Transcriptomic and rRNA:rDNA signatures of environmental vs. enteric Enterococcus faecalis isolates under oligotrophic freshwater conditions

Abstract

ABSTRACTThe use of enterococci as a fecal indicator bacterial group for public health risk assessment has been brought into question by recent studies showing that “naturalized” populations of E. faecalis exist in the extraenteric environment in a viable but not culturable (VBNC) state. The extent to which these naturalized or VBNC E. faecalis can confound water quality monitoring is unclear. To determine if strains isolated from different habitats display different survival strategies and responses, we compared the decay patterns of three E. faecalis isolates from the natural environment (environmental strains) against three human gut isolates (enteric strains) in laboratory mesocosms that simulate an oligotrophic, aerobic freshwater environment. Our results showed similar overall decay rates between enteric and environmental isolates based on viable plate and qPCR counts. However, the enteric isolates exhibited a spike in rRNA:rDNA ratios between days 1 and 3 of the mesocosm incubations that was not observed in environmental isolates, which could indicate a different stress response. Nevertheless, there was no strong evidence of differential expression of genes thought to be related to habitat adaptation in the accompanying mesocosm metatranscriptomes when compared between environmental and enteric isolates. Overall, our results provide novel information on how rRNA levels may vary over different metabolic states (i.e., alive vs. VBNC) for this important indicator bacteria. We also observed some evidence for habitat adaptation in E. faecalis; however, this adaptation may not be substantial or consistent enough for integration in water quality monitoring.IMPORTANCEEnterococci are commonly used worldwide to monitor environmental fecal contamination and public health risk for waterborne diseases. However, some species within this group can enter an inactive, viable but not culturable (VBNC) state that make it difficult to accurately quantify during routine monitoring. Furthermore, lower-risk, environmental enterococci strains may also confound water quality estimates. We developed an rRNA:rDNA viability assay for E. faecalis (a predominant species within this fecal group) and tested it against both enteric and environmental isolates in freshwater mesocosms to assess whether this approach can serve as a more sensitive water quality monitoring tool. We were unable to reliably distinguish the different isolate types using this assay under the conditions tested here; thus, environmental strains should continue to be counted during routine water monitoring. However, this assay could be useful for distinguishing more recent (i.e., higher risk) fecal pollution because rRNA levels significantly decreased after one week in all isolates.