Mara F. Müller scite author profile

Analysing the effect water temperature has on Daphnia magna is essential in anticipating the impact climate change will have on this freshwater zooplanktonic keystone species. While many authors have followed this line of research, few have covered an extensive temperature range or complex temperature change scenarios. Global warming is mostly associated with increased extreme temperature events, such as heat waves, as well as earlier and more intense thermal stratification. Both of these events may directly influence D. magna fitness, especially in those populations performing diel vertical migration (DVM). We analysed the effect water temperatures, ranging from 11 to 29°C, have on the filtration capacity (FC) of D. magna, to anticipate the effects of acclimation, temperature change rate (TCR) and potential reversibility of responses to such conditions. Results show that sudden temperature changes have an immediate negative impact on the FC of D. magna and is more severe at higher temperatures and higher TCRs. However, D. magna individuals have shown themselves to be capable of quasi-acclimating to temperatures ranging from 11 to 25°C in around a week and achieving much higher FCs; albeit never reaching the optimal FC achieved at 20°C. That said, 29°C is lethal for D. magna individuals within approximately five days. Finally, non-optimal temperature acclimated individuals can recover maximal FC within 2–4 days of the optimal long-term acclimation temperature (20°C) being re-established, thus proving temperature responses to be reversible.

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Optimal light conditions for Daphnia filtration

Serra

Müller

Barcelona

et al. 2019

Science of The Total Environment

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Functional responses of Daphnia magna to zero-mean flow turbulence

Serra

Müller

Colomer

2019

Sci Rep

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Daphnia are important to understanding the biogeochemistry of aquatic ecosystems, mainly because of their ability to filter bacteria, algae and inorganic particles as well. Although there are many studies on the general effects that biotic and abiotic stressors, increased temperature and hypoxia, salinity, metals, pharmaceuticals, pesticides, etc., have on Daphnia populations, little is known about the impact elevated turbulence has. Here, we show that turbulence affects Daphnia magna survival, swimming behaviour and filtering capacity. Our data demonstrate that altering their habitat by induced mixing from turbulence, induces an increased filtering capacity of the Daphnia magna individuals, provided the level of background turbulence (defined by the dissipation of turbulent kinetic energy) is lower than ε = 0.04 cm 2 s −3 . The filtering capacity reduced exponentially with increasing ε, and at ε > 1 cm 2 s −3 both mobility and filtration were suppressed and eventually led to the death of all the Daphnia magna individuals.

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Mediated food and hydrodynamics on the ingestion of microplastics by Daphnia magna

Colomer

Müller

Barcelona

et al. 2019

Environmental Pollution

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The rise of animal biotelemetry and genetics research data integration

Müller

Banks

Crewe

et al. 2023

Ecology and Evolution

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Mara F. Müller

Temperature-driven response reversibility and short-term quasi-acclimation of Daphnia magna

Optimal light conditions for Daphnia filtration

Functional responses of Daphnia magna to zero-mean flow turbulence

Mediated food and hydrodynamics on the ingestion of microplastics by Daphnia magna

The rise of animal biotelemetry and genetics research data integration

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