The effects of substratum on locomotor performance in lacertid lizards

Vanhooydonck, Bieke; Measey, John; Edwards, Shelley; Makhubo, Buyisile G.; Tolley, Krystal A.; Herrel, Anthony

doi:10.1111/bij.12542

Cited by 35 publications

(27 citation statements)

References 54 publications

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“…Previous studies of the effects of substrate on locomotor performance in lizards have focused primarily on variation in substrate inclination and diameter (Huey & Hertz 1982;Losos & Sinervo 1989;Spezzano & Jayne 2004), but fewer studies have assessed the effects of substrate texture or roughness (but see Tulli, Abdala & Cruz 2012;Brandt, Galvani & Kohlsdorf 2015;Vanhooydonck et al 2015). Using a lizard habitat generalist, Tropidurus torquatus, Brandt, Galvani & Kohlsdorf (2015) found a positive relationship between grip strength and maximum sprint speed across seven different types of substrate on a level track.…”

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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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%

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

2015

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“…On the high-friction surface, antechinus used faster pre-turn speeds in later trials, but this did not make them more or less likely to slip when turning. Lizards run faster on high-friction surfaces (Brandt et al, 2015;Höfling et al, 2012;Vanhooydonck et al, 2015), but our results suggest that variation in straight-running speeds over different surfaces may be due in part to choices made by the animals rather than biomechanical constraints. The risk and cost of motor mistakes are likely to be important in speed choice, particularly during predator pursuits.…”

Section: Discussionmentioning

confidence: 53%

“…Friction is so important to animal movement that many species have evolved specialised foot pads or claws to augment their purchase on the ground (Alexander, 2002;Cartmill, 1979). Although studies on lizards recorded faster straight running speeds on substrates that allowed increased friction (Brandt et al, 2015;Höfling et al, 2012;Vanhooydonck et al, 2015), to our knowledge, no studies have compared other performance traits across substrates that vary in surface friction.…”

Section: Introductionmentioning

confidence: 99%

Surface friction alters the agility of a small Australian marsupial

Wheatley

Clemente

Niehaus

et al. 2018

Journal of Experimental Biology

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Movement speed can underpin an animal's probability of success in ecological tasks. Prey often use agility to outmanoeuvre predators; however, faster speeds increase inertia and reduce agility. Agility is also constrained by grip, as the foot must have sufficient friction with the ground to apply the forces required for turning. Consequently, ground surface should affect optimum turning speed. We tested the speed-agility trade-off in buff-footed antechinus () on two different surfaces. Antechinus used slower turning speeds over smaller turning radii on both surfaces, as predicted by the speed-agility trade-off. Slipping was 64% more likely on the low-friction surface, and had a higher probability of occurring the faster the antechinus were running before the turn. However, antechinus compensated for differences in surface friction by using slower pre-turn speeds as their amount of experience on the low-friction surface increased, which consequently reduced their probability of slipping. Conversely, on the high-friction surface, antechinus used faster pre-turn speeds in later trials, which had no effect on their probability of slipping. Overall, antechinus used larger turning radii (0.733±0.062 versus 0.576±0.051 m) and slower pre-turn (1.595±0.058 versus 2.174±0.050 m s) and turning speeds (1.649±0.061 versus 2.01±0.054 m s) on the low-friction surface. Our results demonstrate the interactive effect of surface friction and the speed-agility trade-off on speed choice. To predict wild animals' movement speeds, future studies should examine the interactions between biomechanical trade-offs and terrain, and quantify the costs of motor mistakes in different ecological activities.

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“…The best described effects of habitat structure on lizard locomotor performance are the speed reductions observed in animals moving on inclined surfaces (Irschick & Jayne, ; Jayne & Irschick, ) and on perches of distinct diameters (Losos & Sinervo, ; Losos & Irschick, ). The effects of moving on different substrates on running speeds are less known (Van Damme & Vanhooydonck, ; but see also Kohlsdorf et al ., ; Vanhooydonck et al ., ; Kohlsdorf & Navas, ; Tulli, Abdala & Cruz, ; Vanhooydonck et al ., ), and the focus of the existing studies has mostly been given to the evolution of morphologies adapted to specific substrates (Kohlsdorf et al ., ; Tulli et al ., ). The influence of characteristics as grip or structural complexity of different substrates on performance, on the contrary, still remains neglected (with some exceptions as Vanhooydonck et al ., and Li et al ., ).…”

Section: Introductionmentioning

confidence: 99%

“…Frictional properties of the substrates also potentially affect performance, as the interaction between a lizard's foot and substrates of different textures likely results on distinct friction coefficients (Alexander, 2003). Accordingly, lower friction coefficients probably restrict acceleration and limit maximum sprint speeds (Vanhooydonck et al, 2015) likely determining if animals slip during locomotion (van der Tol et al, 2005) and how do lizards grip to specific substrates (Zani, 2000;Tulli, Abdala & Cruz, 2011).…”

Section: Introductionmentioning

confidence: 99%

Sprint performance of a generalist lizard running on different substrates: grip matters

2015

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The relationships between locomotor performance and major features of environmental structure, such as incline and diameter, have been consistently identified in several vertebrate groups. The effects of variation in characteristics such as texture and structural complexity, in contrast, remain neglected, and associations between sprint speeds achieved during steady-level locomotion and the way an animal grips the surface are particularly obscure. In the present study, we have used the habitat generalist lizard Tropidurus torquatus to test the hypothesis that animals run faster on the substrates where gripping performance is higher. We ran 18 individuals on seven different substrates (wood, thin and coarse sand, coarse gravel, rock, leaf litter and grass) and recorded their maximum speeds using high-speed cameras. Surfaces were characterized for height variation and grip, the last given by average grip performance achieved by lizards of different sizes. Maximum sprint speeds were highest on rock and grass and lowest on thin and coarse sand, and variation in performance among substrates was explained by grip: substrates in which lizards gripped stronger are those that enhanced average maximum sprint speed. This study is the first report providing evidence for variation in maximum sprint speeds achieved by a generalist lizard running on different substrates, and demonstrates how friction resulting from the interaction of the lizard with the substrate may be critically important for sprint speed.

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The effects of substratum on locomotor performance in lacertid lizards

Cited by 35 publications

References 54 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

Surface friction alters the agility of a small Australian marsupial

Sprint performance of a generalist lizard running on different substrates: grip matters

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