Brain size predicts problem-solving ability in mammalian carnivores

Benson‐Amram, Sarah; Dantzer, Ben; Stricker, Gregory; Swanson, Eli M.; Holekamp, Kay E.

doi:10.1073/pnas.1505913113

Cited by 302 publications

(278 citation statements)

References 75 publications

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“…One potential explanation for the differences in relative brain size between food treatments is that they are adaptive. For instance, increased brain size is broadly associated with higher levels of intelligence, problem‐solving abilities, and cognition across species (Benson‐Amram et al., 2016). It is thus plausible that larger brains are favored when resources are scarce because larger brains may improve foraging capabilities and ultimately fitness.…”

Section: Discussionmentioning

confidence: 99%

“…There are clear fitness benefits associated with a larger brain as brain size is positively correlated with increased intelligence, cognition, learning capability, population persistence, and decreased susceptibility to predation (Sol & Lefebvre, 2000; Tebbich & Bshary, 2004; Shultz & Dunbar, 2006a; Sol, Szekely, Liker, & Lefebvre, 2007; Sol, Bacher, Reader, & Lefebvre, 2008; Overington, Morand‐Ferron, Boogert, & Lefebvre, 2009; Barrickman, Bastian, Isler, & van Schaik, 2008; Amiel, Tingley, & Shine, 2011; Reader, Hager, & Laland, 2011; Kotrschal et al., 2013b; MacLean et al., 2014; Kotrschal et al., 2015a; Kotrschal, Corral‐Lopez, Amcoff, & Kolm, 2015b; Benson‐Amram, Dantzer, Stricker, Swanson, & Holekamp, 2016; but also see Drake, 2007). Key hypotheses, such as the expensive tissue hypothesis (i.e., expensive metabolic cost of brain tissue) (Aiello & Wheeler, 1995; Isler & van Schaik, 2009) and energy trade‐off hypothesis (increased encephalization leads to trade‐offs with other functions) (Isler & van Schaik, 2006a,b, 2009; Navarrete, van Schaik, & Isler, 2011; Tsuboi et al., 2015), recognize that brain tissue is costly and that fitness trade‐offs likely underlie increased encephalization (Aiello & Wheeler, 1995).…”

Section: Introductionmentioning

confidence: 99%

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Increased juvenile predation is not associated with evolved differences in adult brain size in Trinidadian killifish (Rivulus hartii)

Beston

Broyles

Walsh

2017

Ecology and Evolution

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Vertebrates exhibit extensive variation in brain size. The long‐standing assumption is that this variation is driven by ecologically mediated selection. Recent work has shown that an increase in predator‐induced mortality is associated with evolved increases and decreases in brain size. Thus, the manner in which predators induce shifts in brain size remains unclear. Increased predation early in life is a key driver of many adult traits, including life‐history and behavioral traits. Such results foreshadow a connection between age‐specific mortality and selection on adult brain size. Trinidadian killifish, Rivulus hartii, are found in sites with and without guppies, Poecilia reticulata. The densities of Rivulus drop dramatically in sites with guppies because guppies prey upon juvenile Rivulus. Previous work has shown that guppy predation is associated with the evolution of adult life‐history traits in Rivulus. In this study, we compared second‐generation laboratory‐born Rivulus from sites with and without guppies for differences in brain size and associated trade‐offs between brain size and other components of fitness. Despite the large amount of existing research on the importance of early‐life events on the evolution of adult traits, and the role of predation on both behavior and brain size, we did not find an association between the presence of guppies and evolutionary shifts in Rivulus brain size. Such results argue that increased rates of juvenile mortality may not alter selection on adult brain size.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Increased juvenile predation is not associated with evolved differences in adult brain size in Trinidadian killifish (Rivulus hartii)

Beston

Broyles

Walsh

2017

Ecology and Evolution

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“…Because the numbers of individuals tested varied substantially for different species in Benson-Amram et al (2016; from one to nine), it is difficult to draw firm conclusions regarding species differences, given the lack of attention to individual differences within a species, particularly in light of the vast differences in rearing history and environmental enrichment that captive animals experience. Furthermore, the number of individuals that eventually succeeded (a dichotomous measure of success) fails to capture the full range of cognitive traits involved in problem solving.…”

