Autotrophic biological nitrogen removal in anammox system at elevated temperature: EPS regulation and metagenomic analysis

Abstract

Carbon reduction in wastewater treatment industry has been attracted global attention. Anaerobic ammonium oxidation (anammox) process is known as a promising and energy-efficient technology. In this study, the effects of elevated temperature on anammox system were thoroughly investigated. Analyses of effluent and microbial community indicated that long-term exposure to 45℃ led to system collapse and a huge shift in community structure. Network analysis revealed that the sudden drop in abundance of AnAOB at 45℃ (from 36.19 % to 10.71 %) made them uncompetitive with heterotrophic bacteria. The decrease of EPS concentration (a minimum of 7.22 mg·g−1-VSS at 45℃) combined with the enhancement of EPS metabolism at higher temperature suggested a shift in the role of EPS from protective function at 35℃ to utilization as a carbon source for heterotrophic bacteria at higher temperatures. Through constructing the cross-feeding relationships associated with amino acids, polysaccharides, and cofactors, we found the dependence of heterotrophs on AnAOB became weaker at high temperature, and the disturbances in interspecific relationships might be responsible for the collapse of the anammox system. This work presents significant insights into the engineering of anammox process under high temperature.