008 ; Schreiter et al, 2014b ; Eltlbany et al, 2019 ). In order to understand establishment efficiency, it is important to consider rhizosphere and rhizoplane colonization patterns of the inoculant ( Götz et al, 2006 ; Elsayed et al, 2020 ). A successful establishment depends on strain traits ( Adesina et al, 2009 ), application mode ( Götz et al, 2006 ; Schmidt et al, 2012 ), and on the structure of the target microbiome ( van Elsas et al, 2012 ).…”

Section: Interactions Of Microbial Inoculants With the Plant And Its Microbiomementioning

confidence: 99%

“…Similar effects were observed in tomato plants infected with Ralstonia solanacearum B3B through the inoculation of Bacillus velezensis B63 or Pseudomonas fluorescens P142. Here, a microbiome shift toward genera that comprise multiple strains with plant growth promoting activity such as Arthrobacter and Gaiella (Actinobacteria ) or Ochrobactrum ( Alphaproteobacteria ) was observed ( Elsayed et al, 2020 ). Fusarium stalk rot in maize caused by Fusarium graminearum can be controlled via application of Trichoderma harzianum CCTCC-RW0024, which resulted in an increase of plant growth promoting Acidobacteria ( Saravanakumar et al, 2017 ).…”

Section: Interactions Of Microbial Inoculants With the Plant And Its Microbiomementioning

confidence: 99%

“…Representative isolates of the health indicators ( Brevibacterium frigoritolerans HRS1, Bacillus niacini HRS2, Solibacillus silvestris HRS3, and Bacillus luciferensis HRS4) were able to induce an immune activation and extended plant protection against R. solanacearum. In addition, several studies described the depletion of potential pathogens due to inoculant application ( Schmidt et al, 2012 ; Saravanakumar et al, 2017 ; Elsayed et al, 2020 ). These studies provide indications that depletion of pathogens might be an accompanying effect to the enrichment of plant-beneficial strains, which together constitutes the observed microbiome shifts.…”

Section: Interactions Of Microbial Inoculants With the Plant And Its Microbiomementioning

confidence: 99%

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Microbiome Modulation—Toward a Better Understanding of Plant Microbiome Response to Microbial Inoculants

et al. 2021

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Plant-associated microorganisms are involved in important functions related to growth, performance and health of their hosts. Understanding their modes of action is important for the design of promising microbial inoculants for sustainable agriculture. Plant-associated microorganisms are able to interact with their hosts and often exert specific functions toward potential pathogens; the underlying in vitro interactions are well studied. In contrast, in situ effects of inoculants, and especially their impact on the plant indigenous microbiome was mostly neglected so far. Recently, microbiome research has revolutionized our understanding of plants as coevolved holobionts but also of indigenous microbiome-inoculant interactions. Here we disentangle the effects of microbial inoculants on the indigenous plant microbiome and point out the following types of plant microbiome modulations: (i) transient microbiome shifts, (ii) stabilization or increase of microbial diversity, (iii) stabilization or increase of plant microbiome evenness, (iv) restoration of a dysbiosis/compensation or reduction of a pathogen-induced shift, (v) targeted shifts toward plant beneficial members of the indigenous microbiota, and (vi) suppression of potential pathogens. Therefore, we suggest microbiome modulations as novel and efficient mode of action for microbial inoculants that can also be mediated via the plant.

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Biocontrol of Bacterial Wilt Disease Through Complex Interaction Between Tomato Plant, Antagonists, the Indigenous Rhizosphere Microbiota, and Ralstonia solanacearum

Cited by 82 publications

References 65 publications

Streptomyces strains modulate dynamics of soil bacterial communities and their efficacy in disease suppression caused by Phytophthora capsici

Streptomyces strains modulate dynamics of soil bacterial communities and their efficacy in disease suppression caused by Phytophthora capsici

Efficacy of indigenous plant growth-promoting rhizobacteria and Trichoderma strains in eliciting resistance against bacterial wilt in a tomato

Microbiome Modulation—Toward a Better Understanding of Plant Microbiome Response to Microbial Inoculants

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