Your search keyword '"Plant legacy"' showing total 6 results

1. Rhizosheath–root system changes exopolysaccharide content but stabilizes bacterial community across contrasting seasons in a desert environment

Author

Ramona Marasco, Marco Fusi, Maria Mosqueira, Jenny Marie Booth, Federico Rossi, Massimiliano Cardinale, Grégoire Michoud, Eleonora Rolli, Gianmarco Mugnai, Lorenzo Vergani, Sara Borin, Roberto De Philippis, Ameur Cherif, and Daniele Daffonchio

Subjects

Rhizosheath, Plant-microbiome, Desert, Extracellular polymeric substances (EPS), Plant legacy, Environmental fluctuation, Environmental sciences, GE1-350, Microbiology, QR1-502

Abstract

Abstract Background In hot deserts daily/seasonal fluctuations pose great challenges to the resident organisms. However, these extreme ecosystems host unique microenvironments, such as the rhizosheath–root system of desert speargrasses in which biological activities and interactions are facilitated by milder conditions and reduced fluctuations. Here, we examined the bacterial microbiota associated with this structure and its surrounding sand in the desert speargrass Stipagrostis pungens under the contrasting environmental conditions of summer and winter in the Sahara Desert. Results The belowground rhizosheath–root system has higher nutrient and humidity contents, and cooler temperatures than the surrounding sand. The plant responds to the harsh environmental conditions of the summer by increasing the abundance and diversity of extracellular polymeric substances (EPS) compared to the winter. On the contrary, the bacterial community associated with the rhizosheath–root system and its interactome remain stable and, unlike the bulk sand, are unaffected by the seasonal environmental variations. The rhizosheath–root system bacterial communities are consistently dominated by Actinobacteria and Alphaproteobacteria and form distinct bacteria communities from those of bulk sand in the two seasons. The microbiome-stabilization mediated by the plant host acts to consistently retain beneficial bacteria with multiple plant growth promoting functions, including those capable to produce EPS, which increase the sand water holding capacity ameliorating the rhizosheath micro-environment. Conclusions Our results reveal the capability of plants in desert ecosystems to stabilize their below ground microbial community under seasonal contrasting environmental conditions, minimizing the heterogeneity of the surrounding bulk sand and contributing to the overall holobiont resilience under poly-extreme conditions.

Published

2022

2. Rhizosheath–root system changes exopolysaccharide content but stabilizes bacterial community across contrasting seasons in a desert environment.

Author

Marasco, Ramona, Fusi, Marco, Mosqueira, Maria, Booth, Jenny Marie, Rossi, Federico, Cardinale, Massimiliano, Michoud, Grégoire, Rolli, Eleonora, Mugnai, Gianmarco, Vergani, Lorenzo, Borin, Sara, De Philippis, Roberto, Cherif, Ameur, and Daffonchio, Daniele

Subjects

*BACTERIAL communities, *DESERTS, *HOST plants, *COMMUNITIES, *PLANT growth, *ECOSYSTEMS, *MICROBIAL communities, *SEASONS

Abstract

Background: In hot deserts daily/seasonal fluctuations pose great challenges to the resident organisms. However, these extreme ecosystems host unique microenvironments, such as the rhizosheath–root system of desert speargrasses in which biological activities and interactions are facilitated by milder conditions and reduced fluctuations. Here, we examined the bacterial microbiota associated with this structure and its surrounding sand in the desert speargrass Stipagrostis pungens under the contrasting environmental conditions of summer and winter in the Sahara Desert. Results: The belowground rhizosheath–root system has higher nutrient and humidity contents, and cooler temperatures than the surrounding sand. The plant responds to the harsh environmental conditions of the summer by increasing the abundance and diversity of extracellular polymeric substances (EPS) compared to the winter. On the contrary, the bacterial community associated with the rhizosheath–root system and its interactome remain stable and, unlike the bulk sand, are unaffected by the seasonal environmental variations. The rhizosheath–root system bacterial communities are consistently dominated by Actinobacteria and Alphaproteobacteria and form distinct bacteria communities from those of bulk sand in the two seasons. The microbiome-stabilization mediated by the plant host acts to consistently retain beneficial bacteria with multiple plant growth promoting functions, including those capable to produce EPS, which increase the sand water holding capacity ameliorating the rhizosheath micro-environment. Conclusions: Our results reveal the capability of plants in desert ecosystems to stabilize their below ground microbial community under seasonal contrasting environmental conditions, minimizing the heterogeneity of the surrounding bulk sand and contributing to the overall holobiont resilience under poly-extreme conditions. [ABSTRACT FROM AUTHOR]