Section: Foraging Social Intelligencementioning

confidence: 99%

“…Furthermore, the latter study was limited to three species of felines and hyenasspecies that do not vary considerably with regard to diet and brain size, perhaps leaving sociality as the only differentiating factor to explain differences in problem-solving ability. Neither study tested social problem solving, so both are mute with regard to the advantages of predictive factors for specific cognitive domains.Because the numbers of individuals tested varied substantially for different species in Benson-Amram et al (2016; from one to nine), it is difficult to draw firm conclusions regarding species differences, given the lack of attention to individual differences within a species, particularly in light of the vast differences in rearing history and environmental enrichment that captive animals experience. Furthermore, the number of individuals that eventually succeeded (a dichotomous measure of success) fails to capture the full range of cognitive traits involved in problem solving.…”

mentioning

confidence: 99%

“…Benson-Amram and colleagues (Benson-Amram, Dantzer, Stricker, Swanson, & Holekamp, 2016) recently published the results of an ambitious study designed to investigate whether problem-solving abilities in a large number of carnivore species (140 members of 39 species from nine families) could be predicted by neuroanatomical and socio-ecological measures. This undertaking is all the more impressive when one considers how grossly understudied carnivores have been with regard to their cognitive abilities, relative to other orders (e.g., primates, cetaceans, Passeriformes).…”

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confidence: 99%

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Bigger brains may make better problem-solving carnivores

Vonk

2016

Learn Behav

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) recent demonstration that larger-brained carnivores were more successful in a single problem-solving task, relative to smaller-brained carnivores, irrespective of social complexity, poses a challenge to proponents of the social intelligence hypothesis (Humphrey, 1976) and provides some support for the idea that larger relative brain sizes have evolved to support greater problem-solving abilities. However, an important question, neglected by the authors, is the extent to which foraging ecology, rather than social environment, more accurately predicts problem solving, and whether this relationship would be observed in noncarnivore, noncaptive animals across a range of tasks.Keywords Problem solving . Carnivores . Brain size . Foraging . Social intelligenceBenson-Amram and colleagues (Benson-Amram, Dantzer, Stricker, Swanson, & Holekamp, 2016) recently published the results of an ambitious study designed to investigate whether problem-solving abilities in a large number of carnivore species (140 members of 39 species from nine families) could be predicted by neuroanatomical and socio-ecological measures. This undertaking is all the more impressive when one considers how grossly understudied carnivores have been with regard to their cognitive abilities, relative to other orders (e.g., primates, cetaceans, Passeriformes). This historical oversight is even more glaring when one considers the diversity of foraging ecologies, social structures, and brain sizes in the Carnivore order. The results of the study, based on a single problem-solving task, are intriguing in large part because they run counter to the oft-touted social intelligence hypothesis (Humphrey, 1976): Social complexity did not predict problem-solving success in this study, even though it had recently been shown to do so for a smaller number of species within the same order using a similar task (Borrego & Gaines, 2016). One possible explanation for these differing conclusions may rest upon the dichotomous measure of success in the Benson-Amram et al. study, as compared to the more inclusive measure of innovation in Borrego and Gaines. Furthermore, the latter study was limited to three species of felines and hyenasspecies that do not vary considerably with regard to diet and brain size, perhaps leaving sociality as the only differentiating factor to explain differences in problem-solving ability. Neither study tested social problem solving, so both are mute with regard to the advantages of predictive factors for specific cognitive domains.Because the numbers of individuals tested varied substantially for different species in Benson-Amram et al. (2016; from one to nine), it is difficult to draw firm conclusions regarding species differences, given the lack of attention to individual differences within a species, particularly in light of the vast differences in rearing history and environmental enrichment that captive animals experience. Furthermore, the number of individuals that eventually succeeded (a dichotomous measure of success) fails to capture th...

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