posted on 2018-07-24, 00:00authored bySandeep Sathyamoorthy, Catherine Hoar, Kartik Chandran
A wide
range of trace organic contaminants (TOrCs), including the
endocrine-disrupting compound bisphenol A (BPA), are subject to microbial
transformations during biological wastewater treatment. However, relatively
little is known about the identity of organisms capable of assimilating emerging contaminants. Here, 13C-DNA
stable isotope probing (DNA-SIP) was used to investigate biodegradation
and assimilation of BPA by mixed microbial communities collected from
two full-scale wastewater treatment plant bioreactors in New York
City and subsequently enriched under two BPA exposure conditions.
The four enrichment modes (two reactors with two initial BPA concentrations)
resulted in four distinct communities with different BPA degradation
rates. On the basis of DNA-SIP, bacteria related to Sphingobium spp. were dominant in the assimilation
of BPA or its metabolites. Variovorax spp. and Pusillimonas spp. also assimilated
BPA or its metabolites. Our results highlight that microbial communities
originating from wastewater treatment facilities harbor the potential
for addressing not only human-derived carbon but also BPA, a complex
anthropogenic TOrC. While previous studies focus on microbial biodegradation
of BPA, this study uniquely determines the “active”
fraction of microorganisms engaged in assimilation of BPA-derived
carbon. Ultimately, information on both biodegradation and assimilation
can facilitate better design and operation of engineered treatment
processes to achieve BPA removal.