Multigenerational exposure to elevated temperatures leads to a reduction in standard metabolic rate in the wild

Pilakouta, Natalie; Killen, Shaun S.; Kristjánsson, Bjarni K.; Skúlason, Skúli; Lindström, Jan; Metcalfe, Neil B.; Parsons, Kevin J.

doi:10.1101/749986

Cited by 8 publications

(21 citation statements)

References 52 publications

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“…In the same way, studies of selection for stress resistance have found a reduction of metabolic rate in selected lines (Harshmann et al, 1999; Padfield et al, 2016). In addition, a study reported that populations of sticklebacks inhabiting geothermally warmed lakes showed a lower RMR than populations from cold lakes, but that this difference was only detected when both populations were acclimated to different temperatures (Pilakouta et al, 2020). However, our results agree a study published by Messamah et al (2017), who reported that the variation in the metabolic rate of 65 Drosophila species was not related to the annual mean temperature of their habitats of origin.…”

Section: Discussionmentioning

confidence: 99%

“…In ectotherms, metabolism increases with environmental temperatures, inducing high metabolic costs in individuals exposed to heat stress as expected by global warming (Lighton & Turner, 2004; Huey & Kingsolver, 2019). Therefore, metabolic depression could be an important strategy to prevent that metabolism exceeds the physiological limits and energy expenditure, which has adversely effects on fitness under extreme heat conditions (Marshall & McQuaid, 2011; González-Tokman et al, 2020; Pilakouta et al, 2020). This metabolic response to high temperature could partially explain the counter gradient variation proposed in metabolic cold adaptation hypothesis (Addo-Bediako, 2002; Gaston et al, 2009), which establishes that ectotherm species from temperate habitats have lower metabolic rates than those living in colder environments (Addo-Bediako et al, 2002; Sylvestre et al, 2007; Schaefer & Walters 2010; Bruning et al, 2013; Sinnatamby et al, 2015; Pilakouta et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

“…Therefore, metabolic depression could be an important strategy to prevent that metabolism exceeds the physiological limits and energy expenditure, which has adversely effects on fitness under extreme heat conditions (Marshall & McQuaid, 2011; González-Tokman et al, 2020; Pilakouta et al, 2020). This metabolic response to high temperature could partially explain the counter gradient variation proposed in metabolic cold adaptation hypothesis (Addo-Bediako, 2002; Gaston et al, 2009), which establishes that ectotherm species from temperate habitats have lower metabolic rates than those living in colder environments (Addo-Bediako et al, 2002; Sylvestre et al, 2007; Schaefer & Walters 2010; Bruning et al, 2013; Sinnatamby et al, 2015; Pilakouta et al, 2020). On other hand, experimental populations exposed to warm environmental conditions during several generations showed an evolutionary increase of their thermal tolerance accompanied with a reduced metabolic rate (Padfield et al, 2016, but see Mallard et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

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Evolutionary responses of energy metabolism, development, and reproduction to artificial selection for increasing heat tolerance inDrosophila subobscura

Mesas

Castañeda

2022

Preprint

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1. Adaptation to increasing environmental temperatures implies an increase of the upper thermal limit (CTmax), but also an enhanced capacity of the organisms to perform fundamental biological functions at high temperatures. 2. Evolution of stress resistance is companied with a metabolic depression, which allows to organisms have reduced maintaining costs and allocate the energy surplus to energy demanding resistance mechanisms and reproduction. 3. Heat tolerance evolution depends on the heat intensity selection and it could have different consequences on the evolution of correlated traits such as energy metabolism and fitness-related traits. Thus, we evaluated the correlated responses of metabolic rate, metabolism-related enzymes (G6P branchpoint enzymes), reproductive and preadult survival in control and selected lines for increasing heat tolerance in Drosophila subobscura. 4. We did not find a correlated response of metabolic rate associated with heat tolerance evolution, but we detected a reduced hexokinase activity in the slow-ramping selected lines. On the other hand, we found an increase in fecundity in the fast- and slow-ramping selected lines, but an increase in egg-to-adult viability was only found in the slow-ramping selected lines. 5. Our results show that the evolution of heat tolerance does not imply an increase in energy demand neither a tradeoff with reproduction and preadult survival, which suggests that heat tolerance evolution induces correlated response to increase the performance at high temperatures. Therefore, spatial and temporal variability of thermal stress intensity should be taking into account in future studies if we want to understand and predict the adaptive response to ongoing and future climatic conditions.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Evolutionary responses of energy metabolism, development, and reproduction to artificial selection for increasing heat tolerance inDrosophila subobscura

Mesas

Castañeda

2022

Preprint

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“…Geothermally heated habitats can offer valuable natural experiments that overcome the limitations of other natural thermal gradients and experimental approaches. For example, the use of geothermal or artificially heated waterways has recently demonstrated that long‐term exposure (e.g., 1000s of years) to increased temperatures may reduce the temperature sensitivity of metabolism in freshwater fishes (Bruneaux et al, 2014; Pilakouta et al, 2020). Similar reductions in metabolic temperature sensitivity may occur over shorter time scales (e.g., 10s to 100s of years) congruent with current environmental warming caused by climate change (Moffett et al, 2018; Sandblom et al, 2016; White & Wahl, 2020).…”

