Abstract
AbstractRoot‐colonizing fungi form species‐rich assemblages with key functions in principal ecosystem processes, making them prospectively important players in conservation and applied ecology. Harnessing the processes and services they drive requires a better understanding of their patterns of diversity and community structure, and how these link to function. Here, we search for possible adaptations to contrasting environmental and host conditions, indicative of participation in habitat‐specific processes. We surveyed heathland and grassland habitats across a latitudinal gradient in Western Europe, using a spatially explicit design to assess community variation at scales from centimeters, to thousands of kilometers. Root‐associated fungi assemble into strongly site‐specific communities irrespective of habitat type, shaped by environmental factors and spatial distance operating at different scales, but also by a high level of endemism, likely to be determined by local stochastic processes such as drift and dispersal limitation at short distances. Despite the high site specificity in communities, they are dominated everywhere by a core set of lineages with little preferences toward habitat conditions or host phylogeny. Our results suggest a convergent evolution across phylogenetically distant lineages toward the root‐colonizing habit, and a functional redundancy in strategies for habitat colonization and host interaction. Further efforts are needed to integrate functional trait composition in future community ecology studies of root‐colonizing fungi.
Highlights
Plant roots provide niches for rich assemblages of fungi that play key functions in ecosystem productivity, nutrient cycling, and soil formation
Rootassociated fungi assemble into strongly site-specific communities irrespective of habitat type, shaped by environmental factors and spatial distance operating at different scales, and by a high level of endemism, likely to be determined by local stochastic processes such as drift and dispersal limitation at short distances
We identified OTUs putatively analysis of the belonging to ericoid mycorrhizas (ErM), ectomycorrhizal (EcM), or arbuscular mycorrhizas (AM) fungi samples from the other study, in which treatment repli- using FUNGuild v1.0 (Nguyen et al 2016), by selecting cates were distributed between the two runs, showed that taxa with a likelihood of belonging to each guild as the sequencing run explained a maximum of 1.9% of “Probable” or “Highly Problable.”
Summary
Plant roots provide niches for rich assemblages of fungi that play key functions in ecosystem productivity, nutrient cycling, and soil formation. Root and rhizosphere-colonizing fungi are directly responsible for the mineralization of soil organic matter that renders nutrients available to plants, for the massive storage of soil nutrients, and for their transfer to and between plants (Smith and Read 1997, van der Heijden et al 2015, Klein et al 2016, Tedersoo et al 2020b) They confer plant tolerance against environmental stressors (Van der Heijden et al 1998), or act as parasites and pathogens with important roles in controlling plant diversity and productivity (Ruijven et al 2020). Considering the effects of fungal associations on plant traits and productivity may enhance predictions of ecosystem dynamics and biosphere impacts of global climate change (Terrer et al 2016), as well as enable the Manuscript received 11 February 2021; revised 10 May 2021; accepted 7 July 2021; final version received 8 October 2021.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
