Mycorrhiza-mediated recruitment of complete denitrifying Pseudomonas reduces N2O emissions from soil

Mycorrhiza-mediated recruitment of complete denitrifying Pseudomonas reduces N2O emissions from soil

Arbuscular mycorrhizal fungi (AMF) are key soil organisms and their extensive hyphae create a unique hyphosphere associated with microbes actively involved in N cycling. However, the underlying mechanisms how AMF and hyphae-associated microbes may cooperate to influence N2O emissions from “hot spot” residue patches remain unclear. Here we explored the key microbes in the hyphosphere involved in N2O production and consumption using amplicon and shotgun metagenomic sequencing. Chemotaxis, growth and N2O emissions of isolated N2O-reducing bacteria in response to hyphal exudates were tested using in vitro cultures and inoculation experiments. Results: AMF hyphae reduced denitrification-derived N2O emission (max. 63%) in C- and N-rich residue patches. AMF consistently enhanced the abundance and expression of clade I nosZ gene, and inconsistently increased that of nirS and nirK genes. The reduction of N2O emissions in the hyphosphere was linked to N2O-reducing Pseudomonas specifically enriched by AMF, concurring with the increase in the relative abundance of the key genes involved in bacterial citrate cycle. Phenotypic characterization of the isolated complete denitrifying P. fluorescens strain JL1 (possessing clade I nosZ) indicated that the decline of net N2O emission was a result of upregulated nosZ expression in P. fluorescens following hyphal exudation (e.g. carboxylates). These findings were further validated by re-inoculating sterilized residue patches with P. fluorescens and by an 11-year-long field experiment showing significant positive correlation between hyphal length density with the abundance of clade I nosZ gene. Conclusions: The cooperation between AMF and the N2O-reducing Pseudomonas residing on hyphae significantly reduce N2O emissions in the microsites. Carboxylates exuded by hyphae act as attractants in recruiting P. fluorescens and also as stimulants triggering nosZ gene expression. Our discovery indicates that reinforcing synergies between AMF and hyphosphere microbiome may provide unexplored opportunities to stimulate N2O consumption in nutrient-enriched microsites, and consequently reduce N2O emissions from soils. This knowledge opens novel avenues to exploit cross-kingdom microbial interactions for sustainable agriculture and for climate change mitigation. [MediaObject not available: see fulltext.]

