Environmental DNA survey captures patterns of fish and invertebrate diversity across a tropical seascape

Nguyen, Bryan; Shen, Elaine W.; Seemann, Janina; Correa, Adrienne M. S.; O’Donnell, James L.; Altieri, Andrew H.; Knowlton­, Nancy­; Crandall, Keith A.; Egan, Scott P.; McMillan, W. Owen; Leray, Matthieu

doi:10.1038/s41598-020-63565-9

Cited by 62 publications

(48 citation statements)

References 67 publications

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“…The results of this study suggest the potential of the molecular approach for biodiversity assessments of remote ecosystems. eDNA sequencing was sensitive enough to detect distinct communities between adjacent habitat types, as was previously shown for shallow water tropical habitats (Nguyen et al, 2020). Sessile taxa detected on nodules with eDNA were broadly consistent with previous inventories of species associated with this abyssal substrate type.…”

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confidence: 86%

Seabed mining could come at a high price for a unique fauna

Leray

Machida

2020

Molecular Ecology

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The deep seafloor is teeming with life, most of which remains poorly known to science. It also constitutes an important reserve of natural resources, particularly minerals, that mining companies will start harvesting in the next few years (Nat Rev Earth Environ, 1, 2020, 158). In this context, broad biodiversity assessments of deep‐sea ecosystems are urgently needed to establish a baseline prior to mining. However, significant gaps in our taxonomic knowledge and the high cost of sampling in the deep sea limit the effectiveness of conventional morphology‐based surveys. In this issue of Molecular Ecology, Laroche et al. (Mol Ecol, 2020) capitalize on high throughput molecular methods to conduct one of the most detailed and rigorous surveys of the composition and biogeography of deep‐seafloor metazoan communities to date. The authors show that deep seamounts in the Clarion Clipperton Zone are inhabited by rich metazoan communities that are distinct from those of the surrounding abyssal plains. These results have important conservation implications: if communities on deep seamounts were to persist after large‐scale industrial mining operations on the surrounding plains, the seamounts would not serve as appropriate reservoirs to repopulate impacted areas.

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supporting

confidence: 86%

Seabed mining could come at a high price for a unique fauna

Leray

Machida

2020

Molecular Ecology

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“…However, Jeunen et al (2019) demonstrated that eDNA was able to discriminate diverse marine habitats within a small spatial scale subject to tidal and water currents. Indeed, some studies have already shown that eDNA surveys are able to detect fine-scale community composition patterns in heterogeneous aquatic habitats (Port et al, 2016;O'Donnell et al, 2017;Pont et al, 2018;Bakker et al, 2019;Stat et al, 2019;Nguyen et al, 2020;Oka et al, 2020). In our study, the residency time and degradation rate of nsDNA in the sponge tissues is an important factor that can hamper the detection of community patterns.…”

Section: Discussionmentioning

confidence: 80%

“…Some recent studies have pointed out the differences between eDNA metabarcoding methods and visual or capture methods (Tkachenko et al, 2016;Yamamoto et al, 2017;Fujii et al, 2019;Stat et al, 2019). The main advantages of metabarcoding rely on its time efficiency (Yamamoto et al, 2017;Nguyen et al, 2020), its detection capability of eDNA signatures of fishes that cannot be observed during visual surveys (Nguyen et al, 2020) and the dispensable need of taxonomic expertise (DiBattista et al, 2017). In this sense, censuses made by different observers may not be comparable, while results from eDNA are more objective and, particularly, better suited for archiving and future reanalyses (the sequences remain in databases, visual observations are hardly archivable).…”

Section: Comparisons With Visual Census Datamentioning

confidence: 99%

“…In this sense, censuses made by different observers may not be comparable, while results from eDNA are more objective and, particularly, better suited for archiving and future reanalyses (the sequences remain in databases, visual observations are hardly archivable). However, the main drawbacks of the eDNA approach lie on the accuracy of the results obtained, which are biased by the coverage of the reference database (Nguyen et al, 2020), the number of replicates (Yamamoto et al, 2017), the possible PCR inhibition (Fujii et al, 2019), and the differences in the species DNA shedding rates (Port et al, 2016).…”

