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Soil fungal networks maintain local dominance of ectomycorrhizal treesLiang, M., Johnson, D., Burslem, D.F.R.P., Yu, S., Fang, M., Taylor, Joe D., Taylor, A.F.S., Helgason, T., Liu, X. 18 February 2021 (has links)
Yes / The mechanisms regulating community composition and local dominance of trees in species-rich forests are poorly resolved, but the importance of interactions with soil microbes is increasingly acknowledged. Here, we show that tree seedlings that interact via root-associated fungal hyphae with soils beneath neighbouring adult trees grow faster and have greater survival than seedlings that are isolated from external fungal mycelia, but these effects are observed for species possessing ectomycorrhizas (ECM) and not arbuscular mycorrhizal (AM) fungi. Moreover, survival of naturally-regenerating AM seedlings over ten years is negatively related to the density of surrounding conspecific plants, while survival of ECM tree seedlings displays positive density dependence over this interval, and AM seedling roots contain greater abundance of pathogenic fungi than roots of ECM seedlings. Our findings show that neighbourhood interactions mediated by beneficial and pathogenic soil fungi regulate plant demography and community structure in hyperdiverse forests. / This research was funded by the National Key Research and Development Program of China (Project No. 2017YFA0605100) and the National Natural Science Foundation of China (NSFC 31770466 to X.L. and 31870403 to M.L.), and partly supported by awards from the UK Natural Environment Research Council (NERC NE/M004848/1 and NE/R004986/1). D.J. is also supported by the N8 AgriFood programme.
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Modelling Bacterial Growth, Dispersal and Biodegradation: An experiment-based modelling study of the spatiotemporal dynamics of bacterial colonies, their responses to dispersal networks, and their performance in degrading organic contaminantsBanitz, Thomas 22 August 2011 (has links)
Successful bioremediation of polluted soils is often limited by the bioavailability of organic contaminants to degrading bacteria. Recent studies revealed that fungal hyphae have the potential to promote bacterial dispersal, and thus raised the idea of specifically stimulating the establishment of fungal networks in soils to increase contaminant bioavailability. Can such bacterial dispersal networks improve biodegradation performance considerably? If so, how are the improvements affected by abiotic conditions and by the spatial structure of dispersal networks? This doctoral thesis aims at answering these research questions. To this end, laboratory experiments are performed and a bacterial simulation model is developed, incorporating both microbiological and ecological theory. Manifold simulations and analyses of the microbial ecosystems’ spatiotemporal dynamics under different environmental scenarios reveal key factors and processes controlling biodegradation performance and determining benefits from bacterial dispersal networks.
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