Published

2022

3. Shaping of soil microbial communities by plants does not translate into specific legacy effects on organic carbon mineralization

Author

Françoise Binet, Eve Hellequin, Jaanis Juhanson, Virginie Daburon, Cécile Monard, Sara Hallin, Olivier Klarzynski, Ecosystèmes, biodiversité, évolution [Rennes] (ECOBIO), Université de Rennes (UR)-Institut Ecologie et Environnement (INEE), Centre National de la Recherche Scientifique (CNRS)-Centre National de la Recherche Scientifique (CNRS)-Observatoire des Sciences de l'Univers de Rennes (OSUR), Université de Rennes (UR)-Institut national des sciences de l'Univers (INSU - CNRS)-Université de Rennes 2 (UR2)-Centre National de la Recherche Scientifique (CNRS)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE)-Institut national des sciences de l'Univers (INSU - CNRS)-Université de Rennes 2 (UR2)-Centre National de la Recherche Scientifique (CNRS)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE)-Centre National de la Recherche Scientifique (CNRS), Bio3G, Swedish University of Agricultural Sciences (SLU), This research was supported by the 'Association Nationale de la Recherche et de la Technologies » (ANRT) through the convention N° 2016/0091 to F. Binet and O. Klarzynski and by the University of Rennes 1 through its international mobility programm N° 12/2018 to E. Hellequin. This research was also partly funded by the 2015–2016 BiodivERsA call by The Swedish Research Council Formas (contract 2016–0194)., Centre National de la Recherche Scientifique (CNRS)-Observatoire des Sciences de l'Univers de Rennes (OSUR)-Institut Ecologie et Environnement (INEE), Centre National de la Recherche Scientifique (CNRS)-Centre National de la Recherche Scientifique (CNRS)-Université de Rennes 1 (UR1), and Université de Rennes (UNIV-RENNES)-Université de Rennes (UNIV-RENNES)

Subjects

0106 biological sciences, Arabidopsis thaliana, microbial succession, Triticum aestivum, Soil Science, Litter mineralization, Biology, 010603 evolutionary biology, 01 natural sciences, Microbiology, complex mixtures, Carbon cycle, 03 medical and health sciences, soil fungi, Ecosystem, 030304 developmental biology, 2. Zero hunger, Total organic carbon, Plant legacy, 0303 health sciences, soil bacteria, fungi, food and beverages, Soil carbon, Mineralization (soil science), 15. Life on land, Plant litter, Agronomy, Microbial population biology, Soil water, [SDE.BE]Environmental Sciences/Biodiversity and Ecology

Abstract

International audience; Plants shape soil microbial communities through their root architecture, their rhizodeposits and return of dead plant material to the soil. These interactions can have a strong influence on the soil organic carbon dynamics. However, it is unclear whether the plant species effects on the soil microbial community could influence the organic carbon mineralization through plant legacy effects. Therefore, we examined how and to what extent a short-term plant growing phase affected the total and active soil microorganisms and through a possible plant legacy, also the mineralization of soil organic carbon, a central ecosystem function. Using a controlled pot experiment, we first showed that the two phylogenetically distinct plants, Arabidopsis thaliana and Triticum aestivum, differently shaped the soil microbial communities when recruiting from the same soil community. Although both plants recruited plant-growth promoting bacteria in the vicinity of their roots, A. thaliana had a stronger effect than T. aestivum and also recruited saprophytic fungi, while inhibiting fungal pathogens. Due to plant legacy effects on the soil microbial communities, different microbial successions occurred in the two previously planted soils when subjected to plant litter. By contrast, plant legacy effects on soil basal respiration were not plant-specific, with basal respiration increasing similarly in both cases and moreover did not translate to changes in litter carbon mineralization in the short-term of 49 days. Our results suggest that the soil nutrient dynamics rather than changes in soil microbial community composition drive the organic carbon mineralization of added litter. The present study brings new insights in how the relationships between plants, microorganisms and soil nutrient dynamics affect litter carbon cycling.

