The detection of aquatic macroorganisms using environmental DNA analysis—A review of methods for collection, extraction, and detection

Tsuji, Satsuki; Takahara, Teruhiko; Doi, Hideyuki; Shibata, Naoki; Yamanaka, Hiroki

doi:10.1002/edn3.21

Cited by 201 publications

(184 citation statements)

References 60 publications

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“…Nylon filters (47 mm, 0.45 µm) were chosen initially for concentrating eDNA as they are hydrophilic, offer a relatively fast filtration speed, and have a small pore size to recover the majority of macroorganismal eDNA ranging from 1 to 10 µm (Turner et al, 2014). Although nylon filters are widely used (Thomsen et al, 2012;Stat et al, 2017;Stoeckle M. et al, 2017), other filter types are available (Kelly et al, 2014;Turner et al, 2014;Hinlo et al, 2017;Kelly et al, 2017;Lacoursière-Roussel et al, 2018;Tsuji et al, 2019). We compared the performance of nylon filters to that of polycarbonate filters, as the latter is most commonly used for concentrating microbial cells.…”

Section: Filter Type Influences Rare Taxa Detectionmentioning

confidence: 99%

“…To better realize the potential for eDNA methods to address a wide range of ecological questions, spatiotemporal variations of eDNA in marine environments must be more thoroughly understood, and targeted studies addressing technical details regarding eDNA sample collection and processing are required. One such technical detail revolves around the choice of eDNA concentrating matrix -membrane filters, with both filter material and pore size playing important roles in eDNA capture (Djurhuus et al, 2017;Tsuji et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

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Application of Environmental DNA Metabarcoding to Spatiotemporal Finfish Community Assessment in a Temperate Embayment

et al. 2019

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Environmental DNA (eDNA) metabarcoding was used to characterize finfish communities in the nearshore estuarine environment. Monthly sampling was conducted June-August 2017 at two sites with structured habitats: a natural rock reef and a shellfish aquaculture farm within the same coastal embayment of Long Island Sound (LIS), CT, United States. Seventeen common and 25 rare finfish taxa were detected using eDNA metabarcoding. Incomplete status of reference sequence databases for finfish species was identified as a methodological challenge. Confidence in molecular identification was improved appreciably through the use of publicly available data obtained from local trawling and seining surveys. Comparison between eDNA metabarcoding and trawling surveys on 6/27/2017, the only day when both data types were available, revealed more finfish species detected by eDNA metabarcoding. The high sensitivity of eDNA metabarcoding detected finfish species rarely observed in traditional surveys and showed the potential for this methodology to augment existing literature for finfish species distribution patterns and invasive species detection. Non-metric multidimensional scaling (NMS) analysis of finfish communities achieved a low-stress, 2D solution, and revealed greater variation between samples collected from different months than samples collected from the two habitats. Similarly, permutational analysis of variance (PERMANOVA) found both month and the interaction term (month × site) significant, with the latter identifying site as significant only in July and August. Different finfish assemblages were significantly associated with each axis, axes representing temporal and spatial variations, respectively. Additionally, polycarbonate and nylon filters were compared to optimize the sampling method; finfish communities retrieved using the two types of filters were statistically indistinguishable by NMS analysis, although the filtration time for nylon filters was shorter. If the objective is to detect rare species, nylon filters are recommended over polycarbonate filters because of higher capture rates of rare taxa. Our study demonstrates the potential for applying eDNA metabarcoding as a stand-alone method to conduct finfish surveys with high sensitivity.

