Influence of supraphysiological cortisol manipulation on predator avoidance behaviors and physiological responses to a predation threat in a wild marine teleost fish

The stress axis in teleost fish attempts to maintain internal homeostasis in the face of allostatic loading. However, stress axis induction has been associated with a higher predation rate in fish. To date, the physiological and behavioral factors associated with this outcome are poorly understood....

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Veröffentlicht in:	Integrative zoology 2018-03, Vol.13 (2), p.206-218
Hauptverfasser:	LAWRENCE, Michael J., ELIASON, Erika J., BROWNSCOMBE, Jacob W., GILMOUR, Kathleen M., MANDELMAN, John W., GUTOWSKY, Lee F.G., COOKE, Steven J.
Format:	Artikel
Sprache:	eng
Schlagworte:	Animals Anti-Inflammatory Agents - pharmacology Aquatic Organisms Avoidance behavior Avoidance Learning Behavior Behavior, Animal - drug effects Behavioural responses Blood Body weight Catecholamines Cocoa butter Elevation Exposure Fish Fishes - physiology Glucose Homeostasis homeostatic overload Hormones Hydrocortisone - pharmacology Interactions Interspecific relationships Lactate Lactic acid lemon shark Marine fishes Negaprion brevirostris Physiological responses Physiology Predation Predators refuging Risk taking Sharks Shelters Stress stress axis Stress, Physiological - drug effects teleost physiology
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container_title	Integrative zoology
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creator	LAWRENCE, Michael J. ELIASON, Erika J. BROWNSCOMBE, Jacob W. GILMOUR, Kathleen M. MANDELMAN, John W. GUTOWSKY, Lee F.G. COOKE, Steven J.
description	The stress axis in teleost fish attempts to maintain internal homeostasis in the face of allostatic loading. However, stress axis induction has been associated with a higher predation rate in fish. To date, the physiological and behavioral factors associated with this outcome are poorly understood. The purpose of the present study was to investigate the impact of experimental cortisol elevation on anti‐predator behavior and physiological responses to predator presence. We hypothesized that semi‐chronic cortisol elevation would increase susceptibility to predation by increasing stress‐induced risk‐taking behaviors. To test this hypothesis, schoolmaster snapper were given cocoa butter implants without cortisol (sham) or with cortisol (50 mg/kg body weight) and tethered to cover. Fish were exposed to either a lemon shark or control conditions for 15‐min. Space use and activity were recorded throughout and fish were terminally sampled for blood. Cortisol implantation, relative to shams, resulted in higher blood glucose and plasma cortisol concentrations with a lower plasma lactate concentration. Shark exposure, relative to controls, elicited higher blood glucose and lactate concentrations but had no effect on plasma cortisol concentration. No interactions were detected between shark exposure and cortisol treatment for any physiological trait. Behavioral metrics, including shelter use and activity, were unaffected by either cortisol implantation or shark exposure. Physiological responses to cortisol implantation likely resulted from enhanced gluconeogenic activity, whereas alterations under predator exposure may have been the product of catecholamine mobilization. Further work should address context‐specific influences of stress in mediating behavioral responses to predation.
doi_str_mv	10.1111/1749-4877.12282
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However, stress axis induction has been associated with a higher predation rate in fish. To date, the physiological and behavioral factors associated with this outcome are poorly understood. The purpose of the present study was to investigate the impact of experimental cortisol elevation on anti‐predator behavior and physiological responses to predator presence. We hypothesized that semi‐chronic cortisol elevation would increase susceptibility to predation by increasing stress‐induced risk‐taking behaviors. To test this hypothesis, schoolmaster snapper were given cocoa butter implants without cortisol (sham) or with cortisol (50 mg/kg body weight) and tethered to cover. Fish were exposed to either a lemon shark or control conditions for 15‐min. Space use and activity were recorded throughout and fish were terminally sampled for blood. Cortisol implantation, relative to shams, resulted in higher blood glucose and plasma cortisol concentrations with a lower plasma lactate concentration. Shark exposure, relative to controls, elicited higher blood glucose and lactate concentrations but had no effect on plasma cortisol concentration. No interactions were detected between shark exposure and cortisol treatment for any physiological trait. Behavioral metrics, including shelter use and activity, were unaffected by either cortisol implantation or shark exposure. Physiological responses to cortisol implantation likely resulted from enhanced gluconeogenic activity, whereas alterations under predator exposure may have been the product of catecholamine mobilization. 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However, stress axis induction has been associated with a higher predation rate in fish. To date, the physiological and behavioral factors associated with this outcome are poorly understood. The purpose of the present study was to investigate the impact of experimental cortisol elevation on anti‐predator behavior and physiological responses to predator presence. We hypothesized that semi‐chronic cortisol elevation would increase susceptibility to predation by increasing stress‐induced risk‐taking behaviors. To test this hypothesis, schoolmaster snapper were given cocoa butter implants without cortisol (sham) or with cortisol (50 mg/kg body weight) and tethered to cover. Fish were exposed to either a lemon shark or control conditions for 15‐min. Space use and activity were recorded throughout and fish were terminally sampled for blood. Cortisol implantation, relative to shams, resulted in higher blood glucose and plasma cortisol concentrations with a lower plasma lactate concentration. Shark exposure, relative to controls, elicited higher blood glucose and lactate concentrations but had no effect on plasma cortisol concentration. No interactions were detected between shark exposure and cortisol treatment for any physiological trait. Behavioral metrics, including shelter use and activity, were unaffected by either cortisol implantation or shark exposure. Physiological responses to cortisol implantation likely resulted from enhanced gluconeogenic activity, whereas alterations under predator exposure may have been the product of catecholamine mobilization. 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Shark exposure, relative to controls, elicited higher blood glucose and lactate concentrations but had no effect on plasma cortisol concentration. No interactions were detected between shark exposure and cortisol treatment for any physiological trait. Behavioral metrics, including shelter use and activity, were unaffected by either cortisol implantation or shark exposure. Physiological responses to cortisol implantation likely resulted from enhanced gluconeogenic activity, whereas alterations under predator exposure may have been the product of catecholamine mobilization. Further work should address context‐specific influences of stress in mediating behavioral responses to predation.</abstract><cop>Australia</cop><pub>Wiley Subscription Services, Inc</pub><pmid>29078038</pmid><doi>10.1111/1749-4877.12282</doi><tpages>13</tpages></addata></record>
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subjects	Animals Anti-Inflammatory Agents - pharmacology Aquatic Organisms Avoidance behavior Avoidance Learning Behavior Behavior, Animal - drug effects Behavioural responses Blood Body weight Catecholamines Cocoa butter Elevation Exposure Fish Fishes - physiology Glucose Homeostasis homeostatic overload Hormones Hydrocortisone - pharmacology Interactions Interspecific relationships Lactate Lactic acid lemon shark Marine fishes Negaprion brevirostris Physiological responses Physiology Predation Predators refuging Risk taking Sharks Shelters Stress stress axis Stress, Physiological - drug effects teleost physiology
title	Influence of supraphysiological cortisol manipulation on predator avoidance behaviors and physiological responses to a predation threat in a wild marine teleost fish
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