The evolutionary biomechanics of locomotor function in giant land animals

Hutchinson, John R.

doi:10.1242/jeb.217463

Cited by 27 publications

(30 citation statements)

References 191 publications

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“…Finally, the addition of the results on hind limb (this study) to those obtained on forelimb (Mallet et al, in press) enables the critical evaluation of the concept of graviportality and its application to Rhinocerotoidea (Hutchinson, 2021). The shape of the limb bones in Rhinocerotoidea diversified broadly during the more than 50 Ma of evolution of this group, while its variation still carries a strong phylogenetic signal.…”

Section: Graviportality: An Irrelevant Concept In Rhinocerotoids?mentioning

confidence: 67%

“…As Rhinocerotoidea hardly display the anatomical criteria classically associated with graviportality, two possible assessments arise: either Rhinocerotoidea should not be considered graviportal, or the graviportal framework is too limited to describe the diverse conditions by which species adapt to heavy weight (Hutchinson, 2021). The limitations of the framework of Gregory (1912) and Osborn (1929) may be related to the archetypal groups used to define graviportality (and cursoriality), as they mainly considered elephants and extinct groups with a similar limb architecture like Dinocerata in this regard (Osborn, 1900).…”

Section: Graviportality: An Irrelevant Concept In Rhinocerotoids?mentioning

confidence: 99%

“…Except in their general increase of robustness, Rhinocerotoidea show no clear convergence of shape or limb construction with that of Proboscidea, especially in extremely large but gracile taxa like Paraceratheriidae. Most criteria associated with graviportality in elephants are thus not universally shared in heavy quadrupeds showing that the classic graviportal framework should be considered with caution (Hutchinson, 2021). Therefore, it may be more relevant to search for the features repeatedly encountered in diverse taxa showing a high body mass before defining a general concept such as graviportality.…”

Section: Graviportality: An Irrelevant Concept In Rhinocerotoids?mentioning

confidence: 99%

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Adaptation to graviportality in Rhinocerotoidea? An investigation through the long bone shape variation in their hindlimb

Mallet

Billet²,

Cornette

et al. 2022

Zoological Journal of the Linnean Society

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Weight support is a strong functional constraint modelling limb bones in heavy quadrupeds. However, the complex relations between bone shape, mass, size and body proportions have been poorly explored. Rhinocerotoidea is one of the groups showing the highest body mass reached by terrestrial mammals through time. Here, we explore the evolutionary variation of shape in hindlimb stylopod and zeugopod bones and its relationship with mass, size and gracility in this superfamily. Our results show that bones undergo a general increase in robustness towards high masses, associated with reinforcements of the main muscle insertions. The shape of the femur, carrying a marked phylogenetic signal, varies conjointly with mass, size and gracility, whereas that of the tibia appears related to gracility and mass only. The shape of the fibula does not vary according to that of the tibia. Moreover, congruent variation of shape between the distal part of the femur and the complete tibia underlines the potentially strong covariation of the elements constituting the knee joint. These results, coupled with those previously obtained from forelimb study, allow a better comprehension of the relationship between bone shape and mass among Rhinocerotoidea, and a refining of the concept of ‘graviportality’ in this superfamily.

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Section: Graviportality: An Irrelevant Concept In Rhinocerotoids?mentioning

confidence: 67%

Section: Graviportality: An Irrelevant Concept In Rhinocerotoids?mentioning

confidence: 99%

Section: Graviportality: An Irrelevant Concept In Rhinocerotoids?mentioning

confidence: 99%

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Adaptation to graviportality in Rhinocerotoidea? An investigation through the long bone shape variation in their hindlimb

Mallet

Billet²,

Cornette

et al. 2022

Zoological Journal of the Linnean Society

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“…A second possibility is that the lack of asymmetrical gaits in several clades could be due to the lack of the required neural circuits or a change in musculoskeletal anatomy. Gigantism is thought to limit the use of galloping gaits as a result of biomechanical challenges of extreme bone loading (Hutchinson, 2021). In this case, selection for very large body size results in myriad phenotypic changes that make galloping mechanically impossible or at least very dangerous, which may explain why elephants do not gallop.…”

