Biotransformation of Sulfluramid (N-ethyl perfluorooctane sulfonamide) and dynamics of associated rhizospheric microbial community in microcosms of wetland plants.

Autor: Yin, Tingru1, Te, Shu Harn2, Reinhard, Martin2,3, Yang, Yi2, Chen, Huiting2, He, Yiliang1,4 ylhe@sjtu.edu.cn, Gin, Karina Yew-Hoong1,2 ceeginyh@nus.edu.sg
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Zdroj: Chemosphere. Nov2018, Vol. 211, p379-389. 11p.
Abstrakt: Abstract Although the use of Sulfluramid (N-ethyl perfluorooctane sulfonamide (N-EtFOSA)) has been restricted by the Stockholm Convention, it is still frequently detected in the environmental matrices and in use in some countries. Employing constructed wetlands as treatment systems requires understanding of the biodegradation process in the rhizosphere and the effect of contaminants on the microbes of wetlands. This study aimed to investigate the interactions between the microbial community and N-EtFOSA under aerobic and anaerobic conditions. Aerobic biotransformation of N-EtFOSA occurred with a half-life of 0.51 day and yielded 85.1 mol% PFOS of after 91 days. Kinetic modelling revealed that cleavage of the S N was the rate-limiting degradation step. Biotransformation was not observed under anaerobic and anoxic conditions, suggesting that N-EtFOSA is recalcitrant to biodegradation without dissolved oxygen. Under aerobic condition, the presence of N-EtFOSA and its biotransformation products decreased the microbial richness and diversity and exerted selective pressure on the microbial community. Enrichment of Methylocaldum was significant (49%) in the presence of N-EtFOSA compared to unexposed conditions (11%), suggesting that Methylocaldum is relatively tolerant to N-EtFOSA and potentially degrading N-EtFOSA. Under anaerobic conditions, the microbial richness and diversity were not significantly altered by the presence of N-EtFOSA. Only Methanomethylovorans increased significantly in the spiked microcosm (30% vs. 20%). These findings provide knowledge for comprehending the contribution of N-EtFOSA to other PFASs in various environmental conditions, information about microbial community changes in response to PFASs and robust microbial species which can degrade N-EtFOSA in the environment. Graphical abstract Image 1 Highlights • Biodegradation and microbial population shifts were studied in wetland microcosms. • Spiked N-EtFOSA was biotransformed aerobically but not anaerobically. • PFOS yield was 85.1 mol% after 91 days of aerobic incubation. • During aerobic degradation, the microbial community shifted to Methylocaldum. • Anaerobic exposure to N-EtFOSA had no significant effect on the community. [ABSTRACT FROM AUTHOR]
Databáze: GreenFILE
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