Experimental Manipulation of Air Temperature in Captivity Appears Unsuitable for Evaluating Fecal Glucocorticoid Metabolite Responses of Wild-Caught Birds to Heat Exposure.

IF 1.8 3区生物学 Q3 PHYSIOLOGY

Physiological and Biochemical Zoology Pub Date : 2021-09-01 DOI:10.1086/716043

Celiwe A Ngcamphalala, Michelle Bouwer, Susan W Nicolson, André Ganswindt, Andrew E McKechnie

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引用次数: 1

Abstract

AbstractNoninvasive measurement of stress-related alterations in fecal glucocorticoid metabolite (fGCM) concentrations has considerable potential for quantifying physiological responses to very hot weather in free-ranging birds, but practical considerations related to sampling will often make this method feasible only for habituated study populations. Here we evaluate an alternate approach, the use of experimentally manipulated thermal environments for evaluating stress responses to high environmental temperatures in wild-caught birds housed in captivity. Using an enzyme immunoassay utilizing antibodies against 5ß-pregnane-3α,11ß,21-triol-20-one-CMO∶BSA (tetrahydrocorticosterone), we quantified fGCMs in captive individuals of three southern African arid-zone species (southern pied babblers [Turdoides bicolor], white-browed sparrow-weavers [Plocepasser mahali], and southern yellow-billed hornbills [Tockus leucomelas]) experiencing daily air temperature maxima (T_max) ranging from 30°-32°C to 42°-44°C. For none of the three species did T_max emerge as a significant predictor of elevated fGCM concentrations, and no stress response to simulated hot weather was evident. The apparent lack of a stress response to T_max = 42°C in captive southern pied babblers contrasts with linear increases in fGCMs at T_max > 38°C in free-ranging conspecifics. The lack of an effect of T_max on fGCM levels may potentially be explained by several factors, including differences in operative temperatures and the availability of water and food between free-ranging and captive settings or the stress effect of captivity itself. Our results suggest that experimental manipulations of thermal environments experienced by wild-caught captive birds have limited usefulness for testing hypotheses concerning the effects of hot weather events on fGCM (and, by extension, glucocorticoid) concentrations.

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圈养环境下的实验温度似乎不适合评估野生捕获鸟类对热暴露的粪便糖皮质激素代谢物反应。

摘要:无创伤测量粪便糖皮质激素代谢物(fGCM)浓度与压力相关的变化，对于量化自由放养鸟类对高温天气的生理反应具有相当大的潜力，但与采样有关的实际考虑往往使这种方法仅适用于习惯的研究种群。在这里，我们评估了另一种方法，使用实验操纵的热环境来评估圈养野生捕获的鸟类对高温环境的应激反应。采用针对5ß-孕酮-3α，11ß，21-三醇-20- 1- cmo∶BSA(四氢皮质酮)抗体的酶免疫测定法，我们定量了3种非洲南部干旱地区物种(南方斑嘴鸟[Turdoides bicolor]，白额麻雀[Plocepasser mahali]和南方黄嘴犀鸟[Tockus leucomelas])的圈养个体的fgcm，这些物种的日最高气温(Tmax)为30°-32°C至42°-44°C。对于三个物种来说，Tmax都没有成为fGCM浓度升高的显著预测因子，并且对模拟炎热天气没有明显的应激反应。圈养的南方斑斑鹦鹉在Tmax = 42°C时明显缺乏应激反应，而自由放养的同种鹦鹉在Tmax > 38°C时fgcm呈线性增加。Tmax对fGCM水平没有影响，可能有几个因素可以解释，包括自由放养和圈养环境中操作温度、水和食物供应的差异，或圈养本身的压力效应。我们的研究结果表明，对野生捕获的圈养鸟类所经历的热环境进行实验操作，对于测试炎热天气事件对fGCM(以及糖皮质激素)浓度影响的假设的有用性有限。

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来源期刊

Physiological and Biochemical Zoology 生物-动物学

CiteScore

3.20

自引率

6.20%

发文量

审稿时长

6-12 weeks

期刊介绍： Physiological and Biochemical Zoology: Ecological and Evolutionary Approaches primarily publishes original research in animal physiology and biochemistry as considered from behavioral, ecological, and/or evolutionary perspectives. Studies at all levels of biological organization from the molecular to the whole organism are welcome, and work that integrates across levels of organization is particularly encouraged. Studies that focus on behavior or morphology are welcome, so long as they include ties to physiology or biochemistry, in addition to having an ecological or evolutionary context. Subdisciplines of interest include nutrition and digestion, salt and water balance, epithelial and membrane transport, gas exchange and transport, acid-base balance, temperature adaptation, energetics, structure and function of macromolecules, chemical coordination and signal transduction, nitrogen metabolism and excretion, locomotion and muscle function, biomechanics, circulation, behavioral, comparative and mechanistic endocrinology, sensory physiology, neural coordination, and ecotoxicology ecoimmunology.