Abstract
The increasing occurrence of tetrabromobisphenol A (TBBPA) in the environment is raising questions about its potential ecological and human health impacts. TBBPA is microbially transformed under anaerobic conditions to bisphenol A (BPA). However, little is known about which taxa degrade TBBPA and the adaptation of microbial communities exposed to TBBPA. The objectives of this study were to characterize the effect of TBBPA on microbial community structure during the start-up phase of a bench-scale anaerobic sludge reactor, and identify taxa that may be associated with TBBPA degradation. TBBPA degradation was monitored using LC/MS-MS, and the microbial community was characterized using Ion Torrent sequencing and qPCR. TBBPA was nearly completely transformed to BPA via reductive debromination in 55 days. Anaerobic reactor performance was not negatively affected by the presence of TBBPA and the bulk of the microbial community did not experience significant shifts. Several taxa showed a positive response to TBBPA, suggesting they may be associated with TBBPA degradation. Some of these taxa had been previously identified as dehalogenating bacteria including Dehalococcoides, Desulfovibrio, Propionibacterium, and Methylosinus species, but most had not previously been identified as having dehalogenating capacities. This study is the first to provide in-depth information on the microbial dynamics of anaerobic microbial communities exposed to TBBPA.
Highlights
Tetrabromobisphenol A (TBBPA) is currently the most highly produced brominated flame retardant, globally
At Day 28, while no significant degradation had occurred in the co-metabolic reactors, 26±21.6% of tetrabromobisphenol A (TBBPA) had already been transformed in the metabolic reactors
TBBPA degradation started after a longer lag period in the co-metabolic reactors, TBBPA was almost completely transformed over a shorter period of time
Summary
Tetrabromobisphenol A (TBBPA) is currently the most highly produced brominated flame retardant, globally. Used in the electronic industry, TBBPA is added to plastics and printed circuit boards at concentrations ranging from 10 to 20% by polymer weight[1]. Not classified as acutely toxic, TBBPA has been shown to illicit various toxicological responses in aquatic wildlife[3,4,5,6], and mammals[7]. Due to its structural resemblance to the thyroid hormone precursor, thyroxine[8], TBBPA has been shown to disrupt thyroid and estrogen regulative functions[9], cause liver and kidney damage[10], and increase risks of uterine cancer in mammals[11].
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