Evolutionary innovation accelerates morphological diversification in pufferfishes and their relatives
Evolutionary innovation accelerates morphological diversification in pufferfishes and their relatives
Evolutionary innovations have played an important role in shaping the diversity of life on Earth. However, how these innovations arise and their downstream effects on patterns of morphological diversification remain poorly understood. Here, we examine the impact of evolutionary innovation on trait diversification in tetraodontiform fishes (pufferfishes, boxfishes, ocean sunfishes, and allies). This order provides an ideal model system for studying morphological diversification owing to their range of habitats and divergent morphologies, including the fusion of the teeth into a beak in several families. Using three-dimensional geometric morphometric data for 176 extant and fossil species, we examine the effect of skull integration and novel habitat association on the evolution of innovation. Strong integration may be a requirement for rapid trait evolution and facilitating the evolution of innovative structures, like the tetraodontiform beak. Our results show that the beak arose in the presence of highly conserved patterns of integration across the skull, suggesting that integration did not limit the range of available phenotypes to tetraodontiforms. Furthermore, we find that beaks have allowed tetraodontiforms to diversify into novel ecological niches, irrespective of habitat. Our results suggest that general rules pertaining to evolutionary innovation may be more nuanced than previously thought.
1869–1882
Troyer, Emily M.
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Evans, Kory M.
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Goatley, Christopher H.R.
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Friedman, Matt
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Carnevale, Giorgio
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Nicholas, Benjamin
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Kolmann, Matthew
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Bemis, Katherine
d0ec2403-7fdb-4ba7-925b-eb40dbae370d
Arcila, Dahiana
e3d78472-3273-4aeb-9191-ae3c19237c27
2 October 2024
Troyer, Emily M.
de7a6393-5766-480d-b5bc-77a31d5b6b40
Evans, Kory M.
24b48867-56fe-4cfb-aac8-048a425cfcba
Goatley, Christopher H.R.
b158dc1a-76f3-4ace-9d33-260d8c76ac93
Friedman, Matt
dcd10a20-325c-4caa-9421-7c00825e4e69
Carnevale, Giorgio
2e085b4d-c32c-4a60-af79-b1bfb4b4bb11
Nicholas, Benjamin
80b7af5c-053d-4c48-818b-caf69665ce2b
Kolmann, Matthew
5ac9ceeb-a3ff-4b2e-9155-a376b0f949ac
Bemis, Katherine
d0ec2403-7fdb-4ba7-925b-eb40dbae370d
Arcila, Dahiana
e3d78472-3273-4aeb-9191-ae3c19237c27
Troyer, Emily M., Evans, Kory M., Goatley, Christopher H.R., Friedman, Matt, Carnevale, Giorgio, Nicholas, Benjamin, Kolmann, Matthew, Bemis, Katherine and Arcila, Dahiana
(2024)
Evolutionary innovation accelerates morphological diversification in pufferfishes and their relatives.
Evolution, 78 (11), , [qpae127].
(doi:10.1093/evolut/qpae127).
Abstract
Evolutionary innovations have played an important role in shaping the diversity of life on Earth. However, how these innovations arise and their downstream effects on patterns of morphological diversification remain poorly understood. Here, we examine the impact of evolutionary innovation on trait diversification in tetraodontiform fishes (pufferfishes, boxfishes, ocean sunfishes, and allies). This order provides an ideal model system for studying morphological diversification owing to their range of habitats and divergent morphologies, including the fusion of the teeth into a beak in several families. Using three-dimensional geometric morphometric data for 176 extant and fossil species, we examine the effect of skull integration and novel habitat association on the evolution of innovation. Strong integration may be a requirement for rapid trait evolution and facilitating the evolution of innovative structures, like the tetraodontiform beak. Our results show that the beak arose in the presence of highly conserved patterns of integration across the skull, suggesting that integration did not limit the range of available phenotypes to tetraodontiforms. Furthermore, we find that beaks have allowed tetraodontiforms to diversify into novel ecological niches, irrespective of habitat. Our results suggest that general rules pertaining to evolutionary innovation may be more nuanced than previously thought.
Text
qpae127
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Accepted/In Press date: 10 September 2024
e-pub ahead of print date: 11 September 2024
Published date: 2 October 2024
Identifiers
Local EPrints ID: 495130
URI: http://eprints.soton.ac.uk/id/eprint/495130
ISSN: 0014-3820
PURE UUID: 353133d7-3ebb-4e24-b355-550fc7d601c6
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Date deposited: 30 Oct 2024 17:35
Last modified: 13 Nov 2024 03:06
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Contributors
Author:
Emily M. Troyer
Author:
Kory M. Evans
Author:
Christopher H.R. Goatley
Author:
Matt Friedman
Author:
Giorgio Carnevale
Author:
Benjamin Nicholas
Author:
Matthew Kolmann
Author:
Katherine Bemis
Author:
Dahiana Arcila
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