Photosynthetic carbon (C) fixation and its partitioning in the plant-soil system are responsible for soil C sequestration and nutrient cycling. These microbially-mediated biogeochemical processess are impacted strongly by soil nutrient availability and soil moisture, which are being altered by global environmental change.
We studied the interactive effects of fertilization (fertilized vs unfertilized) and water regime (high-water vs low-water level) on plant C fixation and rhizodeposition, and the subsequent microbial processing of plant-derived C substrates in mesocosms planted with the wetland sedge Carex acuta. We used a (CO2)-C-13 pulse-labelling approach to track assimilates in plants, microbial phospholipid fatty acids (PLFA) and soils for 7 days.
Fertilizer X water regime interactions affected the dynamics of root C-13 efflux, microbial utilization and final C-13 sequestration in the soil. Plants growing in high-water unfertilized soils rapidly exuded a greater proportion of C-13 into the rhizosphere, but the temporal increase in soil 13C was lower than in the other treatments.
In contrast, the greatest temporal increase in soil C-13 was observed in high-water fertilized systems. This occurred because fertilized plants were more productive and fixed more C, which resulted in larger root biomass with faster turnover and consequently larger amounts of C-13 immobilized in the high-water fertilized soils than high-water unfertilized soils.
The composition of microbial communities processing the C rhizodeposits was dynamic during the 7 d study. Initially, the exuded C-13 was processed mainly by bacteria, while fungal PLFA became progressively more enriched after 7 d.
This indicates that fungi were the main recipients of C in rhizodeposits at this time, regardless of nutrient availability or soil water regime. In summary, fertilization of the C. acuta sedge wetland stimulated above- and belowground production and selected for a smaller but more active microbial community dominated by fungi.
Fertilization enhanced soil C sequestration of recently fixed photosynthates in this wet sedge grassland.