Plasticity in algal stoichiometry: Experimental evidence of a temperature‐induced shift in optimal supply N:P ratio

Thrane, Jan‐Erik; Hessen, Dag O.; Andersen, Tom

doi:10.1002/lno.10500

Cited by 47 publications

(41 citation statements)

References 44 publications

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“…, Thrane et al. , Verbeek et al. ) or the effect of temperature variability independently (Vasseur et al.…”

Section: Introductionmentioning

confidence: 99%

“…Nutrient supply has empirically been shown to interact strongly with temperature (Thrane et al. , Marañón et al. , Verbeek et al.…”

Section: Introductionmentioning

confidence: 99%

“…Moreover, recent studies have analyzed the effect of temperature on the phytoplankton resource use and stoichiometry, showing that higher temperatures may cause an increase in the phytoplankton optimal N:P supply ratio (Thrane et al. ) as in the phytoplankton intracellular N:P ratios (Yvon‐Durocher et al. ).…”

Section: Introductionmentioning

confidence: 99%

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Phytoplankton community responses to temperature fluctuations under different nutrient concentrations and stoichiometry

Gerhard

Koussoroplis

Hillebrand

et al. 2019

Ecology

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Nutrient availability and temperature are important drivers of phytoplankton growth and stoichiometry. However, the interactive effects of nutrients and temperature on phytoplankton have been analyzed mostly by addressing changes in average temperature, whereas recent evidence suggests an important role of temperature fluctuations. In a laboratory experiment, we grew a natural phytoplankton community under fluctuating and constant temperature regimes across 25 combinations of nitrogen (N) and phosphorus (P) supply. Temperature fluctuations decreased phytoplankton growth rate (rmax), as predicted by nonlinear averaging along the temperature–growth relationship. rmax increased with increasing P supply, and a significant temperature × P × N interaction reflected that the shape of the thermal reaction norm depended on nutrients. By contrast, phytoplankton carrying capacity increased with N supply and in fluctuating rather than constant temperature. Higher phytoplankton N:P ratios under constant temperature showed that temperature regimes affected cellular nutrient incorporation. Minor differences in species diversity and composition existed. Our results suggest that temperature variability interacts with nutrient supply to affect phytoplankton physiology and stoichiometry at the community level.

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“…, Thrane et al. , Verbeek et al. ) or the effect of temperature variability independently (Vasseur et al.…”

Section: Introductionmentioning

confidence: 99%

“…Nutrient supply has empirically been shown to interact strongly with temperature (Thrane et al. , Marañón et al. , Verbeek et al.…”

Section: Introductionmentioning

confidence: 99%

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Phytoplankton community responses to temperature fluctuations under different nutrient concentrations and stoichiometry

Gerhard

Koussoroplis

Hillebrand

et al. 2019

Ecology

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“…For example, older tropical soils are richer in N than P, whereas soils of recently glaciated regions at higher latitudes show the opposite pattern, implying reduced N:P ratios in colder areas (Reich and Oleksyn, 2004). Latitudinal and temperature-related changes in N:P likely reflect a higher demand for ribosomes (and thus P) to maintain sufficient protein synthesis at lower temperatures (Toseland et al, 2013;Thrane et al, 2017). This apparent link between temperature and stoichiometry in primary producers is perhaps unsurprising given that temperature drives the rates of many biological processes, including photosynthesis (C gain) and N and P uptake from the environment.…”

Section: Future Research Prioritiesmentioning

confidence: 99%

“…At the genomic level, transcription rates in plants also increase with temperature (Sidaway-Lee et al, 2014). The higher demands for ribosomes at lower temperatures may occur to maintain protein synthesis or arise from the increased number of stored immature ribosomes in the nucleolus (Leitch et al, 1995), which can also translate into higher P-demands (and lower N:P) (Woods et al, 2003;Toseland et al, 2013;Thrane et al, 2017).…”

Section: Future Research Prioritiesmentioning

confidence: 99%

Impacts of Nitrogen and Phosphorus: From Genomes to Natural Ecosystems and Agriculture

et al. 2017

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Nitrogen (N) and/or phosphorus (P) availability can limit growth of primary producers across most of the world's aquatic and terrestrial ecosystems. These constraints are commonly overcome in agriculture by applying fertilizers to improve yields. However, excessive anthropogenic N and P inputs impact natural environments and have far-reaching ecological and evolutionary consequences, from individual species up to entire ecosystems. The extent to which global N and P cycles have been perturbed over the past century can be seen as a global fertilization experiment with significant redistribution of nutrients across different ecosystems. Here we explore the effects of N and P availability on stoichiometry and genomic traits of organisms, which, in turn, can influence: (i) plant and animal abundances; (ii) trophic interactions and population dynamics; and (iii) ecosystem dynamics and productivity of agricultural crops. We articulate research priorities for a deeper understanding of how bioavailable N and P move through the environment and exert their ultimate impacts on biodiversity and ecosystem services.

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Temperature and stoichiometric dependence of phytoplankton traits

Hofmann

Chatzinotas

Dunker

2019

Ecology

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Understanding the links between intraspecific trait variability and environmental gradients is an important step toward unravelling the mechanisms that link species performance to environmental variation. Here, we performed a comparative, experimental study to investigate variability of cellular traits in three prokaryotic and three eukaryotic freshwater phytoplankton species along gradients of temperature and nitrogen:phosphorus ratio (N:P) in laboratory microcosms. Temperature and N:P strongly affect phytoplankton growth and are changing due to climate change and eutrophication. Metabolic theory and allometric scaling predict that smaller organisms should be favored at higher temperatures through improved metabolic uptake partly due to greater surface area to volume ratios. In addition, chlorophyll a (chl a) concentration should increase due to higher chlorophyll synthesis in response to light limitation at higher cell densities. We found that cell volume both increased and decreased with temperature, whereas intermediate N:P yielded higher growth rates and more extreme conditions yielded bigger cell volumes. Species growth responses to these gradients were distinct and not related to phylogenetic differences. Meaningfully coupled traits like the chl a fluorescence and cell volume shifted consistently and can improve our understanding of individual cell responses to abiotic drivers. This study showed that intraspecific trait variability of freshwater phytoplankton harbors potential for short term acclimation to environmental gradients. Finally, the high trait variability in some species has strong implications for their ecology and the accuracy of predictions where responses may differ when based on mean or fixed trait values.

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Plasticity in algal stoichiometry: Experimental evidence of a temperature‐induced shift in optimal supply N:P ratio

Cited by 47 publications

References 44 publications

Phytoplankton community responses to temperature fluctuations under different nutrient concentrations and stoichiometry

Phytoplankton community responses to temperature fluctuations under different nutrient concentrations and stoichiometry

Impacts of Nitrogen and Phosphorus: From Genomes to Natural Ecosystems and Agriculture

Temperature and stoichiometric dependence of phytoplankton traits

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