Published

2021

4. Interactions sol-plante au sein d'une culture associée céréale-légumineuse et effets sur le fonctionnement du sol

Author

de Oliveira, Ana Beatriz, Ecologie fonctionnelle et biogéochimie des sols et des agro-écosystèmes (UMR Eco&Sols), Centre de Coopération Internationale en Recherche Agronomique pour le Développement (Cirad)-Institut de Recherche pour le Développement (IRD)-Institut National de la Recherche Agronomique (INRA)-Centre international d'études supérieures en sciences agronomiques (Montpellier SupAgro)-Institut national d’études supérieures agronomiques de Montpellier (Montpellier SupAgro), Montpellier SupAgro, Philippe Hinsinger, and Édith Le Cadre

Subjects

Plant-Soil feedback, Plant legacy, Diversité végétale, Plant diversity, Resilience, Resistance, Effet d’héritage, Résistance, [SDV.SA.SDS]Life Sciences [q-bio]/Agricultural sciences/Soil study, Résilience, Nitrification, Boucle de rétroaction plante-Sol, [SDV.EE.IEO]Life Sciences [q-bio]/Ecology, environment/Symbiosis

Abstract

In a context of climate change and necessary agro-ecological transition, plant diversity can be an important lever to replace synthetic inputs by biological regulations. Cereal-legume intercrops are promising in this context, but in such agricultural systems, plant-soil feedbacks have to be better understood, and in particular the processes occurring in the rhizosphere, the narrow volume of soil under influence of root activities and resource availability. Hence, under cereal-legume intercrops, nitrogen (N) availability could mediate soil-plant interactions. Our goals were to (i) evaluate if rhizosphere effects of a cereal-legume intercrop are modified by a soil mineral N gradient and (ii) to identify a possible plant legacy of intercropping on soil microbial functioning in terms of resistance and resilience after a heat stress. To address these objectives, wheat (Triticum aestivum) and white lupin (Lupinus albus) were grown alone or intercropped along a soil mineral N gradient on a Mediterranean soil, under controlled conditions. The N gradient did alter some rhizosphere effects of the intercrops. Within one growth cycle, intercrop was able to maintain and in some extent to improve the soil functioning relative to sole crops. We demonstrated that rhizosphere processes are able to induce plant legacies after disappearance of the intercrops. Indeed, we also estimated that resistance and resilience of some microbial process related to carbon and nitrogen cycles were improved under intercrops after a heat stress. Finally, we suggest that positive plant legacies under intercrops may contribute to adaptation of Mediterranean agriculture to the climate change, but fertilization have to be better investigated for its effect on plant legacies.; Dans un contexte de changement climatique et de nécessaire transition agro-écologique des agroécosystèmes, la diversité végétale est un levier important pour remplacer les intrants synthétiques par des régulations biologiques. Les associations céréales-légumineuses sont un des moyens d’augmenter la diversité végétale au sein des parcelles agricoles. Dans ce type de systèmes, les boucles de rétroaction entre le sol et les cultures associées sont méconnues, notamment par la complexité des processus pouvant se dérouler dans la zone de sol influencée par les racines, la rhizosphère, sous influence des ressources du sol affectant les interactions entre plantes. Dans ce contexte, la disponibilité de l’azote (N) pourrait modifier les interactions entre le sol et les cultures associées. Cette thèse avait donc pour objectif (i) d’évaluer si l’effet rhizosphère d’une association céréale-légumineuse peut être modifié par un gradient de N, et (ii) si un effet différentiel d’héritage (plant legacy) des associations sur le fonctionnement microbien des sols est perceptible à court terme, en considérant la réponse des microorganismes du sol à un stress thermique. Pour répondre à ces objectifs, le blé tendre (Triticum aestivum) et le lupin blanc (Lupinus albus) ont été cultivés seuls ou en association en condition contrôlées avec 3 niveaux de N minéral à partir d’un sol méditerranéen. Nos résultats ont montré que notre gradient de N a eu un effet significatif sur quelques paramètres de la rhizosphère de l’association blé-lupin, comparativement aux cultures pures. Au cours d’un cycle de culture, l’association blé-lupin a été capable de maintenir voire d’améliorer le fonctionnement du sol, comparativement à l’une des deux cultures pures, même dans les conditions les plus fertilisées. Ce travail a mis en exergue que les processus rhizosphériques ayant lieu au sein de l’association blé-lupin sont à l’origine des effets observés, montrant l’importance du compartiment rhizosphère pour produire des effets d’héritage positifs (positive plant legacy effects), pouvant s’étendre au sol entier, une fois les plantes récoltées. Nous avons également montré que l’effet d’héritage produit à court terme par l’association peut également se traduire par une meilleure stabilité d’activités microbiennes liées aux cycles du carbone et de l’azote, face à un stress thermique. Enfin, les résultats de cette thèse suggèrent que les effets d’héritage positifs à court terme peuvent être un levier d’adaptation des agroécosystèmes méditerranéens au changement climatique sous conditions d’une gestion de la fertilisation adaptée.

