2021
DOI: 10.1038/s41598-021-00288-5
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Modeling characterization of the vertical and temporal variability of environmental DNA in the mesopelagic ocean

Abstract: Increasingly, researchers are using innovative methods to census marine life, including identification of environmental DNA (eDNA) left behind by organisms in the water column. However, little is understood about how eDNA is distributed in the ocean, given that organisms are mobile and that physical and biological processes can transport eDNA after release from a host. Particularly in the vast mesopelagic ocean where many species vertically migrate hundreds of meters diurnally, it is important to link the loca… Show more

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Cited by 37 publications
(54 citation statements)
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References 64 publications
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“…Furthermore, despite a myriad of processes that could potentially blur eDNA signatures in oceanic environments -such as particle sinking, ocean currents, vertical mixing, and biologically-mediated transport such as diel vertical migration, our results and other recent studies indicate that eDNA signatures may remain localized. Our finding that eDNA detected diversity changes on the order of 10s of meters in depth are consistent with modeling results that show midwater eDNA signatures remain within 20 meters of their origin in the vertical direction (Allan et al, 2021), and add to a growing body of field evidence from pelagic systems demonstrating that eDNA can detect biodiversity changes with depth (Canals et al, 2021;Easson et al, 2020;Govindarajan et al, 2021).…”
Section: Biodiversity Changes With Depthsupporting
confidence: 89%
“…Furthermore, despite a myriad of processes that could potentially blur eDNA signatures in oceanic environments -such as particle sinking, ocean currents, vertical mixing, and biologically-mediated transport such as diel vertical migration, our results and other recent studies indicate that eDNA signatures may remain localized. Our finding that eDNA detected diversity changes on the order of 10s of meters in depth are consistent with modeling results that show midwater eDNA signatures remain within 20 meters of their origin in the vertical direction (Allan et al, 2021), and add to a growing body of field evidence from pelagic systems demonstrating that eDNA can detect biodiversity changes with depth (Canals et al, 2021;Easson et al, 2020;Govindarajan et al, 2021).…”
Section: Biodiversity Changes With Depthsupporting
confidence: 89%
“…As for the resident species, sponge nsDNA may pro- When there is no bar at the corresponding time point, it represents that no fish species were detected. Colour codes refer to the experimental fish species for each tank (three species for each tank, two of which ubiquitous) detection (Allan et al, 2021;Canals et al, 2021). Thus, the sessile nature of sponges could more exhaustively track the diel fluctuations and other behaviours of fishes.…”
Section: Discussionmentioning
confidence: 99%
“…Our evidence further demonstrates how certain sponges could help monitor these more elusive species (preserving eDNA for longer), which may be missed by other monitoring methods. As for the resident species, sponge nsDNA may provide insightful fish detection compared to aquatic eDNA because spatial and temporal variability of aquatic eDNA may affect species detection (Allan et al, 2021; Canals et al, 2021). Thus, the sessile nature of sponges could more exhaustively track fish’s diel fluctuations and other behaviours.…”
Section: Discussionmentioning
confidence: 99%