Tire-wear microplastics (T-MPs) are increasingly present in surface water, which can intact with ferrihydrite and influence biofilm formation on T-MPs. However, the interaction of T-MPs and ferrihydrite on biofilm formation and its effect on nitrogen transformation in surface water is still unknown. In this paper, four sets of experiments were set up in simulated surface water inoculated with precultured bacteria, respectively, A: simulated surface water, B: addition of ferrihydrite, C: addition of T-MPs, and D: addition of both T-MPs and ferrihydrite. Characterization results showed that co-exposure of T-MPs and ferrihydrite increased roughness and decreased hydrophobicity in the surface of T-MPs, and resulted in higher biomass and EPS values in biofilm of T-MPs with ferrihydrite. Under co-exposure, the nitrate removal efficiency for 12 h was increased by 32.37 % and 25.74 % comparing with single ferrihydrite and T-MPs, and the accumulation and removal of nitrite as well as the production of higher concentrations of nitrous oxide indicated that the co-exposure contributed to the denitrification and stimulated nitrogen transformation. Furthermore, α-diversity index characterized a rich microbial community, especially the enrichment of functional microorganisms Firmicutes and Thauera, which were altered to enhance nitrogen transformation function (glutamine synthetase, nitronate monooxygenase). Ferrihydrite promoted complete denitrification process in the system and strengthened the role of nitrogen transformation microorganisms in the T-MPs biofilm. The abundance of key enzymes and functional genes (napA, nrtC, nirB, nosZ) increased with co-exposure T-MPs and ferrihydrite, and genes associated with nitrate and nitrite reduction (narG, narI) exhibited higher abundance in biofilm of T-MPs compared to the surrounding water. This research provided important insights into the effects of T-MPs co-exposure interactions with ferrihydrite on nitrogen transformation in surface water.
Read full abstract