Quantifying effects of UV-B, temperature, and pH on eDNA degradation in aquatic microcosms
•We investigated the effects of temperature, pH, and UV-B on eDNA degradation.•Most degradation occurred within 10days, but some eDNA persisted up to 58days.•Degradation rates were lowest in cold, low UV-B, and alkaline conditions.•Effects of environmental factors on eDNA degradation may be biologic...
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Veröffentlicht in: | Biological conservation 2015-03, Vol.183, p.85-92 |
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Sprache: | eng |
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Zusammenfassung: | •We investigated the effects of temperature, pH, and UV-B on eDNA degradation.•Most degradation occurred within 10days, but some eDNA persisted up to 58days.•Degradation rates were lowest in cold, low UV-B, and alkaline conditions.•Effects of environmental factors on eDNA degradation may be biologically mediated.•These results can help improve eDNA sampling and interpretation of eDNA detection.
Environmental DNA (eDNA) degradation is a primary mechanism limiting the detection of rare species using eDNA techniques. To better understand the environmental drivers of eDNA degradation, we conducted a laboratory experiment to quantify degradation rates. We held bullfrog (Lithobates catesbeianus) tadpoles in microcosms, then removed the tadpoles and assigned the microcosms to three levels each of temperature, ultraviolet B (UV-B) radiation, and pH in a full factorial design. We collected water samples from each microcosm at six time steps (0 to 58days). In all microcosms, most degradation occurred in the first three to 10days of the experiment, but eDNA remained detectable after 58days in some treatments. Degradation rates were lowest under cold temperatures (5°C), low UV-B levels, and alkaline conditions. Higher degradation rates were associated with factors that contribute to favorable environments for microbial growth (higher temperatures, neutral pH, moderately high UV-B), indicating that the effects of these factors may be biologically mediated. The results of this experiment indicate that aquatic habitats that are colder, more protected from solar radiation, and more alkaline are likely to hold detectable amounts of eDNA longer than those that are warmer, sunnier, and neutral or acidic. These results can be used to facilitate better characterization of environmental conditions that reduce eDNA persistence, improved design of temporal sampling intervals and inference, and more robust detection of aquatic species with eDNA methods. |
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ISSN: | 0006-3207 1873-2917 |
DOI: | 10.1016/j.biocon.2014.11.038 |