Abstract
Here, we report and discuss the applicability of Variovorax paradoxus strain BFB1_13 in the bioremediation of BTEX contaminated sites. Strain BFB1_13 was capable of degrading all the six BTEX-compounds under both aerobic (O2 conc. 8 mg l−1) and micro-aerobic/oxygen-limited (O2 conc. 0.5 mg l−1) conditions using either individual (8 mg‧l−1) or a mixture of compounds (~ 1.3 mg‧l−1 of each BTEX compound). The BTEX biodegradation capability of SBP-encapsulated cultures (SBP—Small Bioreactor Platform) was also assessed. The fastest degradation rate was observed in the case of aerobic benzene biodegradation (8 mg l−1 per 90 h). Complete biodegradation of other BTEX occurred after at least 168 h of incubation, irrespective of the oxygenation and encapsulation. No statistically significant difference was observed between aerobic and microaerobic BTEX biodegradation. Genes involved in BTEX biodegradation were annotated and degradation pathways were predicted based on whole-genome shotgun sequencing and metabolic analysis. We conclude that V. paradoxus strain BFB1_13 could be used for the development of reactive biobarriers for the containment and in situ decontamination of BTEX contaminated groundwater plumes. Our results suggest that V. paradoxus strain BFB1_13—alone or in co-culture with other BTEX degrading bacterial isolates—can be a new and efficient commercial bioremediation agent for BTEX contaminated sites.
Highlights
BTEX compounds are of great concern as they are common water resource and potable water contaminants posing risk to the human health (Li et al 2017)
No significant difference between aerobic and microaerobic BTEX biodegradation
By using planktonic and Small Bioreactor Platform technology (SBP) encapsulated cultures of strain BFB1_13, we investigated aerobic and micro-aerobic/ oxygen-limited biodegradation of BTEX compounds
Summary
BTEX (benzene, toluene, ethylbenzene, o-, m- and p-xylene) compounds are of great concern as they are common water resource and potable water contaminants posing risk to the human health (Li et al 2017). Their presence in groundwater is especially worrisome in vulnerable regions like Africa and South-East Asia, where the population is highly dependent on drinking water from wells and boreholes (Fayemiwo et al 2017). BTEX are treated as priority pollutants according to U.S EPA They are included in the Hazardous Air Pollutants List (rank 78) in the CERLA List from the 275 substances identified as significant threats to human health (Rahul and Balomajumder 2013). O-, m- and p-xylene have severe acute effects of exposure such as neurotoxicity and reproductive problems (Wilbur and Bosch 2004)
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