Environmental DNA (eDNA) can be used to detect the presence and abundance of aquatic organisms from water samples. Before implementing this methodology as a tool for monitoring, more knowledge is needed on variation in eDNA concentrations in relation to species abundance and potential confounding factors. Shedding and decay of eDNA may vary extensively over the season and are dependent on environmental factors such as water temperature and on biological processes such as activity level and reproduction. In lotic systems, eDNA concentrations are also affected by downstream transport of eDNA. Sessile freshwater mussels provide an ideal study system for investigating the relationship between species spatial distribution and eDNA concentrations in lotic systems. We quantified freshwater pearl mussel (Margaritifera margaritifera) eDNA concentrations at four localities in a natural river with detailed knowledge of mussel spatial distribution: (a) upstream of the known species distribution, just downstream (b) a small and (c) a large aggregation and (d) 1,700 m downstream of the large aggregation. To study seasonal variation, we quantified eDNA concentrations during three periods: (a) in late spring, with cold water and relatively inactive mussels; (b) in mid-summer, with higher water temperature and active mussel filtration; and (c) in late summer, during the release of larvae.Species detection was highly reliable, with no detection of eDNA upstream of the species distribution and complete detection downstream of the large aggregation.Detection success of the small aggregation was low, with 13% of the samples testing positive. Downstream transport was efficient, with no significant decrease in eDNA concentrations over 1,700 m river distance. Seasonal variation was strong, with a 20-fold increase in eDNA concentrations from late spring to late summer, during reproduction. Our results highlight both the potential and challenges of eDNA monitoring in lotic systems. K E Y W O R D Sconservation genetics, environmental DNA, freshwater mussels, species detection, unionidae | 65 WACKER Et Al.
BackgroundInvasive species represent a major challenge for the conservation of biodiversity. The invasive ectoparasitic fluke Gyrodactylus salaris is considered one of the major threats to the Atlantic salmon (Salmo salar), and the parasite has so far been detected in 50 rivers in Norway.AimsWe investigate environmental DNA (eDNA) as a tool for detecting and assessing relative abundance of G. salaris and Atlantic salmon, upstream and downstream of a recently constructed artificial migration barrier in the River Driva in Norway. In addition, we also use eDNA to assess abundance of the less pathogenic G. derjavinoides and its main host, the brown trout (S. trutta).Material & MethodsWe filtered 1 L and 10 L of water through a 0.45 μm cellulose filter and a 2.0 μm glass fiber filter, respectively, at nine different localities along the river. Concentrations of eDNA were assessed using droplet digital PCR (ddPCR) and compared to parasite abundance based on conventional methodology using electrofishing and the counting of individual parasites on juvenile salmon.ResultsAll four species could successfully be detected from water samples using two different protocols varying in sample volumes, filter types, and DNA‐isolation methods. However, eDNA‐occupancy modeling revealed that the probability of detecting the two gyrodactylid species was higher when filtering 10 L water through a 2.0 μm glass fiber filter (p > .99) than when filtering 1 L water through a 0.45 μm cellulose filter (p = .48–.78). The eDNA concentrations of the two fish species were markedly higher below the migration barrier, reflecting the expected higher biomass of fish. For the two gyrodactylid parasites, eDNA concentrations showed a peak upstream of the migration barrier and decreased below the migration barrier. The observed pattern was consistent with parasite abundance based on conventional methodology.DiscussionAssessing abundance in rivers using eDNA is challenging and potentially influenced by downstream accumulation and dilution from tributaries, but our results suggest that G. salaris eDNA concentrations were indicative of parasite abundance.ConclusionWe conclude that eDNA is an efficient way of monitoring gyrodactylid parasites and their salmonid hosts, and we suggest that eDNA should be incorporated into future monitoring of G. salaris.
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