Terrestriality constrains salamander limb diversification: Implications for the evolution of pentadactyly

Ledbetter, Nicholus M.; Bonett, Ronald M.

doi:10.1111/jeb.13444

Cited by 17 publications

(31 citation statements)

References 93 publications

(130 reference statements)

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“…Changes in developmental strategy are consistently associated with shifts in rate of cranial evolution, with paedomorphic and biphasic species showing faster rates than terrestrial direct-developing species. Furthermore, a reversal from a terrestrial biphasic to an aquatic paedomorphic life cycle is also accompanied by an increase in the rate of cranial evolution, as found in Ledbetter 33 . These results suggest that the rapid morphological evolution in paedomorphic taxa, which tend to live in inhospitable environments with poor access to food resources and mates (such as caves or organic muck habitats) 31,43 , may facilitate the persistence of these species in such challenging conditions 44,45 .…”

Section: Discussionmentioning

confidence: 79%

“…Changes in developmental strategy have impacted the dynamics of body form and limb evolution in salamanders over the last ~160My 25,33 . As shown in previous studies, a biphasic life cycle was recovered as the ancestral condition for Caudata 41,42 , with direct-development evolving once, paedomorphy evolving several times independently 25,29,31 , and biphasic (and sometimes then paedomorphic) strategies evolving and re-evolving multiple times among direct-developing plethodontids.…”

Section: Discussionmentioning

confidence: 99%

“…Among the organisms experiencing metamorphosis, salamanders (Amphibia: Caudata, ~ 700 species 27,28 ) display a tremendous diversity of species, ecologies and life cycles with multiple independent evolutions thereof 25,[29][30][31][32][33] . Thus, salamanders provide an excellent framework to study how developmental processes can produce morphological diversity.…”

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confidence: 99%

“…They also found that constraints on body form evolution are stage-specific and that shifts in life cycle complexity can alter the dynamics of morphological evolution in salamanders. Ledbetter and Bonett 33 showed that limbs evolve faster and are less constrained for aquatic species (mostly paedomorphic) than terrestrial species (mostly direct-developing). Vučić, et al 26 demonstrated that metamorphosis cannot be regarded as a developmental constraint on the overall external head in a newt.…”

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confidence: 99%

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Metamorphosis shapes cranial diversity and rate of evolution in salamanders

et al. 2020

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Metamorphosis is widespread across the animal kingdom and induces fundamental changes in the morphology, habitat, and resources used by an organism during its lifetime. Metamorphic species are likely to experience more dynamic selective pressures through ontogeny compared to those with single-phase life cycles, which may drive divergent evolutionary dynamics. Here, we reconstruct the cranial evolution of the salamander using geometric morphometric data from 148 species spanning their full phylogenetic, developmental, and ecological diversity. We demonstrate that life cycle influences cranial shape diversity and rate of evolution. Shifts in rate of cranial evolution are consistently associated with transitions from biphasic to either direct-developing or paedomorphic life cycle strategies. Direct-developers exhibit the slowest rates of evolution and lowest disparity, and paedomorphic species the highest. Species undergoing complete metamorphosis (biphasic and direct-developing) exhibit greater cranial modularity (evolutionary independence among regions) than do paedomorphic species, which undergo differential metamorphosis. Biphasic and direct-developing species also display elevated disparity relative to evolutionary rate for bones associated with feeding, whereas this is not the case for paedomorphic species. Metamorphosis has profoundly influenced salamander cranial evolution, requiring greater autonomy of cranial elements and facilitating the rapid evolution of regions that are remodelled through ontogeny. Rather than compounding functional constraints on variation, metamorphosis appears to have promoted salamander morphological evolution over 180 million years, which may explain the ubiquity of this complex life cycle strategy across disparate organisms. MainDevelopmental processes play a fundamental role in structuring the morphological diversity of organisms 1-3 , being both a driver of, and a constraint on, phenotypic change 1,4,5 . As such, shifts in development and life history can have profound impacts on the evolutionary trajectories of lineages. Early attempts to delineate these effects resulted in the recapitulationist doctrine, stating that ontogeny replicates phylogeny 6 . However, studies of groups such as amphibians have shown that shifts in developmental strategies (e.g., biphasic, direct-development, paedomorphy, and viviparity) have occurred many times. In some cases, metamorphic species can even eliminate later ontogenetic stages and mature with larval

