Evolution of locomotion in Anthropoidea: the semicircular canal evidence

Ryan, Timothy M.; Silcox, Mary; Walker, Alan; Mao, Xiaole; Begun, David R.; Benefit, Brenda R.; Gingerich, Philip D.; Köhler, Meike; Kordos, László; McCrossin, Monte L.; Moyà‐Solà, Salvador; Sanders, William J.; Seiffert, Erik R.; Simons, Elwyn L.; Zalmout, Iyad S.; Spoor, Fred

doi:10.1098/rspb.2012.0939

Cited by 55 publications

(54 citation statements)

References 62 publications

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“…However, body mass alone explains ∼79% of the variation in R, whereas agility explains only 0.18% of the variation in R (37). Paleontologists have used R and body mass estimates to infer the agility of movement in extinct species (2,(4)(5)(6)(7)(8)(9)(10). Because R is so much more strongly correlated with body mass than with agility, such inferences can be considered reliable only when body mass is known precisely.…”

Section: Discussionmentioning

confidence: 99%

“…Canal morphology affects endolymph flow and thus influences an animal's sensitivity to rotation; if an animal is more sensitive to rotations about some axes than others, and if different patterns of head rotation are produced by different locomotor behaviors, then canal morphology and locomotion could be functionally related. By this reasoning, differences in canal morphology in living and extinct animals have been attributed to interspecific differences in locomotion (1)(2)(3)(4)(5)(6)(7)(8)(9)(10), but characterization of any functional relationship between canal morphology and locomotion has been limited by the use of simplified models of canal sensitivity and the absence of in vivo data about how the head actually moves (11).…”

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confidence: 99%

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Locomotor head movements and semicircular canal morphology in primates

Malinzak

Kay

Hullar

2012

Proc. Natl. Acad. Sci. U.S.A.

107

222

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Animal locomotion causes head rotations, which are detected by the semicircular canals of the inner ear. Morphologic features of the canals influence rotational sensitivity, and so it is hypothesized that locomotion and canal morphology are functionally related. Most prior research has compared subjective assessments of animal "agility" with a single determinant of rotational sensitivity: the mean canal radius of curvature (R). In fact, the paired variables of R and body mass are correlated with agility and have been used to infer locomotion in extinct species. To refine models of canal functional morphology and to improve locomotor inferences for extinct species, we compare 3D vector measurements of head rotation during locomotion with 3D vector measures of canal sensitivity. Contrary to the predictions of conventional models that are based upon R, we find that axes of rapid head rotation are not aligned with axes of either high or low sensitivity. Instead, animals with fast head rotations have similar sensitivities in all directions, which they achieve by orienting the three canals of each ear orthogonally (i.e., along planes at 90°angles to one another). The extent to which the canal configuration approaches orthogonality is correlated with rotational head speed independent of body mass and phylogeny, whereas R is not.angular velocity | vestibular T he inner ear contains three bony semicircular canals, each of which encloses an endolymph-filled duct. Head rotations during locomotion cause inertial endolymph movements that are communicated to the brain. Canal morphology affects endolymph flow and thus influences an animal's sensitivity to rotation; if an animal is more sensitive to rotations about some axes than others, and if different patterns of head rotation are produced by different locomotor behaviors, then canal morphology and locomotion could be functionally related. By this reasoning, differences in canal morphology in living and extinct animals have been attributed to interspecific differences in locomotion (1-10), but characterization of any functional relationship between canal morphology and locomotion has been limited by the use of simplified models of canal sensitivity and the absence of in vivo data about how the head actually moves (11).The relevant variables for comparing canal sensitivity with head movement are angular velocity vectors and vestibular sensitivity vectors, respectively. (Although the direct stimulus to the canal is angular acceleration, the canal response is proportional to angular velocity within a range of head movement frequencies. Angular velocity was used here for a variety of reasons, as described in SI Materials and Methods.) Angular velocity vectors characterize instantaneous head rotations about different axes and can be experimentally measured in moving animals. Vestibular sensitivity vectors characterize the extent to which an animal is more sensitive to rotations about some axes than other axes. Although vestibular sensitivity vectors cannot be measured directly, t...

