Denitrifying Bacteria from the Genus Rhodanobacter Dominate Bacterial Communities in the Highly Contaminated Subsurface of a Nuclear Legacy Waste Site

Stefan J Green,James M Tiedje,Daniela Hubbard,Puja Jasrotia,Will A Overholt,David B Watson,Erick Cardenas,Scott C Brooks,Om Prakash,Joel E Kostka,Christopher W Schadt

doi:10.1128/aem.06435-11

Abstract

The effect of long-term mixed-waste contamination, particularly uranium and nitrate, on the microbial community in the terrestrial subsurface was investigated at the field scale at the Oak Ridge Integrated Field Research Challenge (ORIFRC) site in Oak Ridge, TN. The abundance, community composition, and distribution of groundwater microorganisms were examined across the site during two seasonal sampling events. At representative locations, subsurface sediment was also examined from two boreholes, one sampled from the most heavily contaminated area of the site and another from an area with low contamination. A suite of DNA- and RNA-based molecular tools were employed for community characterization, including quantitative PCR of rRNA and nitrite reductase genes, community composition fingerprinting analysis, and high-throughput pyrotag sequencing of rRNA genes. The results demonstrate that pH is a major driver of the subsurface microbial community structure and that denitrifying bacteria from the genus Rhodanobacter (class Gammaproteobacteria) dominate at low pH. The relative abundance of bacteria from this genus was positively correlated with lower-pH conditions, and these bacteria were abundant and active in the most highly contaminated areas. Other factors, such as the concentration of nitrogen species, oxygen level, and sampling season, did not appear to strongly influence the distribution of Rhodanobacter bacteria. The results indicate that these organisms are acid-tolerant denitrifiers, well suited to the acidic, nitrate-rich subsurface conditions, and pH is confirmed as a dominant driver of bacterial community structure in this contaminated subsurface environment.

Highlights

The effect of long-term mixed-waste contamination, uranium and nitrate, on the microbial community in the terrestrial subsurface was investigated at the field scale at the Oak Ridge Integrated Field Research Challenge (ORIFRC) site in Oak Ridge, TN
QPCR data from 35 sampling points were recovered, and these were characteristic of the broad range of subsurface geochemical conditions across the site, ranging from highly acidic and nitrate-rich close to the contaminant source zone (Area 3) to circumneutral with lower contaminant levels down gradient from the source zone (Area 2)
The contaminant source zone (Area 3) of the ORIFRC site contains low microbial abundance and diversity where subsurface microbial communities are adapted to extremely high contaminant concentrations

Summary

Introduction

The effect of long-term mixed-waste contamination, uranium and nitrate, on the microbial community in the terrestrial subsurface was investigated at the field scale at the Oak Ridge Integrated Field Research Challenge (ORIFRC) site in Oak Ridge, TN. The relative abundance of bacteria from this genus was positively correlated with lower-pH conditions, and these bacteria were abundant and active in the most highly contaminated areas Other factors, such as the concentration of nitrogen species, oxygen level, and sampling season, did not appear to strongly influence the distribution of Rhodanobacter bacteria. Research on subsurface ecosystems has intensified over the past two decades, leading to important discoveries on the ecology, physiology, and phylogeny of subsurface microorganisms [14, 24]. There is geochemical evidence for active denitrification at the site (Juske Horita, personal communication), and several groups have previously isolated denitrifying bacteria from the ORIFRC site subsurface [25, 47, 52]

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Conclusion