Anatomy of Rhinochelys pulchriceps (Protostegidae) and marine adaptation during the early evolution of chelonioids.

Serjoscha W Evers,Paul M Barrett,Roger B J Benson

doi:10.7717/peerj.6811

Serjoscha W Evers, Paul M Barrett + Show 1 more

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https://doi.org/10.7717/peerj.6811

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Journal: PeerJ	Publication Date: May 1, 2019
Citations: 47	License type: CC BY 4.0

Affiliation: University of Oxford, Natural History Museum

Abstract

Knowledge of the early evolution of sea turtles (Chelonioidea) has been limited by conflicting phylogenetic hypotheses resulting from sparse taxon sampling and a superficial understanding of the morphology of key taxa. This limits our understanding of evolutionary adaptation to marine life in turtles, and in amniotes more broadly. One problematic group are the protostegids, Early–Late Cretaceous marine turtles that have been hypothesised to be either stem-cryptodires, stem-chelonioids, or crown-chelonioids. Different phylogenetic hypotheses for protostegids suggest different answers to key questions, including (1) the number of transitions to marine life in turtles, (2) the age of the chelonioid crown-group, and (3) patterns of skeletal evolution during marine adaptation. We present a detailed anatomical study of one of the earliest protostegids, Rhinochelys pulchriceps from the early Late Cretaceous of Europe, using high-resolution μCT. We synonymise all previously named European species and document the variation seen among them. A phylogeny of turtles with increased chelonioid taxon sampling and revised postcranial characters is provided, recovering protostegids as stem-chelonioids. Our results imply a mid Early Cretaceous origin of total-group chelonioids and an early Late Cretaceous age for crown-chelonioids, which may inform molecular clock analyses in future. Specialisations of the chelonioid flipper evolved in a stepwise-fashion, with innovations clustered into pulses at the origin of total-group chelonioids, and subsequently among dermochelyids, crown-cheloniids, and gigantic protostegids from the Late Cretaceous.

Highlights

Turtles (Testudinata) are a major group of reptiles comprising 335 living species (Turtle Taxonomy Working Group, 2017), with a high ecological diversity, inhabiting marine, freshwater, and terrestrial environments
Computed-tomography data and 3D models used in this study We used high-resolution X-ray CT to generate slice data for six specimens of Rhinochelys, including the holotype specimens of R. pulchriceps, R. elegans, and R. cantabrigiensis
R. pulchriceps differs from R. nammourensis in having a relatively larger frontal bone which laterally has an anteroposteriorly longer contribution to the orbit; a mediolaterally broader dorsal surface of the parietal which forms more than 50% of the width of the skull roof in dorsal view; posteriorly rounded squamosals that lack the elongate processes seen in R. nammourensis

Summary

Introduction

Turtles (Testudinata) are a major group of reptiles comprising 335 living species (Turtle Taxonomy Working Group, 2017), with a high ecological diversity, inhabiting marine, freshwater, and terrestrial environments. (i.e. Angolachelonia (sensu Evers & Benson, 2019): Meylan et al, 2000; Anquetin, Püntener & Billon-Bruyat, 2015; Anquetin, Püntener & Joyce, 2017; Evers & Benson, 2019; Bothremydidae: Gaffney, Tong & Meylan, 2006; Rabi, Tong & Botfalvai, 2012; Stereogyina: Sánchez-Villagra et al, 2000; Winkler & Sánchez-Villagra 2006; Gaffney et al, 2011; Ferreira et al, 2015; Chelonioidea: Hirayama, 1994, 1998; Evers & Benson, 2019) Only one such group is extant: Chelonioidea. Extant chelonioids are highly marine animals with adaptations to a pelagic lifestyle that include modifications in the shell, limbs, and skull (Zangerl, 1980; Hirayama, 1994)

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