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Section: Discussionmentioning

confidence: 79%

Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

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confidence: 99%

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Metamorphosis shapes cranial diversity and rate of evolution in salamanders

et al. 2020

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“…Thus investigation into finer-scale patterns of static and evolutionary integration for additional lissamphibian groups may reveal whether this pattern is conserved across Lissamphibia. Caudata (salamanders) comprises 10 ecologically and morphologically diverse families and displays a tremendous range of life cycle strategies (e.g., Bonett, 2018;Bonett & Blair, 2017;Bonett et al, 2013;Ledbetter & Bonett, 2019). Extensive phenotypic variation can also extend intraspecifically in salamanders, as in the fire salamander Salamandra salamandra (Linnaeus, 1758) which exhibits a range of morphologies, colour patterns and reproductive strategies depending on the subspecies (Sparreboom, 2014;Beukema et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

Cranial integration in the fire salamander, Salamandra salamandra (Caudata: Salamandridae)

Bon

Bardua

Goswami

et al. 2020

Biological Journal of the Linnean Society

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Phenotypic integration and modularity are concepts that represent the pattern of connectivity of morphological structures within an organism. Integration describes the coordinated variation of traits, and analyses of these relationships among traits often reveals the presence of modules, sets of traits that are highly integrated but relatively independent of other traits. Phenotypic integration and modularity have been studied at both the evolutionary and static level across a variety of clades, although most studies thus far are focused on amniotes, and especially mammals. Using a high-dimensional geometric morphometric approach, we investigated the pattern of cranial integration and modularity of the Italian fire salamander (Salamandra salamandra giglioli). We recovered a highly modular pattern, but this pattern did not support either entirely developmental or functional hypotheses of cranial organisation, possibly reflecting complex interactions amongst multiple influencing factors. We found that size had no significant effect on cranial shape, and that morphological variance of individual modules had no significant relationship with degree of within-module integration. The pattern of cranial integration in the fire salamander is similar to that previously recovered for caecilians, with highly integrated jaw suspensorium and occipital regions, suggesting possible conservation of patterns across lissamphibians.

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Covariation of proximal finger and toe phalanges inHomo sapiens: A novel approach to assess covariation of serially corresponding structures

Heteren

Frieß

Détroit

et al. 2021

American Journal of Biological Anthropology

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Objectives: As hands and feet are serially repeated corresponding structures in tetrapods, the morphology of fingers and toes is expected to covary due to a shared developmental origin. The present study focuses on the covariation of the shape of proximal finger and toe phalanges of adult Homo sapiens to determine whether covariation is different in the first ray relative to the others, as its morphology is also different.Material and methods: Proximal phalanges of 76 individuals of unknown sex (Muséum national d'Histoire naturelle, Paris, and the Natural History Museum, London) were digitized using a surface scanner. Landmarks were positioned on 3D surface models of the phalanges. Generalized Procrustes analysis and two-block partial least squares (PLS) analyses were conducted. A novel landmark-based geometric morphometric approach focusing on covariation is based on a PCoA of the angles between PLS axes in morphospace. The results can be statistically evaluated. Results:The difference in PCo scores between the first and the other rays indicates that the integration between the thumb and the big toe is different from that between the lateral rays of the hand and foot.Discussion: We speculate that the results are possibly the evolutionary consequence of differential selection pressure on the big toe relative to the other toes related to the rise of bipedalism, which is proposed to have emerged very early in the hominin clade. In contrast, thumb morphology and its precision grip never ceased undergoing changes, suggesting less acute selection pressures related to the evolution of the precision grip.

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Terrestriality constrains salamander limb diversification: Implications for the evolution of pentadactyly

Cited by 17 publications

References 93 publications

Metamorphosis shapes cranial diversity and rate of evolution in salamanders

Metamorphosis shapes cranial diversity and rate of evolution in salamanders

Cranial integration in the fire salamander, Salamandra salamandra (Caudata: Salamandridae)

Covariation of proximal finger and toe phalanges inHomo sapiens: A novel approach to assess covariation of serially corresponding structures

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