Your search keyword '"fungal ITS2 region"' showing total 5 results

1. Effect of Long-Term Agricultural Management on the Soil Microbiota Influenced by the Time of Soil Sampling.

Author

Fernandez-Gnecco, Gabriela, Covacevich, Fernanda, Consolo, Veronica F., Behr, Jan H., Sommermann, Loreen, Moradtalab, Narges, Maccario, Lorrie, Sørensen, Søren J., Deubel, Annette, Schellenberg, Ingo, Geistlinger, Joerg, Neumann, Günter, Grosch, Rita, Smalla, Kornelia, and Babin, Doreen

Abstract

Application of agrochemicals and mechanization enabled increasing agricultural productivity yet caused various environmental and soil health-related problems. Agricultural practices affect soil microorganisms, which are the key players of many ecosystem processes. However, less is known about whether this effect differs between time points. Therefore, soil was sampled in winter (without crop) and in summer (in the presence of maize) from a long-term field experiment (LTE) in Bernburg (Germany) managed either under cultivator tillage (CT) or moldboard plow (MP) in combination with either intensive nitrogen (N)-fertilization and pesticides (Int) or extensive reduced N-fertilization without fungicides (Ext), respectively. High-throughput sequencing of 16S rRNA gene and fungal ITS2 amplicons showed that changes in the microbial community composition were correlated to differences in soil chemical properties caused by tillage practice. Microbial communities of soils sampled in winter differed only depending on the tillage practice while, in summer, also a strong effect of the fertilization intensity was observed. A small proportion of microbial taxa was shared between soils from the two sampling times, suggesting the existence of a stable core microbiota at the LTE. In general, taxa associated with organic matter decomposition (such as Actinobacteria, Bacteroidetes, Rhizopus, and Exophiala) had a higher relative abundance under CT. Among the taxa with significant changes in relative abundances due to different long-term agricultural practices were putative pathogenic (e.g., Gibellulopsis and Gibberella) and beneficial microbial genera (e.g., Chitinophagaceae, Ferruginibacter, and Minimedusa). In summary, this study suggests that the effects of long-term agricultural management practices on the soil microbiota are influenced by the soil sampling time, and this needs to be kept in mind in future studies for the interpretation of field data. [ABSTRACT FROM AUTHOR]

Published

2022

2. Effect of Long-Term Agricultural Management on the Soil Microbiota Influenced by the Time of Soil Sampling

Author

Gabriela Fernandez-Gnecco, Fernanda Covacevich, Veronica F. Consolo, Jan H. Behr, Loreen Sommermann, Narges Moradtalab, Lorrie Maccario, Søren J. Sørensen, Annette Deubel, Ingo Schellenberg, Joerg Geistlinger, Günter Neumann, Rita Grosch, Kornelia Smalla, and Doreen Babin

Subjects

tillage practice, fertilization intensity, high-throughput amplicon sequencing, 16S rRNA gene, fungal ITS2 region, Chemistry, QD1-999, Engineering geology. Rock mechanics. Soil mechanics. Underground construction, TA703-712

Abstract

Application of agrochemicals and mechanization enabled increasing agricultural productivity yet caused various environmental and soil health-related problems. Agricultural practices affect soil microorganisms, which are the key players of many ecosystem processes. However, less is known about whether this effect differs between time points. Therefore, soil was sampled in winter (without crop) and in summer (in the presence of maize) from a long-term field experiment (LTE) in Bernburg (Germany) managed either under cultivator tillage (CT) or moldboard plow (MP) in combination with either intensive nitrogen (N)-fertilization and pesticides (Int) or extensive reduced N-fertilization without fungicides (Ext), respectively. High-throughput sequencing of 16S rRNA gene and fungal ITS2 amplicons showed that changes in the microbial community composition were correlated to differences in soil chemical properties caused by tillage practice. Microbial communities of soils sampled in winter differed only depending on the tillage practice while, in summer, also a strong effect of the fertilization intensity was observed. A small proportion of microbial taxa was shared between soils from the two sampling times, suggesting the existence of a stable core microbiota at the LTE. In general, taxa associated with organic matter decomposition (such as Actinobacteria, Bacteroidetes, Rhizopus, and Exophiala) had a higher relative abundance under CT. Among the taxa with significant changes in relative abundances due to different long-term agricultural practices were putative pathogenic (e.g., Gibellulopsis and Gibberella) and beneficial microbial genera (e.g., Chitinophagaceae, Ferruginibacter, and Minimedusa). In summary, this study suggests that the effects of long-term agricultural management practices on the soil microbiota are influenced by the soil sampling time, and this needs to be kept in mind in future studies for the interpretation of field data.

