Bite of the Cats: Relationships between Functional Integration and Mechanical Performance as Revealed by Mandible Geometry

Cat-like carnivorous mammals represent a relatively homogeneous group of species whose morphology appears constrained by exclusive adaptations for meat eating. We present the most comprehensive data set of extant and extinct cat-like species to test for evolutionary transformations in size, shape an...

Full description

Saved in:
Bibliographic Details
Published in:Systematic biology 2013-11, Vol.62 (6), p.878-900
Main Authors: Piras, Paolo, Maiorino, Leonardo, Teresi, Luciano, Meloro, Carlo, Lucci, Federico, Kotsakis, Tassos, Raia, Pasquale
Format: Article
Language:English
Subjects:
Allometry
Anatomy & physiology
Animal morphology
Animals
Biological taxonomies
Carnivory - physiology
Cats
Computer Simulation
Evolution
Evolutionary biology
Felidae - anatomy & histology
Finite element analysis
Geometric shapes
Linear Models
Mandible
Mandible - anatomy & histology
Models, Biological
Morphology
Multivariate Analysis
Phylogenetics
Phylogeny
Skull
Software
Systematic biology
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Cat-like carnivorous mammals represent a relatively homogeneous group of species whose morphology appears constrained by exclusive adaptations for meat eating. We present the most comprehensive data set of extant and extinct cat-like species to test for evolutionary transformations in size, shape and mechanical performance, that is, von Mises stress and surface traction, of the mandible. Size and shape were both quantified by means of geometric morphometrics, whereas mechanical performance was assessed applying finite element models to 2D geometry of the mandible. Additionally, we present the first almost complete composite phylogeny of cat-like carnivorans for which well-preserved mandibles are known, including representatives of 35 extant and 59 extinct species of Felidae, Nimravidae, and Barbourofelidae. This phylogeny was used to test morphological differentiation, allometry, and covariation of mandible parts within and among clades. After taking phylogeny into account, we found that both allometry and mechanical variables exhibit a significant impact on mandible shape. We also tested whether mechanical performance was linked to morphological integration. Mechanical stress at the coronoid process is higher in sabertoothed cats than in any other clade. This is strongly related to the high degree of covariation within modules of sabertooths mandibles. We found significant correlation between integration at the clade level and per-clade averaged stress values, on both original data and by partialling out interclade allometry from shapes when calculating integration. This suggests a strong interaction between natural selection and the evolution of developmental and functional modules at the clade level.
ISSN:1063-5157
1076-836X
DOI:10.1093/sysbio/syt053