Global patterns of body size evolution in squamate reptiles are not driven by climate

Slavenko, Alex; Feldman, Anat; Allison, Allen; Bauer, Aaron M.; Böhm, Monika; Chirio, Laurent; Colli, Guarino R.; Das, Indraneil; Doan, Tiffany M.; LeBreton, Matthew; Martins, Marcio Roberto; Meirte, Danny; Nagy, Zoltán T.; Nogueira, Cristiano de Campos; Pauwels, Olivier S. G.; Pincheira‐Donoso, Daniel; Wagner, Philipp; Wang, Yuezhao; Meiri, Shai

doi:10.1111/geb.12868

Cited by 51 publications

(72 citation statements)

References 79 publications

(132 reference statements)

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“…In our study, we found a similar and significant role for high environmental temperatures in driving shorter life span (although the temperature-size rule is unlikely to be the driver, as amphibians and reptiles show no size-temperature clines either within or between species; Adams & Church, 2008;Slavenko et al, 2019;. Our findings align with recent predictions emerging from the mathematical integration between neutral, metabolic and niche theories (Worm & Tittensor, 2018) that evolutionary processes on a global scale are dominated by environmental temperatures.…”

Section: Discussionsupporting

confidence: 90%

No evidence for the ‘rate‐of‐living’ theory across the tetrapod tree of life

Stark

Pincheira‐Donoso

Meiri

2020

Global Ecol Biogeogr

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Aim The ‘rate‐of‐living’ theory predicts that life expectancy is a negative function of the rates at which organisms metabolize. According to this theory, factors that accelerate metabolic rates, such as high body temperature and active foraging, lead to organismic ‘wear‐out’. This process reduces life span through an accumulation of biochemical errors and the build‐up of toxic metabolic by‐products. Although the rate‐of‐living theory is a keystone underlying our understanding of life‐history trade‐offs, its validity has been recently questioned. The rate‐of‐living theory has never been tested on a global scale in a phylogenetic framework, or across both endotherms and ectotherms. Here, we test several of its fundamental predictions across the tetrapod tree of life. Location Global. Time period Present. Major taxa studied Land vertebrates. Methods Using a dataset spanning the life span data of 4,100 land vertebrate species (2,214 endotherms, 1,886 ectotherms), we performed the most comprehensive test to date of the fundamental predictions underlying the rate‐of‐living theory. We investigated how metabolic rates, and a range of factors generally perceived to be strongly associated with them, relate to longevity. Results Our findings did not support the predictions of the rate‐of‐living theory. Basal and field metabolic rates, seasonality, and activity times, as well as reptile body temperatures and foraging ecology, were found to be unrelated to longevity. In contrast, lower longevity across ectotherm species was associated with high environmental temperatures. Main conclusions We conclude that the rate‐of‐living theory does not hold true for terrestrial vertebrates, and suggest that life expectancy is driven by selection arising from extrinsic mortality factors. A simple link between metabolic rates, oxidative damage and life span is not supported. Importantly, our findings highlight the potential for rapid warming, resulting from the current increase in global temperatures, to drive accelerated rates of senescence in ectotherms.

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Section: Discussionsupporting

confidence: 90%

No evidence for the ‘rate‐of‐living’ theory across the tetrapod tree of life

Stark

Pincheira‐Donoso

Meiri

2020

Global Ecol Biogeogr

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“…The leading rule, Bergmann's rule -increases in body sizes toward colder climates as greater body mass, relative to surface area, reduces heat loss (Bergmann 1847) -has set the theoretical benchmark for research on large-scale patterns of animal size (James 1970, Blackburn et al 1999, Meiri and Dayan 2003. However, evidence from across the animal kingdom reveals that Bergmann's rule tends to hold in endotherms (Freckleton et al 2003, Meiri and Dayan 2003, de Queiroz and Ashton 2004, Olson et al 2009, but see Riemer et al 2018), while its validity is inconsistent in ectotherms (Ashton and Feldman 2003, Olalla-Tarraga et al 2006, Olalla-Tarraga and Rodriguez 2007, Pincheira-Donoso et al 2007, Adams and Church 2008, Pincheira-Donoso and Meiri 2013, Feldman and Meiri 2014, Moreno-Azocar et al 2015, Amado et al 2019, Slavenko et al 2019). These discrepancies have discredited temperature as a primary driver of body size clines (Pincheira-Donoso 2010, Meiri 2011, Olalla-Tarraga 2011.…”