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Main Authors: Li, Xia, Zhao, Ruotong, Li, Dandan, Wang, Guangzhou, Bei, Shuikuan, Ju, Xiaotang, An, Ran, Li, Long, Kuyper, Thomas W., Christie, Peter, Bender, Franz S., Veen, Ciska, van der Heijden, Marcel G.A., van der Putten, Wim H., Zhang, Fusuo, Butterbach-Bahl, Klaus, Zhang, Junling
Format: Article/Letter to editor biblioteca
Language:English
Subjects:Arbuscular mycorrhizal fungi, Carboxylates, NO, Pseudomonas, nosZ,
Online Access:https://research.wur.nl/en/publications/mycorrhiza-mediated-recruitment-of-complete-denitrifying-pseudomo
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spelling dig-wur-nl-wurpubs-6127042024-12-04 Li, Xia Zhao, Ruotong Li, Dandan Wang, Guangzhou Bei, Shuikuan Ju, Xiaotang An, Ran Li, Long Kuyper, Thomas W. Christie, Peter Bender, Franz S. Veen, Ciska van der Heijden, Marcel G.A. van der Putten, Wim H. Zhang, Fusuo Butterbach-Bahl, Klaus Zhang, Junling Article/Letter to editor Microbiome 11 (2023) 1 ISSN: 2049-2618 Mycorrhiza-mediated recruitment of complete denitrifying Pseudomonas reduces N2O emissions from soil 2023 Arbuscular mycorrhizal fungi (AMF) are key soil organisms and their extensive hyphae create a unique hyphosphere associated with microbes actively involved in N cycling. However, the underlying mechanisms how AMF and hyphae-associated microbes may cooperate to influence N2O emissions from “hot spot” residue patches remain unclear. Here we explored the key microbes in the hyphosphere involved in N2O production and consumption using amplicon and shotgun metagenomic sequencing. Chemotaxis, growth and N2O emissions of isolated N2O-reducing bacteria in response to hyphal exudates were tested using in vitro cultures and inoculation experiments. Results: AMF hyphae reduced denitrification-derived N2O emission (max. 63%) in C- and N-rich residue patches. AMF consistently enhanced the abundance and expression of clade I nosZ gene, and inconsistently increased that of nirS and nirK genes. The reduction of N2O emissions in the hyphosphere was linked to N2O-reducing Pseudomonas specifically enriched by AMF, concurring with the increase in the relative abundance of the key genes involved in bacterial citrate cycle. Phenotypic characterization of the isolated complete denitrifying P. fluorescens strain JL1 (possessing clade I nosZ) indicated that the decline of net N2O emission was a result of upregulated nosZ expression in P. fluorescens following hyphal exudation (e.g. carboxylates). These findings were further validated by re-inoculating sterilized residue patches with P. fluorescens and by an 11-year-long field experiment showing significant positive correlation between hyphal length density with the abundance of clade I nosZ gene. Conclusions: The cooperation between AMF and the N2O-reducing Pseudomonas residing on hyphae significantly reduce N2O emissions in the microsites. Carboxylates exuded by hyphae act as attractants in recruiting P. fluorescens and also as stimulants triggering nosZ gene expression. Our discovery indicates that reinforcing synergies between AMF and hyphosphere microbiome may provide unexplored opportunities to stimulate N2O consumption in nutrient-enriched microsites, and consequently reduce N2O emissions from soils. This knowledge opens novel avenues to exploit cross-kingdom microbial interactions for sustainable agriculture and for climate change mitigation. [MediaObject not available: see fulltext.] en application/pdf https://research.wur.nl/en/publications/mycorrhiza-mediated-recruitment-of-complete-denitrifying-pseudomo 10.1186/s40168-023-01466-5 https://edepot.wur.nl/590712 Arbuscular mycorrhizal fungi Carboxylates NO Pseudomonas nosZ https://creativecommons.org/licenses/by/4.0/ https://creativecommons.org/licenses/by/4.0/ Wageningen University & Research
institution WUR NL
collection DSpace
country Países bajos
countrycode NL
component Bibliográfico
access En linea
databasecode dig-wur-nl
tag biblioteca
region Europa del Oeste
libraryname WUR Library Netherlands
language English
topic Arbuscular mycorrhizal fungi
Carboxylates
NO
Pseudomonas
nosZ
Arbuscular mycorrhizal fungi
Carboxylates
NO
Pseudomonas
nosZ
spellingShingle Arbuscular mycorrhizal fungi
Carboxylates
NO
Pseudomonas
nosZ
Arbuscular mycorrhizal fungi
Carboxylates
NO
Pseudomonas
nosZ
Li, Xia
Zhao, Ruotong
Li, Dandan
Wang, Guangzhou
Bei, Shuikuan
Ju, Xiaotang
An, Ran
Li, Long
Kuyper, Thomas W.
Christie, Peter
Bender, Franz S.
Veen, Ciska
van der Heijden, Marcel G.A.
van der Putten, Wim H.
Zhang, Fusuo
Butterbach-Bahl, Klaus
Zhang, Junling
Mycorrhiza-mediated recruitment of complete denitrifying Pseudomonas reduces N2O emissions from soil
description Arbuscular mycorrhizal fungi (AMF) are key soil organisms and their extensive hyphae create a unique hyphosphere associated with microbes actively involved in N cycling. However, the underlying mechanisms how AMF and hyphae-associated microbes may cooperate to influence N2O emissions from “hot spot” residue patches remain unclear. Here we explored the key microbes in the hyphosphere involved in N2O production and consumption using amplicon and shotgun metagenomic sequencing. Chemotaxis, growth and N2O emissions of isolated N2O-reducing bacteria in response to hyphal exudates were tested using in vitro cultures and inoculation experiments. Results: AMF hyphae reduced denitrification-derived N2O emission (max. 63%) in C- and N-rich residue patches. AMF consistently enhanced the abundance and expression of clade I nosZ gene, and inconsistently increased that of nirS and nirK genes. The reduction of N2O emissions in the hyphosphere was linked to N2O-reducing Pseudomonas specifically enriched by AMF, concurring with the increase in the relative abundance of the key genes involved in bacterial citrate cycle. Phenotypic characterization of the isolated complete denitrifying P. fluorescens strain JL1 (possessing clade I nosZ) indicated that the decline of net N2O emission was a result of upregulated nosZ expression in P. fluorescens following hyphal exudation (e.g. carboxylates). These findings were further validated by re-inoculating sterilized residue patches with P. fluorescens and by an 11-year-long field experiment showing significant positive correlation between hyphal length density with the abundance of clade I nosZ gene. Conclusions: The cooperation between AMF and the N2O-reducing Pseudomonas residing on hyphae significantly reduce N2O emissions in the microsites. Carboxylates exuded by hyphae act as attractants in recruiting P. fluorescens and also as stimulants triggering nosZ gene expression. Our discovery indicates that reinforcing synergies between AMF and hyphosphere microbiome may provide unexplored opportunities to stimulate N2O consumption in nutrient-enriched microsites, and consequently reduce N2O emissions from soils. This knowledge opens novel avenues to exploit cross-kingdom microbial interactions for sustainable agriculture and for climate change mitigation. [MediaObject not available: see fulltext.]
format Article/Letter to editor
topic_facet Arbuscular mycorrhizal fungi
Carboxylates
NO
Pseudomonas
nosZ
author Li, Xia
Zhao, Ruotong
Li, Dandan
Wang, Guangzhou
Bei, Shuikuan
Ju, Xiaotang
An, Ran
Li, Long
Kuyper, Thomas W.
Christie, Peter
Bender, Franz S.
Veen, Ciska
van der Heijden, Marcel G.A.
van der Putten, Wim H.
Zhang, Fusuo
Butterbach-Bahl, Klaus
Zhang, Junling
author_facet Li, Xia
Zhao, Ruotong
Li, Dandan
Wang, Guangzhou
Bei, Shuikuan
Ju, Xiaotang
An, Ran
Li, Long
Kuyper, Thomas W.
Christie, Peter
Bender, Franz S.
Veen, Ciska
van der Heijden, Marcel G.A.
van der Putten, Wim H.
Zhang, Fusuo
Butterbach-Bahl, Klaus
Zhang, Junling
author_sort Li, Xia
title Mycorrhiza-mediated recruitment of complete denitrifying Pseudomonas reduces N2O emissions from soil
title_short Mycorrhiza-mediated recruitment of complete denitrifying Pseudomonas reduces N2O emissions from soil
title_full Mycorrhiza-mediated recruitment of complete denitrifying Pseudomonas reduces N2O emissions from soil
title_fullStr Mycorrhiza-mediated recruitment of complete denitrifying Pseudomonas reduces N2O emissions from soil
title_full_unstemmed Mycorrhiza-mediated recruitment of complete denitrifying Pseudomonas reduces N2O emissions from soil
title_sort mycorrhiza-mediated recruitment of complete denitrifying pseudomonas reduces n2o emissions from soil
url https://research.wur.nl/en/publications/mycorrhiza-mediated-recruitment-of-complete-denitrifying-pseudomo
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