Thermal flexibility is a repeatable mechanism to cope with environmental stressors in a passerine bird

AbstractFor many vertebrates, urban environments are characterised by frequent environmental stressors. Coping with such stressors can demand that urban individuals activate energetically costly physiological pathways (e.g. the fight-or-flight response) more regularly than rural-living conspecifics. However, urban environments also commonly demand appreciable expenditure toward thermoregulation, owing to their often extreme climatic variations. To date, whether and how vertebrates can balance expenditure toward both the physiological stress response and thermoregulation, and thus persist in an urbanising world, remains an unanswered and urgent question among ecologists.In some species, changes in body surface temperature (Ts) and peripheral heat loss (qTot) that accompany the stress response are thought to balance energetic expenditure toward thermoregulation and responding to a stressor. Thus, augmentation of stressinduced thermal responses may be a mechanism by which urban individuals cope with simultaneously high thermoregulatory and stress-physiological demands.We tested whether stress-induced changes in Ts and qTot: (1) differed between urban- and rural-origin individuals, (2) reduce thermoregulatory demands in urban individuals relative to rural conspecifics, and (3) meet an essential first criterion for evolutionary responses to selection (variability among, and consistency within, individuals).Using the black-capped chickadee (Poecile atricapillus; n = 19), we show that neither rapid nor chronic changes in Ts and qTot following exposure to randomised stressors differed between urban- and rural-origin individuals (nurban = 9; nrural = 10). Nevertheless, we do find that stress-induced changes in Ts and qTot are highly repeatable across chronic time periods (RTs = 0.61; RqTot = 0.67) and display signatures of stabilising or directional selection (i.e. reduced variability and increase repeatability relative to controls).Our findings suggest that, although urban individuals appear no more able to balance expenditure toward thermoregulation and the stress response than rural conspecifics, the capacity to do so may be subject to selection in some species. To our knowledge this is also the first study to report repeatability of any theorised stress-induced trade-off.

Download Full-text

Exploring the mechanistic link between corticosterone and insulin-like growth factor-1 in a wild passerine bird

PeerJ ◽

10.7717/peerj.5936 ◽

2018 ◽

Vol 6 ◽

pp. e5936 ◽

Cited By ~ 4

Author(s):

Zsófia Tóth ◽

Jenny Q. Ouyang ◽

Ádám Z. Lendvai

Keyword(s):

Life History ◽

Stress Response ◽

Growth Factor ◽

Physiological Stress ◽

Passerine Bird ◽

Insulin Like Growth Factor ◽

Handling Stress ◽

Trade Offs ◽

Physiological Stress Response ◽

Panurus Biarmicus

Background Physiological regulators of life history trade-offs need to be responsive to sudden changes of resource availability. When homeostasis is challenged by unpredictable stressors, vertebrates respond through a set of physiological reactions, which can promote organismal survival. Glucocorticoids have been traditionally recognized as one of the main regulators of the physiological stress response, but the role of an evolutionarily more conserved pathway, the hypothalamic-pituitary-somatotropic (HPS) axis producing insulin-like growth factor-1 (IGF-1) has received much less attention. Although IGF-1 is known to affect several life history traits, little is known about its role in the physiological stress response and it has never been studied directly in adult wild animals. Methods In this study, we combined field observations with a controlled experiment to investigate how circulating levels of IGF-1 change in response to stress and whether this change is due to concomitant change in glucocorticoids in a free-living songbird, the bearded reedling Panurus biarmicus. We used a standard capture-restraint protocol in field observation, in which we took first and second (stress induced: 15 minutes later) samples. In a follow-up experiment, we used a minimally invasive oral corticosterone manipulation. Results We showed that corticosterone levels significantly increased while IGF-1 levels significantly decreased during capture and handling stress. However, change in corticosterone levels were not related to change in IGF-1 levels. We found that experimentally elevated corticosterone levels did not affect IGF-1 levels. Discussion Our results are the first to highlight that circulating IGF-1 levels are responsive to stress independently from glucocorticoids and suggest that the HPS axis is an autonomous physiological pathway that may play an important role as regulator of life-history decisions.