Section: Introductionmentioning

confidence: 99%

Global patterns of body size evolution are driven by precipitation in legless amphibians

et al. 2019

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Body size shapes ecological interactions across and within species, ultimately influencing the evolution of large‐scale biodiversity patterns. Therefore, macroecological studies of body size provide a link between spatial variation in selection regimes and the evolution of animal assemblages through space. Multiple hypotheses have been formulated to explain the evolution of spatial gradients of animal body size, predominantly driven by thermal (Bergmann's rule), humidity (‘water conservation hypothesis’) and resource constraints (‘resource rule’, ‘seasonality rule’) on physiological homeostasis. However, while integrative tests of all four hypotheses combined are needed, the focus of such empirical efforts needs to move beyond the traditional endotherm–ectotherm dichotomy, to instead interrogate the role that variation in lifestyles within major lineages (e.g. classes) play in creating neglected scenarios of selection via analyses of largely overlooked environment–body size interactions. Here, we test all four rules above using a global database spanning 99% of modern species of an entire Order of legless, predominantly underground‐dwelling amphibians (Gymnophiona, or caecilians). We found a consistent effect of increasing precipitation (and resource abundance) on body size reductions (supporting the water conservation hypothesis), while Bergmann's, the seasonality and resource rules are rejected. We argue that subterranean lifestyles minimize the effects of aboveground selection agents, making humidity a dominant selection pressure – aridity promotes larger body sizes that reduce risk of evaporative dehydration, while smaller sizes occur in wetter environments where dehydration constraints are relaxed. We discuss the links between these principles with the physiological constraints that may have influenced the tropically‐restricted global radiation of caecilians.

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“…Macroecological studies have usually asked whether geographical body size gradients (e.g. mean body sizes across assemblages) are associated with spatial environmental variation (Terribile et al , Olalla‐Tárraga et al , Slavenko et al ). These studies typically use an assemblage‐based approach wherein body size is averaged for each set of species occurring in a single grid cell or latitudinal band (Olalla‐Tárraga et al ).…”

Section: Introductionmentioning

confidence: 99%

“…These approaches often uses phylogenetic comparative methods (PCMs) to evaluate the contribution of phylogenetic effects from the resulting geographical body size gradients but they do not explicitly address questions about macroevolutionary processes. That is, PCMs in macroecology have been commonly used for ‘correction for phylogeny’ in statistical analyses and not necessarily to infer evolutionary processes through deep temporal scales (Slavenko et al ). Conversely, macroevolutionary approaches based on PCMs allow identifying changes in tempo (i.e.…”

Section: Introductionmentioning

confidence: 99%

“…The integration of macroecological and macroevolutionary perspectives has been a challenging for researchers attempting to evaluate how biodiversity patterns emerge across spatial and temporal scales (Bromham and Cardillo , McGill et al ). Most studies have usually explored each dimension, spatial or temporal, separately (Smith and Lyons , Amado et al 2019, Slavenko et al ). Few studies have attempted to integrate both spatial and temporal dimensions simultaneously to evaluate geographical and evolutionary body size patterns (Carotenuto et al , Villalobos et al ).…”

Section: Introductionmentioning

confidence: 99%

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Macroecology and macroevolution of body size inAnolislizards

et al. 2020

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Body size is one of the most influential traits affecting many ecological and physiological processes across animal and plant taxa. Studies of the environmental factors shaping body size patterns may evaluate either temporal or spatial dimensions. Here, we analyzed body size evolution in the radiation of Anolis lizards across both geographical and temporal dimensions. We used a set of macroecological and macroevolutionary methods to test current and past environmental effects on geographical gradients of body size and its evolutionary rates. First, we test whether a set of current ecological/ physiological hypotheses (heat balance, productivity and seasonality) explains spatial body size gradients. Second, we evaluate how tempo (i.e. evolutionary rates) and mode (i.e. evolutionary process) of body size evolution changed through time and the role of paleo-temperatures on rates of body size evolution during the Cenozoic. We did not find a signature of current environmental variables driving spatial body size gradients. By contrast, we found strong support for a correlation between temperature changes (i.e. climate cooling) during the Cenozoic and rates of body size evolution (i.e. body size diversification). We suggest that patterns of body size evolution in Anolis lizards might be influenced by thermoregulatory behavior across clades and regions.

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Global patterns of body size evolution in squamate reptiles are not driven by climate

Cited by 51 publications

References 79 publications

No evidence for the ‘rate‐of‐living’ theory across the tetrapod tree of life

No evidence for the ‘rate‐of‐living’ theory across the tetrapod tree of life

Global patterns of body size evolution are driven by precipitation in legless amphibians

Macroecology and macroevolution of body size inAnolislizards

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