Bricks, trusses and superstructures: Strategies for skeletal reinforcement in batoid fishes (rays and skates)

Clark, Brett; Chaumel, Júlia; Johanson, Zerina; Underwood, Charlie J.; Smith, Moya Meredith; Dean, Mason N.

doi:10.3389/fcell.2022.932341

Cited by 3 publications

(1 citation statement)

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“… 2015 ; Clark et al . 2022 ). A further feeding shift occurred during the Palaeogene when some durophagous stingrays evolved planktivory, with a reduction in dentition (Adnet et al .…”

mentioning

confidence: 99%

The evolutionary origin of the durophagous pelagic stingray ecomorph

Marramà

Villalobos-Segura

Zorzin³

et al. 2023

Palaeontology

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Studies of the origin of evolutionary novelties (novel traits, feeding modes, behaviours, ecological niches, etc.) have considered a number of taxa experimenting with new body plans, allowing them to occupy new habitats and exploit new trophic resources. In the marine realm, colonization of pelagic environments by marine fishes occurred recurrently through time. Stingrays (Myliobatiformes) are a diverse clade of batoid fishes commonly known to possess venomous tail stings. Current hypotheses suggest that stingrays experimented with a transition from a benthic to a pelagic/benthopelagic habitat coupled with a transition from a non‐durophagous diet to extreme durophagy. However, there is no study detailing macroevolutionary patterns to understand how and when habitat shift and feeding specialization arose along their evolutionary history. A new exquisitely preserved fossil stingray from the Eocene Konservat‐Lagerstätte of Bolca (Italy) exhibits a unique mosaic of plesiomorphic features of the rajobenthic ecomorph, and derived traits of aquilopelagic taxa, that helps to clarify the evolutionary origin of durophagy and pelagic lifestyle in stingrays. A scenario of early evolution of the aquilopelagic ecomorph is proposed based on new data, and the possible adaptive meaning of the observed evolutionary changes is discussed. The body plan of †Dasyomyliobatis thomyorkei gen. et sp. nov. is intermediate between the rajobenthic and more derived aquilopelagic stingrays, supporting its stem phylogenetic position and the hypothesis that the aquilopelagic body plan arose in association with the evolution of durophagy and pelagic lifestyle from a benthic, soft‐prey feeder ancestor.

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“… 2015 ; Clark et al . 2022 ). A further feeding shift occurred during the Palaeogene when some durophagous stingrays evolved planktivory, with a reduction in dentition (Adnet et al .…”

mentioning

confidence: 99%

The evolutionary origin of the durophagous pelagic stingray ecomorph

Marramà

Villalobos-Segura

Zorzin³

et al. 2023

Palaeontology

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Growth of a Tessellation: Geometric rules for the Development of Stingray Skeletal Patterns

Yang,

Knötel,

Ciecierska‐Holmes

et al. 2024

Advanced Science

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The skeletons of sharks and rays, fashioned from cartilage, and armored by a veneer of mineralized tiles (tesserae) present a mathematical challenge: How can the continuous covering be maintained as the skeleton expands? This study, using microCT and custom visual data analyses of growing stingray skeletons, systematically examines tessellation patterns and morphologies of the many thousand interacting tesserae covering the hyomandibula (a skeletal element critical to feeding), over a two‐fold developmental change in hyomandibula length. The number of tesserae remains surprisingly constant, even as the hyomandibula expands isometrically, with all hyomandibulae displaying self‐similar distributions of tesserae shapes/sizes. Although the distribution of tesserae geometries largely agrees with the rules for polyhedra tiling of complex surfaces—dominated by hexagons and a minor fraction of pentagons and heptagons, but very few other polygons—the agreement with Euler's classic mathematical laws is not perfect. Contrary to the assumed uniform growth rate (which is shown would create geometric incompatibilities), larger tesserae grow faster to accommodate skeletal expansion. It is hypothesized that this local regulation of global system complexity is driven by tension (from cartilaginous core expansion) in the fibers connecting tesserae, with strain‐responsive cells orchestrating local mineral apposition.

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