Comparison of the transport of Bacteroides fragilis and Escherichia coli within saturated sand packs.

Pathogens in groundwater accounted for ∼50% of waterborne disease outbreaks in the United States between 1971 and 2006. The fast and reliable detection of groundwater microbial contamination and the identification of the contamination sources are of critical importance to the protection of public health. Recent studies suggested that fecal anaerobe Bacteriodes spp. could be employed as an effective tool for surface water microbial source tracking (MST). The usefulness of Bacteroides spp. for groundwater MST depends strongly on its mobility within the subsurface system. This research provides laboratory results comparing transport and attachment of E. coli K12 and B. fragilis within packed quartz sands. The results indicate that at low ionic strengths both E. coli K12 and B. fragilis are readily transported through saturated sand packs. At higher ionic strengths such as may be found near concentrated sources of fecal contamination, B. fragilis displayed significantly higher mobility than E. coli K12. Analysis of the extended Derjaguin-Landau-Verweu-Overbeek (XDLVO) energy interactions for both types of bacteria showed a significant repulsive energy barrier exists between the sand surface and the bacteria, precluding attachment directly to the sand surface. However a secondary minimum energy level exists under higher ionic strength conditions. The depth of this energy low is greater for E. coli K12, which results in greater attachment of E. coli K12 than of B. fragilis. The high mobility of B. fragilis suggests that it represents a promising tool for the detection of groundwater fecal contamination as well as the identification of the microbial sources.

Influence of enterococcal surface protein (esp) on the transport of Enterococcus faecium within saturated quartz sands.

Enterococcus was selected by US EPA as a Gram-positive indicator microorganism for groundwater fecal contamination. It was recently reported that enterococcal surface protein (esp) was more prevalent in Enterococcus from human sources than in Enterococcus from nonhuman sources and esp could potentially be used as a source tracking tool for fecal contamination (Scott et al., 2005). In this research, we performed laboratory column transport experiments to investigate the transport of Enterococcus faecium within saturated quartz sands. Particularly, we used a wild type strain (E1162) and a mutant (E1162Δesp) to examine the influence of esp on the transport behavior of E. faecium. Our results showed that esp could significantly enhance the attachment of E. faecium cells onto the surface of silica sands and thus lower the mobility of E. faecium within sand packs. Cell surface properties (e.g., zeta potential) were determined and the extended Derjaguin-Landau-Verwey-Overbeek (XDLVO) theory was applied to explain the effects of esp on the retention of E. faecium. Overall, our results suggested that E. faecium strains with esp could display lower mobility within saturated sand packs than E. faecium strains without esp. The disparity in the transport behavior of E. faecium with and without esp could limit the effectiveness of esp as a source tracking tool within the groundwater system.