Abstract
Nanoparticulate titanium dioxide (nTiO2) is frequently applied, raising concerns about potential side effects on the environment. While various studies have assessed structural effects in aquatic model ecosystems, its impact on ecosystem functions provided by microbial communities (biofilms) is not well understood. This is all the more the case when considering additional stressors, such as UV irradiation — a factor known to amplify nTiO2-induced toxicity. Using pairwise comparisons, we assessed the impact of UV (UV-A = 1.6 W/m2; UV-B = 0.7 W/m2) at 0, 20 or 2000 μg nTiO2/L on two ecosystem functions provided by leaf-associated biofilms: while leaf litter conditioning, important for detritivorous invertebrate nutrition, seems unaffected, microbial leaf decomposition was stimulated (up to 25%) by UV, with effect sizes being higher in the presence of nTiO2. Although stoichiometric and microbial analyses did not allow for uncovering the underlying mechanism, it seems plausible that the combination of a shift in biofilm community composition and activity together with photodegradation as well as the formation of reactive oxygen species triggered changes in leaf litter decomposition. The present study implies that the multiple functions a microbial community performs are not equally sensitive. Consequently, relying on one of the many functions realized by the same microbial community may be misleading for environmental management.
Highlights
IntroductionEngineered nanoparticles (NPs) feature unique physicochemical properties (e.g. size, surface area, surface reactivity, charge, shape) relative to their bulk or ionic counterparts (Bundschuh et al 2016), which makes them suitable for various applications
Engineered nanoparticles (NPs) feature unique physicochemical properties relative to their bulk or ionic counterparts (Bundschuh et al 2016), which makes them suitable for various applications
We assessed the effects of nTiO2 on leaf palatability for shredders, hypothesizing that UV irradiation would negatively influence leaf palatability for shredders, which could be explained by shifts in microbial conditioning
Summary
Engineered nanoparticles (NPs) feature unique physicochemical properties (e.g. size, surface area, surface reactivity, charge, shape) relative to their bulk or ionic counterparts (Bundschuh et al 2016), which makes them suitable for various applications. Nanoparticulate titanium dioxide (nTiO2), for instance, is used in a broad range of products including textiles, sunscreens, and facade paints Its environmental concentrations have been predicted to be in the microgram per litre range (Gottschalk et al 2013) and were reported to be up to 27 μg/L during the bathing season in a recreational lake in Austria (Gondikas et al 2014). Most studies assessing acute or chronic effects indicate only a low risk of nTiO2 for aquatic life (e.g. Seitz et al 2014; Zhu et al 2010), experimental evidence points towards substantial crossgenerational implications in aquatic key species at fieldrelevant concentrations (Bundschuh et al 2012)
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