Dissolved oxygen disturbs nitrate transformation by modifying microbial community, co-occurrence networks, and functional genes during aerobic-anoxic transition

Xiaoyan Liu; Sihai Hu; Ran Sun; Yaoguo Wu; Zixia Qiao; Sichang Wang; Zehong Zhang; Chuwen Cui

doi:10.1016/j.scitotenv.2021.148245

Dissolved oxygen disturbs nitrate transformation by modifying microbial community, co-occurrence networks, and functional genes during aerobic-anoxic transition

Sci Total Environ. 2021 Oct 10:790:148245. doi: 10.1016/j.scitotenv.2021.148245. Epub 2021 Jun 8.

Authors

Xiaoyan Liu¹, Sihai Hu¹, Ran Sun¹, Yaoguo Wu², Zixia Qiao¹, Sichang Wang¹, Zehong Zhang¹, Chuwen Cui¹

Affiliations

¹ School of Chemistry and Chemical Engineering, Northwestern Polytechnical University, Xi'an 710129, China.
² School of Chemistry and Chemical Engineering, Northwestern Polytechnical University, Xi'an 710129, China. Electronic address: wuygal@nwpu.edu.cn.

PMID: 34380284
DOI: 10.1016/j.scitotenv.2021.148245

Abstract

No consensus has been achieved among researchers on the effect of dissolved oxygen (DO) on nitrate (NO₃^--N) transformation and the microbial community, especially during aerobic-anoxic transition. To supplement this knowledge, NO₃^--N transformation, microbial communities, co-occurrence networks, and functional genes were investigated during aerobic-anoxic transition via microcosm simulation. NO₃^--N transformation rate in the early stage (DO ≥2 mg/L) was always significantly higher than that in the later stage (DO <2 mg/L) during aerobic-anoxic transition, and NO₂^--N accumulation was more significant during the anoxic stage, consistent with the result obtained under constant DO conditions. These NO₃^--N transformation characteristics were not affected by other environmental factors, indicating the important role of DO in NO₃^--N transformation during aerobic-anoxic transition. Changes in DO provoked significant alterations in microbial diversity and abundance of functional bacteria dominated by Massilia, Bacillus, and Pseudomonas, leading to the variation in NO₃^--N transformation. Co-occurrence network analysis revealed that NO₃^--N transformation was performed by the interactions between functional bacteria including symbiotic and competitive relationship. In the presence of oxygen, these interactions accelerated the NO₃^--N transformation rate, and bacterial metabolization proceeded via increasingly varied pathways including aerobic and anoxic respiration, which was demonstrated through predicted genes. The higher relative abundance of genes narG, narH, and napA suggested the occurrence of coupled aerobic-anoxic denitrification in the early stage. NO₃^--N transformation rate decreased accompanied by a significant NO₂^--N accumulation with the weakening of coupled aerobic-anoxic denitrification during aerobic-anoxic transition. Structural equation modeling further demonstrated the relationship between DO and NO₃^--N transformation. DO affects NO₃^--N transformation by modifying microbial community, bacterial co-occurrence, and functional genes during aerobic-anoxic transition.

Keywords: Aerobic-anoxic transition; Co-occurrence network; Dissolved oxygen; Microbial communities; Nitrate transformation.

MeSH terms

Bioreactors
Denitrification
Microbiota*
Nitrates*
Nitrogen
Nitrogen Oxides
Oxygen

Substances

Nitrates
Nitrogen Oxides
Nitrogen
Oxygen