Convergent Evolution of Claw Shape in a Transcontinental Lizard Radiation

Baeckens, Simon; Goeyers, Charlotte; Damme, Raoul Van

doi:10.1093/icb/icz151

Cited by 21 publications

(19 citation statements)

References 89 publications

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“…Conversely, claw morphology in a variety of birds was considered to be independent of phylogeny and size by Glen and Bennett (2007) and it was recently found to be independent of both specifically in birds of prey, being linked more to biomechanics and relative prey size (Tsang et al, 2019). Another study found only a weak phylogenetic signal in lacertid claw morphology which did not interfere with attempts to link morphology with habitat use (Baeckens et al, 2019). Regardless of these findings and despite the incorporation of claw specimens from a wide variety of bird, mammal, and reptile species, covering a diverse range of phylogenetic, behavioral and size groups, the outcome of the LDA may be phylogenetically biased.…”

Section: Methodsmentioning

confidence: 99%

“…In one study, the use of geometric morphometric methods showed promise for separating aquatic/terrestrial, arboreal, and predatory birds (McIntosh, 2017) whereas another study found that these methods were unable to significantly separate birds into predatory, ground‐dwelling, and generalist groups (Hedrick et al, 2019). There have been few investigations into the functional morphology of reptile claws, most of which deal with narrow taxonomic groups (Baeckens et al, 2019; D'Amore et al, 2018; M. J. Tulli et al, 2009; Yuan et al, 2020; Yuan et al, 2019; Zani, 2000). This may be due to the relative dearth of information on reptile claw function in the natural history literature, especially compared to that which exists for birds and mammals.…”

Section: Introductionmentioning

confidence: 99%

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Functional morphology of vertebrate claws investigated using functionally based categories and multiple morphological metrics

Thomson

Motani

2021

Journal of Morphology

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The link between claw morphology and function has been historically difficult to quantify, analyze, and interpret. In this study, the functional morphology of vertebrate claws is analyzed using measurements taken from 80 modern claw specimens spanning birds, mammals, and one reptile. Claw measurements were chosen for their potential biomechanical significance and a revised, expanded categorization of claw function is defined and used. This categorization scheme is the result of an extensive literature review and is based on the observed mechanics of claw function rather than the animal's overall ecology, an important departure from the norm followed in previous studies. A principal component analysis of the claw measurements reveals that some of the morphological disparity is related to functional differences; however, different functional categories are not clearly separated based solely on morphology. A linear discriminant analysis successfully classifies 81.25% of the claw specimens to their documented functional categories. When the posterior probabilities of each classification are examined, and the next highest probabilities are considered, the analysis is able to successfully classify 96.25% of the claw specimens. Expressing angle measurements in terms of lengths prior to analysis and incorporating cross‐sectional shape data both serve to reduce the misclassification rate. The use of biomechanically meaningful claw measurements and categories based on function (rather than ecology) improves confidence in the ability to infer claw function based on morphology using discriminant analysis methods. While overall claw morphology is most certainly the result of multiple factors (e.g., growth, size, etc.), this study establishes that it reflects mechanical function more than previously demonstrated.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Functional morphology of vertebrate claws investigated using functionally based categories and multiple morphological metrics

Thomson

Motani

2021

Journal of Morphology

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“…Ecological information concerning claws is not included in this review. This information can be found elsewhere (Baeckens et al, 2019; Zani, 2000). The review also presents some information on the patterns of immunolabeling detected in developing and adult claws, integrated from the molecular and proteomic data derived from the analyses of extracted claw proteins in some representative species of lizards, tuatara, turtles, and alligator.…”

Section: Introductionmentioning

confidence: 99%

“…The almost ubiquitous presence of variously shaped claws in amniotes indicates the fundamental importance of these horny structures for life on land. Claws were likely initial adaptations for moving efficiently on a muddy or more solid surface, and became useful for grasping, clinging, manipulating objects, fighting, and tearing (Zani, 2000; Homberger et al, 2009; Moyer, Zheng, & Schweitzer, 2016; Baeckens, Goeyers, & Van Damme, 2019; Figure 1e). The fossil record shows that claws were present in early amniotes of the Permian‐Carboniferous, both synapsids and sauropsids, and even in pre‐amniotes, such as Diadectes (Maddin & Reisz, 2007; Moyer et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

