Beddow Jessica, Stolpe Björn, Cole Paula A, Lead Jamie R, Sapp Melanie, Lyons Brett P, Colbeck Ian, Whitby Corinne
School of Biological Sciences, University of Essex, Essex, CO4 3SQ, UK.
School of Geography, Earth and Environmental Sciences, University of Birmingham, Birmingham, B15 2TT, UK.
Environ Microbiol. 2017 Feb;19(2):500-510. doi: 10.1111/1462-2920.13441. Epub 2016 Jul 29.
Silver nanoparticles (AgNPs) enter estuaries via wastewater treatment effluents, where they can inhibit microorganisms, because of their antimicrobial properties. Ammonia-oxidising bacteria (AOB) and archaea (AOA) are involved in the first step of nitrification and are important to ecosystem function, especially where effluent discharge results in high nitrogen inputs. Here, we investigated the effect of a pulse addition of AgNPs on AOB and AOA ammonia monooxygenase (amoA) gene abundances and benthic nitrification potential rates (NPR) in low-salinity and mesohaline estuarine sediments. Whilst exposure to 0.5 mg L AgNPs had no significant effect on amoA gene abundances or NPR, 50 mg L AgNPs significantly decreased AOB amoA gene abundance (up to 76% over 14 days), and significantly decreased NPR by 20-fold in low-salinity sediments and by twofold in mesohaline sediments, after one day. AgNP behaviour differed between sites, whereby greater aggregation occurred in mesohaline waters (possibly due to higher salinity), which may have reduced toxicity. In conclusion, AgNPs have the potential to reduce ammonia oxidation in estuarine sediments, particularly where AgNPs accumulate over time and reach high concentrations. This could lead to long-term risks to nitrification, especially in polyhaline estuaries where ammonia-oxidation is largely driven by AOB.
银纳米颗粒(AgNPs)通过污水处理厂的废水进入河口,由于其抗菌特性,它们在河口能够抑制微生物。氨氧化细菌(AOB)和古菌(AOA)参与硝化作用的第一步,对生态系统功能至关重要,特别是在废水排放导致高氮输入的地方。在此,我们研究了脉冲添加AgNPs对低盐度和中盐度河口沉积物中AOB和AOA氨单加氧酶(amoA)基因丰度以及底栖硝化潜力速率(NPR)的影响。虽然暴露于0.5 mg/L的AgNPs对amoA基因丰度或NPR没有显著影响,但50 mg/L的AgNPs显著降低了AOB amoA基因丰度(14天内高达76%),并在一天后使低盐度沉积物中的NPR显著降低了20倍,中盐度沉积物中的NPR降低了两倍。AgNP在不同地点的行为有所不同,在中盐度水域中聚集程度更高(可能是由于盐度较高),这可能降低了毒性。总之,AgNPs有可能降低河口沉积物中的氨氧化作用,特别是在AgNPs随着时间积累并达到高浓度的地方。这可能会给硝化作用带来长期风险,尤其是在氨氧化主要由AOB驱动的多盐度河口。
