We conducted experiments to determine whether bioaugmentation
with
aerobic, polychlorinated biphenyl (PCB)-degrading microorganisms can
mitigate polychlorinated biphenyl (PCB) emissions from contaminated
sediment to air. Paraburkholderia xenovorans strain LB400 was added to bioreactors containing PCB-contaminated
site sediment. PCB mass in both the headspace and aqueous bioreactor
compartments was measured using passive samplers over 35 days. Time-series
measurements of all 209 PCB congeners revealed a 57% decrease in total
PCB mass accumulated in the vapor phase of bioaugmented treatments
relative to non-bioaugmented controls, on average. A comparative congener-specific
analysis revealed preferential biodegradation of lower-chlorinated
PCBs (LC-PCBs) by LB400. Release of the most abundant congener (PCB
4 [2,2′-dichlorobiphenyl]) decreased by over 90%. Simulations
with a PCB reactive transport model closely aligned with experimental
observations. We also evaluated the effect of the phytogenic biosurfactant,
saponin, on PCB bioavailability and biodegradation by LB400. Time-series
qPCR measurements of biphenyl dioxygenase (bphA)
genes showed that saponin better maintained bphA abundance,
compared to the saponin-free treatment. These findings indicate that
an active population of bioaugmented, aerobic PCB-degrading microorganisms
can effectively lower PCB emissions and may therefore contribute to
minimizing PCB inhalation exposure in communities surrounding PCB-contaminated
sites.
Polychlorinated biphenyls (PCBs) are a class of persistent organic pollutants that are distributed worldwide. Although industrial PCB production has stopped, legacy contamination can be traced to several different commercial mixtures (e.g., Aroclors in the USA). Despite their persistence, PCBs are subject to naturally occurring biodegradation processes, although the microbes and enzymes involved are poorly understood. The biodegradation potential of PCB-contaminated sediments in a wastewater lagoon located in Virginia (USA) was studied. Total PCB concentrations in sediments ranged from 6.34 to 12,700 mg/kg. PCB congener profiles in sediment sample were similar to Aroclor 1248; however, PCB congener profiles at several locations showed evidence of dechlorination. The sediment microbial community structure varied among samples but was dominated by Proteobacteria and Firmicutes. The relative abundance of putative dechlorinating Chloroflexi (including Dehalococcoides sp.) was 0.01–0.19% among the sediment samples, with Dehalococcoides sp. representing 0.6–14.8% of this group. Other possible PCB dechlorinators present included the Clostridia and the Geobacteraceae. A PCR survey for potential PCB reductive dehalogenase genes (RDases) yielded 11 sequences related to RDase genes in PCB-respiring Dehalococcoides mccartyi strain CG5 and PCB-dechlorinating D. mccartyi strain CBDB1. This is the first study to retrieve potential PCB RDase genes from unenriched PCB-contaminated sediments.
Microbial communities that support respiration of halogenated organic contaminants by Dehalococcoides sp. facilitate full-scale bioremediation of chlorinated ethenes and demonstrate the potential to aid in bioremediation of halogenated aromatics like polychlorinated biphenyls (PCBs). However, it remains unclear if Dehalococcoides-containing microbial community dynamics observed in sediment-free systems quantitatively resemble that of sediment environments. To evaluate that possibility we assembled, annotated, and analyzed a Dehalococcoides sp. metagenome-assembled genome (MAG) from PCB-contaminated sediments. Phylogenetic analysis of reductive dehalogenase gene (rdhA) sequences within the MAG revealed that pcbA1 and pcbA4/5-like rdhA were absent, while several candidate PCB dehalogenase genes and potentially novel rdhA sequences were identified. Using a compositional comparative metagenomics approach, we quantified Dehalococcoides-containing microbial community structure shifts in response to halogenated organics and the presence of sediments. Functional level analysis revealed significantly greater abundances of genes associated with cobamide remodeling and horizontal gene transfer in tetrachloroethene-fed cultures as compared to halogenated aromatic-exposed consortia with or without sediments, despite little evidence of statistically significant differences in microbial community taxonomic structure. Our findings support the use of a generalizable comparative metagenomics workflow to evaluate Dehalococcoides-containing consortia in sediments and sediment-free environments to eludicate functions and microbial interactions that facilitate bioremediation of halogenated organic contaminants.
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