Increasing picocyanobacteria success in shelf waters contributes to long‐term food web degradation

Schmidt, Katrin; Birchill, Antony J.; Atkinson, Angus; Brewin, Robert J. W.; Clark, James R.; Hickman, Anna E.; Johns, David G.; Lohan, Maeve C.; Milne, Angela; Pardo, Silvia; Polimene, Luca; Smyth, T. J.; Tarran, Glen A.; Widdicombe, Claire E.; Woodward, E. Malcolm S.; Ussher, Simon J.

doi:10.1111/gcb.15161

Cited by 73 publications

(73 citation statements)

References 75 publications

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“…At the level of functional groups, there is also evidence that diatoms sustain faster growth rates in conditions when they contribute most to the community biomass [41][42][43] . In this connection, the association between a higher ability to sustain fast growth rates and an enhanced contribution to total biomass agrees with the observation that picoeukaryotes tend to become dominant over the picocyanobacteria Synechococcus and Prochlorococcus as conditions become less oligotrophic 31,44,45 . A similar result has been described also for phytoplankton of larger cell sizes, whereby the size distribution of pico-and nanoeukaryotes in the Atlantic Ocean shifted from a biomass dominance of picoeukaryotes in oligotrophic regions towards a dominance by nanoeukaryotes in more nutrient-rich waters 46 .…”

Section: Discussionsupporting

confidence: 87%

Effect of temperature on the unimodal size scaling of phytoplankton growth

Fernández-González

Marañón

2021

Sci Rep

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Contrary to predictions by the allometric theory, there is evidence that phytoplankton growth rates peak at intermediate cell sizes. However, it is still unknown if this pattern may result from the effect of experimental temperature. Here we test whether temperature affects the unimodal size scaling pattern of phytoplankton growth by (1) growing Synechococcus sp., Ostreococcus tauri, Micromonas commoda and Pavlova lutheri at 18 °C and 25 °C, and (2) using thermal response curves available in the literature to estimate the growth rate at 25 °C as well as the maximum growth rate at optimal temperature for 22 species assayed previously at 18 °C. We also assess the sensitivity of growth rate estimates to the metric employed for measuring standing stocks, by calculating growth rates based on in vivo fluorescence, chlorophyll a concentration, cell abundance and biomass (particulate organic carbon and nitrogen content). Our results show that the unimodal size scaling pattern of phytoplankton growth, with a peak at intermediate cell sizes, is observed at 18 °C, 25 °C and at the optimal temperature for growth, and that it prevails irrespective of the standing-stock metric used. The unimodal size scaling pattern of phytoplankton growth is supported by two independent field observations reported in the literature: (i) a positive relationship between cell size and metabolic rate in the picophytoplankton size range and (ii) the dominance of intermediate-size cells in nutrient-rich waters during blooms.

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Section: Discussionsupporting

confidence: 87%

Effect of temperature on the unimodal size scaling of phytoplankton growth

Fernández-González

Marañón

2021

Sci Rep

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“…The observed synergic effect between LT and HL might have important implications for the dynamics of natural Synechococcus populations in the field, where cells are often subjected to concomitant variations of temperature and irradiance, notably in upwelling areas or during seasonal mixing events. In these circumstances, this effect could negatively impact the competitiveness of Synechococcus cells with regard to other phytoplanktonic groups, such as picoeukaryotes or diatoms that often predominate in cold mixed waters (Uysal and Köksalan, 2006;Schmidt et al, 2020).…”

Section: Resultsmentioning

confidence: 99%

Synergic Effects of Temperature and Irradiance on the Physiology of the Marine Synechococcus Strain WH7803

et al. 2020

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“…(Li et al 2009;Morán et al 2010). Such changes are already being observed (Schmidt et al 2020) and are concomitant with changing human nutrient inputs to inshore eutrophic waters (Capuzzo et al 2018). Such shifts underline the need to better understand how pelagic food web efficiency relates to nutrient status.…”

Section: Future Perspectivesmentioning

confidence: 99%

“…Clearly, size spectrum approaches have limitations. They cannot resolve important species-specific detail, for example on changing distribution patterns or replacement of nutritious taxa with those of similar size, but which are non-nutritious or harmful (Schmidt et al 2020). Their key advantage is that, when based on time averaging measurements, and across a sufficiently large range of body mass, they provide insights into some key properties of the system.…”

Section: Groupmentioning

confidence: 99%

Increasing nutrient stress reduces the efficiency of energy transfer through planktonic size spectra

Atkinson

Lilley

Hirst

et al. 2020

Limnology & Oceanography

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Size-spectral approaches quantify the efficiency of energy transfer through food webs, but theory and field studies disagree over how changes in temperature, nutrients, and extreme weather impact on this efficiency. We address this at two scales: via 6 years of weekly sampling of the plankton size spectrum at the Plymouth L4 shelf sea site, and via a new, global-scale, meta-analysis of aquatic size spectra. The time series showed that with summertime nutrient starvation, the energy transfer efficiency from picoplankton to macroplankton decreased (i.e., steepening slopes of the size spectra). This reflected increasing dominance by small cells and their microbial consumers. The extreme storms in winter 2013/2014 caused high metazoan mortality, steep size-spectral slopes, and reduced plankton biomass. However, recovery was within months, demonstrating an inbuilt resilience of the system. Both L4 and our meta-analysis showed steep slopes of normalized size spectra (median −1.11). This reflects much lower values, either of trophic transfer efficiency (3.5%) or predator-prey mass ratio (569), compared to commonly quoted values. Results from the meta-analysis further showed that to represent energy transfer faithfully, size spectra are best constructed in units of carbon mass and not biovolume, and span a mass range of > 10 7. When this range is covered, both the meta-analysis and time series show a dome-shaped relationship between spectral slopes and plankton biomass, with steepening slopes under increasingly oligotrophic and eutrophic conditions. This suggests that ocean warming could decrease the efficiency of energy transfer through pelagic food webs via indirect effects of increasing stratification and nutrient starvation. Climate change and the efficiency of energy transfer through the plankton In a warming climate, increases in ocean temperature, stratification, nutrient shortage, and the frequency of extreme

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Increasing picocyanobacteria success in shelf waters contributes to long‐term food web degradation

Cited by 73 publications

References 75 publications

Effect of temperature on the unimodal size scaling of phytoplankton growth

Effect of temperature on the unimodal size scaling of phytoplankton growth

Synergic Effects of Temperature and Irradiance on the Physiology of the Marine Synechococcus Strain WH7803

Increasing nutrient stress reduces the efficiency of energy transfer through planktonic size spectra

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