Published

2019

5. Short-term plant species impact on microbial community structure in soils with long-term agricultural history.

Author

Maul, Jude and Drinkwater, Laurie

Subjects

*PLANT ecology, *PLANT species, *GRASSES, *ZEA, *GREENHOUSE plants, *PLANT-soil relationships

Abstract

The goal of our study was to capture the short-term effects of individual plant species on an established microbial community in a soil with a well-defined agricultural history. Using biochemical and molecular techniques we quantified the effects of plant species on changes in the soil microbial community over an 8-week time-course. We conducted a greenhouse experiment using field soil from a site that was managed as a Zea mays monoculture for over 50 years. The conditioned soil provided a baseline from which changes in microbial community composition through the effects of newly introduced plants could be determined. Within a short time frame (8 weeks), introduced plants influenced the soil microbial community in ways unique to each plant. Some species ( Fagopyrm esculentum and x Triticosecale spp.) resulted in an increase of total microbial community richness, diversity and the stimulation of new microbial species not associated with the legacy vegetation. Other plants ( Vicia villosa and Lolium multiflorum) tended to reduce community diversity. We suggest root surface area is good general predictor of rhizosphere microbial community diversity, but in some cases other plant traits may have dominant influence on plant-induced changes in microbial community composition. [ABSTRACT FROM AUTHOR]

Published

2010

6. Shaping of soil microbial communities by plants does not translate into specific legacy effects on organic carbon mineralization.

Author

Hellequin, Eve, Binet, Françoise, Klarzynski, Olivier, Hallin, Sara, Juhanson, Jaanis, Daburon, Virginie, and Monard, Cécile

Subjects

*MICROBIAL communities, *PLANT communities, *NUTRIENT cycles, *SOIL microbiology, *MINERALIZATION, *SOIL microbial ecology, *SOILS, *SOIL dynamics

Abstract

Plants shape soil microbial communities through their root architecture, their rhizodeposits and return of dead plant material to the soil. These interactions can have a strong influence on the soil organic carbon dynamics. However, it is unclear whether the plant species effects on the soil microbial community could influence the organic carbon mineralization through plant legacy effects. Therefore, we examined how and to what extent a short-term plant growing phase affected the total and active soil microorganisms and through a possible plant legacy, also the mineralization of soil organic carbon, a central ecosystem function. Using a controlled pot experiment, we first showed that the two phylogenetically distinct plants, Arabidopsis thaliana and Triticum aestivum , differently shaped the soil microbial communities when recruiting from the same soil community. Although both plants recruited plant-growth promoting bacteria in the vicinity of their roots, A. thaliana had a stronger effect than T. aestivum and also recruited saprophytic fungi, while inhibiting fungal pathogens. Due to plant legacy effects on the soil microbial communities, different microbial successions occurred in the two previously planted soils when subjected to plant litter. By contrast, plant legacy effects on soil basal respiration were not plant-specific, with basal respiration increasing similarly in both cases and moreover did not translate to changes in litter carbon mineralization in the short-term of 49 days. Our results suggest that the soil nutrient dynamics rather than changes in soil microbial community composition drive the organic carbon mineralization of added litter. The present study brings new insights in how the relationships between plants, microorganisms and soil nutrient dynamics affect litter carbon cycling. • A. thaliana and T. aestivum differently shaped the soil microbial communities. • A. thaliana had a stronger effect, especially for fungal communities. • PGPB were recruited in the vicinity of the roots of both A. thaliana and T. aestivum. • Plant legacy effects traduced in changes in soil organic carbon and nutrient dynamics. • Plant legacy effects linked to nutrient dynamics rather than to microbial community. [ABSTRACT FROM AUTHOR]

Published

2021