Published

2022

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

Author

Saskia Windisch, Loreen Sommermann, Doreen Babin, Soumitra Paul Chowdhury, Rita Grosch, Narges Moradtalab, Frank Walker, Birgit Höglinger, Abbas El-Hasan, Wolfgang Armbruster, Joseph Nesme, Søren Johannes Sørensen, Ingo Schellenberg, Jörg Geistlinger, Kornelia Smalla, Michael Rothballer, Uwe Ludewig, and Günter Neumann

Subjects

fertilization management, root exudates, rhizosphere microbiota, high-throughout amplicon sequencing, 16S rRNA, fungal ITS2 region, Microbiology, QR1-502

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.

Published

2021

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

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, and Neumann, Günter

Subjects

PLANT fertilization, RHIZOSPHERE, PLANT health, LETTUCE, VESICULAR-arbuscular mycorrhizas, FERTILIZERS, PLANT performance

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. [ABSTRACT FROM AUTHOR]

Published

2021

5. Impact of long-term organic and mineral fertilization on rhizosphere metabolites, root-microbial interactions and plant health of lettuce

Author

Soumitra Paul Chowdhury, Wolfgang Armbruster, Rita Grosch, Joseph Nesme, Søren J. Sørensen, Ingo Schellenberg, Saskia Windisch, Doreen Babin, Jörg Geistlinger, Uwe Ludewig, Günter Neumann, Frank Walker, Narges Moradtalab, Abbas El-Hasan, Birgit Höglinger, Loreen Sommermann, Kornelia Smalla, and Michael Rothballer

Subjects

0106 biological sciences, Microbiology (medical), Exudate, lcsh:QR1-502, fungal ITS2 region, 01 natural sciences, Microbiology, root exudates, lcsh:Microbiology, 03 medical and health sciences, Human fertilization, rhizosphere microbiota, Botany, Gammaproteobacteria, medicine, 16s Rrna, Fertilization Management, Fungal Its2 Region, High-throughout Amplicon Sequencing, Rhizosphere Microbiota, Root Exudates, Stress-related Gene Expression, high-throughout amplicon sequencing, Olpidium, fertilization management, 16S rRNA, 030304 developmental biology, Original Research, 0303 health sciences, Rhizosphere, biology, stress-related gene expression, Pseudomonas, food and beverages, biology.organism_classification, Loam, Shoot, medicine.symptom, 010606 plant biology & botany

Abstract

Fertilization management affects not only plant performance but also soil microbiota, with specific rhizosphere interactions influenced by root activity, still poorly understood. We assumed that long-term fertilization exerts selective effects on rhizodeposition with consequences for recruitment of rhizosphere microbiota and plant performance. To address this hypothesis, we conducted a minirhizotron-experiment with lettuce as model plant, using 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. Although no consistent fertilization effects were detectable on alpha-diversity of fungal and prokaryotic/archaeal rhizosphere communities, increased abundance of plant-beneficial arbuscular-mycorrhizal fungi was characteristic for the rhizospheres of the organically managed soils (HU-org; BIODYN2). However, their rhizosphere microbiota also comprised more fungal pathotrophs, and the plants systemically expressed defense-related genes in shoot tissues. However, there was no consistent effect of fertilization history on shoot biomass and root development, which remained unaffected in HUB-LTE. In the BIODYN2 soil, shoot and root growth was severely suppressed and affected by Olpidium infection, coinciding with the highest rhizosphere abundance of the pathogen (89 %). This was associated with a reduction of potentially plant growth-promoting microorganisms, such as Pseudomonaceae and Mortierella elongata by 87 and 97 %. These profound alterations of rhizosphere microbial communities were linked with characteristic changes in the composition of the rhizosphere solution. Olpidium-induced growth suppression and low rhizosphere abundance of Pseudomonadaceae were associated with reduced rhizosphere concentrations of the antifungal root exudate benzoic acid. This metabolite was described in the literature to be increased by Pseudomonas inoculation. By contrast, high abundance of Pseudomonadaceae (Gammaproteobacteria) in the rhizosphere of plants 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. Under these conditions no plant growth depressions were recorded even in presence of a high Olpidium abundance (76 %) in the rhizosphere. Our results suggest a complex network of belowground interactions between crop roots, site-specific factors and rhizosphere microbiota, modulating the impact of fertilization management with consequences for plant health and crop performance.

Published

2021