Development, structure, and protein composition of reptilian claws and hypotheses of their evolution

Alibardi¹

2020

The Anatomical Record

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Here, we review the development, morphology, genes, and proteins of claws in reptiles. Claws likely form owing to the inductive influence of phalangeal mesenchyme on the apical epidermis of developing digits, resulting in hyperproliferation and intense protein synthesis in the dorsal epidermis, which forms the unguis. The tip of claws results from prevalent cell proliferation and distal movement along most of the ungueal epidermis in comparison to the ventral surface forming the subunguis. Asymmetrical growth between the unguis and subunguis forces beta‐cells from the unguis to rotate into the apical part of the subunguis, sharpening the claw tip. Further sharpening occurs by scratching and mechanical wearing. Ungueal keratinocytes elongate, form an intricate perimeter and cementing junctions, and remain united impeding desquamation. In contrast, thin keratinocytes in the subunguis form a smooth perimeter, accumulate less corneous beta proteins (CBPs) and cysteine‐poor intermediate filament (IF)‐keratins, and desquamate. In addition to prevalent glycine–cysteine–tyrosine rich CBPs, special cysteine‐rich IF‐keratins are also synthesized in the claw, generating numerous SS bonds that harden the thick and compact corneous material. Desquamation and mechanical wear at the tip ensure that the unguis curvature remains approximately stable over time. Reptilian claws are likely very ancient in evolution, although the unguis differentiated like the outer scale surface of scales, while the subunguis might have derived from the inner scale surface. The few hair‐like IF‐keratins synthesized in reptilian claws indicate that ancestors of sauropsids and mammals shared cysteine‐rich IF‐keratins. However, the number of these keratins remained low in reptiles, while new types of CBPs function to strengthen claws.

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“…A daptations to habitats are responsible for some of the most striking examples of phenotypic evolution, driving profound shifts in morphology [1][2][3][4][5][6] , in shape diversity ('disparity') 7 and in rate of shape evolution 1,[8][9][10][11] . Adaptations to similar habitats also result in phenotypic convergence when responses to selection produce similar shifts in phenotypic optima across diverse clades 2,[12][13][14][15] , as in the body forms of pelagic fishes, ichthyosaurs and whales.…”

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confidence: 99%

Size, microhabitat, and loss of larval feeding drive cranial diversification in frogs

et al. 2021

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Habitat is one of the most important factors shaping organismal morphology, but it may vary across life history stages. Ontogenetic shifts in ecology may introduce antagonistic selection that constrains adult phenotype, particularly with ecologically distinct developmental phases such as the free-living, feeding larval stage of many frogs (Lissamphibia: Anura). We test the relative influences of developmental and ecological factors on the diversification of adult skull morphology with a detailed analysis of 15 individual cranial regions across 173 anuran species, representing every extant family. Skull size, adult microhabitat, larval feeding, and ossification timing are all significant factors shaping aspects of cranial evolution in frogs, with late-ossifying elements showing the greatest disparity and fastest evolutionary rates. Size and microhabitat show the strongest effects on cranial shape, and we identify a “large size-wide skull” pattern of anuran, and possibly amphibian, evolutionary allometry. Fossorial and aquatic microhabitats occupy distinct regions of morphospace and display fast evolution and high disparity. Taxa with and without feeding larvae do not notably differ in cranial morphology. However, loss of an actively feeding larval stage is associated with higher evolutionary rates and disparity, suggesting that functional pressures experienced earlier in ontogeny significantly impact adult morphological evolution.

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Convergent Evolution of Claw Shape in a Transcontinental Lizard Radiation

Cited by 21 publications

References 89 publications

Functional morphology of vertebrate claws investigated using functionally based categories and multiple morphological metrics

Functional morphology of vertebrate claws investigated using functionally based categories and multiple morphological metrics

Development, structure, and protein composition of reptilian claws and hypotheses of their evolution

Size, microhabitat, and loss of larval feeding drive cranial diversification in frogs

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