Losing stability: tail loss and jumping in the arboreal lizard<i>Anolis carolinensis</i>

Gillis, Gary B.; Bonvini, Lauren; Irschick, Duncan J.

doi:10.1242/jeb.024349

Cited by 103 publications

(113 citation statements)

References 39 publications

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“…The negative landing angles appeared to be caused by the perch striking the lizard tail upon recoil (supplementary material Movie1). We observed that when lizards jumped from rigid perches, they often dragged their tail along the perch during takeoff, as also noted in a previous study (Gillis et al, 2009). When jumping from compliant perches, the part of the tail that was still in contact with (or sometimes above) the perch was struck when the perch recoiled, thus lifting the tail and ultimately changing the body position of the lizard during flight and landing (Fig.3A).…”

Section: Laboratory Trialssupporting

confidence: 88%

“…Lizards jumped from the rigid perch with the same general kinematics as seen in other studies (Bels et al, 1992;Gillis et al, 2009): the jump started with placement of the hind feet towards the front of the body; lizards then used their hind limbs to propel themselves forward with a mean positive body angle of 12.1±1.7deg and a mean speed and duration of 130.4±2.6cms -1 and 0.1±0s. After the takeoff phase, the aerial phase followed with the forelimbs limbs tucked close to the body, and lizards landed with the body angled so that the hind feet contacted the landing substrate first (26.7±4.2deg), at a mean distance of 34.4±0.9cm.…”

Section: Laboratory Trialsmentioning

confidence: 84%

“…For example, there are 400+ species of Anolis lizards, the majority of which use a variety of arboreal habitats and regularly use jumping to move around (Irschick and Losos, 1999). Anole ecology and locomotion has been widely studied (Calsbeek and Irschick, 2007;Irschick and Losos, 1999;Losos and Sinervo, 1989;Spezzano and Jayne, 2004;Vanhooydonck et al, 2006), although one anole species has been particularly well studied in terms of jumping, namely the green anole, A. carolinensis Voigt 1832 (Bels et al, 1992;Gillis et al, 2009;Kuo et al, 2011;Losos and Irschick, 1996;Toro et al, 2003;Vanhooydonck et al, 2005). However, the effect of perch compliance on this species, or any small (<65g) species, is unknown.…”

Section: Introductionmentioning

confidence: 99%

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Total recoil: perch compliance alters jumping performance and kinematics in green anole lizards (Anolis carolinensis)

Gilman

Gillis

Irschick

2012

Journal of Experimental Biology

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SUMMARY Jumping is a common form of locomotion for many arboreal animals. Many species of the arboreal lizard genus Anolis occupy habitats in which they must jump to and from unsteady perches, e.g. narrow branches, vines, grass and leaves. Anoles therefore often use compliant perches that could alter jump performance. In this study we conducted a small survey of the compliance of perches used by the arboreal green anole Anolis carolinensis in the wild (N=54 perches) and then, using perches within the range of compliances used by this species, investigated how perch compliance (flexibility) affects the key jumping variables jump distance, takeoff duration, takeoff angle, takeoff speed and landing angle in A. carolinensis in the laboratory (N=11). We observed that lizards lost contact with compliant horizontal perches prior to perch recoil, and increased perch compliance resulted in decreased jump distance and takeoff speed, likely because of the loss of kinetic energy to the flexion of the perch. However, the most striking effect of perch compliance was an unexpected one; perch recoil following takeoff resulted in the lizards being struck on the tail by the perch, even on the narrowest perches. This interaction between the perch and the tail significantly altered body positioning during flight and landing. These results suggest that although the use of compliant perches in the wild is common for this species, jumping from these perches is potentially costly and may affect survival and behavior, particularly in the largest individuals.

