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RESEARCH PRODUCT
Plant species identities and fertilization influence on arbuscular mycorrhizal fungal colonisation and soil bacterial activities
Thomas PommierEmmanuelle PersoneniJean-christophe ClémentF. PolyNicolas LegaySophie PérigonFabrice GrasseinSandra LavorelJeremy PuissantBello MouhamadouCindy ArnoldiMarie-noëlle Binetsubject
0106 biological sciencesNutrient cycle[SDE.MCG]Environmental Sciences/Global Changesmedia_common.quotation_subjectSoil Science010603 evolutionary biology01 natural sciencesCompetition (biology)[ SDE ] Environmental SciencesNutrientBotanyColonizationNitrification enzyme activityBromus erectusmedia_common2. Zero hunger[ SDE.BE ] Environmental Sciences/Biodiversity and EcologyMycorrhizal colonizationEcologybiologyfungifood and beveragesRoot traits15. Life on landbiology.organism_classificationAgricultural and Biological Sciences (miscellaneous)Colonisation[ SDE.MCG ] Environmental Sciences/Global ChangesDactylis glomerataAgronomyLeaf traits[SDE]Environmental SciencesShootNutrient availability[SDE.BE]Environmental Sciences/Biodiversity and EcologyDenitrification enzyme activity010606 plant biology & botanydescription
International audience; Plant species influence soil microbial communities, mainly through their functional traits. However, mechanisms underlying these effects are not well understood, and in particular how plant/ microorganism interactions are affected by plant identities and/or environmental conditions. Here, we performed a greenhouse experiment to assess the effects of three plant species on arbuscular mycorrhizal fungal (AMF) colonization, bacterial potential nitrification (PNA) and denitrification activities (PDA) through their functional traits related to nitrogen acquisition and turnover. Three species with contrasting functional traits and strategies (from exploitative to conservative), Dactylis glomerata (L.), Bromus erectus (Hudson) and Festuca paniculata (Schinz and Tellung), were cultivated in monocultures on soil grassland with or without N fertilization. Fertilization impacted some plant traits related to nutrient cycling (leaf and root N concentration, root C:N) but did not affect directly microbial parameters. The highest PDA and PNA were observed in D. glomerata and F. paniculata monocultures, respectively. The highest AMF colonization was obtained for F. paniculata, while B. erectus exhibited both the lowest AMF colonization and bacterial activities. Bacterial activities were influenced by specific above-ground plant traits across fertilization treatments: above-ground biomass for PDA, shoot:root ratio and leaf C:N ratio for PNA. Mycorrhizal colonization was influenced by below-ground traits either root dry matter content or root C:N. Hence, AMF colonization and bacterial activities were impacted differently by species-specific plant biomass allocation, root traits and nutrient requirement. We suggest that such effects may be linked to distinct root exudation patterns and plant abilities for nutrient acquisition and/or nutrient competition.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2016-02-01 | Applied Soil Ecology |