Impact of Long-Term Organic and Mineral Fertilization on Rhizosphere Metabolites, Root–Microbial Interactions and Plant Health of Lettuce

Publikation: Bidrag til tidsskriftTidsskriftartikelForskningfagfællebedømt

Standard

Impact of Long-Term Organic and Mineral Fertilization on Rhizosphere Metabolites, Root–Microbial Interactions and Plant Health of Lettuce. / Windisch, Saskia; Sommermann, Loreen; Babin, Doreen; Chowdhury, Soumitra Paul; Grosch, Rita; Moradtalab, Narges; Walker, Frank; Höglinger, Birgit; El-Hasan, Abbas; Armbruster, Wolfgang; Nesme, Joseph; Sørensen, Søren Johannes; Schellenberg, Ingo; Geistlinger, Jörg; Smalla, Kornelia; Rothballer, Michael; Ludewig, Uwe; Neumann, Günter.

I: Frontiers in Microbiology, Bind 11, 597745, 2021.

Publikation: Bidrag til tidsskriftTidsskriftartikelForskningfagfællebedømt

Harvard

Windisch, S, Sommermann, L, Babin, D, Chowdhury, SP, Grosch, R, Moradtalab, N, Walker, F, Höglinger, B, El-Hasan, A, Armbruster, W, Nesme, J, Sørensen, SJ, Schellenberg, I, Geistlinger, J, Smalla, K, Rothballer, M, Ludewig, U & Neumann, G 2021, 'Impact of Long-Term Organic and Mineral Fertilization on Rhizosphere Metabolites, Root–Microbial Interactions and Plant Health of Lettuce', Frontiers in Microbiology, bind 11, 597745. https://doi.org/10.3389/fmicb.2020.597745

APA

Windisch, S., Sommermann, L., Babin, D., Chowdhury, S. P., Grosch, R., Moradtalab, N., Walker, F., Höglinger, B., El-Hasan, A., Armbruster, W., Nesme, J., Sørensen, S. J., Schellenberg, I., Geistlinger, J., Smalla, K., Rothballer, M., Ludewig, U., & Neumann, G. (2021). Impact of Long-Term Organic and Mineral Fertilization on Rhizosphere Metabolites, Root–Microbial Interactions and Plant Health of Lettuce. Frontiers in Microbiology, 11, [597745]. https://doi.org/10.3389/fmicb.2020.597745

Vancouver

Windisch S, Sommermann L, Babin D, Chowdhury SP, Grosch R, Moradtalab N o.a. Impact of Long-Term Organic and Mineral Fertilization on Rhizosphere Metabolites, Root–Microbial Interactions and Plant Health of Lettuce. Frontiers in Microbiology. 2021;11. 597745. https://doi.org/10.3389/fmicb.2020.597745

Author

Windisch, Saskia ; Sommermann, Loreen ; Babin, Doreen ; Chowdhury, Soumitra Paul ; Grosch, Rita ; Moradtalab, Narges ; Walker, Frank ; Höglinger, Birgit ; El-Hasan, Abbas ; Armbruster, Wolfgang ; Nesme, Joseph ; Sørensen, Søren Johannes ; Schellenberg, Ingo ; Geistlinger, Jörg ; Smalla, Kornelia ; Rothballer, Michael ; Ludewig, Uwe ; Neumann, Günter. / Impact of Long-Term Organic and Mineral Fertilization on Rhizosphere Metabolites, Root–Microbial Interactions and Plant Health of Lettuce. I: Frontiers in Microbiology. 2021 ; Bind 11.