Section: Introductionmentioning

confidence: 99%

Multigenerational exposure to increased temperature reduces metabolic rate but increases boldness in Gambusia affinis

Moffett

Fryxell

Simon

2022

Ecology and Evolution

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Acute exposure to warming temperatures increases minimum energetic requirements in ectotherms. However, over and within multiple generations, increased temperatures may cause plastic and evolved changes that modify the temperature sensitivity of energy demand and alter individual behaviors. Here, we aimed to test whether populations recently exposed to geothermally elevated temperatures express an altered temperature sensitivity of metabolism and behavior. We expected that long‐term exposure to warming would moderate metabolic rate, reducing the temperature sensitivity of metabolism, with concomitant reductions in boldness and activity. We compared the temperature sensitivity of metabolic rate (acclimation at 20 vs. 30°C) and allometric slopes of routine, standard, and maximum metabolic rates, in addition to boldness and activity behaviors, across eight recently divergent populations of a widespread fish species (Gambusia affinis). Our data reveal that warm‐source populations express a reduced temperature sensitivity of metabolism, with relatively high metabolic rates at cool acclimation temperatures and relatively low metabolic rates at warm acclimation temperatures compared to ambient‐source populations. Allometric scaling of metabolism did not differ with thermal history. Across individuals from all populations combined, higher metabolic rates were associated with higher activity rates at 20°C and bolder behavior at 30°C. However, warm‐source populations displayed relatively bolder behavior at both acclimation temperatures compared to ambient‐source populations, despite their relatively low metabolic rates at warm acclimation temperatures. Overall, our data suggest that in response to warming, multigenerational exposure (e.g., plasticity, adaptation) may not result in trait change directed along a simple “pace‐of‐life syndrome” axis, instead causing relative decreases in metabolism and increases in boldness. Ultimately, our data suggest that multigenerational warming may produce a novel combination of physiological and behavioral traits, with consequences for animal performance in a warming world.

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“…Populations from warmer environments commonly display metabolic rates below expectations, suggesting that evolutionary adaptation can reduce E (‘countergradient variation’, ‘metabolic cold adaptation hypothesis’; Pilakouta et al., 2020; White et al., 2012; although see Alton et al., 2017). Studies of fish species have recently demonstrated that metabolic reduction at warmer temperatures can arise over few generations (<100 years), but these studies have not assessed the relative contribution of evolutionary change versus plasticity in shaping these patterns (Moffett et al., 2018; Pilakouta et al., 2020).…”

Section: Introductionmentioning

confidence: 99%

Plasticity and evolution shape the scaling of metabolism and excretion along a geothermal temperature gradient

et al. 2022

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Physiological rates are heavily dependent on temperature and body size. Most current predictions of organisms’ response to environmental warming are based on the assumption that key physiological rates such as metabolism and excretion scale independently with body size and temperature and will not evolve. However, temperature is a significant driver for phenotypic variability in the allometric scaling and thermal sensitivity of physiological rates within ectotherm species, suggesting that evolution may play a role in shaping these parameters. We common‐reared six populations of western mosquitofish that have recently established (~100 years ago) in geothermal springs along a broad thermal gradient (19–33°C) to determine whether these scaling parameters are affected by evolutionary and/or plastic responses to warming over ecological timescales. Each population was reared at four different temperatures (23, 26, 30 and 32°C). We measured routine metabolic and nitrogen excretion rates on mosquitofish across a wide body size range. We found evidence for plasticity, but not evolution, increasing the allometric scaling of metabolic rate with temperature. Plasticity in metabolism allometry reflected a decrease in thermal sensitivity at smaller body sizes. We found evidence for evolution of phenotypic plasticity on the allometry of excretion rate, reflecting evolutionary differences in how thermal sensitivity varies with body size across different populations. Evolutionary differences in excretion rate scaling did not influence the relationship between excretion and metabolism across rearing temperatures, suggesting that warming does not affect the balance between mosquitofish energy demands and nutrient recycling rates. Read the free Plain Language Summary for this article on the Journal blog.

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Multigenerational exposure to elevated temperatures leads to a reduction in standard metabolic rate in the wild

Cited by 8 publications

References 52 publications

Evolutionary responses of energy metabolism, development, and reproduction to artificial selection for increasing heat tolerance inDrosophila subobscura

Evolutionary responses of energy metabolism, development, and reproduction to artificial selection for increasing heat tolerance inDrosophila subobscura

Multigenerational exposure to increased temperature reduces metabolic rate but increases boldness in Gambusia affinis

Plasticity and evolution shape the scaling of metabolism and excretion along a geothermal temperature gradient

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