Experimental evolution in fluctuating environments: tolerance measurements at constant temperatures incorrectly predict the ability to tolerate fluctuating temperatures

Ketola, Tarmo; Saarinen, Kati

doi:10.1111/jeb.12606

Cited by 50 publications

(66 citation statements)

References 68 publications

(110 reference statements)

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“…Allowing our populations to acclimate at a temperature regularly experienced during summer months in the wild (16°C; Table 1 and Supplementary material Fig. S1), measuring CT max in a fluctuating thermal environment (Ketola and Saarinen, 2015), increasing temperature at a rate previously found to be optimal for fish studies on thermal tolerance (0.3°C/min; Becker and Genoway, 1979) and measuring both CT max and a behavioural metric of agitation temperature have provided new evidence for less variability in thermal tolerance than previously thought. Reasons for this may be the scale at which other studies were conducted (see McDermid et al ., 2012; Stitt et al ., 2014) as well as the historical genetic or environmentally driven similarities in the populations being assessed.…”

Section: Discussionmentioning

confidence: 99%

Limited variability in upper thermal tolerance among pure and hybrid populations of a cold-water fish

et al. 2016

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Section: Discussionmentioning

confidence: 99%

Limited variability in upper thermal tolerance among pure and hybrid populations of a cold-water fish

et al. 2016

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“…, ; Phillips et al. ; Ketola and Saarinen ). Temperature is a major factor affecting species distributions, particularly of ectotherms (Angilletta et al.…”

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confidence: 97%

Keeping your options open: Maintenance of thermal plasticity during adaptation to a stable environment

et al. 2015

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Phenotypic plasticity may allow species to cope with environmental variation. The study of thermal plasticity and its evolution helps understanding how populations respond to variation in temperature. In the context of climate change, it is essential to realize the impact of historical differences in the ability of populations to exhibit a plastic response to thermal variation and how it evolves during colonization of new environments. We have analyzed the real-time evolution of thermal reaction norms of adult and juvenile traits in Drosophila subobscura populations from three locations of Europe in the laboratory. These populations were kept at a constant temperature of 18ºC, and were periodically assayed at three experimental temperatures (13ºC, 18ºC, and 23ºC). We found initial differentiation between populations in thermal plasticity as well as evolutionary convergence in the shape of reaction norms for some adult traits, but not for any of the juvenile traits. Contrary to theoretical expectations, an overall better performance of high latitude populations across temperatures in early generations was observed. Our study shows that the evolution of thermal plasticity is trait specific, and that a new stable environment did not limit the ability of populations to cope with environmental challenges.

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“…For example a study with ciliates showed no adaptation to fluctuating environments when measured at constant temperatures, but strains adapted to rapidly fluctuating thermal environments had increased expression of the heat shock protein Hsp90, indicating evolution of tolerance to cope with acute stress (Ketola et al, 2004). From studies that have tested the effect of evolution in fluctuating environments on tolerance curves and performance also in fluctuating environments (Bennett and Lenski, 1993;Leroi et al, 1994;Kassen and Bell, 1998;Hughes et al, 2007;Ketola and Saarinen, 2015), only one study shows a positive link between tolerance curve parameters obtained across constant environments and the performance in fluctuating environments (Hughes et al, 2007) and one suggests a strong negative link (Ketola and Saarinen, 2015).…”

Section: Problems With Tolerance Curvesmentioning

confidence: 99%

“…When this information is projected on tolerance curves obtained at constant environments it unambiguously indicates if fitness in fluctuating environments is reflected in the tolerance curves. Ketola and Saarinen (2015) did not utilize marker strains and they used fitness surrogates in their experiments. Still, this study provides insights on the value of tolerance curves obtained from constant thermal environments.…”

Section: Experimental Evolutionmentioning

confidence: 99%

“…Still, this study provides insights on the value of tolerance curves obtained from constant thermal environments. The idea in Ketola and Saarinen (2015) was to test if fluctuations increased growth or yield of bacterial clones during fluctuations, which could be seen as an adaptation to prevailing conditions. Accordingly, strains evolved in fluctuating regimes had higher growth rate under fluctuations than strains evolved in constant environments.…”

Section: Experimental Evolutionmentioning

confidence: 99%

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Experimental Approaches for Testing if Tolerance Curves Are Useful for Predicting Fitness in Fluctuating Environments

Ketola

Kristensen

2017

Front. Ecol. Evol.

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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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Experimental evolution in fluctuating environments: tolerance measurements at constant temperatures incorrectly predict the ability to tolerate fluctuating temperatures

Cited by 50 publications

References 68 publications

Limited variability in upper thermal tolerance among pure and hybrid populations of a cold-water fish

Limited variability in upper thermal tolerance among pure and hybrid populations of a cold-water fish

Keeping your options open: Maintenance of thermal plasticity during adaptation to a stable environment

Experimental Approaches for Testing if Tolerance Curves Are Useful for Predicting Fitness in Fluctuating Environments

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