Bibtex

@article{06537e1f68a54f38b25e35383f903ab7,
title = "Impact of Long-Term Organic and Mineral Fertilization on Rhizosphere Metabolites, Root–Microbial Interactions and Plant Health of Lettuce",
abstract = "Fertilization management can affect plant performance and soil microbiota, involving still poorly understood rhizosphere interactions. We hypothesized that fertilization practice exerts specific effects on rhizodeposition with consequences for recruitment of rhizosphere microbiota and plant performance. To address this hypothesis, we conducted a minirhizotron experiment using lettuce as model plant and field soils with contrasting properties from two long-term field experiments (HUB-LTE: loamy sand, DOK-LTE: silty loam) with organic and mineral fertilization history. Increased relative abundance of plant-beneficial arbuscular mycorrhizal fungi and fungal pathotrophs were characteristic of the rhizospheres in the organically managed soils (HU-org; BIODYN2). Accordingly, defense-related genes were systemically expressed in shoot tissues of the respective plants. As a site-specific effect, high relative occurrence of the fungal lettuce pathogen Olpidium sp. (76–90%) was recorded in the rhizosphere, both under long-term organic and mineral fertilization at the DOK-LTE site, likely supporting Olpidium infection due to a lower water drainage potential compared to the sandy HUB-LTE soils. However, plant growth depressions and Olpidium infection were exclusively recorded in the BIODYN2 soil with organic fertilization history. This was associated with a drastic (87–97%) reduction in rhizosphere abundance of potentially plant-beneficial microbiota (Pseudomonadaceae, Mortierella elongata) and reduced concentrations of the antifungal root exudate benzoate, known to be increased in presence of Pseudomonas spp. In contrast, high relative abundance of Pseudomonadaceae (Gammaproteobacteria) in the rhizosphere of plants grown in soils with long-term mineral fertilization (61–74%) coincided with high rhizosphere concentrations of chemotactic dicarboxylates (succinate, malate) and a high C (sugar)/N (amino acid) ratio, known to support the growth of Gammaproteobacteria. This was related with generally lower systemic expression of plant defense genes as compared with organic fertilization history. Our results suggest a complex network of belowground interactions among root exudates, site-specific factors and rhizosphere microbiota, modulating the impact of fertilization management with consequences for plant health and performance.",
keywords = "16S rRNA, fertilization management, fungal ITS2 region, high-throughout amplicon sequencing, rhizosphere microbiota, root exudates, stress-related gene expression",
author = "Saskia Windisch and Loreen Sommermann and Doreen Babin and Chowdhury, {Soumitra Paul} and Rita Grosch and Narges Moradtalab and Frank Walker and Birgit H{\"o}glinger and Abbas El-Hasan and Wolfgang Armbruster and Joseph Nesme and S{\o}rensen, {S{\o}ren Johannes} and Ingo Schellenberg and J{\"o}rg Geistlinger and Kornelia Smalla and Michael Rothballer and Uwe Ludewig and G{\"u}nter Neumann",
year = "2021",
doi = "10.3389/fmicb.2020.597745",
language = "English",
volume = "11",
journal = "Frontiers in Microbiology",
issn = "1664-302X",
publisher = "Frontiers Media S.A.",

}

RIS

TY - JOUR

T1 - Impact of Long-Term Organic and Mineral Fertilization on Rhizosphere Metabolites, Root–Microbial Interactions and Plant Health of Lettuce

