Effect of High Salinity on Elemental Sulfur Autotrophic Partial Denitrification and Feasibility Evaluation of an Enhanced Strategy with Glycine Betaine Addition: Performance, Microorganisms, and Mechanisms: Fid-Bau Portal

Effect of High Salinity on Elemental Sulfur Autotrophic Partial Denitrification and Feasibility Evaluation of an Enhanced Strategy with Glycine Betaine Addition: Performance, Microorganisms, and Mechanisms

Li, Yong / Chen, Bohan / Zhang, Xiaolei / Luo, Zhizhan / Lei, Mengen / Song, Tao / Wei, Youcheng / Li, Ji / Long, Zhiyun / Ma, Jun

Abstract

Elemental sulfur autotrophic partial denitrification (S⁰-PDN) can supply nitrite for anaerobic ammonium oxidation without an organic carbon requirement. This study aimed to evaluate the impact of high salinity on S⁰-PDN and investigate the feasibility of an enhanced strategy involving the addition of glycine betaine (GB). The results showed that high salinity inhibited S⁰-PDN by over 60% as salinity increased from low (0 and 5 g/L) to high (10 and 15 g/L) levels, even though Thiobacillus (65.9%–84.0%) was always the dominant genus. The reason might be the suppression of high salinity on the bioactivity. Surprisingly, the addition of GB (1 mmol/L) effectively enhanced the performance of S⁰-PDN under high salinity conditions (10 g/L), resulting in a 5.1-fold increase in the NO₃ ^–-N conversion efficiency and a 3.1-fold increase in the effluent NO₂ ^–-N concentration. Metagenomics analysis revealed that high salinity did not alter the dominant microbial composition. GB facilitated the recovery of the nitrate conversion capacity of sulfur autotrophic denitrifying bacteria with the up-regulation of nitrate reductase genes (by 18.1%) and Sox genes (by 21.4%). However, GB also stimulated the growth of heterotrophic denitrifying bacteria. Part of the nitrite produced in S⁰-PDN was reduced through heterotrophic denitrification with GB as an electron donor. Overall, the addition of GB was demonstrated as an effective approach to mitigate the inhibitory effects of high salinity on S⁰-PDN, which offers valuable theoretical support for its application in high-salinity wastewater treatment.