The Ectomycorrhizospheric Habitat of Norway Spruce and Tricholoma vaccinum: Promotion of Plant Growth and Fitness by a Rich Microorganismic Community.
Identifieur interne : 000058 ( Main/Exploration ); précédent : 000057; suivant : 000059The Ectomycorrhizospheric Habitat of Norway Spruce and Tricholoma vaccinum: Promotion of Plant Growth and Fitness by a Rich Microorganismic Community.
Auteurs : Katharina Wagner [Allemagne] ; Katrin Krause [Allemagne] ; Ramses Gallegos-Monterrosa [Allemagne] ; Dominik Sammer [Allemagne] ; Ákos T. Kovács [Allemagne] ; Erika Kothe [Allemagne]Source :
- Frontiers in microbiology [ 1664-302X ] ; 2019.
Abstract
The contribution of the mycorrhizospheric microbes in a stand of ectomycorrhizal Norway spruce (Picea abies) featuring mycorrhiza with the basidiomycete Tricholoma vaccinum was addressed by microbiome analysis and in vitro reconstruction of microbial as well as plant-microbe interactions. The protective role of the mycorrhizal fungus with respect to pathogen attack could be validated against Botrytis cinerea and Heterobasidion annosum in co-cultures revealing reduced pathogen growth, higher survival rate of the spruce trees and reduced symptoms on needles upon symbiosis with T. vaccinum. The community structure was shown to yield a high diversity in ECM forming basidiomycetes of Thelephorales and Agaricales associated with a rich bacterial diversity dominated by Rhizobiales with the most abundant Nitrobacter winogradski (3.9%). Isolated bacteria were then used to address plant growth promoting abilities, which included production of the phytohormone indole-3-acetic acid (performed by 74% of the bacterial isolates), siderophores (22%), and phosphate mobilization (23%). Among the isolates, mycorrhiza helper bacteria (MHB) were identified, with Bacillus cereus MRZ-1 inducing hyperbranching in T. vaccinum, supporting tree germination, shoot elongation, and root formation as well as higher mycorrhization rates. Thus, a huge pool of potential MHB and fungal community with widely distributed auxin-production potential extended the ability of T. vaccinum to form ectomycorrhiza. The forest community profited from the mycorrhizal fungus T. vaccinum, with spruce survival enhanced by 33% in microcosms using soil from the native habitat. A higher fungal abundance and diversity in cases where the tree had died during the experiment, showing that decomposition of plant litter from a dead tree supported a different community. T. vaccinum thus actively structured the community of microorganisms in its habitat.
DOI: 10.3389/fmicb.2019.00307
PubMed: 30842767
PubMed Central: PMC6391851
Affiliations:
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<front><div type="abstract" xml:lang="en">The contribution of the mycorrhizospheric microbes in a stand of ectomycorrhizal Norway spruce (<i>Picea abies</i>
) featuring mycorrhiza with the basidiomycete <i>Tricholoma vaccinum</i>
was addressed by microbiome analysis and <i>in vitro</i>
reconstruction of microbial as well as plant-microbe interactions. The protective role of the mycorrhizal fungus with respect to pathogen attack could be validated against <i>Botrytis cinerea</i>
and <i>Heterobasidion annosum</i>
in co-cultures revealing reduced pathogen growth, higher survival rate of the spruce trees and reduced symptoms on needles upon symbiosis with <i>T. vaccinum.</i>
The community structure was shown to yield a high diversity in ECM forming basidiomycetes of <i>Thelephorales</i>
and <i>Agaricales</i>
associated with a rich bacterial diversity dominated by <i>Rhizobiales</i>
with the most abundant <i>Nitrobacter winogradski</i>
(3.9%). Isolated bacteria were then used to address plant growth promoting abilities, which included production of the phytohormone indole-3-acetic acid (performed by 74% of the bacterial isolates), siderophores (22%), and phosphate mobilization (23%). Among the isolates, mycorrhiza helper bacteria (MHB) were identified, with <i>Bacillus cereus</i>
MRZ-1 inducing hyperbranching in <i>T. vaccinum</i>
, supporting tree germination, shoot elongation, and root formation as well as higher mycorrhization rates. Thus, a huge pool of potential MHB and fungal community with widely distributed auxin-production potential extended the ability of <i>T. vaccinum</i>
to form ectomycorrhiza. The forest community profited from the mycorrhizal fungus <i>T. vaccinum</i>
, with spruce survival enhanced by 33% in microcosms using soil from the native habitat. A higher fungal abundance and diversity in cases where the tree had died during the experiment, showing that decomposition of plant litter from a dead tree supported a different community. <i>T. vaccinum</i>
thus actively structured the community of microorganisms in its habitat.</div>
</front>
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<ArticleTitle>The Ectomycorrhizospheric Habitat of Norway Spruce and <i>Tricholoma vaccinum</i>
: Promotion of Plant Growth and Fitness by a Rich Microorganismic Community.</ArticleTitle>
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<Abstract><AbstractText>The contribution of the mycorrhizospheric microbes in a stand of ectomycorrhizal Norway spruce (<i>Picea abies</i>
) featuring mycorrhiza with the basidiomycete <i>Tricholoma vaccinum</i>
was addressed by microbiome analysis and <i>in vitro</i>
reconstruction of microbial as well as plant-microbe interactions. The protective role of the mycorrhizal fungus with respect to pathogen attack could be validated against <i>Botrytis cinerea</i>
and <i>Heterobasidion annosum</i>
in co-cultures revealing reduced pathogen growth, higher survival rate of the spruce trees and reduced symptoms on needles upon symbiosis with <i>T. vaccinum.</i>
The community structure was shown to yield a high diversity in ECM forming basidiomycetes of <i>Thelephorales</i>
and <i>Agaricales</i>
associated with a rich bacterial diversity dominated by <i>Rhizobiales</i>
with the most abundant <i>Nitrobacter winogradski</i>
(3.9%). Isolated bacteria were then used to address plant growth promoting abilities, which included production of the phytohormone indole-3-acetic acid (performed by 74% of the bacterial isolates), siderophores (22%), and phosphate mobilization (23%). Among the isolates, mycorrhiza helper bacteria (MHB) were identified, with <i>Bacillus cereus</i>
MRZ-1 inducing hyperbranching in <i>T. vaccinum</i>
, supporting tree germination, shoot elongation, and root formation as well as higher mycorrhization rates. Thus, a huge pool of potential MHB and fungal community with widely distributed auxin-production potential extended the ability of <i>T. vaccinum</i>
to form ectomycorrhiza. The forest community profited from the mycorrhizal fungus <i>T. vaccinum</i>
, with spruce survival enhanced by 33% in microcosms using soil from the native habitat. A higher fungal abundance and diversity in cases where the tree had died during the experiment, showing that decomposition of plant litter from a dead tree supported a different community. <i>T. vaccinum</i>
thus actively structured the community of microorganisms in its habitat.</AbstractText>
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<affiliations><list><country><li>Allemagne</li>
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