Experimental Approaches for Testing if Tolerance Curves Are Useful for Predicting Fitness in Fluctuating Environments
Ketola, T., & Kristensen, T. N. (2017). Experimental Approaches for Testing if Tolerance Curves Are Useful for Predicting Fitness in Fluctuating Environments. Frontiers in Ecology and Evolution, 5, Article 129. https://doi.org/10.3389/fevo.2017.00129
Julkaistu sarjassa
Frontiers in Ecology and EvolutionPäivämäärä
2017Oppiaine
Ekologia ja evoluutiobiologiaBiologisten vuorovaikutusten huippututkimusyksikköEcology and Evolutionary BiologyCentre of Excellence in Biological Interactions ResearchTekijänoikeudet
© 2017 Ketola and Kristensen. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY).
Most experimental studies on adaptation to stressful environments are performed under
conditions that are rather constant and rarely ecologically relevant. Fluctuations in natural
environmental conditions are ubiquitous and include for example variation in intensity
and duration of temperature, droughts, parasite loads, and availability of nutrients,
predators and competitors. The frequency and amplitude of many of these fluctuations
are expected to increase with climate change. Tolerance curves are often used to
describe fitness components across environmental gradients. Such curves can be
obtained by assessing performance in a range of constant environmental conditions. In
this perspective we briefly list theoretical and experimental evidence why results obtained
under constant environmental conditions might be misleading for processes in nature
and therefore may not be suitable for predicting fitness and future species distribution
and abundance. We further suggest experimental avenues that can provide a better
foundation for forecasts of the distribution of biota.
...
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