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Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

Locomotor head movements and semicircular canal morphology in primates

Malinzak

Kay

Hullar

2012

Proc. Natl. Acad. Sci. U.S.A.

107

222

View full text Add to dashboard Cite

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“…However, with the benefits of modern non-invasive imaging techniques, such as high-resolution computed tomography (mCT), the first aspect has become a favourite topic for functional morphological analyses (e.g. [2][3][4][5][6][7][8][9][10][11][12][13]), but also for phylogenetic approaches [14 -20].…”

Section: Introductionmentioning

confidence: 99%

Bony labyrinth morphometry indicates locomotor adaptations in the squirrel-related clade (Rodentia, Mammalia)

2015

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The semicircular canals (SCs) of the inner ear detect angular acceleration and are located in the bony labyrinth of the petrosal bone. Based on highresolution computed tomography, we created a size-independent database of the bony labyrinth of 50 mammalian species especially rodents of the squirrel-related clade comprising taxa with fossorial, arboreal and gliding adaptations. Our sampling also includes gliding marsupials, actively flying bats, the arboreal tree shrew and subterranean species. The morphometric anatomy of the SCs was correlated to the locomotion mode. Even if the phylogenetic signal cannot entirely be excluded, the main significance for functional morphological studies has been found in the diameter of the SCs, whereas the radius of curvature is of minor interest. Additionally, we found clear differences in the bias angle of the canals between subterranean and gliding taxa, but also between sciurids and glirids. The sensitivity of the inner ear correlates with the locomotion mode, with a higher sensitivity of the SCs in fossorial species than in flying taxa. We conclude that the inner ear of flying and gliding mammals is less sensitive due to the large information flow into this sense organ during locomotion.

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“…Accordingly, its bony morphology presents diverse morphological patterns correlated to the modes of locomotion and agility [1,2,[4][5][6]. A common assumption is that, notably owing to adaptive constraints, the morphology of the mammalian inner ear, especially the SC, shows low levels of intraspecific variation [7][8][9][10][11].…”

Section: Introductionmentioning

confidence: 99%

High morphological variation of vestibular system accompanies slow and infrequent locomotion in three-toed sloths

et al. 2012

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The semicircular canals (SCs), part of the vestibular apparatus of the inner ear, are directly involved in the detection of angular motion of the head for maintaining balance, and exhibit adaptive patterns for locomotor behaviour. Consequently, they are generally believed to show low levels of intraspecific morphological variation, but few studies have investigated this assumption. On the basis of high-resolution computed tomography, we present here, to our knowledge, the first comprehensive study of the pattern of variation of the inner ear with a focus on Xenarthra. Our study demonstrates that extant three-toed sloths show a high level of morphological variation of the bony labyrinth of the inner ear. Especially, the variation in shape, relative size and angles of their SCs greatly differ from those of other, faster-moving taxa within Xenarthra and Placentalia in general. The unique pattern of variation in three-toed sloths suggests that a release of selection and/or constraints on their organ of balance is associated with the observed wide range of phenotypes. This release is coincident with their slow and infrequent locomotion and may be related, among other possible factors, to a reduced functional demand for a precise sensitivity to movement.

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Evolution of locomotion in Anthropoidea: the semicircular canal evidence

Cited by 55 publications

References 62 publications

Locomotor head movements and semicircular canal morphology in primates

Locomotor head movements and semicircular canal morphology in primates

Bony labyrinth morphometry indicates locomotor adaptations in the squirrel-related clade (Rodentia, Mammalia)

High morphological variation of vestibular system accompanies slow and infrequent locomotion in three-toed sloths

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