Plasticity of upper thermal limits to acute and chronic temperature variation in <i>Manduca sexta</i> larvae

Kingsolver, Joel G.; MacLean, Heidi J.; B., Goddin, Silvan; Augustine, Kate E.

doi:10.1242/jeb.138321

Cited by 37 publications

(44 citation statements)

References 43 publications

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“…For instance, in lizards heat hardening can increase CT MAX by 2.6°C, although trade-offs with basal CT MAX is suggestive of an upper limit to hardening responses (Phillips et al, 2016). In addition, developmental acclimation and hardening can also increase CT MAX in the copepod Tigriopus californicus, the springtail Orchesella cincta and the moth Manduca sexta by 1.3°C,~1.5°C and~1.2°C, respectively (Kingsolver et al, 2016;Alemu et al, 2017;Pereira et al, 2017). It is possible that more extreme temperatures, Table 2 Phylogenetic least squares analysis examining the relationship between CT MAX and acclimation response ratio (ARR) and environmental variables.…”

Section: Discussionmentioning

confidence: 99%

Evidence for lower plasticity in CT_MAX at warmer developmental temperatures

Kellermann

Sgrò

2018

J of Evolutionary Biology

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Understanding the capacity for different species to reduce their susceptibility to climate change via phenotypic plasticity is essential for accurately predicting species extinction risk. The climatic variability hypothesis suggests that spatial and temporal variation in climatic variables should select for more plastic phenotypes. However, empirical support for this hypothesis is limited. Here, we examine the capacity for ten Drosophila species to increase their critical thermal maxima (CT ) through developmental acclimation and/or adult heat hardening. Using four fluctuating developmental temperature regimes, ranging from 13 to 33 °C, we find that most species can increase their CT via developmental acclimation and adult hardening, but found no relationship between climatic variables and absolute measures of plasticity. However, when plasticity was dissected across developmental temperatures, a positive association between plasticity and one measure of climatic variability (temperature seasonality) was found when development took place between 26 and 28 °C, whereas a negative relationship was found when development took place between 20 and 23 °C. In addition, a decline in CT and egg-to-adult viability, a proxy for fitness, was observed in tropical species at the warmer developmental temperatures (26-28 °C); this suggests that tropical species may be at even greater risk from climate change than currently predicted. The combined effects of developmental acclimation and adult hardening on CT were small, contributing to a <0.60 °C shift in CT . Although small shifts in CT may increase population persistence in the shorter term, the degree to which they can contribute to meaningful responses in the long term is unclear.

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Section: Discussionmentioning

confidence: 99%

Evidence for lower plasticity in CT_MAX at warmer developmental temperatures

Kellermann

Sgrò

2018

J of Evolutionary Biology

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“…As an example, the TPCs for larval growth rates in Manduca sexta measured over short (24 h) or long (duration of larval growth period, 15-50 days) time scales differ in optimal temperature, thermal . Similarly, thermal thresholds of larval M. sexta are much higher at shorter than at longer time scales: the mean upper thermal limit for survival (through the larval period) is 35-368C, whereas mean CT max and upper lethal limits are 44-468C [34].…”

Section: Responses Of Ectotherms To Variable Weathermentioning

confidence: 99%

“…For example, the stressful impacts of heat waves are often determined by repeated exposures to high daily maximum temperatures rather than to overall mean temperatures. In addition, the biological effects of single versus repeated exposures to extreme temperatures can be qualitatively different [33][34][35][36][37][38]. To explore this issue, we average daily maximum temperatures for two North American sites across weeks (moving average), months and years.…”

Section: (B) Environmental Variability Depends On Time Scalementioning

confidence: 99%

Quantifying thermal extremes and biological variation to predict evolutionary responses to changing climate

Kingsolver

Buckley

2017

Phil. Trans. R. Soc. B

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133

129

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Central ideas from thermal biology, including thermal performance curves and tolerances, have been widely used to evaluate how changes in environmental means and variances generate changes in fitness, selection and microevolution in response to climate change. We summarize the opportunities and challenges for extending this approach to understanding the consequences of extreme climatic events. Using statistical tools from extreme value theory, we show how distributions of thermal extremes vary with latitude, time scale and climate change. Second, we review how performance curves and tolerances have been used to predict the fitness and evolutionary responses to climate change and climate gradients. Performance curves and tolerances change with prior thermal history and with time scale, complicating their use for predicting responses to thermal extremes. Third, we describe several recent case studies showing how infrequent extreme events can have outsized effects on the evolution of performance curves and heat tolerance. A key issue is whether thermal extremes affect reproduction or survival, and how these combine to determine overall fitness. We argue that a greater focus on tails-in the distribution of environmental extremes, and in the upper ends of performance curves-is needed to understand the consequences of extreme events.This article is part of the themed issue 'Behavioural, ecological and evolutionary responses to extreme climatic events'.

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“…For instance, adult plasticity of swimming performance and metabolic rate depends on developmental environment in mosquitofish (Gambusia holbrooki; Seebacher et al, 2014;Seebacher and Grigaltchik, 2015). Yet, despite the likely biogeographic importance of thermal tolerance limits (Sunday et al, 2012), and many published examples of thermal tolerance limit plasticity in ectothermic organisms as a result of developmental or adulthood temperatures (e.g., Stillman and Somero, 2000;Ford and Beitinger, 2005;Fangue et al, 2006;Angiletta, 2009;Overgaard et al, 2011;Cooper et al, 2012;Tepolt and Somero, 2014;Jakobs et al, 2015;Troia et al, 2015;Kingsolver et al, 2016;Pereira et al, 2017;Diamond et al, 2018;Yanar et al, 2019), relatively few studies have assessed the potential for developmental temperatures to shape the phenotypic plasticity of upper thermal tolerance in adults (although see Schaefer and Ryan, 2006;Kellermann et al, 2017;Kellermann and Sgrò, 2018). Here we examine these effects, and their potential mechanistic basis in populations of the intertidal copepod Tigriopus californicus.…”

Section: Introductionmentioning

confidence: 99%

Variation in developmental temperature alters adulthood plasticity of thermal tolerance inTigriopus californicus

Healy

Bock

Burton

2019

Journal of Experimental Biology

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Developmental temperatures affect thermal limit plasticity in adults of a marine ectotherm, and changes in these limits are paralleled by differences in ATP synthesis rate and heat shock protein expression. 2 List of abbreviations Analysis of variance-ANOVA Critical thermal maximum-CT max Electron transport system complexes I and II-CI+II Quantitative real-time polymerase chain reaction-qRT-PCR Temperature coefficient-Q 10

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Plasticity of upper thermal limits to acute and chronic temperature variation in Manduca sexta larvae

Cited by 37 publications

References 43 publications

Evidence for lower plasticity in CT_MAX at warmer developmental temperatures

Evidence for lower plasticity in CT_MAX at warmer developmental temperatures

Quantifying thermal extremes and biological variation to predict evolutionary responses to changing climate

Variation in developmental temperature alters adulthood plasticity of thermal tolerance inTigriopus californicus

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Plasticity of upper thermal limits to acute and chronic temperature variation in Manduca sexta larvae

Cited by 37 publications

References 43 publications

Evidence for lower plasticity in CTMAX at warmer developmental temperatures

Evidence for lower plasticity in CTMAX at warmer developmental temperatures

Quantifying thermal extremes and biological variation to predict evolutionary responses to changing climate

Variation in developmental temperature alters adulthood plasticity of thermal tolerance inTigriopus californicus

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Evidence for lower plasticity in CT_MAX at warmer developmental temperatures

Evidence for lower plasticity in CT_MAX at warmer developmental temperatures