Litcius/Paper detail

Mycorrhizae enhance reactive minerals but reduce mineral‐associated carbon

Huan Li, Guanghui Yu, Liping Hao, Yunpeng Qiu, Shuijin Hu

2023Global Change Biology24 citationsDOIOpen Access PDF

Abstract

Abstract Soil organic carbon (C) is the largest active C pool of Earth's surface and is thus vital in sustaining terrestrial productivity and climate stability. Arbuscular mycorrhizal fungi (AMF) form symbioses with most terrestrial plants and critically modulate soil C dynamics. Yet, it remains unclear whether and how AMF–root associations (i.e., mycorrhizae) interact with soil minerals to affect soil C cycling. Here we showed that the presence of both roots and AMF increased soil dissolved organic C and reactive Fe minerals, as well as litter decomposition and soil CO 2 emissions. However, it reduced mineral‐associated C. Also, high‐resolution nanoscale secondary ion mass spectrometry images showed the existence of a thin coating (0.5–1.0 μm thick) of 56 Fe 16 O − (Fe minerals) on the surface of 12 C 14 N − (fungal biomass), illustrating the close physical association between fungal hyphae and soil Fe minerals. In addition, AMF genera were divergently related to reactive Fe minerals, with Glomus being positively but Paraglomus and Acaulospora negatively correlated with reactive Fe minerals. Moreover, the presence of roots and AMF, particularly when combined with litter addition, enhanced the abundances of several critical soil bacterial genera that are associated with the formation of reactive minerals in soils. A conceptual framework was further proposed to illustrate how AMF–root associations impact soil C cycling in the rhizosphere. Briefly, root exudates and the inoculated AMF not only stimulated the decomposition of litter and SOC and promoted the production of CO 2 emission, but also drove soil C persistence by unlocking mineral elements and promoting the formation of reactive minerals. Together, these findings provide new insights into the mechanisms that underlie the formation of reactive minerals and have significant implications for understanding and managing soil C persistence.

Topics & Concepts

MineralEnvironmental scienceCarbon sequestrationCarbon fibersEarth scienceEnvironmental chemistryGeochemistryGeologyChemistryEcologyCarbon dioxideBiologyMaterials scienceComposite numberComposite materialMycorrhizal Fungi and Plant InteractionsSoil Carbon and Nitrogen DynamicsHeavy metals in environment