TY - JOUR
T1 - Relative Brain Volume of Carnivorans Has Evolved in Correlation with Environmental and Dietary Variables Differentially among Clades
AU - Lynch, Leigha M.
AU - Allen, Kari L.
N1 - Funding Information:
We thank A. Morhardt, T. Ritzman, and A. Bauernfeind for brainstorming and data interpretation. We also thank M. Carson for assistance with GIS packages and coding. We thank E. Lynch and M. Berg for code proofing and finessing. Thank you to C.P. Heesy for thoughtful discussions and feedback. We thank S. Lynch and R. Allen for their never-ending support during the period in which this project was developed. Costs of manuscript publication will be paid by Midwestern University. No other funding sources were used in the preparation of this data or manuscript.
Publisher Copyright:
© 2022 S. Karger AG, Basel.
PY - 2022/8/1
Y1 - 2022/8/1
N2 - Carnivorans possess relatively large brains compared to most other mammalian clades. Factors like environmental complexity (Cognitive Buffer Hypothesis) and diet quality (Expensive-Tissue Hypothesis) have been proposed as mechanisms for encephalization in other large-brained clades. We examine whether the Cognitive Buffer and Expensive-Tissue Hypotheses account for brain size variation within Carnivora. Under these hypotheses, we predict a positive correlation between brain size and environmental complexity or protein consumption. Relative endocranial volume (phylogenetic generalized least-squares residual from species' mean body mass) and 9 environmental and dietary variables were collected from the literature for 148 species of terrestrial and marine carnivorans. We found that the correlation between relative brain volume and environment and diet differed among clades, a trend consistent with other larger brained vertebrates (i.e., Primates, Aves). Mustelidae and Procyonidae demonstrate larger brains in species with higher-quality diets, consistent with the Expensive-Tissue Hypothesis, while in Herpestidae, correlations between relative brain size and environment are consistent with the Cognitive Buffer Hypothesis. Our results indicate that carnivorans may have evolved relatively larger brains under similar selective pressures as primates despite the considerable differences in life history and behavior between these two clades.
AB - Carnivorans possess relatively large brains compared to most other mammalian clades. Factors like environmental complexity (Cognitive Buffer Hypothesis) and diet quality (Expensive-Tissue Hypothesis) have been proposed as mechanisms for encephalization in other large-brained clades. We examine whether the Cognitive Buffer and Expensive-Tissue Hypotheses account for brain size variation within Carnivora. Under these hypotheses, we predict a positive correlation between brain size and environmental complexity or protein consumption. Relative endocranial volume (phylogenetic generalized least-squares residual from species' mean body mass) and 9 environmental and dietary variables were collected from the literature for 148 species of terrestrial and marine carnivorans. We found that the correlation between relative brain volume and environment and diet differed among clades, a trend consistent with other larger brained vertebrates (i.e., Primates, Aves). Mustelidae and Procyonidae demonstrate larger brains in species with higher-quality diets, consistent with the Expensive-Tissue Hypothesis, while in Herpestidae, correlations between relative brain size and environment are consistent with the Cognitive Buffer Hypothesis. Our results indicate that carnivorans may have evolved relatively larger brains under similar selective pressures as primates despite the considerable differences in life history and behavior between these two clades.
KW - Carnivora
KW - Cognitive Buffer Hypothesis
KW - Diet quality
KW - Environmental complexity
KW - Expensive-Tissue Hypothesis
UR - http://www.scopus.com/inward/record.url?scp=85135596246&partnerID=8YFLogxK
U2 - 10.1159/000523787
DO - 10.1159/000523787
M3 - Article
C2 - 35235933
AN - SCOPUS:85135596246
SN - 0006-8977
VL - 97
SP - 284
EP - 297
JO - Brain, Behavior and Evolution
JF - Brain, Behavior and Evolution
IS - 5
ER -