Evaluation of environmental DNA surveys for identifying occupancy and spatial distribution of Pacific Lamprey (<i>Entosphenus tridentatus</i>) and <i>Lampetra</i> spp. in a Washington coast watershed

Ostberg, Carl O.; Chase, Dorothy M.; Hoy, Marshal S.; Duda, Jeffrey J.; Hayes, Michael C.; Jolley, Jeffrey C.; Silver, Gregory S.; Cook‐Tabor, Carrie

doi:10.1002/edn3.15

Cited by 15 publications

(15 citation statements)

References 72 publications

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“…Nevertheless, snorkel surveys conducted in previous years suggest that in reaches where a single spawning event occurs, progeny often distribute themselves relatively evenly in pools within a few hundred meters of their natal area (B. Spence, unpublished data); thus, we are confident that the relative abundances of fish observed during our surveys serve as a reasonable proxy for reach-level differences in abundance. Our success in detecting coho salmon eDNA is consistent with those of other researchers who have found eDNA methods to be as or more effective in detecting rare fish species than traditional methods such as snorkeling or electrofishing in riverine environments (Baldigo et al, 2017;Banks et al, 2016;Evans et al, 2017;Hinlo et al, 2018;Laramie et al, 2015;McKelvey et al, 2016;Ostberg et al, 2019;Robinson et al, 2019;Sigsgaard et al, 2015;Strickland & Roberts, 2019;Wilcox et al, 2016).…”

Section: Field Methods Comparisonsupporting

confidence: 89%

“…Our study adds to the growing body of evidence indicating that eDNA methods can be a valuable tool for detecting rare fish species in riverine environments (Baldigo et al, 2017;Hinlo et al, 2018;Ostberg et al, 2019;Robinson et al, 2019;Strickland & Roberts, 2019; among others). However, similar to previous studies, the combined results from our cage experiment and field sampling indicate that the downstream detection probabilities are significantly influenced by factors related to both DNA production (i.e., fish density) and downstream transport and degradation processes, which in turn are likely strongly dependent on local environmental conditions.…”

Section: Discussionmentioning

confidence: 66%

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Efficacy of environmental DNA sampling to detect the occurrence of endangered coho salmon (Oncorhynchus kisutch) in Mediterranean‐climate streams of California's central coast

et al. 2020

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Analysis of environmental DNA (eDNA) has emerged as an important tool for investigating the occurrence and distribution of fish and other species in aquatic environments. However, in lotic systems, uncertainty remains about how environmental factors influence the downstream transport, degradation, and dilution of eDNA, and hence how detection probability varies with distance from the eDNA source. We conducted cage experiments and paired eDNA and snorkel surveys to evaluate the potential for eDNA methods to detect endangered coho salmon in Mediterraneanclimate streams of the Santa Cruz Mountains, California. Juvenile coho salmon at two densities were placed in cages, and water samples were collected and analyzed (qPCR) at seven locations from 10 to 1,000 m downstream. Although we detected coho salmon eDNA up to 1,000 m downstream of the cage, the vast majority of detections were within 200 m, and detections at greater distances occurred only at the higher fish density. In field collections from 21 stream reaches across the Santa Cruz Mountains, eDNA methods and snorkeling produced identical outcomes in terms of reach-level detection of coho salmon. Probability of occurrence in a water sample and detection in a qPCR replicate both increased with observed fish density; however, even at the lowest densities, a protocol of three water samples and two qPCR replicates resulted in a >90% cumulative probability of detection. Overall, our studies suggest that detection probability decreased rapidly with distance in Santa Cruz Mountain streams, likely because low stream discharges, slow transport velocities, and strong interaction between the water column and stream substrate result in rapid degradation or settling of eDNA. Our findings thus support the use of eDNA methods for detecting rare species, but also indicate that local conditions strongly influence transport dynamics and hence need to be considered when developing survey designs.

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Section: Field Methods Comparisonsupporting

confidence: 89%

Section: Discussionmentioning

confidence: 66%

Efficacy of environmental DNA sampling to detect the occurrence of endangered coho salmon (Oncorhynchus kisutch) in Mediterranean‐climate streams of California's central coast

et al. 2020

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“…However, the majority of our study streams had sites without detections in‐between sites with detections, evidence that eDNA can degrade quickly over space. Other studies from further downstream have reported that eDNA varies along a stream, is conserved over short distances of tens of meters (Tillotson et al 2018), and degrades over longer distances (kilometers; Laramie et al 2015, Tillotson et al 2018, Ostberg et al 2019), proposing that eDNA reflects a here‐and‐now presence of local abundances.…”

Section: Discussionmentioning

confidence: 99%

“…Environmental DNA can detect Killer Whales Orcinus orca in seawater (Baker et al 2018), carnivores in snow (Franklin et al 2019), and fish in freshwater (Jerde et al 2011, Lacoursière‐Roussel et al 2016). Specifically, eDNA has been shown to be comparable to, or more sensitive at, detecting fish than electrofishing in streams (Wilcox et al 2016, Baldigo et al 2017, Evans et al 2017, Ostberg et al 2019), particularly when species are low in abundance (Dejean et al 2012, Pilliod et al 2013, Sigsgaard et al 2015, Itakura et al 2019). Although eDNA has been used to delimit fish distribution boundaries (Jerde et al 2011, McKelvey et al 2016, Carim et al 2019), it has yet to be evaluated empirically within the context of forest management by identifying the transition from fish to no fish in a stream network (Coble et al 2019).…”

