| Article ID | Journal | Published Year | Pages | File Type |
|---|---|---|---|---|
| 6365800 | Water Research | 2015 | 8 Pages |
â¢Catellicoccus marimammalium and enterococci decay were measured in sand and seawater.â¢Decay was quicker in wetted vs. unwetted sand and in sunlit vs. dark seawater.â¢Decay of the targets was similar in sand and dark seawater.â¢Decay varied among targets in sunlit seawater.â¢Understanding temporal stability of the targets is important for source allocation.
Most studies characterize microbial source tracking (MST) target performance using sensitivity and specificity metrics. However, it is important to also consider the temporal stability of MST targets in relation to regulated microbial pollutants. Differences among bacterial target stabilities may lead to erroneous conclusions about sources of contamination. The present study evaluates the relative stability of MST targets and fecal indicator organisms using the gull/pigeon-associated Catellicoccus marimammalium (CAT) marker and enterococci (ENT). The decay rates of CAT and ENT measured by culture (cENT) and QPCR (tENT) were compared in sand and seawater laboratory microcosms under environmentally relevant conditions (subject to tidal wetting versus no wetting in sand, and sunlit versus dark conditions in seawater). Bacterial targets were more persistent in beach sand than in seawater with decay rates on the order of 0.01-0.1 per day and 1 to 10 per day, respectively. Targets were more persistent in unwetted compared to wetted sand, and dark compared to sunlit seawater. During the first 8 days of the sand experiment, the decay rate k of CAT was greater than that of cENT. The decay rates of CAT, tENT, and cENT were similar in sand after day 8 and in dark seawater. In sunlit seawater, the decay rates were different between targets with kcENTÂ >Â kCATÂ >Â ktENT. The decay rates presented here are useful for fate and transport models and also inform the use of MST marker concentrations to infer ENT sources in the environment.
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