Early amphibians evolved distinct vertebrae for habitat invasions

Living tetrapods owe their existence to a critical moment 360-340 million years ago when their ancestors walked on land. Vertebrae are central to locomotion, yet systematic testing of correlations between vertebral form and terrestriality and subsequent reinvasions of aquatic habitats is lacking, ob...

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Veröffentlicht in:	PloS one 2021-06, Vol.16 (6), p.e0251983-e0251983
Hauptverfasser:	Carter, Aja Mia, Hsieh, S. Tonia, Dodson, Peter, Sallan, Lauren
Format:	Artikel
Sprache:	eng
Schlagworte:	Amphibia Amphibians Analogs Biology Biology and Life Sciences Biomedical materials Computer and Information Sciences Earth Earth Sciences Editing Environmental science Functional morphology Habitat (Ecology) Locomotion Medicine and Health Sciences Methodology Modification Morphology Muscles Paleozoic Phylogenetics Physiological aspects Reviews Spine Terrestrial environments Vertebra Vertebrae Vertebrates Veterinary medicine Visualization Zoological research
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creator	Carter, Aja Mia Hsieh, S. Tonia Dodson, Peter Sallan, Lauren
description	Living tetrapods owe their existence to a critical moment 360-340 million years ago when their ancestors walked on land. Vertebrae are central to locomotion, yet systematic testing of correlations between vertebral form and terrestriality and subsequent reinvasions of aquatic habitats is lacking, obscuring our understanding of movement capabilities in early tetrapods. Here, we quantified vertebral shape across a diverse group of Paleozoic amphibians (Temnospondyli) encompassing different habitats and nearly the full range of early tetrapod vertebral shapes. We demonstrate that temnospondyls were likely ancestrally terrestrial and had several early reinvasions of aquatic habitats. We find a greater diversity in temnospondyl vertebrae than previously known. We also overturn long-held hypotheses centered on weight-bearing, showing that neural arch features, including muscle attachment, were plastic across the water-land divide and do not provide a clear signal of habitat preferences. In contrast, intercentra traits were critical, with temnospondyls repeatedly converging on distinct forms in terrestrial and aquatic taxa, with little overlap between. Through our geometric morphometric study, we have been able to document associations between vertebral shape and environmental preferences in Paleozoic tetrapods and to reveal morphological constraints imposed by vertebrae to locomotion, independent of ancestry.
doi_str_mv	10.1371/journal.pone.0251983
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We also overturn long-held hypotheses centered on weight-bearing, showing that neural arch features, including muscle attachment, were plastic across the water-land divide and do not provide a clear signal of habitat preferences. In contrast, intercentra traits were critical, with temnospondyls repeatedly converging on distinct forms in terrestrial and aquatic taxa, with little overlap between. 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We also overturn long-held hypotheses centered on weight-bearing, showing that neural arch features, including muscle attachment, were plastic across the water-land divide and do not provide a clear signal of habitat preferences. In contrast, intercentra traits were critical, with temnospondyls repeatedly converging on distinct forms in terrestrial and aquatic taxa, with little overlap between. 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subjects	Amphibia Amphibians Analogs Biology Biology and Life Sciences Biomedical materials Computer and Information Sciences Earth Earth Sciences Editing Environmental science Functional morphology Habitat (Ecology) Locomotion Medicine and Health Sciences Methodology Modification Morphology Muscles Paleozoic Phylogenetics Physiological aspects Reviews Spine Terrestrial environments Vertebra Vertebrae Vertebrates Veterinary medicine Visualization Zoological research
title	Early amphibians evolved distinct vertebrae for habitat invasions
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