Fungi are mediators of the nitrogen and carbon cycles in terrestrial ecosystems. Examining
how nitrogen uptake and organic matter decomposition potential differs in fungi can provide …

Forest soil organic matter (SOM) is derived from both above-and belowground plant inputs,
with a significant portion of this plant-derived organic carbon being processed by fungal …

Nitrogen (N) deposition usually increases plant tissue N concentrations and thus
phosphorus (P) demand in young and/or N‐limited forests, but the N deposition effect on …

Soil microbial diversity plays key roles in plant nutrient acquisition and resilience. In recent
years, interactions between plants and their associated microorganisms in soil have …

In the global change scenario, nitrogen (N) deposition has the potential to affect the soil
microbial communities that play critical roles in ecosystem functioning. Although the impacts …

Global eutrophication of growth-limiting nutrients for plants and microbes, including nitrogen
(N) and phosphorus (P), can cause enzymatic feedbacks at different levels of biological …

The impacts of invasive species on biodiversity may be mitigated or exacerbated by abiotic
environmental changes. Invasive plants can restructure soil fungal communities with …

Recent studies have highlighted the critical role of manganese (Mn) in plant litter
decomposition and soil organic carbon (C) cycling in forest ecosystems. Long term nitrogen …

Nitrogen (N) deposition increases soil carbon (C) storage by reducing microbial activity.
These effects vary in soil beneath trees that associate with arbuscular (AM) and …

The continuous upsurge in soil nitrogen (N) enrichment has had strong impacts on the
structure and function of ecosystems. Elucidating how plant ectomycorrhizal fungi (EMF) …