Abstract
Anthropogenic activities have resulted in the intensified use of water resources. For example, open pit bitumen extraction by Canada’s oil sands operations uses an estimated volume of three barrels of water for every barrel of oil produced. The waste tailings–oil sands process water (OSPW)–are stored in holding ponds, and present an environmental concern as they are comprised of residual hydrocarbons and metals. Following the hypothesis that endogenous OSPW microbial communities have an enhanced tolerance to heavy metals, we tested the capacity of planktonic and biofilm populations from OSPW to withstand metal ion challenges, using Cupriavidus metallidurans, a known metal-resistant organism, for comparison. The toxicity of the metals toward biofilm and planktonic bacterial populations was determined by measuring the minimum biofilm inhibitory concentrations (MBICs) and planktonic minimum inhibitory concentrations (MICs) using the MBEC ™ assay. We observed that the OSPW community and C. metallidurans had similar tolerances to 22 different metals. While thiophillic elements (Te, Ag, Cd, Ni) were found to be most toxic, the OSPW consortia demonstrated higher tolerance to metals reported in tailings ponds (Al, Fe, Mo, Pb). Metal toxicity correlated with a number of physicochemical characteristics of the metals. Parameters reflecting metal-ligand affinities showed fewer and weaker correlations for the community compared to C. metallidurans, suggesting that the OSPW consortia may have developed tolerance mechanisms toward metals present in their environment.
Highlights
Industrial wastewater has become a pervasive issue in the modern world
This contrasts that of C. metallidurans growth, whose planktonic inhibitory concentrations were not reached for Li, Ca, or Mg
In order to assess whether the oil sands process water (OSPW) consortia and C. metallidurans demonstrated a similar sensitivity to metal challenges, we investigated how the inhibitory concentrations of the metals correlated with the metals’ physicochemical characteristics
Summary
Industrial wastewater has become a pervasive issue in the modern world. Anthropogenic activities, such as mining, introduce and concentrate organic and inorganic contaminants from source or bodies to the surrounding environment [1]. We wanted to explore the hypothesis that microbes from industrial wastewaters would have metal tolerances reflective of the environment from which they were sourced. To this end, we evaluated an endogenous microbial community inoculated from the wastewater of a Canadian oil sands extraction operation for our proof of principle. The process of PLOS ONE | DOI:10.1371/journal.pone.0148682 February 5, 2016
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