Foils of flexion: the effects of perch compliance on lizard locomotion and perch choice in the wild

Gilman, Casey; Irschick, Duncan J.

doi:10.1111/1365-2435.12063

Cited by 36 publications

(36 citation statements)

References 38 publications

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“…). The substrates on which lizards perch have an important impact on their locomotor performance (Losos & Sinervo ; Gilman & Irschick ). We assessed the effects of inclination and roughness on performance because of the higher frequency of smooth, vertical substrates, such as buildings, fences and walls, in urban areas.…”

Section: Discussionmentioning

confidence: 99%

“…Previous studies have found that habitat characteristics influenced locomotor behaviour in green anoles: despite using perches with a range of compliances, green anoles selectively jumped from less compliant (less flexible) perches (Gilman & Irschick ). Other research shows anoles tend to jump less often from broad surfaces (Pounds ; Losos & Irschick ) and when nearby perches are lacking (Moermond ; Avilés‐Rodríguez ).…”

Section: Discussionmentioning

confidence: 99%

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City slickers: poor performance does not deter Anolis lizards from using artificial substrates in human‐modified habitats

2015

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Summary As animals move through their environments, they encounter a variety of substrates, which have important effects on their locomotor performance. Habitat modification can alter the types of substrates available for locomotion. In particular, many types of artificial substrates have been added to urban areas, but effects of these novel surfaces on animal locomotion are little known. In this study, we assessed locomotor performance of two Anolis lizard species (A. cristatellus and A. stratulus) on substrates that varied in inclination and surface roughness. Rough substrates represented the tree trunks and branches typically used in natural forest habitats, whereas smooth, vertical substrates captured the qualities of artificial surfaces, such as posts and walls, available in human‐modified habitats. We then observed habitat use to test the habitat constraint hypothesis – that lizards should more frequently occupy portions of the habitat in which they perform better. Increased inclination and decreased surface roughness caused lizards to run slower. Both A. cristatellus and A. stratulus ran slowest on the smooth, vertical surface, and A. cristatellus often slipped and fell on this surface. In contrast to predictions, both species frequently used smooth, vertical substrates in the wild. Anolis cristatellus occupied artificial substrates 73% of the time in human‐modified habitats despite performing worse than A. stratulus on the smooth, vertical track. We therefore rejected the habitat constraint hypothesis for anoles in these human‐modified habitats. Despite overall poor performance on the smooth, vertical track, A. cristatellus had a significant morphology–performance relationship that supports the prediction that selection should favour smaller lizards with relatively longer limbs in human‐modified habitats. The smaller bodied A. stratulus performed better than A. cristatellus on smooth, vertical substrates and therefore may not be exposed to the same selective pressures. We contend that habitat modification by humans may alter morphology‐performance–habitat use relationships found in natural habitats. This may lead to changes in selective pressures for some species, which may influence their ability to occupy human‐modified habitats such as cities.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

City slickers: poor performance does not deter Anolis lizards from using artificial substrates in human‐modified habitats

2015

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“…Specifically, compliant substrates absorb some of the mechanical work that would be otherwise employed to redirect and accelerate the CoM during steady locomotion, and compromise stability by undermining the animal's ability to estimate body orientation (MacLellan and Patla, 2006). Previous research has shown that increasing branch compliance significantly compromises the locomotor performance of leaping primates (Crompton et al, 1993;Demes et al, 1995;Warren and Crompton, 1997;Walker, 2005;Channon et al, 2011) and lizards (Gilman et al, 2012;Gilman and Irschick, 2013), and necessitates numerous postural and locomotor adjustments in orangutans (Thorpe et al, 2009;Myatt and Thorpe, 2011). However, relative to the breadth of research on the effects of substrate diameter, studies of how perch compliance affects quadrupedal gait mechanics are sparse (but see Stevens et al, 2001;GosselinIldari, 2010).…”

Section: Influence Of Substrate Compliance On Gait Kinematicsmentioning

confidence: 99%

Effects of support diameter and compliance on common marmoset (Callithrix jacchus) gait kinematics

