Morphological integration and modularity in the hyperkinetic feeding system of aquatic-foraging snakes

The kinetic skull is a key innovation that allowed snakes to capture, manipulate, and swallow prey exclusively using their heads using the coordinated movement of eight bones. Despite these unique feeding behaviors, patterns of evolutionary integration and modularity within the feeding bones of snak...

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Veröffentlicht in:	Evolution 2021-01, Vol.75 (1), p.56-72
Hauptverfasser:	Rhoda, Daniel, Polly, P. David, Raxworthy, Christopher, Segall, Marion
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Sprache:	eng
Schlagworte:	Animal biology Biomechanics Bones Feeding behavior Functional modularity Integration Life Sciences Mandible Maxilla Modularity morphological evolution Morphology morphometrics ORIGINAL ARTICLE Phylogeny Prey Procrustes superimposition Skull snakes
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creator	Rhoda, Daniel Polly, P. David Raxworthy, Christopher Segall, Marion
description	The kinetic skull is a key innovation that allowed snakes to capture, manipulate, and swallow prey exclusively using their heads using the coordinated movement of eight bones. Despite these unique feeding behaviors, patterns of evolutionary integration and modularity within the feeding bones of snakes in a phylogenetic framework have yet to be addressed. Here, we use a dataset of 60 µ CT-scanned skulls and high-density geometric morphometric methods to address the origin and patterns of variation and integration in the feeding bones of aquatic-foraging snakes. By comparing alternate superimposition protocols allowing us to analyze the entire kinetic feeding system simultaneously, we find that the feeding bones are highly integrated, driven predominantly by functional selective pressures. The most supported pattern of modularity contains four modules, each associated with distinct functional roles: the mandible, the palatopterygoid arch, the maxilla, and the suspensorium. Further, the morphological disparity of each bone is not linked to its magnitude of integration, indicating that integration within the feeding system does not strongly constrain morphological evolution, and that adequate biomechanical solutions to a wide range of feeding ecologies and behaviors are readily evolvable within the constraint due to integration in the snake feeding system.
doi_str_mv	10.1111/evo.14130
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The most supported pattern of modularity contains four modules, each associated with distinct functional roles: the mandible, the palatopterygoid arch, the maxilla, and the suspensorium. Further, the morphological disparity of each bone is not linked to its magnitude of integration, indicating that integration within the feeding system does not strongly constrain morphological evolution, and that adequate biomechanical solutions to a wide range of feeding ecologies and behaviors are readily evolvable within the constraint due to integration in the snake feeding system.</description><identifier>ISSN: 0014-3820</identifier><identifier>EISSN: 1558-5646</identifier><identifier>DOI: 10.1111/evo.14130</identifier><identifier>PMID: 33226114</identifier><language>eng</language><publisher>United States: Wiley</publisher><subject>Animal biology ; Biomechanics ; Bones ; Feeding behavior ; Functional modularity ; Integration ; Life Sciences ; Mandible ; Maxilla ; Modularity ; morphological evolution ; Morphology ; morphometrics ; ORIGINAL ARTICLE ; Phylogeny ; Prey ; Procrustes superimposition ; Skull ; snakes</subject><ispartof>Evolution, 2021-01, Vol.75 (1), p.56-72</ispartof><rights>2020 The Authors. 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source	Jstor Complete Legacy; Oxford University Press Journals All Titles (1996-Current); Wiley Online Library Journals Frontfile Complete
subjects	Animal biology Biomechanics Bones Feeding behavior Functional modularity Integration Life Sciences Mandible Maxilla Modularity morphological evolution Morphology morphometrics ORIGINAL ARTICLE Phylogeny Prey Procrustes superimposition Skull snakes
title	Morphological integration and modularity in the hyperkinetic feeding system of aquatic-foraging snakes
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