The project ECTOMYC addresses species richness and ecosystem functions of ectomycorrhizal fungal assemblages in response to forest management. We identified soil pH, forest management intensity, tree species and root nutrient contents as important drivers of the structure of root-associated fungal communities. Using stable isotopes (15NO3-, 15NH4+), we found that different ectomycorrhizal fungal species differed strongly in nitrogen enrichment, suggesting large differences in substrate use. Analyses of the structure of root-associated fungal assemblages across all forest experimental plots in the Exploratories revealed that nitrogen explained a significant portion of the variation in root-associated fungal assemblages. These results suggest that fungal traits for nutrient use contribute to ecosystem dynamics. Experimental approaches to obtain information on substrate preferences of ectomycorrhizal fungi under field conditions are scarce. Based on the results of the previous phases, the specific aims of this project are:(i) to dissect temporal and spatial turnover of root-associated fungal assemblages according to ecological groups (symbiotroph, saprotroph, pathotroph) and their main drivers (land use, climate, abiotic soil conditions, and root nutrients).(ii) to investigate fungal traits for nutrient use by bait experiments (iii) to establish causal relationships between forest management measures (tree cutting and gap formation) between the function and composition of root-associated fungi and root nutrient physiology.To achieve these goals, we will sample roots in 150 forest plots of the Biodiversity Exploratories and use the results from 2014, 2017 and 2020 to investigate spatiotemporal variation of fungi on roots. In bait experiments, mesh containers accessible for fungal hyphae, will be supplemented with substrates and the colonizing fungal community will be studied. Tree cutting affects carbon allocation to the soil. We will use the new forest experiment (tree cutting) to investigate the impact of changes in root carbon physiology on the structure of associated ectomycorrhizal, saprotrophic and other fungal groups and the feedback for tree mineral nutrition. These results will contribute to increase our understanding of ecosystem functioning.

DFG Programme Infrastructure Priority Programmes

Subproject of SPP 1374:  Biodiversity Exploratories