Chronic addition of a common engineered nanomaterial alters biomass, activity and composition of stream biofilm communities

• Published in: Environmental science. Nano Vol. 3; no. 3; pp. 619 - 63
• Main Authors: Binh, Chu Thi Thanh, Adams, Erin, Vigen, Erika, Tong, Tiezheng, Alsina, Marco A, Gaillard, Jean-François, Gray, Kimberly A, Peterson, Christopher G, Kelly, John J
• Format: Journal Article
• Language: English
• Published: 01.01.2016
• Subjects: Algae; Azoarcus; Bacteria; Biofilms; Communities; Ecosystems; Microorganisms; Nanostructure; Paracoccus; Streams
• ISSN: 2051-8153; 2051-8161
• DOI: 10.1039/c5en00274e

Nano-TiO 2 is an engineered nanomaterial that is found in a wide range of commercial products. Production of nano-TiO 2 has increased rapidly over the last several decades, raising concerns about release of this material into the environment. Domestic wastewater is one route through which this material enters the environment, resulting in chronic inputs of low concentrations of nano-TiO 2 to surface waters. The goal of this study was to assess impacts of chronic addition of an environmentally realistic concentration of nano-TiO 2 on microbial biofilms, which play a foundational role in lotic ecosystems. Microbial consortia were collected from natural benthic habitats, cultivated in stream mesocosms, and exposed to daily additions of commercial nano-TiO 2 pigment at a concentration that has been measured in treated wastewater effluent (30 μg L −1 ). After 22 weeks treated streams showed significantly lower amounts of biofilm (biofilm mass, bacterial and algal cell densities), lower biofilm metabolic activity (respiration and photosynthesis) and altered algal and bacterial community composition (the latter based on high-throughput sequencing of 16S rRNA genes) as compared to control streams. Specific changes in bacterial communities resulting from nano-TiO 2 additions included increases in relative abundance of taxa linked to resistance to reactive oxygen species ( Novosphingobium and Achromobacter ) and decreases in relative abundance of taxa linked to nitrogen fixation ( Pleurocapsa and Azoarcus ) and denitrification ( Paracoccus ). These data provide one of the first demonstrations that low-level, chronic release of nano-TiO 2 to streams can have significant, negative effects on structure and function of benthic communities and the critical ecosystem services they provide. We report that chronic addition of a low-concentration of nano-TiO 2 to model streams reduced biofilm-associated microbial abundance and activity.