Characterization of microbial communities assimilating rhizosphere-deposited carbon in a soybean/maize intercropping system using the DNA-SIP technique

Abstract

Legume/cereal intercropping is an example of classic nitrogen-efficient planting that can effectively improve crop yield and nutrient-utilization efficiency. However, the interaction between rhizosphere microorganisms and rhizodeposition and the related ecological mechanisms remain unclear. We conducted a pot experiment using ¹³CO₂ continuous labeling, DNA stable isotope probe technology, high-throughput sequencing, and the carbon-nitrogen-phosphorus functional gene chip to effectively track rhizosphere-deposited C and compare the microorganisms that utilize this C pool in the rhizosphere of a soybean/maize intercropping system at 21 days after labeling. The relative abundance of Caldalkalibacillus and Nesterenkonia that use rhizosphere-deposited C was significantly higher in the soybean/maize intercropping system than in monocropped soybean, but there were no significant differences between intercropped and monocropped maize. The soybean/maize intercropping system altered the composition of the microbial community that utilizes rhizosphere-deposited C and reduced the community richness. Moreover, intercropping improved the expression of functional genes associated with carbon fixation (acsH and exg) and nitrous oxide reduction (nosZ1). Overall, by tracking the flow of C from plant photosynthetic products to root exudates, our research provides new insights into identifying the microbial communities that assimilate and deposit carbon in soil.