Response of Development and Body Mass to Daily Temperature Fluctuations: a Study on Tribolium castaneum

Kramarz, Paulina; Małek, Dariusz; Naumiec, Karolina; Zając, Katarzyna; Drobniak, Szymon M.

doi:10.1007/s11692-016-9375-6

Cited by 9 publications

(3 citation statements)

References 36 publications

(54 reference statements)

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“…This pattern is opposite to the observed plastic decreases in development time at warmer temperatures both in the laboratory and in the field, highlighting that evolutionary responses may differ based on expectations from plasticity alone. Studies in other organisms also suggest that development time is heritable (Bradshaw et al , ), although it was low and nonsignificant, regardless of thermal regimes, in the beetle Tribolium castaneum (Kramarz et al , ). Diapause occurrence in insects has also found to be heritable in a number of species (Roff, ; Begin & Roff, ; Han & Denlinger, ; Chen et al , ) (but see also Piiroinen et al , ) and may be an important adaptive response for insects to avoid stressful temperatures with climate change.…”

Section: Adaptive Responses To Climate Changementioning

confidence: 99%

Terrestrial insects and climate change: adaptive responses in key traits

2019

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Understanding and predicting how adaptation will contribute to species' resilience to climate change will be paramount to successfully managing biodiversity for conservation, agriculture, and human health‐related purposes. Making predictions that capture how species will respond to climate change requires an understanding of how key traits and environmental drivers interact to shape fitness in a changing world. Current trait‐based models suggest that low‐ to mid‐latitude populations will be most at risk, although these models focus on upper thermal limits, which may not be the most important trait driving species' distributions and fitness under climate change. In this review, we discuss how different traits (stress, fitness and phenology) might contribute and interact to shape insect responses to climate change. We examine the potential for adaptive genetic and plastic responses in these key traits and show that, although there is evidence of range shifts and trait changes, explicit consideration of what underpins these changes, be that genetic or plastic responses, is largely missing. Despite little empirical evidence for adaptive shifts, incorporating adaptation into models of climate change resilience is essential for predicting how species will respond under climate change. We are making some headway, although more data are needed, especially from taxonomic groups outside of Drosophila, and across diverse geographical regions. Climate change responses are likely to be complex, and such complexity will be difficult to capture in laboratory experiments. Moving towards well designed field experiments would allow us to not only capture this complexity, but also study more diverse species.

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Section: Adaptive Responses To Climate Changementioning

confidence: 99%

Terrestrial insects and climate change: adaptive responses in key traits

2019

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“…Despite this, it remains poorly understood how such trade-offs are determined by the variation in temperature experienced by wild populations, because laboratory studies have typically tested the fitness costs of thermal stress using constant temperature regimes (Fischer et al, 2011;Colinet et al, 2015), which may have little relevance to those experienced in naturally varying environments (Mitchell & Hoffmann, 2010;Anderson et al, 2014). The heritability of a trait can also vary substantially depending upon the environment, making it important to estimate genetic variance and trait correlations under ecologically realistic conditions (Hoffmann & Merila, 1999;Loeschcke et al, 1999;Kramarz et al, 2016), in order to determine the potential for evolutionary responses to climatic change (Hoffmann & Sgro, 2011).…”

Section: Introductionmentioning

confidence: 99%

Temperature fluctuations during development reduce male fitness and may limit adaptive potential in tropical rainforest Drosophila

Saxon

O’Brien

Bridle

2018

J of Evolutionary Biology

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Understanding the potential for organisms to tolerate thermal stress through physiological or evolutionary responses is crucial given rapid climate change. Although climate models predict increases in both temperature mean and variance, such tolerances are typically assessed under constant conditions. We tested the effects of temperature variability during development on male fitness in the rainforest fly Drosophila birchii, by simulating thermal variation typical of the warm and cool margins of its elevational distribution, and estimated heritabilities and genetic correlations of fitness traits. Reproductive success was reduced for males reared in warm (mean 24 °C) fluctuating (±3 °C) vs. constant conditions but not in cool fluctuating conditions (mean 17 °C), although fluctuations reduced body size at both temperatures. Male reproductive success under warm fluctuating conditions was similar to that at constant 27 °C, indicating that briefly exceeding critical thermal limits has similar fitness costs to continuously stressful conditions. There was substantial heritable variation in all traits. However, reproductive success traits showed no genetic correlation between treatments reflecting temperature variation at elevational extremes, which may constrain evolutionary responses at these ecological margins. Our data suggest that even small increases in temperature variability will threaten tropical ectotherms living close to their upper thermal limits, both through direct effects on fitness and by limiting their adaptive potential.

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“…For the life of ectotherms like insects, the temperature unquestionably has significant impact on biological features at all levels of organisation. (Kramarz et al, 2016). Constant temperatures are used in the majority of thermal biology research.…”

Section: Effects Of Different Temperaturementioning

confidence: 99%

Influence of Different Stored Grains and Temperature on Developmental Stages and Survival Rates of Oryzaephilus surinamensis (L.) (Coleoptera: Silvanidae)

Awadalla,

Hashem,

Ramadan

et al. 2023

Journal of Plant Protection and Pathology

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The sawtoothed grain beetle, Oryzaephilus surinamensis (L.), is a secondary pest causes great damage to cereal grains, commodities, and packaged food all over the world. Beyond cereal grains, this species is a concern because it may be differently impacted based on variation in temperature. Therefore, development time, larval and pupal survival, and adult emergence of O. surinamensis were evaluated on various substrates at different temperatures regimes (22, 28, 32, and 38 °C). With highly significant differences, the larval stage duation of O. surinamensis ranged from 19.2 ± 1.26 days on rice grains to 25.6 ± 0.98 days on white maize grains. The insect exhibited the highest rate of larval survival (95%) on rice grain followed by oat (90%) and wheat grain (89%). The shortest larval stage duration was measured at 38°C (12.1± 0.98 d), followed by 32°C (16.4±1.03 d) with highly significant differences. The total immature stage durations ranged from 22.9 days at 38 °C to 54.2 days at 22 °C. The percentage of larvae that survived varied from 62% at 38°C to 91% at 32°C. The average number of adults that emerged at a temperature of less than 38°C was 5.1 ± 1.12 individuals, which was the lowest recorded value. Therefore, the grain type and temperature range plays a significant role in determining sawtoothed grain beetle infestation, which might have future implications for controlling this insect pest.

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Response of Development and Body Mass to Daily Temperature Fluctuations: a Study on Tribolium castaneum

Cited by 9 publications

References 36 publications

Terrestrial insects and climate change: adaptive responses in key traits

Terrestrial insects and climate change: adaptive responses in key traits

Temperature fluctuations during development reduce male fitness and may limit adaptive potential in tropical rainforest Drosophila

Influence of Different Stored Grains and Temperature on Developmental Stages and Survival Rates of Oryzaephilus surinamensis (L.) (Coleoptera: Silvanidae)

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