Ammonia Oxidation in a Neutral Purple Soil Measured by the 13C-DNA-SIP Method

Abstract

Increasing evidence suggests that ammonia oxidation in acidic soils is primarily catalyzed by ammonia-oxidizing archaea (AOA), while ammonia-oxidizing bacteria (AOB) drive ammonia oxidation in neutral and alkaline soils in which AOA overwhelmingly outnumber AOB. Therefore, neutral purple soil with a pH of 7.2 was selected to study the composition of the active ammoxidation microbial community with a stable isotope nucleic acid probe technique combined with cloning sequencing. Results showed that the nitrification rate was 9.68 mg·(kg·d)-1, and AOA and AOB were abundant in neutral purple soils. By using DNA-based stable isotope probing (SIP), we gathered strong evidence of archaeal ammonia oxidation by AOA and AOB. Phylogenetic analysis indicated that the Nitrosospira Cluster 3a.1 AOB was dominant in terms of quantity at 0 days, and the Nitrosospira Cluster 3a.2 only accounted for a small part. After 56 days of cultivation, the Nitrosospira Cluster 3a.2 replaced the Nitrosospira Cluster 3a.1 as the active AOB that dominated ammonia oxidation. The AOA that predominated quantitatively at day 0 was Nitrososphaera Subcluster 9, but after cultivation this became Nitrososphaera Subcluster 3.2/3.3. Thus, the community structure of AOA and AOB changed. Active autotrophic nitrification was found in this neutral purple soil. Sequencing analysis of the 13C-labeled DNA provided robust evidence that both archaea and bacteria played important roles in the nitrification and not all ammonia oxidizers in native soil were active in the nitrification. Phylogenetic analysis clearly showed that the dominant active archaea and bacteria during the incubation were affiliated with Nitrososphaera Subcluster 3.2/3.3 within the soil group 1.1b lineage and Nitrosospira Cluster 3a.2, respectively, which were different from the dominant ammonia oxidizers at the beginning of the incubation. These results suggest that the community structure of ammonia oxidizers can shift quickly upon changes in the substrate availability in soils.