Why polar gigantism and <scp>P</scp>alaeozoic gigantism are not equivalent: effects of oxygen and temperature on the body size of ectotherms

Verberk, Wilco C. E. P.; Atkinson, David

doi:10.1111/1365-2435.12152

Cited by 126 publications

(174 citation statements)

References 73 publications

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“…This was a consistent pattern, indicated by the nonsignificant three-way interaction term (F 4,248 ¼ 0.53, p ¼ 0.72) when species identity was included as a covariate. This is empirical support for predictions that b is negatively correlated with temperature [7,10,11]. Increased temperature caused an expected increase in metabolism, but this was asymmetric; metabolism in smaller individuals rose relatively more than in larger individuals, reflected in decreasing slope (b) values (e.g.…”

Section: )supporting

confidence: 74%

Size matters: plasticity in metabolic scaling shows body-size may modulate responses to climate change

Carey

Sigwart

2014

Biol. Lett.

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Variability in metabolic scaling in animals, the relationship between metabolic rate ( R ) and body mass ( M ), has been a source of debate and controversy for decades. R is proportional to M b , the precise value of b much debated, but historically considered equal in all organisms. Recent metabolic theory, however, predicts b to vary among species with ecology and metabolic level, and may also vary within species under different abiotic conditions. Under climate change, most species will experience increased temperatures, and marine organisms will experience the additional stressor of decreased seawater pH (‘ocean acidification’). Responses to these environmental changes are modulated by myriad species-specific factors. Body-size is a fundamental biological parameter, but its modulating role is relatively unexplored. Here, we show that changes to metabolic scaling reveal asymmetric responses to stressors across body-size ranges; b is systematically decreased under increasing temperature in three grazing molluscs, indicating smaller individuals were more responsive to warming. Larger individuals were, however, more responsive to reduced seawater pH in low temperatures. These alterations to the allometry of metabolism highlight abiotic control of metabolic scaling, and indicate that responses to climate warming and ocean acidification may be modulated by body-size.

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Section: )supporting

confidence: 74%

Size matters: plasticity in metabolic scaling shows body-size may modulate responses to climate change

Carey

Sigwart

2014

Biol. Lett.

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“…According to the viscosity hypothesis [97], small aquatic animals have greater difficulty engaging in respiratory ventilation and thus oxygen uptake in colder, more viscous water than do larger animals. Consequently, as water temperature decreases, and viscosity increases, smaller animals should exhibit a greater depression of metabolic rate than that of larger animals, thus resulting in a negative association between temperature and the metabolic scaling slope.…”

Section: Implications Of Results For Theorymentioning

confidence: 99%

Effects of Contingency versus Constraints on the Body-Mass Scaling of Metabolic Rate

Glazier

2018

Challenges

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I illustrate the effects of both contingency and constraints on the body-mass scaling of metabolic rate by analyzing the significantly different influences of ambient temperature (T a ) on metabolic scaling in ectothermic versus endothermic animals. Interspecific comparisons show that increasing T a results in decreasing metabolic scaling slopes in ectotherms, but increasing slopes in endotherms, a pattern uniquely predicted by the metabolic-level boundaries hypothesis, as amended to include effects of the scaling of thermal conductance in endotherms outside their thermoneutral zone. No other published theoretical model explicitly predicts this striking variation in metabolic scaling, which I explain in terms of contingent effects of T a and thermoregulatory strategy in the context of physical and geometric constraints related to the scaling of surface area, volume, and heat flow across surfaces. My analysis shows that theoretical models focused on an ideal 3/4-power law, as explained by a single universally applicable mechanism, are clearly inadequate for explaining the diversity and environmental sensitivity of metabolic scaling. An important challenge is to develop a theory of metabolic scaling that recognizes the contingent effects of multiple mechanisms that are modulated by several extrinsic and intrinsic factors within specified constraints.

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“…Yet, comparisons of aquatic and terrestrial species revealed that aquatic species exhibit either equal (Klok and Harrison 2013) or greater (Forster et al 2012) thermal plasticity of body size. According to Verberk and Atkinson (2013), greater thermal plasticity among aquatic species results from unique physical challenges of respiring in water coupled with a greater supply of oxygen in cold water. Yet, our study included samples from cold, hypoxic waters, an environmental scenario ignored by synthetic analyses at the interspecific level.…”

Section: Resultsmentioning

confidence: 99%

Colder rotifers grow larger but only in oxygenated waters

et al. 2015

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Citation: Czarnoleski, M., J. Ejsmont-Karabin, M. J. Angilletta, Jr., and J. Kozlowski. 2015. Colder rotifers grow larger but only in oxygenated waters. Ecosphere 6(9):164. http://dx.doi.org/10.1890/ES15-00024.1Abstract. Why do colder ectotherms grow more slowly but mature at a larger size? Some researchers have argued that oxygen supply and demand play a crucial role in these processes, but many studies conflated the effects of oxygen and temperature. We studied the body sizes of rotifers (Keratella cochlearis) at different depths in 20 European lakes, taking advantage of gradients in oxygen and temperature during summer, when dense, cool waters sink to low depths and become hypoxic. Rotifers were larger in colder waters, but only in the presence of abundant oxygen. In hypoxic waters, rotifers remained small regardless of temperature. We propose that oxygen supply generates a ceiling for maximal possible body size, especially in environments that elevate metabolic demands. Under this condition, any of several processes-developmental plasticity, genetic divergence, size-dependent mortality, or size-dependent selection of microhabitats-could cause a wider range of body sizes in more oxygenated waters, where the maximal possible size exceeds the adaptive size at any temperature.

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Why polar gigantism and Palaeozoic gigantism are not equivalent: effects of oxygen and temperature on the body size of ectotherms

Cited by 126 publications

References 73 publications

Size matters: plasticity in metabolic scaling shows body-size may modulate responses to climate change

Size matters: plasticity in metabolic scaling shows body-size may modulate responses to climate change

Effects of Contingency versus Constraints on the Body-Mass Scaling of Metabolic Rate

Colder rotifers grow larger but only in oxygenated waters

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