Silicified cell walls as a defensive trait in diatoms

Pančić, Marina; Rodríguez-Torres, Rocío; Almeda, Rodrigo; Kiørboe, Thomas

doi:10.1098/rspb.2019.0184

Cited by 65 publications

(67 citation statements)

References 55 publications

(82 reference statements)

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“…This experiment highlights that size diversity (Fig. 8b) is controlled not only by the rate of supply of the limiting nutrients, but also by size-specific grazing (Armstrong, 1994;Poulin and Franks, 2010;Ward et al, 2012).…”

Section: Size Class Diversitymentioning

confidence: 76%

“…Obviously, nutrient supply rate (a bottom up process) cannot alone lead to high size diversity. Top-down processes are essential for the build-up of size classes with higher nutrient supply (see also Poulin and Franks, 2010). Considering only correlations with productivity would lead one to miss this important biotic interaction as a control on diversity.…”

Section: Discussionmentioning

confidence: 99%

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Dimensions of marine phytoplankton diversity

et al. 2020

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Abstract. Biodiversity of phytoplankton is important for ecosystem stability and marine biogeochemistry. However, the large-scale patterns of diversity are not well understood and are often poorly characterized in terms of statistical relationships with factors such as latitude, temperature and productivity. Here we use ecological theory and a global trait-based ecosystem model to provide mechanistic understanding of patterns of phytoplankton diversity. Our study suggests that phytoplankton diversity across three dimensions of trait space (size, biogeochemical function and thermal tolerance) is controlled by disparate combinations of drivers: the supply rate of the limiting resource, the imbalance in different resource supplies relative to competing phytoplankton demands, size-selective grazing and transport by the moving ocean. Using sensitivity studies we show that each dimension of diversity is controlled by different drivers. Models including only one (or two) of the trait dimensions will have different patterns of diversity than one which incorporates another trait dimension. We use the results of our model exploration to infer the controls on the diversity patterns derived from field observations along meridional transects in the Atlantic and to explain why different taxa and size classes have differing patterns.

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Section: Size Class Diversitymentioning

confidence: 76%

Section: Discussionmentioning

confidence: 99%

Dimensions of marine phytoplankton diversity

et al. 2020

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“…There are also specific differences between functional groups in cell elemental stoichiometry, and palatability to grazers (diatoms and coccolithophores, with their hard surface covering deter grazers, see e.g. Monteiro et al, 2016, Pančić et al, 2019. The smallest phytoplankton have the highest affinity for nutrients (Edwards et al, 2012) as a result of the lowest surface to volume ratio in larger cells (Kiorboe 1993, Raven, 1994.…”

Section: Numerical Modelmentioning

confidence: 99%

Dimensions of Marine Phytoplankton Diversity

Dutkiewicz¹,

Cermeño²,

Jahn³

et al. 2019

Preprint

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<p><strong>Abstract.</strong> Biodiversity of phytoplankton is important for ecosystem stability and marine biogeochemistry. However, the large scale patterns of diversity are not well understood, and are often poorly characterized in terms of statistical relationships with environmental factors (e.g. latitude, temperature, productivity). Here we use ecological theory and a global trait-based ecosystem model to provide mechanistic understanding of patterns of phytoplankton diversity. Our study suggests that phytoplankton diversity across three dimensions of trait space (size, biogeochemical function, and thermal tolerance) is controlled by a disparate combinations of drivers: the supply rate of the limiting resource, the imbalance in different resource supplies relative to competing phytoplanktons&#8217; demands, size-selective grazing, and transport by the moving ocean. Using sensitivity studies we show that each dimension of diversity is controlled by different drivers. Models including only one (or two) of the trait dimensions will have different patterns of diversity than one which incorporates another trait dimension. We use the results of our theory/model exploration to infer the controls on the diversity patterns derived from field observations in meridional transects of the Atlantic and to explain why different taxa and size classes have differing patterns. These results suggest that it is unlikely that any single or even combination of environmental variables will be able to explain patterns of diversity.</p>

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“…The shell has the highest mechanical strength relative to its density of any known biological material (Aitken, Luo, Reynolds, Thaulow, & Greer, 2016) and the consequent force required to crush the cell wall is remarkable (Hamm et al., 2003; Wilken et al., 2011). Recent experiments have indeed demonstrated that the shell provides partial protection against copepod grazing (Liu, Chen, Zhu, & Harrison, 2016; Pančić, Torres, Almeda, & Kiørboe, 2019). Thus, a six‐fold increase in silica content in a variety of diatoms decreased the predation mortality due to a copepod grazer by four‐fold and entirely prevented small copepod nauplii from consuming the diatoms (Pančić et al., 2019).…”

Section: Introductionmentioning

confidence: 99%

Diatom defence: Grazer induction and cost of shell‐thickening

Grønning

Kiørboe

2020

Functional Ecology

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Diatoms account for 40% of the ocean primary production and play a key role in the oceans’ ability to sequester carbon. The evolutionary success of diatoms and their role in ocean biogeochemistry are related to the siliceous shell that provide partial protection against grazing. The structure and function of phytoplankton communities are governed by environmental constraints and organismal trade‐offs. Defence mechanisms may help explain the high diversity of phytoplankton (incl. diatoms) in the ocean, but only if the defence comes at a cost. Defence costs have been notoriously difficult to demonstrate and quantify in marine phytoplankton. Here, we demonstrate for seven species of planktonic diatoms that their shell thickens and their growth rate declines when cells are exposed to chemical cues from copepods, important predators of diatoms. The responses are proportional to the concentration of grazer cues, but are also highly variable, both between and within species. At our standard experimental condition, the typical decline in growth rate is 10%, and the typical increase in cellular biogenic silica is 16%. The latter value corresponds to a decline in grazing mortality due to small copepods of 11%. Thus, silification in response to grazers is exactly warranted. The similar magnitude of the costs and benefits of silification suggests a flat fitness landscape along the competition‐defence axis. This may help explain the high diversity of coexisting diatoms in the ocean. The significant but variable contribution of diatoms to the downward flux of organic carbon in the ocean depends to a large extent on the silica content of the cells. This is due less to the ballasting effect of silica, but mainly to the different life histories of more or less defended cells that are governed by evolutionary adaptations and—as demonstrated here—plastic responses to grazers. A free Plain Language Summary can be found within the Supporting Information of this article.

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Silicified cell walls as a defensive trait in diatoms

Cited by 65 publications

References 55 publications

Dimensions of marine phytoplankton diversity

Dimensions of marine phytoplankton diversity

Dimensions of Marine Phytoplankton Diversity

Diatom defence: Grazer induction and cost of shell‐thickening

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