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Título: | Lower relative abundance of ectomycorrhizal fungi under a warmer and drier climate is linked to enhanced soil organic matter decomposition |
Autor: | Querejeta Mercader, José Ignacio CSIC ORCID; Schlaeppi, Klaus; López-García, A.; Ondoño, Sara CSIC ORCID; Prieto Aguilar, Iván CSIC ORCID; Der Heijden, Marcel G. A. van; Alguacil García, María del Mar CSIC ORCID | Palabras clave: | Dissolved nitrogen Dissolved organic carbon Extracellular hydrolytic soil enzymes Fungal functional guilds Gadgil effect Mixed arbuscular/ectomycorrhizal (AM/EM) ecosystems Mycorrhizal nutrient economy |
Fecha de publicación: | nov-2021 | Editor: | New Phytologist Trust | Citación: | New Phytologist 232(3): 1399- 1413 (2021) | Resumen: | The aboveground impacts of climate change receive extensive research attention, but climate change could also alter belowground processes such as the delicate balance between free-living fungal decomposers and nutrient-scavenging mycorrhizal fungi that can inhibit decomposition through a mechanism called the Gadgil effect. We investigated how climate change-induced reductions in plant survival, photosynthesis and productivity alter soil fungal community composition in a mixed arbuscular/ectomycorrhizal (AM/EM) semiarid shrubland exposed to experimental warming (W) and/or rainfall reduction (RR). We hypothesised that increased EM host plant mortality under a warmer and drier climate might decrease ectomycorrhizal fungal (EMF) abundance, thereby favouring the proliferation and activity of fungal saprotrophs. The relative abundance of EMF sequences decreased by 57.5% under W+RR, which was accompanied by reductions in the activity of hydrolytic enzymes involved in the acquisition of organic-bound nutrients by EMF and their host plants. W+RR thereby created an enhanced potential for soil organic matter (SOM) breakdown and nitrogen mineralisation by decomposers, as revealed by 127–190% increases in dissolved organic carbon and nitrogen, respectively, and decreasing SOM content in soil. Climate aridification impacts on vegetation can cascade belowground through shifts in fungal guild structure that alter ecosystem biogeochemistry and accelerate SOM decomposition by reducing the Gadgil effect. | Versión del editor: | http://dx.doi.org/10.1111/nph.17661 | URI: | http://hdl.handle.net/10261/255276 | DOI: | 10.1111/nph.17661 | Identificadores: | doi: 10.1111/nph.17661 issn: 1469-8137 |
Aparece en las colecciones: | (EEZ) Artículos (CEBAS) Artículos |
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