Grab what you can—an evaluation of spatial replication to decrease heterogeneity in sediment eDNA metabarcoding

Hestetun, Jon Thomassen; Lanzén, Anders; Dahlgren, Thomas G.

doi:10.7717/peerj.11619

Cited by 14 publications

(9 citation statements)

References 61 publications

(77 reference statements)

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“…Sampling approaches and theory are understudied aspects of eDNA protocols (Dickie et al, 2018), and future work should evaluate the optimal sampling volume and strategy as a function of the environment and the biology of target taxa (Mächler et al, 2016). Studies in other environments have similarly demonstrated that increasing sample volumes can improve biodiversity detection (Bessey et al, 2020;Hestetun et al, 2021;Schabacker et al, 2020;Sepulveda et al, 2019). Because our eDNA sampler can efficiently pump a much larger volume than that which can be captured by a single Niskin bottle, it represents a better tool for collecting eDNA at deeper ocean depths (i.e., below ~100 m).…”

Section: Sampling Volumementioning

confidence: 99%

Improved biodiversity detection using a large-volume environmental DNA sampler with in situ filtration and implications for marine eDNA sampling strategies

Govindarajan

McCartin

Adams

et al. 2022

Preprint

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Metabarcoding analysis of environmental DNA samples is a promising new tool for marine biodiversity and conservation. Typically, seawater samples are obtained using Niskin bottles and filtered to collect eDNA. However, standard sample volumes are small relative to the scale of the environment, conventional collection strategies are limited, and the filtration process is time consuming. To overcome these limitations, we developed a new large-volume eDNA sampler with in situ filtration, capable of taking up to 12 samples per deployment. We conducted three deployments of our sampler on the robotic vehicle Mesobot in the Flower Garden Banks National Marine Sanctuary in the northwestern Gulf of Mexico and collected samples from 20 to 400 m depth. We compared the large volume (~40-60 liters) samples collected by Mesobot with small volume (~2 liters) samples collected using the conventional CTD-mounted Niskin bottle approach. We sequenced the V9 region of 18S rRNA, which detects a broad range of invertebrate taxa, and found that while both methods detected biodiversity changes associated with depth, our large volume samples detected approximately 66% more taxa than the CTD small volume samples. We found that the fraction of the eDNA signal originating from metazoans relative to the total eDNA signal decreased with sampling depth, indicating that larger volume samples may be especially important for detecting metazoans in mesopelagic and deep ocean environments. We also noted substantial variability in biological replicates from both the large volume Mesobot and small volume CTD sample sets. Both of the sample sets also identified taxa that the other did not; although the number of unique taxa associated with the Mesobot samples was almost four times larger than those from the CTD samples. Large volume eDNA sampling with in situ filtration, particularly when coupled with robotic platforms, has great potential for marine biodiversity surveys, and we discuss practical methodological and sampling considerations for future applications.

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Section: Sampling Volumementioning

confidence: 99%

Improved biodiversity detection using a large-volume environmental DNA sampler with in situ filtration and implications for marine eDNA sampling strategies

Govindarajan

McCartin

Adams

et al. 2022

Preprint

View full text Add to dashboard Cite

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“…The underperformance by the 0.5‐g sample analyses may be resolvable with the collection of several (pseudo‐) replicate samples (i.e. > 2), or subsampling homogenized samples of larger volume (Hestetun, Lanzén, & Dahlgren, 2021; Hestetun, Lanzén, Skaar, & Dahlgren, 2021; van der Loos & Nijland, 2021). Currently, there is no consensus regarding the appropriate level of replication for assessment of total diversity, especially when considering effort/cost vs. benefit (e.g., review by Pawlowski et al, 2022).…”

Section: Discussionmentioning

confidence: 99%

Through the eDNA looking glass: Responses of fjord benthic foraminiferal communities to contrasting environmental conditions

Brinkmann

Schweizer

Quinchard

et al. 2023

J Eukaryotic Microbiology

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The health of coastal marine environments is severely declining with global changes. Proxies, such as those based on microeukaryote communities, can record biodiversity and ecosystem responses. However, conventional studies rely on microscopic observations of limited taxonomic range and size fraction, missing putatively ecologically informative community components. Here, we tested molecular tools to survey foraminiferal biodiversity in a fjord system (Sweden) on spatial and temporal scales: Alpha and beta diversity responses to natural and anthropogenic environmental trends were assessed and variability of foraminiferal environmental DNA (eDNA) compared to morphology‐based data. The identification of eDNA‐obtained taxonomic units was aided by single‐cell barcoding. Our study revealed wide diversity, including typical morphospecies recognized in the fjords, and so‐far unrecognized taxa. DNA extraction method impacted community composition outputs significantly. DNA extractions of 10 g sediment more reliably represented present diversity than of 0.5‐g samples and, thus, are preferred for environmental assessments in this region. Alpha‐ and beta diversity of 10‐g extracts correlated with bottom‐water salinity similar to morpho‐assemblage diversity changes. Sub‐annual environmental variability resolved only partially, indicating damped sensitivity of foraminiferal communities on short timescales using established metabarcoding techniques. Systematically addressing the current limitations of morphology‐based and metabarcoding studies may strongly improve future biodiversity and environmental assessments.

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“…Lear et al (2018) showed that the 18S gene is the most popular marker for targeting eukaryotes in metabarcoding research. 18S primers have been shown to outperform primers from other genes (von Ammon et al 2018, Sawaya et al 2019, Tytgat et al 2019, Hestetun et al 2021). The V9 subregion of the eukaryotic SSU (18S) rRNA gene - used in this research - has both highly conserved and highly variable sites, thus showing great taxonomic resolution potential (Amaral-Zettler et al 2009, Wu et al 2015).…”

Section: Discussionmentioning

confidence: 99%

Soil environmental DNA metabarcoding in low-biomass regions requires protocol optimization: a case study in Antarctica

et al. 2023

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Environmental DNA is a powerful tool for monitoring biodiversity. Although environmental DNA surveys have successfully been implemented in various environments, protocol choice has been shown to affect results and inferences. Thus far, few method comparison studies for soil have been undertaken. Here, we optimized the workflow for soil metabarcoding through a comparative study encompassing variation in sampling strategy (individual and combined samples), DNA extraction (PowerSoil®, NucleoSpin® Soil, PowerSoil® + phosphate buffer and NucleoSpin® Soil + phosphate buffer) and library preparation (one-step and two-step quantitative polymerase chain reaction methods). Using a partial 18S rRNA marker, a total of 309 eukaryotic taxa across 21 phyla were identified from Antarctic soil from one site in the Larsemann Hills. Our optimized workflow was effective with no notable reduction in data quality for a considerable increase in time and cost efficiency. The NucleoSpin® Soil + phosphate buffer was the best-performing extraction method. Compared to similar studies in other regions, we obtained low taxonomic coverage, perhaps because of the paucity of Antarctic terrestrial organisms in genetic reference databases. Our findings provide useful methodological insights for maximizing efficiency in soil metabarcoding studies in Antarctica and other low-biomass environments.

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Grab what you can—an evaluation of spatial replication to decrease heterogeneity in sediment eDNA metabarcoding

Cited by 14 publications

References 61 publications

Improved biodiversity detection using a large-volume environmental DNA sampler with in situ filtration and implications for marine eDNA sampling strategies

Improved biodiversity detection using a large-volume environmental DNA sampler with in situ filtration and implications for marine eDNA sampling strategies

Through the eDNA looking glass: Responses of fjord benthic foraminiferal communities to contrasting environmental conditions

Soil environmental DNA metabarcoding in low-biomass regions requires protocol optimization: a case study in Antarctica

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