Section: Discussion Explaining Patterns Of Asymmetrical Gait Evolutionmentioning

confidence: 99%

The evolution of asymmetrical gaits in gnathostome vertebrates

McElroy

Granatosky

2022

Journal of Experimental Biology

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The difficulty of quantifying asymmetrical limb movements, compared with symmetrical gaits, has resulted in a dearth of information concerning the mechanics and adaptive benefits of these locomotor patterns. Further, no study has explored the evolutionary history of asymmetrical gaits using phylogenetic comparative techniques. Most foundational work suggests that symmetrical gaits are an ancestral feature and asymmetrical gaits are a more derived feature of mammals, some crocodilians, some turtles, anurans and some fish species. In this study, we searched the literature for evidence of the use of asymmetrical gaits across extant gnathostomes, and from this sample (n=308 species) modeled the evolution of asymmetrical gaits assuming four different scenarios. Our analysis shows strongest support for an evolutionary model where asymmetrical gaits are ancestral for gnathostomes during benthic walking and could be both lost and gained during subsequent gnathostome evolution. We were unable to reconstruct the presence/absence of asymmetrical gaits at the tetrapod, amniote, turtle and crocodilian nodes with certainty. The ability to adopt asymmetrical gaits was likely ancestral for Mammalia but was probably not ancestral for Amphibia and Lepidosauria. The absence of asymmetrical gaits in certain lineages may be attributable to neuromuscular and/or anatomical constraints and/or generally slow movement not associated with these gaits. This finding adds to the growing body of work showing the early gnathostomes and tetrapods may have used a diversity of gaits, including asymmetrical patterns of limb cycling.

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“…[1]) and how patterns of anatomical change may be influenced (or limited) by physical constraints on biological form (e.g. [2]). The secondary evolution of quadrupedality from bipedal ancestors is rare in tetrapods.…”

Section: Introductionmentioning

confidence: 99%

Convergent evolution of quadrupedality in ornithischian dinosaurs was achieved through disparate forelimb muscle mechanics

et al. 2023

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The secondary evolution of quadrupedality from bipedal ancestry is a rare evolutionary transition in tetrapods yet occurred convergently at least three times within ornithischian dinosaurs. Despite convergently evolving quadrupedal gait, ornithischians exhibited variable anatomy, particularly in the forelimbs, which underwent a major functional change from assisting in foraging and feeding in bipeds to becoming principal weight-bearing components of the locomotor system in quadrupeds. Here, we use three-dimensional multi-body dynamics models to demonstrate quantitatively that different quadrupedal ornithischian clades evolved distinct forelimb musculature, particularly around the shoulder. We find that major differences in glenohumeral abduction–adduction and long axis rotation muscle leverages were key drivers of mechanical disparity, thereby refuting previous hypotheses about functional convergence in major clades. Elbow muscle leverages were also disparate across the major ornithischian lineages, although high elbow extension muscle leverages were convergent between most quadrupeds. Unlike in ornithischian hind limbs, where differences are more closely tied to functional similarity than phylogenetic relatedness, mechanical disparity in ornithischian forelimbs appears to have been shaped primarily by phylogenetic constraints. Differences in ancestral bipedal taxa within each clade may have resulted in disparate ecomorphological constraints on the evolutionary pathways driving divergence in their quadrupedal descendants.

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The evolutionary biomechanics of locomotor function in giant land animals

Cited by 27 publications

References 191 publications

Adaptation to graviportality in Rhinocerotoidea? An investigation through the long bone shape variation in their hindlimb

Adaptation to graviportality in Rhinocerotoidea? An investigation through the long bone shape variation in their hindlimb

The evolution of asymmetrical gaits in gnathostome vertebrates

Convergent evolution of quadrupedality in ornithischian dinosaurs was achieved through disparate forelimb muscle mechanics

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