Section: Introductionmentioning

confidence: 99%

Better boundaries: identifying the upper extent of fish distributions in forested streams using eDNA and electrofishing

et al. 2021

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The management of species that occur in low densities is a conservation concern worldwide across taxa with consequences for managers and policymakers. The distribution boundary at the upper extent of fish in North America receives extra attention because stream reaches with fish are managed differently and often have more protections than fishless reaches. Here, we examine the relative reliability of water environmental DNA (eDNA), polymerase chain reaction (PCR)-amplified for Coastal Cutthroat Trout (Oncorhynchus clarkii clarkii) to detect the upper extent of fish across streams as a potential management tool compared to standard electrofishing methods. We provide estimates of fish detection probabilities from eDNA analyses, and probabilities of detection for both eDNA field samples and quantitative PCR (qPCR) given covariates of habitat characteristics and fish densities from electrofishing. We present a primer and probe based on the cytochrome oxidase I gene using qPCR to detect trout DNA across water samples from 60 forested streams in the Pacific Northwest, USA using high-resolution spatial sampling. In 28% of streams, the upper extent of fish matches between methods. In over half of the streams, Coastal Cutthroat Trout eDNA was detected above the electrofishing last-fish boundary. Although some detections could be attributed to false-positive errors, eDNA results extend the upstream, leading edge of fish by 50-250 m from the electrofishing boundary. In 20% of the streams, detections of last-fish occurred higher in the stream network with electrofishing rather than eDNA, but generally by only 50 m. Modeled results revealed that the occurrence of trout eDNA was higher in wider-stream locations and that eDNA detections occurred at lower electrofishing densities (<5 trout per 50 linear m). We also showed that three replicate eDNA samples were sufficient to capture trout eDNA when eDNA was present. Although eDNA constitutes an effective addition to approaches to delimit the upper extent of fish, its effectiveness depends on previous knowledge of the last-fish boundary to apprise where to start sampling and targeting fish species anticipated to be last-fish. We present evidence that eDNA is a valuable tool in investigating fish distributions taking its place alongside traditional high-effort catch-release tools.

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“…Our study is among a growing body of literature demonstrating that eDNA can be used to monitor the presence, occurrence, and spatial extent of fish populations (Laramie, Pilliod, & Goldberg., 2015; Matter, Falke, López, & Savereide, 2018; Ostberg et al., 2019; Rees et al., 2014; Wilcox et al., 2013) and to assess river connectivity for migratory fishes (Yamanaka & Minamoto, 2016). In the case of the Elwha River, we used eDNA to assess the presence of fish in upstream areas of the watershed that were previously inaccessible due to the presence of the dams, which provides evidence that key objectives for the dam removal project (i.e., fish passage, restoring connectivity) are being met for several focal species (Peters et al., 2014).…”

Section: Discussionmentioning

confidence: 99%

Environmental DNA is an effective tool to track recolonizing migratory fish following large‐scale dam removal

et al. 2020

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Environmental DNA (eDNA) has emerged as a potentially powerful tool for use in conservation and resource management, including for tracking the recolonization dynamics of fish populations. We used eDNA to assess the effectiveness of dam removal to restore fish passage on the Elwha River in Washington State (USA). Using a suite of 11 species‐specific eDNA polymerase chain reaction (PCR) assays, we showed that most targeted anadromous species (five Pacific Salmon species and Pacific Lamprey) were able to pass upstream of both former dam sites. Multiscale occupancy modeling showed that the timing and spatial extent of recolonization differed among species during the four years of post‐dam removal monitoring. More abundant species like Chinook Salmon and Coho Salmon migrated farther into the upper portions of the watershed than less abundant species like Pink Salmon and Chum Salmon. Sampling also allowed assessment of potamodromous fish species. Bull Trout and Rainbow Trout, ubiquitous species in the watershed, were detected at all sampling locations. Environmental DNA from Brook Trout, a non‐native species isolated between the dams prior to dam removal, was detected downstream of Elwha dam but rarely upstream of the Glines Canyon Dam suggested that the species has not expanded its range appreciably in the watershed following dam removal. We found that eDNA was an effective tool to assess the response of fish populations to large‐scale dam removal on the Elwha River.

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Evaluation of environmental DNA surveys for identifying occupancy and spatial distribution of Pacific Lamprey (Entosphenus tridentatus) and Lampetra spp. in a Washington coast watershed

Cited by 15 publications

References 72 publications

Efficacy of environmental DNA sampling to detect the occurrence of endangered coho salmon (Oncorhynchus kisutch) in Mediterranean‐climate streams of California's central coast

Efficacy of environmental DNA sampling to detect the occurrence of endangered coho salmon (Oncorhynchus kisutch) in Mediterranean‐climate streams of California's central coast

Better boundaries: identifying the upper extent of fish distributions in forested streams using eDNA and electrofishing

Environmental DNA is an effective tool to track recolonizing migratory fish following large‐scale dam removal

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