AU - Windisch, Saskia

AU - Sommermann, Loreen

AU - Babin, Doreen

AU - Chowdhury, Soumitra Paul

AU - Grosch, Rita

AU - Moradtalab, Narges

AU - Walker, Frank

AU - Höglinger, Birgit

AU - El-Hasan, Abbas

AU - Armbruster, Wolfgang

AU - Nesme, Joseph

AU - Sørensen, Søren Johannes

AU - Schellenberg, Ingo

AU - Geistlinger, Jörg

AU - Smalla, Kornelia

AU - Rothballer, Michael

AU - Ludewig, Uwe

AU - Neumann, Günter

PY - 2021

Y1 - 2021

N2 - Fertilization management can affect plant performance and soil microbiota, involving still poorly understood rhizosphere interactions. We hypothesized that fertilization practice exerts specific effects on rhizodeposition with consequences for recruitment of rhizosphere microbiota and plant performance. To address this hypothesis, we conducted a minirhizotron experiment using lettuce as model plant and field soils with contrasting properties from two long-term field experiments (HUB-LTE: loamy sand, DOK-LTE: silty loam) with organic and mineral fertilization history. Increased relative abundance of plant-beneficial arbuscular mycorrhizal fungi and fungal pathotrophs were characteristic of the rhizospheres in the organically managed soils (HU-org; BIODYN2). Accordingly, defense-related genes were systemically expressed in shoot tissues of the respective plants. As a site-specific effect, high relative occurrence of the fungal lettuce pathogen Olpidium sp. (76–90%) was recorded in the rhizosphere, both under long-term organic and mineral fertilization at the DOK-LTE site, likely supporting Olpidium infection due to a lower water drainage potential compared to the sandy HUB-LTE soils. However, plant growth depressions and Olpidium infection were exclusively recorded in the BIODYN2 soil with organic fertilization history. This was associated with a drastic (87–97%) reduction in rhizosphere abundance of potentially plant-beneficial microbiota (Pseudomonadaceae, Mortierella elongata) and reduced concentrations of the antifungal root exudate benzoate, known to be increased in presence of Pseudomonas spp. In contrast, high relative abundance of Pseudomonadaceae (Gammaproteobacteria) in the rhizosphere of plants grown in soils with long-term mineral fertilization (61–74%) coincided with high rhizosphere concentrations of chemotactic dicarboxylates (succinate, malate) and a high C (sugar)/N (amino acid) ratio, known to support the growth of Gammaproteobacteria. This was related with generally lower systemic expression of plant defense genes as compared with organic fertilization history. Our results suggest a complex network of belowground interactions among root exudates, site-specific factors and rhizosphere microbiota, modulating the impact of fertilization management with consequences for plant health and performance.

AB - Fertilization management can affect plant performance and soil microbiota, involving still poorly understood rhizosphere interactions. We hypothesized that fertilization practice exerts specific effects on rhizodeposition with consequences for recruitment of rhizosphere microbiota and plant performance. To address this hypothesis, we conducted a minirhizotron experiment using lettuce as model plant and field soils with contrasting properties from two long-term field experiments (HUB-LTE: loamy sand, DOK-LTE: silty loam) with organic and mineral fertilization history. Increased relative abundance of plant-beneficial arbuscular mycorrhizal fungi and fungal pathotrophs were characteristic of the rhizospheres in the organically managed soils (HU-org; BIODYN2). Accordingly, defense-related genes were systemically expressed in shoot tissues of the respective plants. As a site-specific effect, high relative occurrence of the fungal lettuce pathogen Olpidium sp. (76–90%) was recorded in the rhizosphere, both under long-term organic and mineral fertilization at the DOK-LTE site, likely supporting Olpidium infection due to a lower water drainage potential compared to the sandy HUB-LTE soils. However, plant growth depressions and Olpidium infection were exclusively recorded in the BIODYN2 soil with organic fertilization history. This was associated with a drastic (87–97%) reduction in rhizosphere abundance of potentially plant-beneficial microbiota (Pseudomonadaceae, Mortierella elongata) and reduced concentrations of the antifungal root exudate benzoate, known to be increased in presence of Pseudomonas spp. In contrast, high relative abundance of Pseudomonadaceae (Gammaproteobacteria) in the rhizosphere of plants grown in soils with long-term mineral fertilization (61–74%) coincided with high rhizosphere concentrations of chemotactic dicarboxylates (succinate, malate) and a high C (sugar)/N (amino acid) ratio, known to support the growth of Gammaproteobacteria. This was related with generally lower systemic expression of plant defense genes as compared with organic fertilization history. Our results suggest a complex network of belowground interactions among root exudates, site-specific factors and rhizosphere microbiota, modulating the impact of fertilization management with consequences for plant health and performance.

KW - 16S rRNA

KW - fertilization management

KW - fungal ITS2 region

KW - high-throughout amplicon sequencing

KW - rhizosphere microbiota

KW - root exudates

KW - stress-related gene expression

U2 - 10.3389/fmicb.2020.597745

DO - 10.3389/fmicb.2020.597745

M3 - Journal article

C2 - 33519736

AN - SCOPUS:85100065199

VL - 11

JO - Frontiers in Microbiology

JF - Frontiers in Microbiology

SN - 1664-302X

M1 - 597745

ER -

ID: 256720069