Opportunistic bacteria dominate the soil microbiome response to phenanthrene in a microcosm-based study
Storey, Sean Ashaari, Mardiana Mohd Clipson, Nicholas Doyle, Evelyn de Menezes, Alexandre B.
Storey, Sean
Ashaari, Mardiana Mohd
Clipson, Nicholas
Doyle, Evelyn
de Menezes, Alexandre B.
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Publication Date
2018-11-21
Type
Article
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Citation
Storey, Sean, Ashaari, Mardiana Mohd, Clipson, Nicholas, Doyle, Evelyn, & de Menezes, Alexandre B. (2018). Opportunistic Bacteria Dominate the Soil Microbiome Response to Phenanthrene in a Microcosm-Based Study. Frontiers in Microbiology, 9(2815). doi: 10.3389/fmicb.2018.02815
Abstract
Bioremediation offers a sustainable approach for removal of polycyclic aromatic hydrocarbons (PAHs) from the environment; however, information regarding the microbial communities involved remains limited. In this study, microbial community dynamics and the abundance of the key gene (PAH-RHDa) encoding a ring hydroxylating dioxygenase involved in PAH degradation were examined during degradation of phenanthrene in a podzolic soil from the site of a former timber treatment facility. The 10,000-fold greater abundance of this gene associated with Gram-positive bacteria found in phenanthrene-amended soil compared to unamended soil indicated the likely role of Gram-positive bacteria in PAH degradation. In contrast, the abundance of the Gram-negative PAHs-RHDa gene was very low throughout the experiment. While phenanthrene induced increases in the abundance of a small number of OTUs from the Actinomycetales and Sphingomonadale, most of the remainder of the community remained stable. A single unclassified OTU from the Micrococcaceae family increased similar to 20-fold in relative abundance, reaching 32% of the total sequences in amended microcosms on day 7 of the experiment. The relative abundance of this same OTU increased 4.5-fold in unamended soils, and a similar pattern was observed for the second most abundant PAH-responsive OTU, classified into the Sphingomonas genus. Furthermore, the relative abundance of both of these OTUs decreased substantially between days 7 and 17 in the phenanthrene-amended and control microcosms. This suggests that their opportunistic phenotype, in addition to likely PAH-degrading ability, was determinant in the vigorous growth of dominant PAH-responsive OTUs following phenanthrene amendment. This study provides new information on the temporal response of soil microbial communities to the presence and degradation of a significant environmental pollutant, and as such has the potential to inform the design of PAH bioremediation protocols.
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Frontiers Media
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Attribution-NonCommercial-NoDerivs 3.0 Ireland