Young

Stricklen

Chadwell

2016

Journal of Experimental Biology

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Locomotion is precarious in an arboreal habitat, where supports can vary in both diameter and level of compliance. Several previous studies have evaluated the influence of substrate diameter on the locomotor performance of arboreal quadrupeds. The influence of substrate compliance, however, has been mostly unexamined. Here, we used a multifactorial experimental design to investigate how perturbations in both diameter and compliance affect the gait kinematics of marmosets (Callithrix jacchus; N=2) moving over simulated arboreal substrates. We used 3D-calibrated video to quantify marmoset locomotion over a horizontal trackway consisting of variably sized poles (5, 2.5 and 1.25 cm in diameter), analyzing a total of 120 strides. The central portion of the trackway was either immobile or mounted on compliant foam blocks, depending on condition. We found that narrowing diameter and increasing compliance were both associated with relatively longer substrate contact durations, though adjustments to diameter were often inconsistent relative to compliance-related adjustments. Marmosets also responded to narrowing diameter by reducing speed, flattening center of mass (CoM) movements and dampening support displacement on the compliant substrate. For the subset of strides on the compliant support, we found that speed, contact duration and CoM amplitude explained >60% of the variation in substrate displacement over a stride, suggesting a direct performance advantage to these kinematic adjustments. Overall, our results show that compliant substrates can exert a significant influence on gait kinematics. Substrate compliance, and not just support diameter, should be considered a critical environmental variable when evaluating locomotor performance in arboreal quadrupeds.

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“…A rigid Teflon rod, 9 cm long, was inserted within the tubing midway along the perch to provide a rigid area for frogs to jump from. The perch was stretched to 0, 2 and 4 cm beyond the slack length, creating three different compliance levels (2.3, 1.8 and 1.1 cm deformation under 1 N vertical load; unloaded resonant frequencies of 8.4, 9.5 and 12.1 Hz, respectively) within the range of arboreal substrate compliance observed in their introduced range (Gilman and Irschick, 2013). For rigid perches, frogs jumped from a wooden dowel of equal diameter.…”

Section: Perchesmentioning

confidence: 99%

“…Animals moving through natural habitats commonly encounter compliant substrates (Demes et al, 1995;Gilman et al, 2012;Gilman and Irschick, 2013), which yield when subjected to force, resulting in the absorption of mechanical energy. While some substrates, such as mud, may only dissipate energy, others, such as small-diameter plant branches, are elastic and may return a significant portion of their energy upon recoil (Cannell and Morgan, 1987).…”

Section: Introductionmentioning

confidence: 99%

Robust jumping performance and elastic energy recovery from compliant perches in tree frogs

Astley

Haruta

Roberts

2015

Journal of Experimental Biology

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Arboreal animals often move on compliant branches, which may deform substantially under loads, absorbing energy. Energy stored in a compliant substrate may be returned to the animal or it may be lost. In all cases studied so far, animals jumping from a static start lose all of the energy imparted to compliant substrates and performance is reduced. Cuban tree frogs (Osteopilus septentrionalis) are particularly capable arboreal jumpers, and we hypothesized that these animals would be able to recover energy from perches of varying compliance. In spite of large deflections of the perches and consequent substantial energy absorption, frogs were able to regain some of the energy lost to the perch during the recoil. Takeoff velocity was robust to changes in compliance, but was lower than when jumping from flat surfaces. This highlights the ability of animals to minimize energy loss and maintain dependable performance on challenging substrates via behavioral changes.

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Foils of flexion: the effects of perch compliance on lizard locomotion and perch choice in the wild

Cited by 36 publications

References 38 publications

City slickers: poor performance does not deter Anolis lizards from using artificial substrates in human‐modified habitats

City slickers: poor performance does not deter Anolis lizards from using artificial substrates in human‐modified habitats

Effects of support diameter and compliance on common marmoset (Callithrix jacchus) gait kinematics

Robust jumping performance and elastic energy recovery from compliant perches in tree frogs

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