Maria Thaker

Physical barriers, such as rivers and roads, constrain the movement of animals, usually by preventing access to adjacent habitats and impeding dispersal. Fences are artificial barriers that are commonly used as a conservation tool to intentionally restrict movements of animals to within protected reserves. However, the potential edge-effect of fences on the behaviour of animals within reserves is poorly understood. We examined the effect of fences on the movement patterns of African elephant (Loxodonta africana), an ecosystem modifier, in Pilanesberg National Park, South Africa. We used linear and non-linear models to determine the relationship between minimum distance from fence and seasonal daily net displacement of six GPS-collared female elephant. Elephant movement patterns were best explained by a piecewise regression that showed a strong negative relationship between minimum distance from fence and daily net displacement up to a “breakpoint” distance of 2551 m in the dry season and 3829 m in the wet season. The effect of the fence dissipated beyond this distance in both seasons. The increased tortuosity in movement patterns of elephant in the central area of the reserve suggested that they used this area more intensively for foraging compared to the peripheral area, as confirmed by differences in habitat selection. This occurs despite there being no difference in habitat composition between these areas. The decreased use of areas near the fence and more intensive foraging in the central areas constitute an important edge-effect of fences. Since elephant are ecosystem engineers, such edge-effects could potentially cascade throughout the reserve, adversely altering ecologically processes, particularly in reserves with a high edge-to-area ratio.

In response to stressful events, most vertebrates rapidly elevate plasma glucocorticoid levels. Corticosterone release stimulates physiological and behavioral responses that can promote survival while suppressing behaviors that are not crucial to immediate survival. Corticosterone also has preparatory effects for subsequent stressors. Using male tree lizards (Urosaurus ornatus), we tested our prediction that elevated corticosterone is important for mediating and enhancing antipredator behaviors. Male tree lizards express developmentally fixed polymorphisms that are mediated by early organizational actions of steroid hormones, and thus we also tested the hypothesis that morph-specific differences in antipredator behaviors of adults are independent of circulating corticosterone levels. Plasma corticosterone levels were elevated exogenously for 12–16 h using non-invasive dermal patches, and we then compared the behavioral responses of these corticosterone-patched males to control-patched males during a simulated encounter with a caged predator (collared lizard, Crotaphytus nebrius) in outdoor enclosures. Elevating corticosterone did not alter the antipredator behavioral repertoire of each male morph, but did enhance their responses during the predator encounter: all corticosterone-patched males responded more quickly, hid longer, and displayed more toward the predator than control-patched males. With the corticosterone patch, the non-territorial and wary orange morph was still behaviorally the most wary morph, responding more quickly and hiding longer than either the bolder orange-blue or mottled morphs. Smaller males were generally warier than larger males, regardless of the endocrine treatment or color morph type. In sum, elevated circulating corticosterone enhances antipredator responses for all male tree lizard morphs, without altering morph-specific or size-specific differences in their behavioral responses.

... Maria Thaker 2 , Caitlin R. Gabor 4 , Joe N. Fries 3 ... We appreciate the constructive comments of R. Jaeger, A. Aspbury, F. Weckerly, D. Hews, A.-T. Vanak, TA Baird, and two anonymous reviewers on an earlier version of this manuscript. ...

Most vertebrates respond to acute stressors with rapid plasma glucocorticoid elevations. Variation within species in this hormonal response should correlate with differences in physiological responses and behavioural tactics, yet this is rarely documented. We measured behavioural and hormonal responses of free-ranging male tree lizards (Urosaurus ornatus) during staged encounters with a collared lizard predator (Crotaphytus nebrius) or a control (stick). In our study population, males express alternate reproductive tactics that correlate with throat colour pattern: territorial males have a central blue patch on an orange background (OB males) and nonterritorial males lack the blue patch (O males). We also studied a previously uncharacterized male type with a mottled orange and blue throat (M males). A single encounter with an approaching predator initiated an elevation in plasma corticosterone that was similar among the male types (mean ± SE = 9.64 ± 3.17 (OB), 9.72 ± 2.49 (O), 10.19 ± 2.82 (M)). Despite this similarity, male types differed behaviourally. Compared to OB and M males, O males initiated flight when the predator was further away and stayed hidden longer after seeking refuge. The M males showed responses similar to OB males and may functionally be the same morph. Among individuals of all morphs, total corticosterone levels after the predator encounter correlated strongly with their flight initiation distance and hiding duration during the encounter. We conclude that male tree lizards with alternative reproductive tactics show alternative antipredator behavioural tactics, and that individual variation in escape responses is directly correlated with corticosterone levels.

Elevated plasma corticosterone during stressful events is linked to rapid changes in behavior in vertebrates and can mediate learning and memory consolidation. We tested the importance of acute corticosterone elevation in aversive learning of a novel stressor by wild male eastern fence lizards (Sceloporus undulatus). We found that inhibiting corticosterone elevation (using metyrapone, a corticosterone synthesis blocker) during an encounter with a novel attacker impaired immediate escape responses and limited learning and recall during future encounters. In the wild and in outdoor enclosures, lizards whose acute corticosterone response was blocked by an earlier metyrapone injection did not alter their escape behavior during repeated encounters with the attacker. Control-injected (unblocked) lizards, however, progressively increased flight initiation distance and decreased hiding duration during subsequent encounters. Aversive responses were also initially higher for control lizards exposed to a higher intensity first attack. Further, we demonstrate a role of corticosterone elevation in recollection, since unblocked lizards had heightened antipredator responses 24-28 h later. Exogenously restoring corticosterone levels in metyrapone-injected lizards maintained aversive behaviors and learning at control (unblocked) levels. We suggest that the corticosterone mediation of antipredator behaviors and aversive learning is a critical and general mechanism for the behavioral flexibility of vertebrate prey.