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Section: Laboratory Trialssupporting

confidence: 88%

Section: Laboratory Trialsmentioning

confidence: 84%

Section: Introductionmentioning

confidence: 99%

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Total recoil: perch compliance alters jumping performance and kinematics in green anole lizards (Anolis carolinensis)

Gilman

Gillis

Irschick

2012

Journal of Experimental Biology

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“…Besides adjusting the centre of mass (CoM) close to the vector of propulsive thrust at take-off to avoid later body rotation [7,8], some jumpers actively use dynamic control for in-air stability. Two mechanisms have previously been proposed to counteract unwanted torque in the air: using the inertia of swinging appendages [9][10][11][12] and aerodynamic forces from flapping wings [6,7]. Take-off mechanisms and stability control that evolved in nature have led to significant progress in bioinspired designs for manoeuvrable jumping robots [11,13].…”

Section: Introductionmentioning

confidence: 99%

More than a safety line: jump-stabilizing silk of salticids

Chen¹,

Liao

Tsai

et al. 2013

J. R. Soc. Interface.

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Salticids are diurnal hunters known for acute vision, remarkable predatory strategies and jumping ability. Like other jumpers, they strive for stability and smooth landings. Instead of using inertia from swinging appendages or aerodynamic forces by flapping wings as in other organisms, we show that salticids use a different mechanism for in-air stability by using dragline silk, which was previously believed to function solely as a safety line. Analyses from highspeed images of jumps by the salticid Hasarius adansoni demonstrate that despite being subject to rearward pitch at take-off, spiders with dragline silk can change body orientation in the air. Instantaneous drag and silk forces calculated from kinematic data further suggest a comparable contribution to deceleration and energy dissipation, and reveal that adjustments by the spider to the silk force can reverse its body pitch for a predictable and optimal landing. Without silk, upright-landing spiders would slip or even tumble, deferring completion of landing. Thus, for salticids, dragline silk is critical for dynamic stability and prey-capture efficiency. The dynamic functioning of dragline silk revealed in this study can advance the understanding of silk's physiological control over material properties and its significance to spider ecology and evolution, and also provide inspiration for future manoeuvrable robot designs.

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“…Lizards control their body position in midair during jumping and falling by swinging through air and interacting with takeoff surface. Studies of ground reaction forces (GRFs), moment of inertia and center of mass (CoM) in lizards before and after autotomy showed that changes in these parameters may cause negative impacts on the body dynamics during jumping and falling [48,49,52]. For example, locomotive changes (i.e., morphology, GRFs and kinematics) in Eublepharis macularius due to autotomy, resulted in 13% of anterior shift of CoM.…”

Section: Impact On Performance Due To Autotomy and Regenerated Tailmentioning

confidence: 99%

Current Understanding on Tail Regeneration in Green Anoles (Anolis carolinensis)

Nain

Islam

Chowdhury

et al. 2016

Preprint

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Regeneration of lost tail is of great importance to lizards. Anolis carolinensis, a green lizard, is capable of regenerating its tail efficiently after autotomy. Hence, it is considered as a model organism in regeneration study. A. carolinensis shed its tail in order to distract the predator's attention and thus makes a way to escape. Restoring of the amputated tail takes several days and the mechanism is currently clearly understood. Although save its life, tail regeneration is associated with the impairment of several vital functions in Anoles. In addition, various differences have been observed between original and regenerated tail in terms of mechanism and structure. To date, very little work has been conducted on tail autotomy and regeneration at molecular and genetic level. The genes responsible for regeneration in anoles are identified recently. These genes are evolutionarily conserved through all tetrapod vertebrates. They are, however, in a state of 'switched-off' in other vertebrates including humans. Consequently, a throughout study of these so called 'switched-off' genes may provide a way of restoring lost organs in human, and thus could revolutionize the modern medical science.

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Losing stability: tail loss and jumping in the arboreal lizardAnolis carolinensis

Cited by 103 publications

References 39 publications

Total recoil: perch compliance alters jumping performance and kinematics in green anole lizards (Anolis carolinensis)

Total recoil: perch compliance alters jumping performance and kinematics in green anole lizards (Anolis carolinensis)

More than a safety line: jump-stabilizing silk of salticids

Current Understanding on Tail Regeneration in Green Anoles (Anolis carolinensis)

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