The Impact of Litter from Different Belowground Organs of <i>Phragmites australis</i> on Microbial-Mediated Soil Organic Carbon Accumulation in a Lacustrine Wetland

The Impact of Litter from Different Belowground Organs of <i>Phragmites australis</i> on Microbial-Mediated Soil Organic Carbon Accumulation in a Lacustrine Wetland

Although belowground litter decomposition critically influences lacustrine wetland soil carbon dynamics, the organ-specific microbial mechanisms driving soil organic carbon (SOC) accumulation remain unclear. Existing research has predominantly focused on aboveground litter, leaving a significant gap...

Full description

Saved in:
Bibliographic Details
Main Authors: Chong Chen, Yong Wang, Liu Yang, Yongen Min, Keming Yue, Sitong Lu, Hongfeng Bian, Xue Wang, Leilei Zhang
Format: Article
Language:English
Published: MDPI AG 2025-05-01
Series:Microorganisms
Subjects:
belowground plant litter
community assembly
soil microorganisms
soil organic carbon
survival strategies
Online Access:https://www.mdpi.com/2076-2607/13/5/1146
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Although belowground litter decomposition critically influences lacustrine wetland soil carbon dynamics, the organ-specific microbial mechanisms driving soil organic carbon (SOC) accumulation remain unclear. Existing research has predominantly focused on aboveground litter, leaving a significant gap in the understanding of how roots and rhizomes differentially regulate carbon cycling through microbial community assembly and survival strategies. This study took <i>Phragmites australis</i> (a plant characteristic of lacustrine wetland) as the research object and examined how decomposing belowground litter from different organs affects microbial-mediated SOC accumulation through a one-year in situ field incubation in Jingyuetan National Forest Park, Changchun City, Jilin Province, China. Our findings reveal that root litter exhibited the highest decomposition rate, which was accelerated by intermittent flooding, reaching up to 1.86 times that of rhizome. This process enriched r-strategist microbial taxa, intensified homogeneous selection, and expanded niche width, directly promoting SOC accumulation. Rhizome litter decomposition enhanced dispersal limitation, promoted K-strategist microbial dominance, and indirectly modulated SOC through soil acidification. Mixed-litter treatments significantly enhanced SOC accumulation (up to three times higher than single-litter treatments) through synergistic nutrient release (non-additive effects < 0.04) and reinforced microbial network interactions. SOC accumulation varied significantly with the flooding regime as follows: non-flooded > intermittent flooding > permanent flooding. This study provides new insights into the microbially driven mechanisms of plant-organ-specific decomposition in the carbon cycling of wetland ecosystems.
ISSN:2076-2607

Similar Items