In situ Autonomous Acquisition and Preservation of Marine Environmental DNA Using an Autonomous Underwater Vehicle

Yamahara, Kevan M.; Preston, Christina M.; Birch, James M.; Walz, Kristine; Marin, Roman; Jensen, Scott; Pargett, Douglas; Roman, Brent; Ussler, William; Zhang, Yanwu; Ryan, John P.; Hobson, Brett; Kieft, Brian; Raanan, Ben Yair; Goodwin, Kelly D.; Chávez, Francisco P.; Scholin, Christopher A.

doi:10.3389/fmars.2019.00373

Cited by 97 publications

(88 citation statements)

References 79 publications

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“…However, to perform eDNA biodiversity monitoring on a scale comparable to that of physical attributes, several technical challenges are yet to be overcome. For example, it is essential to develop an autonomous sampling instrument, called an "environmental sample processor" (ESP) (Scholin et al 2017), which is a robotic device that can be programmed to automate water sample filtration and preservation of the captured material for immediate analyses in situ (Yamahara et al 2019;Fukuba et al 2019). Furthermore, such instrumentation should be cost-effective to be installed in large numbers over a wide area.…”

Section: Discussionmentioning

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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Section: Discussionmentioning

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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“…Biomonitoring for common murre, rockfish, and whales in the CCE is usually carried out using visual surveys. The assays we developed here, along with assays that have been previously developed for krill, sardines, anchovies, and mackerel [36,51] In addition to increased monitoring efforts on specific species, an important emerging use of such data sets in the CCE is understanding larger scale questions such as how global climate change is affecting food webs [52].…”

Section: Discussionmentioning

confidence: 99%

“…Samples for testing the humpback whale assay were collected from the surface of the water column using a 10 L 10% HCl-acid washed, autoclaved polypropylene carboy (Nalgene, Rochester, NY) aboard the R/V Paragon.The samples used to test the shortbelly rockfish assay were collected aboard the R/V Reuben Lasker at 40 m depth using a Niskin array during conductivity-temperature-depth (CTD) casts.One liter water samples were collected from the Diving Birds Exhibit at the Monterey Bay Aquarium for testing the common murre assay using a 10% HCl-acid washed bottle. Water samples collected from the R/V Paragon were filtered and preserved with the Environmental Sample Processor using 0.22 µm pore size 255 mm diameter durapore filters (Millipore, Burlington, MA)[36]. All other water samples were filtered through 0.22 µm pore size 47 mm diameter durapore filters using DNA-clean, sterilized vacuum filtration devices.…”

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confidence: 99%

Quantitative PCR assays to detect humpback whale (Megaptera novaeangliae), shortbelly rockfish (Sebastes jordani), and common murre (Uria aalge) in marine water samples

Andruszkiewicz

Yamahara

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et al. 2020

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Monitoring aquatic species by identification of environmental DNA (eDNA) is becoming more common. In order to obtain quantitative datasets for individual species, species-specific quantitative PCR (qPCR) assays are required. Here, we present detailed methodology of qPCR assay design and testing, including in silico, in vitro, and in vivo testing, and comment on the challenges associated with assay design and performance. We use the presented methodology to design assays for three important marine organisms common in the California Current Ecosystem (CCE): humpback whale (Megaptera novaeangliae), shortbelly rockfish (Sebastes jordani), and common murre (Uria aalge). All three assays have excellent sensitivity and high efficiencies ranging from 92% to 99%. However, specificities of the assays varied from species-specific in the case of common murre to the genus-specific shortbelly rockfish assay, to the humpback whale assay which cross-amplified with other two other whale species, including one in a different family. All assays detected their associated targets in complex environmental water samples.

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“…Although we emphasize the applications of optofluidic platforms for the monitoring of chemical parameters in ocean environment in this review, they could also find uses in biological monitoring in the marine ecosystem. For example, a variety of in situ bio/biochemical analyzers (e.g., adenosine triphosphate analyzer and gene analyzer) have been developed on optofluidic platforms, most of them have been evaluated in the real ocean environments including the deep sea [103,104].…”

Section: Discuss and Outlookmentioning

confidence: 99%

Autonomous and In Situ Ocean Environmental Monitoring on Optofluidic Platform

et al. 2020

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Determining the distributions and variations of chemical elements in oceans has significant meanings for understanding the biogeochemical cycles, evaluating seawater pollution, and forecasting the occurrence of marine disasters. The primary chemical parameters of ocean monitoring include nutrients, pH, dissolved oxygen (DO), and heavy metals. At present, ocean monitoring mainly relies on laboratory analysis, which is hindered in applications due to its large size, high power consumption, and low representative and time-sensitive detection results. By integrating photonics and microfluidics into one chip, optofluidics brings new opportunities to develop portable microsystems for ocean monitoring. Optofluidic platforms have advantages in respect of size, cost, timeliness, and parallel processing of samples compared with traditional instruments. This review describes the applications of optofluidic platforms on autonomous and in situ ocean environmental monitoring, with an emphasis on their principles, sensing properties, advantages, and disadvantages. Predictably, autonomous and in situ systems based on optofluidic platforms will have important applications in ocean environmental monitoring.

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In situ Autonomous Acquisition and Preservation of Marine Environmental DNA Using an Autonomous Underwater Vehicle

Cited by 97 publications

References 79 publications

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

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

Quantitative PCR assays to detect humpback whale (Megaptera novaeangliae), shortbelly rockfish (Sebastes jordani), and common murre (Uria aalge) in marine water samples

Autonomous and In Situ Ocean Environmental Monitoring on Optofluidic Platform

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