Johannah Rickman scite author profile

Johannah Rickman

3Publications

29Citation Statements Received

449Citation Statements Given

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Affiliations

University of Washington

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Scaling patterns of body plans differ among squirrel ecotypes

Linden

Burtner

Rickman

et al. 2023

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Body size is often hypothesized to facilitate or constrain morphological diversity in the cranial, appendicular, and axial skeletons. However, how overall body shape scales with body size (i.e., body shape allometry) and whether these scaling patterns differ between ecological groups remains poorly investigated. Here, we test whether and how the relationships between body shape, body size, and limb lengths differ among species with different locomotor specializations, and describe the underlying morphological components that contribute to body shape evolution among squirrel (Sciuridae) ecotypes. We quantified the body size and shape of 87 squirrel species from osteological specimens held at museum collections. Using phylogenetic comparative methods, we first found that body shape and its underlying morphological components scale allometrically with body size, but these allometric patterns differ among squirrel ecotypes: chipmunks and gliding squirrels exhibited more elongate bodies with increasing body sizes whereas ground squirrels exhibited more robust bodies with increasing body size. Second, we found that only ground squirrels exhibit a relationship between forelimb length and body shape, where more elongate species exhibit relatively shorter forelimbs. Third, we found that the relative length of the ribs and elongation or shortening of the thoracic region contributes the most to body shape evolution across squirrels. Overall, our work contributes to the growing understanding of mammalian body shape evolution and how it is influenced by body size and locomotor ecology, in this case from robust subterranean to gracile gliding squirrels.

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Size and locomotor ecology have differing effects on the external and internal morphologies of squirrel (Rodentia: Sciuridae) limb bones

Rickman

Burtner

Linden

et al. 2023

Preprint

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Mammals exhibit a diverse range of limb morphologies that are associated with different locomotor ecologies and structural mechanics. Biologists, however, have rarely investigated whether these factors have different effects on the external and internal morphologies of limb bones. Here, we used squirrels (Sciuridae) as a model clade to examine the effects of locomotor mode and allometry on the size, external shape, and internal structure of the two major limb bones, the humerus and femur. We quantified these humeral and femoral traits using 3D geometric morphometrics and bone structure analyses on a sample of 76 squirrel species across their four major ecotypes. We found significant allometric patterns among squirrel ecotypes in the internal structures of humeri and femora but not in their external shapes. Although humeral and femoral external shape statistically differ among squirrel ecotypes, these associations are lost when analyses account for phylogenetic relationships among species. That all ecotypes are phylogenetically clustered suggests humeral and femoral shape variation partitioned early between clades and their ecomorphologies were maintained to the present. In contrast, interactions between size and ecotype predict variation of the internal structures of these long bones after accounting for phylogenetic relationships. The humeri and femora of ground and tree squirrels tend to exhibit increased bone compactness and more robust diaphyses with increasing bone size, adaptations that would facilitate more efficient digging behaviors. Conversely, there were no allometric changes in internal bone structure of gliding squirrels possibly due to constraints for gliding. Lastly, we found that the external shape of the limbs was associated with changes in cross-sectional shape and diaphysis elongation but not with global bone compactness. Overall, these results indicate that mechanical constraints, locomotor ecology, and evolutionary history may enact different pressures on the external and internal morphology of limb bones in mammals.

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Scaling patterns of body plans differ among squirrel ecotypes

Linden

Burtner

Rickman

et al. 2022

Preprint

View full text Add to dashboard Cite

Body size is often hypothesized to facilitate or constrain morphological diversity in the cranial, appendicular, and axial skeletons. However, how overall body shape scales with body size (i.e., body shape allometry) and whether these scaling patterns differ between ecological groups remains poorly investigated. Here, we test whether and how the relationships between body shape, body size, and limb lengths differ among species with different locomotory specializations, and describe the underlying morphological components that contribute to body shape variation among squirrel (Sciuridae) ecotypes. We quantified the body size and shape of 87 squirrel species from osteological specimens held at museum collections. Using phylogenetic comparative methods on these data, we found that 1) body shape and its underlying morphological components scale allometrically with body size, but these allometric patterns differ among squirrel ecotypes; 2) only ground squirrels exhibit a relationship between forelimb length and body shape, where more elongate species exhibit relatively shorter forelimbs; and 3) the relative length of the ribs and elongation or shortening of the thoracic region contributes the most to body shape variation across squirrels. Overall, our work contributes to the growing understanding of mammalian body shape evolution and how it is influenced by body size and locomotor ecology, in this case from robust subterranean to gracile gliding squirrels.

show abstract

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