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McQuatters-Gollop, A, Stern, RF, Atkinson, A, Best, M, Bresnan, E, Creach, V, Devlin, M, Holland, M, Ostle, C, Schmidt, K, Sheppard, L, Tarran, GA, Woodward, EMS and Tett, P 2024 The silent majority: Pico- and nanoplankton as ecosystem health indicators for marine policy. Ecological Indicators, 159. 111650. https://doi.org/10.1016/j.ecolind.2024.111650
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McQuatters-Gollop et al. 2024.pdf - Published Version Available under License Creative Commons Attribution. Download (7MB) | Preview |
Abstract/Summary
A healthy marine ecosystem is a fully functioning system, able to supply ecosystem services whilst still maintaining resilience to human-induced environmental change. Monitoring and managing the health of resilient marine ecosystems requires indicators that can assess their biodiversity state and food web functioning. Plankton are crucial components of pelagic habitats, occupying the base of the pelagic food web. Larger plankton have long been used to monitor ecosystem productivity and biodiversity due to their identification via traditional light microscopy. In contrast, the regular monitoring of pico- and nanoplankton (<20 µm; hereafter called “tiny plankton”) only started with the development of flow cytometry techniques, which has limited their inclusion as ecosystem health indicators. Four UK plankton surveys have sampled and identified these tiny plankton for up to 14 years, providing an opportunity to test their suitability as indicators of ecosystem state. We investigated six groups of tiny plankton, including heterotrophic nanoeukaryotes, photosynthetic nanoeukaryotes, photosynthetic picoeukaryotes, and Synechococcus cyanobacteria, and two groups of heterotrophic bacteria. Flow cytometry and light microscopy data from an inshore Western English Channel station revealed that 99.98 % of plankton abundance and 71 % of plankton biomass was derived from tiny plankton cells too small to be quantified accurately under a light mi�croscope and thus not adequately considered in assessments of pelagic habitats. Different UK marine and coastal regions showed consistency in peak abundances of these tiny plankton. We used a novel wavelet coherence method to identify time-based relationships between tiny plankton and envi�ronmental variables linked to human pressures. Relationships were found between nitrogenous nutrients and all tiny plankton groups, most commonly at sub-annual to annual time scales. Photosynthetic picoeukaryotes, heterotrophic nanoeukaryotes, and HNA-bacteria were associated with high sea surface temperatures. Given the here established relationship between tiny plankton and environmental variables, and their importance in the full plankton assemblage, we recommend that, alongside existing microplankton lifeforms, tiny plankton groups can be used as plankton lifeforms, either individually or in combination, to inform biodiversity indicators that meet policy obligations under the EU Marine Strategy Framework Directive (MSFD), (Oslo-Paris Convention) OSPAR strategies, and the UK Marine Strategy.
| Item Type: | Publication - Article |
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| Additional Keywords: | Picoplankton Biodiversity Marine strategy framework directive Pelagic habitats Ecosystem approach Synechococcus |
| Divisions: | Plymouth Marine Laboratory > National Capability categories > Single Centre NC - CLASS Plymouth Marine Laboratory > National Capability categories > Western Channel Observatory Plymouth Marine Laboratory > Science Areas > Earth Observation Science and Applications Plymouth Marine Laboratory > Science Areas > Marine Biochemistry and Observations Plymouth Marine Laboratory > Science Areas > Marine Ecology and Biodiversity |
| Depositing User: | S Hawkins |
| Date made live: | 20 Mar 2024 10:35 |
| Last Modified: | 17 Apr 2024 12:09 |
| URI: | https://plymsea.ac.uk/id/eprint/10161 |
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