Section: Comparisons With Visual Census Datamentioning

confidence: 99%

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More Than Expected From Old Sponge Samples: A Natural Sampler DNA Metabarcoding Assessment of Marine Fish Diversity in Nha Trang Bay (Vietnam)

et al. 2020

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Sponges have recently been proposed as ideal candidates to act as natural samplers for environmental DNA due to their efficiency in filtering water. However, validation of the usefulness of DNA recovered from sponges to reveal vertebrate biodiversity patterns in Marine Protected Areas is still needed. Additionally, nothing is known about how different sponge species and morphologies influence the capture of environmental DNA and whether biodiversity patterns obtained from sponges are best described by quantitative or qualitative measures. In this study, we amplified and sequenced a vertebrate specific 12S barcode with a set of universal PCR primers (MiFish) for metabarcoding environmental DNA from fishes, to unveil fine-scale patterns of fish communities from natural-sampler DNA retrieved from 64 sponges (16 species) located in eutrophic and well-preserved coral reefs in Nha Trang Bay (central Vietnam). Ninety tropical fish species were identified from the sponges, corresponding to one third of the total local ichthyofauna reported from previous extensive conventional surveys. Significant differentiation in fish communities between eutrophic and well-preserved environments was observed, albeit eutrophication only explained a modest proportion of the variation between fish communities. Differences in efficiency of capturing fish environmental DNA among sponge species or morphologies were not observed. Overall, the majority of detected fish species corresponded to reef-associated small-sized species, as expected in coral reefs environments. Remarkably, pelagic, migratory, and deep-sea fish species were also recovered from sponge tissues, pointing out the ability of sponge natural sampled DNA to detect fishes that were not permanently associated to the biomes where the sponges were sampled. These results highlight the suitability of natural samplers as a cost-effective way to assess vertebrate diversity in hyper-diverse environments.

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“…In addition to the above six case studies conducted in various marine environments, MiFish eDNA metabarcoding has been applied to biodiversity monitoring at two coastal areas of eastern Java and Sulawesi Sea, Indonesia (Masengi et al 2019;Andriyono et al 2019); port and urban canal area in Osaka Bay, central Japan (Kamimura et al 2018); Innoshima, Seto Inland Sea, Japan (Sakamoto 2019); coastal waters off Zhoushan, China (Chen et al 2019(Chen et al , 2020; a harbor at Sloehaven, the Netherlands (Hoorn and Gittenberger 2019); Gulf of St. Laurence Bay, Canada (Afzali et al 2020); Caribbean bay in Panama (Nguyen et al 2020); and coastal waters along the South Africa by members of the von der Heyden Lab (https ://www.vonde rheyd enlab .com/envir onmen tal-dna-and-metab arcod ing.html).…”

Section: Marine Fish Communitymentioning

confidence: 99%

MiFish metabarcoding: a high-throughput approach for simultaneous detection of multiple fish species from environmental DNA and other samples

2020

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We reviewed the current methodology and practices of the DNA metabarcoding approach using a universal PCR primer pair MiFish, which co-amplifies a short fragment of fish DNA (approx. 170 bp from the mitochondrial 12S rRNA gene) across a wide variety of taxa. This method has mostly been applied to biodiversity monitoring using environmental DNA (eDNA) shed from fish and, coupled with next-generation sequencing technologies, has enabled massively parallel sequencing of several hundred eDNA samples simultaneously. Since the publication of its technical outline in 2015, this method has been widely used in various aquatic environments in and around the six continents, and MiFish primers have demonstrably outperformed other competing primers. Here, we outline the technical progress in this method over the last 5 years and highlight some case studies on marine, freshwater, and estuarine fish communities. Additionally, we discuss various applications of MiFish metabarcoding to non-fish organisms, single-species detection systems, quantitative biodiversity monitoring, and bulk DNA samples other than eDNA. By recognizing the MiFish eDNA metabarcoding strengths and limitations, we argue that this method is useful for ecosystem conservation strategies and the sustainable use of fishery resources in “ecosystem-based fishery management” through continuous biodiversity monitoring at multiple sites.

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Environmental DNA survey captures patterns of fish and invertebrate diversity across a tropical seascape

Cited by 62 publications

References 67 publications

Seabed mining could come at a high price for a unique fauna

Seabed mining could come at a high price for a unique fauna

More Than Expected From Old Sponge Samples: A Natural Sampler DNA Metabarcoding Assessment of Marine Fish Diversity in Nha Trang Bay (Vietnam)

MiFish metabarcoding: a high-throughput approach for simultaneous detection of multiple fish species from environmental DNA and other samples

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