Head‐turning morphologies: Evolution of shape diversity in the mammalian atlas–axis complex

Linden, Abby Vander; Campbell, Kristin M; Bryar, Erin K; Santana, Sharlene E.

doi:10.1111/evo.13815

Evolution

2019

DOI: 10.1111/evo.13815

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Head‐turning morphologies: Evolution of shape diversity in the mammalian atlas–axis complex

Abby Vander Linden

Kristin M Campbell

Erin K Bryar

et al.

Abstract: Mammals flex, extend, and rotate their spines as they perform behaviors critical for survival, such as foraging, consuming prey, locomoting, and interacting with conspecifics or predators. The atlas–axis complex is a mammalian innovation that allows precise head movements during these behaviors. Although morphological variation in other vertebral regions has been linked to ecological differences in mammals, less is known about morphological specialization in the cervical vertebrae, which are developmentally co… Show more

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Cited by 17 publications

(14 citation statements)

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“…In particular, the atlas, or first cervical vertebra, acts as the main interface between the head and the axial skeleton and, therefore, plays a critical role in directing and stabilizing head movements (rev. in 4,5 ). As such, previous studies have emphasized the functional link between the morphology of the atlas, head mobility, and postural and locomotor repertoires in catarrhines (e.g.…”

mentioning

confidence: 99%

“…As such, previous studies have emphasized the functional link between the morphology of the atlas, head mobility, and postural and locomotor repertoires in catarrhines (e.g. [5][6][7] ). More specifically, while the shape and curvature of the articular facets at the atlanto-occipital joint determines the range of head motions in terms of flexion and extension, the atlanto-axial joint is responsible for lateral rotation of the atlas and the head (rev.…”

mentioning

confidence: 99%

“…More specifically, while the shape and curvature of the articular facets at the atlanto-occipital joint determines the range of head motions in terms of flexion and extension, the atlanto-axial joint is responsible for lateral rotation of the atlas and the head (rev. in [4][5][6][7][8]. Combined analysis of the superior and inferior articular facets has the potential to provide essential information about the range of head motions in Australopithecus, which has only been superficially assessed due to the scarcity and fragmentary nature of cervical vertebrae in the hominin fossil record 9,10 .…”

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confidence: 99%

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The atlas of StW 573 and the late emergence of human-like head mobility and brain metabolism

Beaudet

Clarke

Heaton

et al. 2020

Sci Rep

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Functional morphology of the atlas reflects multiple aspects of an organism's biology. More specifically, its shape indicates patterns of head mobility, while the size of its vascular foramina reflects blood flow to the brain. Anatomy and function of the early hominin atlas, and thus, its evolutionary history, are poorly documented because of a paucity of fossilized material. Meticulous excavation, cleaning and high-resolution micro-CT scanning of the StW 573 ('Little Foot') skull has revealed the most complete early hominin atlas yet found, having been cemented by breccia in its displaced and flipped over position on the cranial base anterolateral to the foramen magnum. Description and landmark-free morphometric analyses of the StW 573 atlas, along with other less complete hominin atlases from Sterkfontein (StW 679) and Hadar (AL 333-83), confirm the presence of an arboreal component in the positional repertoire of Australopithecus. Finally, assessment of the cross-sectional areas of the transverse foramina of the atlas and the left carotid canal in StW 573 further suggests there may have been lower metabolic costs for cerebral tissues in this hominin than have been attributed to extant humans and may support the idea that blood perfusion of these tissues increased over the course of hominin evolution.

