Synergistic degradation efficiency of nitrogen, phosphorus and microbial dynamic succession driven by a novel strain Gordonia sp. D4 during synthetic wastewater treatment

Nitrogen (N) and phosphorus (P) coexist in the industrial and domestic wastewater posed a pressing challenge for synergistic removal of N and P by bioenhancement. In this study, a novel denitrifying phosphorus-accumulating organism (DPAO) of Gordonia sp. D4, exhibited peak NO3--N, NO2--N, NH4+-N and TP removal efficiencies of 98.11%, 65.02%, 85.34% and 100%, corresponding to 9.30 mg/(L·h), 6.08 mg/(L·h), 3.63 mg/(L·h) and 0.47 mg/(L·h) removal rates, respectively. Strain D4 contained the nitrogen cycling genes narK, narI, narJ, narH, narG, nirB and nirD, as well as the phosphorus cycling genes ppk1, ppk2 and ppx-gppA, which contributes to its excellent simultaneous removal of N and P. More importantly, the addition of D4 into the sequencing batch reactor (SBR) significantly improved the P, TN and NO3--N removal efficiencies by 18.91%, 7.35%, and 18.55%, respectively. This was closely related to the clear enrichment of Gordonia and its contribution to the increasing abundances of Pararhodobacter, unclassified_f_Cyclobacteriaceae, unclassified_o_Rhodospirillales, Thauera and Candidatus Promineofilum and their associated functional genes that drive P or N removal, thereby enhancing the N and P synergistic degradation efficiency. This study provides a valuable strain resource and process reference for the simultaneously removing N and P from the wastewater.