Evolution of the Turtle Body Plan by the Folding and Creation of New Muscle Connections

Nagashima, Hiroshi; Sugahara, Fumiaki; Takechi, Masaki; Ericsson, Rolf; Kawashima-Ohya, Yoshie; Narita, Yuichi; Kuratani, Shigeru

doi:10.1126/science.1173826

Cited by 122 publications

(153 citation statements)

References 25 publications

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“…More recently, we have added another vertebrate species, the Chinese soft-shell turtle (Pelodiscus sinensis), to the analysis (Wang et al, 2013). Although the turtle has a very different body plan to that of other vertebrates (Nagashima et al, 2009), we found that the most conserved embryonic period between turtle and chicken in terms of expression profiles matched the same vertebrate phylotypic period that had been identified previously (Irie and Kuratani, 2011) (Fig. 2C).…”

Section: The Morphological Features Of the Phylotypic Periodmentioning

confidence: 61%

The developmental hourglass model: a predictor of the basic body plan?

2014

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The hourglass model of embryonic evolution predicts an hourglasslike divergence during animal embryogenesis -with embryos being more divergent at the earliest and latest stages but conserved during a mid-embryonic ( phylotypic) period that serves as a source of the basic body plan for animals within a phylum. Morphological observations have suggested hourglass-like divergence in various vertebrate and invertebrate groups, and recent molecular data support this model. However, further investigation is required to determine whether the phylotypic period represents a basic body plan for each animal phylum, and whether this principle might apply at higher taxonomic levels. Here, we discuss the relationship between the basic body plan and the phylotypic stage, and address the possible mechanisms that underlie hourglass-like divergence.

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Section: The Morphological Features Of the Phylotypic Periodmentioning

confidence: 61%

The developmental hourglass model: a predictor of the basic body plan?

2014

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“…As we have shown here, embryos of a pleurodiran turtle have the rib development axially arrested, with a conserved topographical relationship of different anatomical elements in the same position as other turtles (Hirasawa et al, 2014). This suggests that the development of the shell by the axial arrest of the rib cage and the folding of the body wall is the mechanism by which the carapace was formed in the common ancestors of turtles (Hirasawa et al, 2014, Nagashima et al, 2009. The turtle last common ancestor would probably have had epidermal scutes over the endoskeleton scaffold of the carapace, but the developmental module underlying the formation of the scutes comes later than the CR induction in development , and whether it has been indeed conserved between cryptodiran and pleurodiran still needs further research.…”

Section: Wnt Pathway and The Evolutionary Origin Of The Carapacial Ridgementioning

confidence: 99%

“…Compared with the general tetrapod bauplan, the turtle skeleton is radically different: in the turtle the ribs remain in the dorsal part and grow laterally, instead of ventrally, due to a process that has been called axial arrest . Eventually, unlike in the rest of tetrapods, the rib cage remains open and the shoulder girdle becomes underneath them by folding of the body wall ('Folding Theory'; Kuratani et al, 2011, Nagashima et al, 2009.…”

Section: Introductionmentioning

confidence: 99%

Comparative analysis of pleurodiran and cryptodiran turtle embryos depicts the molecular ground pattern of the turtle carapacial ridge

Pascual-Anaya¹,

Hirasawa²,

Sato³

et al. 2014

Int. J. Dev. Biol.

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The turtle shell is a wonderful example of a genuine morphological novelty, since it has no counterpart in any other extant vertebrate lineages. The evolutionary origin of the shell is a question that has fascinated evolutionary biologists for over two centuries and it still remains a mystery. One of the turtle innovations associated with the shell is the carapacial ridge (CR), a bulge that appears at both sides of the dorsal lateral trunk of the turtle embryo and that probably controls the formation of the carapace, the dorsal moiety of the shell. Although from the beginning of this century modern genetic techniques have been applied to resolve the evolutionary developmental origin of the CR, the use of different models with, in principle, dissimilar results has hampered the establishment of a common mechanism for the origin of the shell. Although modern turtles are divided into two major groups, Cryptodira (or hidden-necked turtles) and Pleurodira (or side-necked turtles), molecular developmental studies have been carried out mostly using cryptodiran models. In this study, we revisit the past data obtained from cryptodiran turtles in order to reconcile the different results. We also analyze the histological anatomy and the expression pattern of main CR factors in a pleurodiran turtle, the red-bellied short-necked turtle Emydura subglobosa. We suggest that the turtle shell probably originated concomitantly with the co-option of the canonical Wnt signaling pathway into the CR in the last common ancestor of the turtle.

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“…Several rather limited taxons such as chelonians and crocodilians have received some attention recently, for very specific purposes (Green et al, 2014, Milinkovitch et al, 2013, Nagashima et al, 2009, Shaffer et al, 2013, Wang et al, 2013, yet the importance of Squamata is certainly not reflected in the number of species used efficiently at the bench, despite the recent releases of genome sequences for the green anole lizard (Alfoldi et al, 2011), the Burmese python (Castoe et al, 2013) the king cobra (Vonk et al, 2013) or other snakes (Gilbert et al, 2014), as well as several high quality transcriptomes (see e.g. (Schwartz et al, 2010, Tzika et al, 2011.…”

Section: 'Snakes' As Model Organisms?mentioning

confidence: 99%

Snakes: hatching of a model system for Evo-Devo?

Guerreiro¹,

Duboule²

2014

Int. J. Dev. Biol.

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Evo-Devo studies rely on a collection of animal model systems belonging to different phylogenetic branches to try and understand how organisms carrying a similar set of genes and pathways can develop into such a variety of shapes and sizes. The squamate clade, however, has only recently started to receive the attention it deserves in particular due to extreme morphological and metabolic aspects and, consequently, the important insights that it could bring in different fields. The recent sequencing of several squamate genomes as well as the generation of high quality trancriptomes for different snake tissues now provide the necessary tools to complement biological studies. Here, we briefly report on recent work involving developing snake embryos to illustrate their interest to assess vertebrate developmental mechanisms. We also discuss the relevance to use snake species as Evo-Devo model systems and potential ways to cross the important limitations intrinsically associated with developmental and genetic studies of these fascinating animals.

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Evolution of the Turtle Body Plan by the Folding and Creation of New Muscle Connections

Cited by 122 publications

References 25 publications

The developmental hourglass model: a predictor of the basic body plan?

The developmental hourglass model: a predictor of the basic body plan?

Comparative analysis of pleurodiran and cryptodiran turtle embryos depicts the molecular ground pattern of the turtle carapacial ridge

Snakes: hatching of a model system for Evo-Devo?

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