The prized wild mushroom Tricholoma matsutake maintains distinctive microbiota within its dominant zone; however, the spatial and seasonal reorganization of microbiota from taxonomic and functional perspectives remain poorly understood. High-throughput amplicon sequencing was performed in warming (March–June) and cooling (September–December) seasons to compare microbial communities among T. matsutake-dominant (present, visible mycelium) and -nondominant soils (transition, adjacent with present; control, distant from fairy ring). Fungal and bacterial community structures in T. matsutake-dominant soils were obviously distinct (ANOSIM, R > 0.6, p = 0.001), and bacterial communities exhibited clear seasonal separation. The relative abundances of Ascomycota and Mortierellomycota significantly reduced, whereas mycorrhiza-helper bacteria, including Paenibacillus, Bacillus, and Cohnella, were enriched. Functional predictions suggested that the potential expression of cofactor and vitamin biosynthesis, nutrient degradation, and inorganic nutrient metabolism pathways may be enriched in T. matsutake-dominant soil. During the fruiting period, the expression of the predicted amino acid biosynthesis pathway may be reduced, whereas that of the cofactor/carrier/vitamin biosynthesis pathway may be enriched. Our findings suggest that T. matsutake dominance could be associated with the spatial and seasonal restructuring of soil microbial communities, potentially leading to the formation of functionally interconnected microbial networks. Therefore, this study predicts hidden ecological insights that, once biochemically validated, may be used to develop important strategies for the sustainable conservation and artificial cultivation of T. matsutake.
Keum et al. (Wed,) studied this question.