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Section: Filter Type Influences Rare Taxa Detectionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Application of Environmental DNA Metabarcoding to Spatiotemporal Finfish Community Assessment in a Temperate Embayment

et al. 2019

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“…The widely used approach for retrieving eDNA from water samples involves filtration, ethanol precipitation, and centrifugation (Tsuji et al ., ). As a result, sampling biodiversity is constrained by the volume of processed water due to limitations of filter membranes (e.g.…”

Section: Sample Collection For Dna Metabarcoding Studiesmentioning

confidence: 97%

“…For water eDNA samples, the use of filtration and DNeasy Blood & Tissue kit (Qiagen, Hilden, Germany) is recommended by Deiner et al . () for eukaryote biodiversity surveys, because this combination showed good detection rates for both lotic and rare species (see also Tsuji et al ., ). Although the Qiagen DNeasy Blood & Tissue kit is widely used for terrestrial bulk invertebrates, the PowerPlant Kit performs better for benthic macroinvertebrates compared with two other tested kits, because it removes PCR inhibitors (Majaneva et al ., ).…”

Section: Minimising Bias In the Laboratorymentioning

confidence: 97%

A practical guide to DNA metabarcoding for entomological ecologists

Liu

Clarke

Baker

et al. 2019

Ecological Entomology

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1. DNA metabarcoding is a cost-effective species identification approach with great potential to assist entomological ecologists. This review presents a practical guide to help entomological ecologists design their own DNA metabarcoding studies and ensure that sound ecological conclusions can be obtained.2. The review considers approaches to field sampling, laboratory work, and bioinformatic analyses, with the aim of providing the background knowledge needed to make decisions at each step of a DNA metabarcoding workflow.3. Although most conventional sampling methods can be adapted to DNA metabarcoding, this review highlights techniques that will ensure suitable DNA preservation during field sampling and laboratory storage. The review also calls for a greater understanding of the occurrence, transportation, and deposition of environmental DNA when applying DNA metabarcoding approaches for different ecosystems.4. Accurate species detection with DNA metabarcoding needs to consider biases introduced during DNA extraction and PCR amplification, cross-contamination resulting from inappropriate amplicon library preparation, and downstream bioinformatic analyses. Quantifying species abundance with DNA metabarcoding is in its infancy, yet recent studies demonstrate promise for estimating relative species abundance from DNA sequencing reads. 5. Given that bioinformatics is one of the biggest hurdles for researchers new to DNA metabarcoding, several useful graphical user interface programs are recommended for sequence data processing, and the application of emerging sequencing technologies is discussed.

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“…In recent years, environmental DNA (eDNA) metabarcoding (the simultaneous identification via next-generation sequencing of multiple taxa using DNA extracted from environmental samples, e.g., water, soil) has delivered on its initial potential and is now revolutionizing how we monitor biodiversity (Deiner et al 2017). The majority of eDNA metabarcoding applications have focused on monitoring fish and macroinvertebrates, with mammals being targeted in only 8% of vertebrate studies (Tsuji et al 2019). However, with the development of universal primers for vertebrates and mammals specifically, there has been a recent surge in studies tailored to detect and/or monitor mammalian communities in terrestrial and freshwater environments (e.g.…”

Section: Introductionmentioning

confidence: 99%

Assessing the potential of environmental DNA metabarcoding for monitoring Neotropical mammals: a case study in the Amazon and Atlantic Forest, Brazil

Sales

Kaizer

Coscia

et al. 2019

Preprint

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The application of environmental DNA (eDNA) metabarcoding as a biomonitoring tool has greatly increased in the last decade. However, most studies have focused on aquatic macro-organisms in temperate areas (e.g., fishes). We apply eDNA metabarcoding to detect the mammalian community in two high-biodiversity regions of Brazil, the Amazon and Atlantic Forest. We identified critically endangered and endangered mammalian species in the Atlantic Forest and Amazon respectively and found congruence with species identified via camera trapping in the Atlantic Forest. In light of our results, we highlight the potential and challenges of eDNA monitoring for mammals in these high biodiverse areas.

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The detection of aquatic macroorganisms using environmental DNA analysis—A review of methods for collection, extraction, and detection

Cited by 201 publications

References 60 publications

Application of Environmental DNA Metabarcoding to Spatiotemporal Finfish Community Assessment in a Temperate Embayment

Application of Environmental DNA Metabarcoding to Spatiotemporal Finfish Community Assessment in a Temperate Embayment

A practical guide to DNA metabarcoding for entomological ecologists

Assessing the potential of environmental DNA metabarcoding for monitoring Neotropical mammals: a case study in the Amazon and Atlantic Forest, Brazil

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