Download Full-text

Exploring the mechanistic link between corticosterone and insulinlike growth factor-1 in a wild passerine bird

10.1101/306407 ◽

2018 ◽

Author(s):

Zsófia Tóth ◽

Jenny Q. Ouyang ◽

Ádám Z. Lendvai

Keyword(s):

Life History ◽

Stress Response ◽

Growth Factor ◽

Physiological Stress ◽

Passerine Bird ◽

Handling Stress ◽

Trade Offs ◽

Physiological Stress Response ◽

Panurus Biarmicus ◽

Response To Stress

AbstractBackgroundPhysiological regulators of life history trade-offs need to be responsive to sudden changes of resource availability. When homeostasis is challenged by unpredictable stressors, vertebrates respond through a set of physiological reactions, which can promote organismal survival. Glucocorticoids have been traditionally recognized as one of the main regulators of the physiological stress response, but the role of an evolutionarily more conserved pathway, the hypothalamic-pituitary-somatotropic (HPS) axis producing insulin-like growth factor-1 (IGF-1) has received much less attention. Although IGF-1 is known to affect several life history traits, little is known about its role in the physiological stress response and it has never been studied directly in adult wild animals.MethodsIn this study, we combined field observations with a controlled experiment to investigate how circulating levels of IGF-1 change in response to stress and whether this change is due to concomitant change in glucocorticoids in a free-living songbird, the bearded reedling Panurus biarmicus. We used a standard capture-restraint protocol in field observation, in which we took first and second (stress induced: 15 minutes later) samples. In a follow-up experiment, we used a minimally invasive oral corticosterone manipulation.ResultsWe showed that corticosterone levels significantly increased while IGF-1 levels significantly decreased during capture and handling stress. However, change in corticosterone levels were not related to change in IGF-1 levels. We found that experimentally elevated corticosterone levels did not affect IGF-1 levels.DiscussionOur results are the first to highlight that circulating IGF-1 levels are responsive to stress independently from glucocorticoids and suggest that the HPS axis is an autonomous physiological pathway that may play an important role as regulator of life-history decisions.

Download Full-text

The reaction of pearl dace (Pisces, Cyprinidae) to alarm substance: time-course of behavior, brain amines, and stress physiology

Canadian Journal of Zoology ◽

10.1139/z87-442 ◽

1987 ◽

Vol 65 (12) ◽

pp. 2916-2921 ◽

Cited By ~ 40

Author(s):

Bradley G. Rehnberg ◽

R. J. F. Smith ◽

B. D. Sloley

Keyword(s):

Stress Response ◽

Initial Phase ◽

Time Course ◽

Physiological Stress ◽

Stress Physiology ◽

Alarm Substance ◽

Behavioral Reactions ◽

Physiological Stress Response ◽

Alarm Reaction ◽

Induced Changes

Pearl dace, Semotilus margarita (Pisces, Cyprinidae), respond behaviorally and physiologically to conspecific alarm substance. The behavioral alarm reaction was biphasic. A brief initial phase of rapid and unpredictable swimming was followed by a period of inactivity that was observable even after 5 h. In nature, biphasic behavioral reactions may function to remove alarmed fish from the area of greatest danger and then render them inconspicuous. The physiological alarm reaction included elements of a stress response. Concentrations of plasma cortisol and glucose were elevated at 15 min after the detection of alarm substance, but had returned to control levels by 5 h. There were no odor-induced changes observed in brain concentrations of dopamine, norepinephrine, 5-hydroxytryptamine, or tryptophan. The biphasic behavioral response and the physiological stress response were interpreted as adaptations that permit pearl dace to successfully react to threats of predation.

Download Full-text