Plants and Associated Soil Microbiota Cooperatively Suppress Plant-Parasitic Nematodes

Topalović, Olivera; Hussain, Muzammil; Heuer, Holger

doi:10.3389/fmicb.2020.00313

Cited by 142 publications

(118 citation statements)

References 138 publications

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“…Above 12 compostpeat mixtures, only CM -10% was able to suppress PHC, due to its microbial composition that can play a major role in its suppressiveness (Reuveni et al, 2002;Tilston et al, 2002;Papasotiriou et al, 2013;De Corato et al, 2019). The mycobiota composition of the CM -10% treated pots clustered separately if compared to CC and UC, confirming that beneficial microorganisms present in CM -10% treatment can protect the plant root system by microbiota modulation (Antoniou et al, 2017;Mwaheb et al, 2017;Cucu et al, 2019;Topalović et al, 2020;Zhang et al, 2020). Further investigations should be necessary to obtain a deeper understanding of how this protection is conferred because the complex interaction between rhizosphere, microbiota and pathogens is less explored.…”

Section: Resultsmentioning

confidence: 86%

“…Among the various organic amendments, compost has been studied the most and has been used because of its suppressiveness activity (Pugliese et al, 2015;Bonanomi et al, 2018). The phenomenon of suppressiveness is the ability to limit or avoid the spread of a disease where both susceptible crop variety and pathogen are present in the field; this is connected with the available amount or the addition of organic matter and the ability of the seeds and roots to establish a connection with diverse microorganisms present in the soil that uptake exudates and, consequently, limit the outbreak of pathogens and parasites (Topalović et al, 2020).…”

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confidence: 99%

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A Compost Treatment Acts as a Suppressive Agent in Phytophthora capsici – Cucurbita pepo Pathosystem by Modifying the Rhizosphere Microbiota

et al. 2020

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Section: Resultsmentioning

confidence: 86%

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confidence: 99%

A Compost Treatment Acts as a Suppressive Agent in Phytophthora capsici – Cucurbita pepo Pathosystem by Modifying the Rhizosphere Microbiota

et al. 2020

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“…However, both organisms also affect each other indirectly through their effects on the host or each other. Rhizobia as well as a number of other soil bacteria often contribute to preventing plant infection by parasitic nematodes, and this can involve changes in plant (systemic) defenses, root exudates that affect both organisms, while some bacteria and fungi can also directly kill or trap nematodes ( Topalović et al., 2020 ). Thus, we were interested to see what effect rhizobia had on nematode gall formation and if this was controlled by any of the selected nodulation genes.…”

Section: Discussionmentioning

confidence: 99%

“…We found that the number of galls formed were influenced by concurrent inoculation with rhizobia, however, this was only significant in WT plants. The observed drop in gall numbers in rhizobia-coinoculated roots could be due to changes in defense, exudation or other responses in the root induced by rhizobia ( Zamioudis and Pietersé, 2012 ; Topalović et al., 2020 ), but it could also be due to resource competition of the established organs, as both nodules and galls act as nutrient sinks in the root ( Carneiro et al., 1999 ; Voisin et al., 2003 ). While resource competition between nodules and galls could account for the drop in galls in WT roots, this drop was not seen in other genotypes that nodulated even better, e.g.…”

Section: Discussionmentioning

confidence: 99%

Infection of Medicago truncatula by the Root-Knot Nematode Meloidogyne javanica Does Not Require Early Nodulation Genes

