Abstract
BackgroundThe ability to withstand thermal stress is considered to be of crucial importance for individual fitness and species' survival. Thus, organisms need to employ effective mechanisms to ensure survival under stressful thermal conditions, among which phenotypic plasticity is considered a particularly quick and effective one.Methodology/Principal FindingsIn a series of experiments we here investigate phenotypic adjustment in temperature stress resistance following environmental manipulations in the butterfly Bicyclus anynana. Cooler compared to warmer acclimation temperatures generally increased cold but decreased heat stress resistance and vice versa. In contrast, short-time hardening responses revealed more complex patterns, with, e.g., cold stress resistance being highest at intermediate hardening temperatures. Adult food stress had a negative effect on heat but not on cold stress resistance. Additionally, larval feeding treatment showed interactive effects with adult feeding for heat but not for cold stress resistance, indicating that nitrogenous larval resources may set an upper limit to performance under heat stress. In contrast to expectations, cold resistance slightly increased during the first eight days of adult life. Light cycle had marginal effects on temperature stress resistance only, with cold resistance tending to be higher during daytime and thus active periods.Conclusions/SignificanceOur results highlight that temperature-induced plasticity provides an effective tool to quickly and strongly modulate temperature stress resistance, and that such responses are readily reversible. However, resistance traits are not only affected by ambient temperature, but also by, e.g., food availability and age, making their measurement challenging. The latter effects are largely underexplored and deserve more future attention. Owing to their magnitude, plastic responses in thermal tolerance should be incorporated into models trying to forecast effects of global change on extant biodiversity.
Highlights
The ability to withstand environmental stress is of crucial importance for any species’ longer-term survival, and the associated stressors are deemed among the strongest forces of natural selection [1,2,3]
Temperature effects on cold stress resistance Throughout, cool-acclimated butterflies showed a shorter chillcoma recovery time compared to warm-acclimated ones, meaning that the former are more resistant to cold stress than the latter and indicating an adaptive response to temperature variation
Having overall found clear evidence for environmentallyinduced variation in temperature stress resistance, one crucial question remains: Did our experimental designs resemble natural conditions closely enough to extrapolate from our results to field conditions? Our answer is a tentative ‘yes’
Summary
The ability to withstand environmental stress is of crucial importance for any species’ longer-term survival, and the associated stressors are deemed among the strongest forces of natural selection [1,2,3]. According mechanisms to adjust phenotypic values to environmental conditions, including behavioural, physiological and molecular ones, are generally found [5,14,15]. They can be categorized into two classes: longer-term genetic adaptation (e.g. through changes in allele frequencies) and phenotypic plasticity [16,17]. Organisms need to employ effective mechanisms to ensure survival under stressful thermal conditions, among which phenotypic plasticity is considered a quick and effective one
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