AI Article Synopsis
- The richness of plankton communities is crucial for the productivity of fish like hakes and tunas, which are important for fisheries.
- Conventional methods of studying plankton involve large water samples and visual analysis, but this study used metabarcoding of environmental DNA (eDNA) from smaller samples collected in the East Atlantic Ocean.
- The research found that zones with high prey for hakes and tunas can be predicted using diatom-based indices, and highlights how climate change impacts these plankton communities, underscoring the value of eDNA for monitoring them.
Article Abstract
The richness of plankton communities determines the fish productivity in the ocean, including important resources that rely on extractive fisheries, such as hakes (genus Merluccius) and tunas (genus Thunnus). Their preys forage on zooplankton, and the latter feed on phytoplankton. Inventories of plankton communities for scientific advice to sustainable fishing are essential in this moment of climate change. Plankton is generally inventoried using conventional methodologies based on large water volumes and visual morphological analyses of samples. In this study, we have employed metabarcoding on environmental DNA (eDNA) samples extracted from small water volumes for plankton inventory from twelve distant sampling stations in the East Atlantic Ocean. Zones rich in hake and tuna prey were detected from eDNA, and multivariate multiple regression analysis was able to predict those zones from diatom-based indices and planktonic diversity based on functional groups. Salinity was negatively correlated with the proportion of diatoms in phytoplankton, highlighting expected impacts of current global change on marine plankton communities. The results emphasise the importance of the plankton richness for fish productivity and support the utility of environmental DNA as a tool to monitor plankton composition changes.
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| http://dx.doi.org/10.1016/j.marenvres.2023.106312 | DOI Listing |
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