Unraveling mechanisms of mechanical shear stress-regulated high nitrite production in denitrification: granular structure and metagenomic evidence
摘要
Partial denitrification granules (PDG) offer a novel approach to supplying nitrite (NO2−) for anammox. Shear stress (τ) induced by mechanical stirring has been recognized as an effective operational strategy for enhancing mass transfer in continuous-flow PDG systems with minimal gas production. However, the effects of shear stress intensity on nitrite (NO2−) accumulation, granular structure, and microbial succession remains unclear. This study established two continuously up-flow PDG systems to assess the influence of low-strength τ (0.2–0.5 Pa) and high-strength τ (1.2–1.4 Pa) on PDG performance under dynamic nitrate (NO3−) loading rates (NLR). Results indicated that low-strength τ promoted the formation of 1–2 mm granules, mitigating the washout of flocs and smaller granules, and sustaining a stable nitrite production rate (NPR) of 7.7 kg N/m3·d) at an NLR as high as 11.7 kg N/(m3·d). In contrast, high-strength τ caused particle fragmentation and reaggregation, accompanied by the washout of sludge containing PD bacteria, leading to a lower NPR of 0.2 kg N/(m3·d). Metagenomic analysis revealed that low-strength τ enhanced nitrogen-carbon metabolism, with Thauera.sp. and Thauera_phenylacetica synergistically driving NO2− accumulation. Although high-strength τ promoted the enrichment of Thauera (∼70%), Thauera.sp. decreased its contribution to napA and improved to nirK, whereas Thauera_phenylacetica reduced its contribution to napA, thereby constraining NO2− accumulation. These findings provide critical insights into optimizing shear conditions for PDG and enhance the understanding of the metagenomic mechanisms of PD.