posted on 2015-10-20, 00:00authored byNicolette
A. Zhou, Henrik Kjeldal, Heidi L. Gough, Jeppe L. Nielsen
Discharge
of the endocrine disrupting compound bisphenol A (BPA)
with wastewater treatment plant (WWTP) effluents into surface waters
results in deleterious effects on aquatic life. Sphingobium sp. BiD32 was previously isolated from activated sludge based on
its ability to degrade BPA. This study investigated BPA metabolism
by Sphingobium sp. BiD32 using label-free
quantitative proteomics. The genome of Sphingobium sp. BiD32 was sequenced to provide a species-specific platform for
optimal protein identification. The bacterial proteomes of Sphingobium sp. BiD32 in the presence and absence
of BPA were identified and quantified. A total of 2155 proteins were
identified; 1174 of these proteins were quantified, and 184 of these
proteins had a statistically significant change in abundance in response
to the presence/absence of BPA (p ≤ 0.05).
Proteins encoded by genes previously identified to be responsible
for protocatechuate degradation were upregulated in the presence of
BPA. The analysis of the metabolites from BPA degradation by Sphingobium sp. BiD32 detected a hydroxylated metabolite.
A novel p-hydroxybenzoate hydroxylase enzyme detected
by proteomics was implicated in the metabolic pathway associated with
the detected metabolite. This enzyme is hypothesized to be involved
in BPA degradation by Sphingobium sp.
BiD32, and may serve as a future genetic marker for BPA degradation.