2020

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Because of the developmental similarities between root nodules induced by symbiotic rhizobia and root galls formed by parasitic nematodes, we investigated the involvement of nodulation genes in the infection of Medicago truncatula by the root knot nematode (RKN), Meloidogyne javanica. We found that gall formation, including giant cell formation, pericycle and cortical cell division, as well as egg laying, occurred successfully in the nonnodulating mutants nfp1 (nod factor perception1), nin1 (nodule inception1) and nsp2 (nodulation signaling pathway2) and the cytokinin perception mutant cre1 (cytokinin receptor1). Gall and egg formation were significantly reduced in the ethylene insensitive, hypernodulating mutant skl (sickle), and to a lesser extent, in the low nodulation, abscisic acid insensitive mutant latd/nip (lateral root-organ defective/numerous infections and polyphenolics). Despite its supernodulation phenotype, the sunn4 (super numeric nodules4) mutant, which has lost the ability to autoregulate nodule numbers, did not form excessive numbers of galls. Co-inoculation of roots with nematodes and rhizobia significantly reduced nodule numbers compared to rhizobia-only inoculated roots, but only in the hypernodulation mutant skl. Thus, this effect is likely to be influenced by ethylene signaling, but is not likely explained by resource competition between galls and nodules. Co-inoculation with rhizobia also reduced gall numbers compared to nematodeonly infected roots, but only in the wild type. Therefore, the protective effect of rhizobia on nematode infection does not clearly depend on nodule number or on Nod factor signaling. Our study demonstrates that early nodulation genes that are essential for successful nodule development are not necessary for nematode-induced gall formation, that gall formation is not under autoregulation of nodulation control, and that ethylene signaling plays a positive role in successful RKN parasitism in M. truncatula.

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“…Despite the importance of this plant parasite, and its close ties with its cohabiting microbiome, microbial ecology studies utilizing deep sequencing approaches are a handful. Only a few studies have attempted to characterize the taxonomic and functional core microbiota [34,35] , or tie the microbial community composition in the soil or plant with RKN suppressiveness [36][37][38][39] . In such studies, temporal dynamics of the microbiome in each of the various niches the nematode occupy at its different life stages, or along the crop season, is not often considered.…”

Section: Introductionmentioning

confidence: 99%

The bacterial community structure dynamics inMeloidogyne incognitainfected roots and its role in worm-microbiome interactions

Yergaliyev

Alexander-Shani

Dimeretz

et al. 2020

Preprint

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BackgroundPlant parasitic nematodes such as Meloidogyne incognita have a complex life cycle, occurring sequentially in various niches of the root and rhizosphere. They are known to form a range of interactions with bacteria and other microorganisms, that can affect their densities and virulence. High throughput sequencing can reveal these interactions in high temporal, and geographic resolutions, although thus far we have only scratched the surface. We have carried out a longitudinal sampling scheme, repeatedly collecting rhizosphere soil, roots, galls and second stage juveniles from 20 plants to provide a high resolution view of bacterial succession in these niches, using 16S rRNA metabarcoding. ResultsWe find that a structured community develops in the root, in which gall communities diverge from root segments lacking a gall, and that this structure is maintained throughout the crop season. We detail the successional process leading toward this structure, which is driven by interactions with the nematode and later by an increase in bacteria often found in hypoxic and anaerobic environments.We show evidence that this structure may play a role in the nematode's chemotaxis towards 1 uninfected root segments. Finally, we describe the J2 epibiotic microenvironment as ecologically deterministic, in part, due to active bacterial attraction of second stage juveniles. ConclusionsHigh density sampling, both temporally and across adjacent microniches, coupled with the power and relative low cost of metabarcoding, has provided us with a high resolution description of our study system. Such an approach can advance our understanding of holobiont ecology. Meloidogyne spp., with their relatively low genetic diversity, large geographic range and the simplified agricultural ecosystems they occupy, can serve as a model organism. Additionally, the perspective this approach provides could promote the efforts toward biological control efficacy.

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Plants and Associated Soil Microbiota Cooperatively Suppress Plant-Parasitic Nematodes

Cited by 142 publications

References 138 publications

A Compost Treatment Acts as a Suppressive Agent in Phytophthora capsici – Cucurbita pepo Pathosystem by Modifying the Rhizosphere Microbiota

A Compost Treatment Acts as a Suppressive Agent in Phytophthora capsici – Cucurbita pepo Pathosystem by Modifying the Rhizosphere Microbiota

Infection of Medicago truncatula by the Root-Knot Nematode Meloidogyne javanica Does Not Require Early Nodulation Genes

The bacterial community structure dynamics inMeloidogyne incognitainfected roots and its role in worm-microbiome interactions

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