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confidence: 99%

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confidence: 99%

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confidence: 99%

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The atlas of StW 573 and the late emergence of human-like head mobility and brain metabolism

Beaudet

Clarke

Heaton

et al. 2020

Sci Rep

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“…Instead, evolution toward more elongate bodies must occur through reduction of body depth, elongation of the head, and/or elongation of the individual vertebrae. Previous work has shown that changes in vertebral shape can generate diverse body shapes from longnecked giraffes with elongate cervical vertebrae to fusiform dolphins with shortened and fused cervical vertebrae (Buchholtz 2001;Buchholtz and Schur 2004;Arnold et al 2017;Vander Linden et al 2019). Furthermore, more recent work has investigated the evolutionary processes that led to increase in the complexity and regionalization of the mammalian vertebral column (Jones et al 2018a, b;Jones et al 2019).…”

mentioning

confidence: 99%

“…2017; Vander Linden et al. 2019). Furthermore, more recent work has investigated the evolutionary processes that led to increase in the complexity and regionalization of the mammalian vertebral column (Jones et al.…”

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confidence: 99%

Evolutionary and morphological patterns underlying carnivoran body shape diversity

Law

2020

Evolution

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The diversity of body shapes is one of the most prominent features of phenotypic variation in vertebrates. Biologists, however, still lack a full understanding of the underlying morphological components that contribute to its diversity, particularly in endothermic vertebrates such as mammals. In this study, hypotheses pertaining to the evolution of the cranial and axial components that contribute to the diversity of carnivoran body shapes were tested. Three trends were found in the evolution of carnivoran body shapes: (1) carnivorans exhibit diverse body shapes with intrafamilial variation predicted best by family clade age, (2) body shape is driven by strong allometric effects of body size where species become more elongate with decreasing size, and (3) the thoracic and lumbar regions and rib length contribute the most to body shape variation, albeit pathways differ between different families. These results reveal the morphological patterns that led to increased diversity in carnivoran body shapes and elucidate the similarities and dissimilarities that govern body shape diversity across vertebrates.

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Small‐ to medium‐sized mammals show greater morphological disparity in cervical than lumbar vertebrae across different terrestrial modes of locomotion

Taewcharoen,

Norris,

Sherratt

2024

Ecology and Evolution

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During mammalian terrestrial locomotion, body flexibility facilitated by the vertebral column is expected to be correlated with observed modes of locomotion, known as gait (e.g., sprawl, trot, hop, bound, gallop). In small‐ to medium‐sized mammals (average weight up to 5 kg), the relationship between locomotive mode and vertebral morphology is largely unexplored. Here we studied the vertebral column from 46 small‐ to medium‐sized mammals. Nine vertebrae across cervical, thoracic, and lumbar regions were chosen to represent the whole vertebral column. Vertebra shape was analysed using three‐dimensional geometric morphometrics with the phylogenetic comparative method. We also applied the multi‐block method, which can consider all vertebrae as a single structure for analysis. We calculated morphological disparity, phylogenetic signal, and evaluated the effects of allometry and gait on vertebral shape. We also investigated the pattern of integration in the column. We found the cervical vertebrae show the highest degree of morphological disparity, and the first thoracic vertebra shows the highest phylogenetic signal. A significant effect of gait type on vertebrae shape was found, with the lumbar vertebrae having the strongest correlation; but this effect was not significant after taking phylogeny into account. On the other hand, allometry has a significant effect on all vertebrae regardless of the contribution from phylogeny. The regions showed differing degrees of integration, with cervical vertebrae most strongly correlated. With these results, we have revealed novel information that cannot be captured from study of a single vertebra alone: although the lumbar vertebrae are the most correlated with gait, the cervical vertebrae are more morphologically diverse and drive the diversity among species when considering whole column shape.

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Head‐turning morphologies: Evolution of shape diversity in the mammalian atlas–axis complex

Cited by 17 publications

References 75 publications

The atlas of StW 573 and the late emergence of human-like head mobility and brain metabolism

The atlas of StW 573 and the late emergence of human-like head mobility and brain metabolism

Evolutionary and morphological patterns underlying carnivoran body shape diversity

Small‐ to medium‐sized mammals show greater morphological disparity in cervical than lumbar vertebrae across different terrestrial modes of locomotion

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