eDNA metabarcoding as a biomonitoring tool for marine protected areas

Gold, Zachary; Sprague, Joshua; Kushner, David J.; Marin, Erick Zerecero; Barber, Paul H.

doi:10.1371/journal.pone.0238557

Cited by 120 publications

(100 citation statements)

References 47 publications

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“…If marine fish eDNA was patchy in this experiment, filtering a larger volume of water may reduce variation among the replicates. However, we chose one liter as our sampling volume since this is the standard sampling volume for marine eDNA studies [ 14 , 15 , 17 , 19 , 26 , 48 ], and passing more than one liter of water through a filter can be difficult in productive coastal ecosystems like kelp forests.…”

Section: Discussionmentioning

confidence: 99%

“…Temporal variation of eDNA in marine ecosystems is becoming increasingly important to understand, as eDNA is being viewed as a potential alternative to traditional visual survey methods used in marine ecosystems monitoring [ 2 , 5 ]. While eDNA has fewer logistical difficulties compared to visual surveys [ 19 ], the primary advantage is eDNA’s ability to efficiently detect larger numbers of taxa [ 3 , 4 , 15 ]. For example, at least 178 fish species inhabit Southern California kelp forest [ 20 ].…”

Section: Introductionmentioning

confidence: 99%

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Short-lived detection of an introduced vertebrate eDNA signal in a nearshore rocky reef environment

et al. 2021

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Environmental DNA (eDNA) is increasingly used to measure biodiversity of marine ecosystems, yet key aspects of the temporal dynamics of eDNA remain unknown. Of particular interest is in situ persistence of eDNA signals in dynamic marine environments, as eDNA degradation rates have predominantly been quantified through mesocosm studies. To determine in situ eDNA residence times, we introduced an eDNA signal from a non-native fish into a protected bay of a Southern California rocky reef ecosystem, and then measured changes in both introduced and background eDNA signals across a fixed transect over 96 hours. Foreign eDNA signal was no longer detected only 7.5 hours after introduction, a time substantially shorter than the multi-day persistence times in laboratory studies. Moreover, the foreign eDNA signal spread along the entire 38 m transect within 1.5 hours after introduction, indicating that transport and diffusion play a role in eDNA detectability even in protected low energy marine environments. Similarly, native vertebrate eDNA signals varied greatly over the 96 hours of observation as well as within two additional nearby fixed transects sampled over 120 hours. While community structure did significantly change across time of day and tidal direction, neither accounted for the majority of observed variation. Combined, results show that both foreign and native eDNA signatures can exhibit substantial temporal heterogeneity, even on hourly time scales. Further work exploring eDNA decay from lagrangian perspective and quantifying effects of sample and technical replication are needed to better understand temporal variation of eDNA signatures in nearshore marine environments.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Short-lived detection of an introduced vertebrate eDNA signal in a nearshore rocky reef environment

et al. 2021

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“…eDNA was extracted and purified from sampled meltwater using a Qiagen DNeasy blood and tissue kit with modifications ([ 45 ], see Supplemental Materials S1 for protocol details). Preparation of sequencing libraries for eDNA analysis consisted of a two-step polymerase chain reaction protocol [ 46 ]. All reactions were conducted in PCR tubes using commercially available reagents (see Supplemental Materials S2 for product and protocol details).…”

Section: Methodsmentioning

confidence: 99%

“…These files were then processed through the Toolkit ’s Anacapa Classifier module to assign taxonomy, where ASVs were queried against the CRUX-generated 12S reference database. Taxonomic identity was assigned probabilistically using the Toolkit ’s modified Bayesian Least Common Ancestor method using a cutoff level of 60, following [ 46 ]. Furthermore, given uneven sequencing depth across samples, taxa with less than 1% of the proportion of reads were excluded from the analysis.…”

Section: Methodsmentioning

confidence: 99%

Characterizing Industrial and Artisanal Fishing Vessel Catch Composition Using Environmental DNA and Satellite-Based Tracking Data

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Gold

et al. 2021

Foods

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The decline in wild-caught fisheries paired with increasing global seafood demand is pushing the need for seafood sustainability to the forefront of national and regional priorities. Validation of species identity is a crucial early step, yet conventional monitoring and surveillance tools are limited in their effectiveness because they are extremely time-consuming and require expertise in fish identification. DNA barcoding methods are a versatile tool for the genetic monitoring of wildlife products; however, they are also limited by requiring individual tissue samples from target specimens which may not always be possible given the speed and scale of seafood operations. To circumvent the need to individually sample organisms, we pilot an approach that uses forensic environmental DNA (eDNA) metabarcoding to profile fish species composition from the meltwater in fish holds on industrial and artisanal fishing vessels in Ecuador. Fish identified genetically as present were compared to target species reported by each vessel’s crew. Additionally, we contrasted the geographic range of identified species against the satellite-based fishing route data of industrial vessels to determine if identified species could be reasonably expected in the catch.

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“…For instance, a rockfish-specific primer set has been developed and successfully discriminated 28 out of 44 commercially harvested species 58 . Further improvements could be also be made through development and curation of more comprehensive DNA reference libraries 59 , or using multiple primers to target different groups.…”

Section: Taxa Richnessmentioning

confidence: 99%

Environmental DNA reveals the fine-grained and hierarchical spatial structure of kelp forest fish communities

Lamy

Pitz

Chávez

et al. 2021

Sci Rep

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Biodiversity is changing at an accelerating rate at both local and regional scales. Beta diversity, which quantifies species turnover between these two scales, is emerging as a key driver of ecosystem function that can inform spatial conservation. Yet measuring biodiversity remains a major challenge, especially in aquatic ecosystems. Decoding environmental DNA (eDNA) left behind by organisms offers the possibility of detecting species sans direct observation, a Rosetta Stone for biodiversity. While eDNA has proven useful to illuminate diversity in aquatic ecosystems, its utility for measuring beta diversity over spatial scales small enough to be relevant to conservation purposes is poorly known. Here we tested how eDNA performs relative to underwater visual census (UVC) to evaluate beta diversity of marine communities. We paired UVC with 12S eDNA metabarcoding and used a spatially structured hierarchical sampling design to assess key spatial metrics of fish communities on temperate rocky reefs in southern California. eDNA provided a more-detailed picture of the main sources of spatial variation in both taxonomic richness and community turnover, which primarily arose due to strong species filtering within and among rocky reefs. As expected, eDNA detected more taxa at the regional scale (69 vs. 38) which accumulated quickly with space and plateaued at only ~ 11 samples. Conversely, the discovery rate of new taxa was slower with no sign of saturation for UVC. Based on historical records in the region (2000–2018) we found that 6.9 times more UVC samples would be required to detect 50 taxa compared to eDNA. Our results show that eDNA metabarcoding can outperform diver counts to capture the spatial patterns in biodiversity at fine scales with less field effort and more power than traditional methods, supporting the notion that eDNA is a critical scientific tool for detecting biodiversity changes in aquatic ecosystems.

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eDNA metabarcoding as a biomonitoring tool for marine protected areas

Cited by 120 publications

References 47 publications

Short-lived detection of an introduced vertebrate eDNA signal in a nearshore rocky reef environment

Short-lived detection of an introduced vertebrate eDNA signal in a nearshore rocky reef environment

Characterizing Industrial and Artisanal Fishing Vessel Catch Composition Using Environmental DNA and Satellite-Based Tracking Data

Environmental DNA reveals the fine-grained and hierarchical spatial structure of kelp forest fish communities

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