Integrating biomechanics in evolutionary studies, with examples from the amphidromous goby model system

Richard W. Blob; Kelly M. Diamond; Raphae L. Lagarde; Takashi Maie; Kristine N. Moody; Amanda M. Palecek; Jessica L. Ward; Heiko L. Schoenfuss

doi:10.1242/jeb.244942

Integrating biomechanics in evolutionary studies, with examples from the amphidromous goby model system

Richard W. Blob, Kelly M. Diamond, Raphae L. Lagarde, Takashi Maie, Kristine N. Moody, Amanda M. Palecek, Jessica L. Ward, Heiko L. Schoenfuss

Biodiversity and Ecosystem Health

Research output: Contribution to journal › Review article › peer-review

4 Scopus citations

Abstract

The functional capacities of animals are a primary factor determining survival in nature. In this context, understanding the biomechanical performance of animals can provide insight into diverse aspects of their biology, ranging from ecological distributions across habitat gradients to the evolutionary diversification of lineages. To survive and reproduce in the face of environmental pressures, animals must perform a wide range of tasks, some of which entail tradeoffs between competing demands. Moreover, the demands encountered by animals can change through ontogeny as they grow, sexuallymature ormigrate across environmental gradients. To understand how mechanisms that underlie functional performance contribute to survival and diversification across challenging and variable habitats, we have pursued diverse studies of the comparative biomechanics of amphidromous goby fishes across functional requirements ranging from prey capture and fast-start swimming to adhesion and waterfall climbing. The pan-Tropical distribution of these fishes has provided opportunities for repeated testing of evolutionary hypotheses. By synthesizing data from the lab and field across approaches spanning high-speed kinematics, selection trials, suction pressure recordings, mechanical property testing, muscle fiber-Type measurements and physical modeling of bioinspired designs, we have clarified how multiple axes of variation in biomechanical performance associate with the ecological and evolutionary diversity of these fishes. Our studies of how these fishes meet both common and extreme functional demands add new, complementary perspectives to frameworks developed from other systems, and illustrate how integrating knowledge of the mechanical underpinnings of diverse aspects of performance can give critical insights into ecological and evolutionary questions.

Original language	English
Article number	jeb244942
Journal	Journal of Experimental Biology
Volume	226
DOIs	https://doi.org/10.1242/jeb.244942
State	Published - Apr 2023

Funding

Our sincere thanks to the editors for their invitation to contribute to this Special Issue, and to E. Kane, H. Larsson and an anonymous reviewer for their helpful comments on our manuscript. Our studies of amphidromous goby biomechanics and evolution were made possible through support from field stations in Hawai’i (Division of Aquatic Resources: R. Nishimoto, L. Nishiura, T. Sakihara, T. Shimoda, T. Shindo, N. Ahu, S. Hau, W. Ishikawa, K. Peyton, C. Gewecke), Réunion (Hydrô Réunion: G. Borie, H. Grondin), and Dominica (ATREC: N. Osler). We also thank T. Baumann, R. Bertram, M. Blum, W. Bridges, R. Cediel, M. Childress, J. Cullen, N. Espinoza, G. Forker, S. Furtek, G. Griner, S. Hunter, M. Julius, S. Kawano, R. Keeffe, D. Kobayashi, G. Leonard, K. Lesteberg, A. McKamy, A. Meister, D. Ponton, K. Powder, M. Ptacek, R. Rai, A. Rubin, N. Schneider, T. Schoenfuss, G. Schrank, R. Toonen, J. Walker, J. Wren and V. Young for their contributions to the studies highlighted in this Review. This manuscript has been in part co-authored by UT-Battelle, LLC, under contract DE-AC05-00OR22725 with the US Department of Energy (DOE). The US government retains and the publisher, by accepting the article for publication, acknowledges that the US government retains a nonexclusive, paid-up, irrevocable, worldwide license to publish or reproduce the published form of this manuscript, or allow others to do so, for US government purposes. DOE will provide public access to these results of federally sponsored research in accordance with the DOE Public Access Plan (http://energy.gov/downloads/doe-public-access-plan). Support was provided by the National Science Foundation (IOS-0817794 to R.W.B., IOS-0817911 to H.L.S. and DEB-1310962 to K.N.M), the American Philosophical Society (K.M.D.), the American Society of Ichthyologists and Herpetologists (K.M.D., A.M.P.), the Society for Integrative and Comparative Biology (K.M.D.), Sigma Xi (K.M.D.), the Clemson University Biological Sciences Professional Development Grant-in-Aid of Research (A.M.P.), Clemson University Creative Inquiry (grant no. 479 to R.W.B.), and St Cloud State University Short-Term Faculty Improvement Grant (SCSU-211228 to H.L.S.).

Keywords

Adhesion
Feeding
Fish
Locomotion
Performance

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10.1242/jeb.244942

Cite this

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title = "Integrating biomechanics in evolutionary studies, with examples from the amphidromous goby model system",

abstract = "The functional capacities of animals are a primary factor determining survival in nature. In this context, understanding the biomechanical performance of animals can provide insight into diverse aspects of their biology, ranging from ecological distributions across habitat gradients to the evolutionary diversification of lineages. To survive and reproduce in the face of environmental pressures, animals must perform a wide range of tasks, some of which entail tradeoffs between competing demands. Moreover, the demands encountered by animals can change through ontogeny as they grow, sexuallymature ormigrate across environmental gradients. To understand how mechanisms that underlie functional performance contribute to survival and diversification across challenging and variable habitats, we have pursued diverse studies of the comparative biomechanics of amphidromous goby fishes across functional requirements ranging from prey capture and fast-start swimming to adhesion and waterfall climbing. The pan-Tropical distribution of these fishes has provided opportunities for repeated testing of evolutionary hypotheses. By synthesizing data from the lab and field across approaches spanning high-speed kinematics, selection trials, suction pressure recordings, mechanical property testing, muscle fiber-Type measurements and physical modeling of bioinspired designs, we have clarified how multiple axes of variation in biomechanical performance associate with the ecological and evolutionary diversity of these fishes. Our studies of how these fishes meet both common and extreme functional demands add new, complementary perspectives to frameworks developed from other systems, and illustrate how integrating knowledge of the mechanical underpinnings of diverse aspects of performance can give critical insights into ecological and evolutionary questions.",

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Integrating biomechanics in evolutionary studies, with examples from the amphidromous goby model system

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