Global distribution and biogeography of ericoid mycorrhizal fungi

Abstract

Ericoid mycorrhizal (ErM) fungi play a crucial role across terrestrial ecosystems, forming mutualistic symbiosis with Ericaceae and contributing to soil organic matter dynamics. However, compared to other fungal groups, their biogeography remains unknown. Here, we combined several analytical approaches to analyze a newly compiled, large-scale dataset comprising 39 163 soil samples and more than 13 million ITS rRNA sequences assigned to ErM fungi. Specifically, we asked: What are the global patterns of ErM fungal species richness and relative abundance (out of all fungi) and their predictors, and how is the distribution of ErM fungi associated with soil carbon content at the global scale? We show that ErM fungi reach their highest species richness in very high latitudes. Soil chemistry is a stronger predictor of ErM fungal species richness than climate or ericoid vegetation cover. The relative abundance of ErM fungi is highest in soils with high surface carbon content, supporting their proposed role in soil carbon storage. Furthermore, we predict that climate change will reduce ErM fungal abundance across 38% of the land cover of their current global distribution. Our study shows distinct biogeographic patterns of ErM fungi compared with arbuscular and ectomycorrhizal fungi and indicates the vulnerability of ErM fungi to climate change.