Lothar Schlüter scite author profile

Temperature has a profound effect on the species composition and physiology of marine phytoplankton, a polyphyletic group of microbes responsible for half of global primary production. Here, we ask whether and how thermal reaction norms in a key calcifying species, the coccolithophore Emiliania huxleyi, change as a result of 2.5 years of experimental evolution to a temperature ≈2°C below its upper thermal limit. Replicate experimental populations derived from a single genotype isolated from Norwegian coastal waters were grown at two temperatures for 2.5 years before assessing thermal responses at 6 temperatures ranging from 15 to 26°C, with pCO 2 (400/1100/2200 μatm) as a fully factorial additional factor. The two selection temperatures (15°/26.3°C) led to a marked divergence of thermal reaction norms. Optimal growth temperatures were 0.7°C higher in experimental populations selected at 26.3°C than those selected at 15.0°C. An additional negative effect of high pCO 2 on maximal growth rate (8% decrease relative to lowest level) was observed. Finally, the maximum persistence temperature (T max) differed by 1–3°C between experimental treatments, as a result of an interaction between pCO 2 and the temperature selection. Taken together, we demonstrate that several attributes of thermal reaction norms in phytoplankton may change faster than the predicted progression of ocean warming.

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Long-term dynamics of adaptive evolution in a globally important phytoplankton species to ocean acidification

Schlüter

Lohbeck

Gröger³

et al. 2016

Sci. Adv.

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Formation and mosaicity of coccolith segment calcite of the marine algae Emiliania huxleyi

Yin

Ziegler

Kelm

et al. 2017

Journal of Phycology

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Coccolithophores belong to the most abundant calcium carbonate mineralizing organisms. Coccolithophore biomineralization is a complex and highly regulated process, resulting in a product that strongly differs in its intricate morphology from the abiogenically produced mineral equivalent. Moreover, unlike extracellularly formed biological carbonate hard tissues, coccolith calcite is neither a hybrid composite, nor is it distinguished by a hierarchical microstructure. This is remarkable as the key to optimizing crystalline biomaterials for mechanical strength and toughness lies in the composite nature of the biological hard tissue and the utilization of specific microstructures.To obtain insight into the pathway of biomineralization of Emiliania huxleyi coccoliths, we examine intracrystalline nanostructural features of the coccolith calcite in combination with cell ultrastructural observations related to the formation of the calcite in the coccolith vesicle within the cell. With TEM diffraction and annular dark-field 1

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Experiment: Adaptation of a globally important coccolithophore to ocean warming and acidification

Schlüter¹,

Lohbeck²,

Gutowska³

et al. 2014

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Long-term dynamics of adaptive evolution in a globally important coccolithophore to ocean acidification

Schlüter¹,

Lohbeck²,

Gutowska³

et al. 2015

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Adaptation of a globally important coccolithophore to ocean warming and acidification: time series

Schlüter¹

2014

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Adaptation of a globally important coccolithophore to ocean warming and acidification: Assay data

Schlüter¹

2014

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