交通噪声对两种蝌蚪的糖皮质激素反应、活动和生长的影响

IF 2.2 3区 生物学 Q1 ZOOLOGY Integrative and Comparative Biology Pub Date : 2024-07-26 DOI:10.1093/icb/icae032
Megan M Flanagan, Hannah J Stottlemyre, Caitlin R Gabor
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引用次数: 0

摘要

有大量证据表明,噪声增加会对动物的健康产生负面影响。人为噪声会诱发一系列类群的行为和生理反应,交通噪声的增加会影响与两栖动物应激反应相关的糖皮质激素(GC)。糖皮质激素有助于维持体内平衡,同时平衡繁殖、生长和活动之间的能量权衡。早期发育过程中的应激反应会影响后期的适应能力。我们测量了两种生活史不同的蝌蚪对高水平交通噪声的生长、活动和 GCs 反应:Acris crepitans 和 Rana berlandieri。我们预测,较早暴露于交通噪声的蝌蚪与较晚暴露于交通噪声的蝌蚪相比,发育速度会减慢,行为和 GC 浓度的改变也会不同。最初,受试者要么暴露在自然水平的交通噪声中 8 天(早期暴露),要么暴露在白噪声对照中 8 天(后期暴露),然后对调处理。蝌蚪的活动是通过焦点取样测量的,如果检测到蝌蚪移动,则将其归类为活跃蝌蚪。在整个实验过程中,暴露于白噪声的蝌蚪最初都能保持质量和活动,而早期暴露于交通噪声对质量、活动和 GCs 的影响更大。暴露于交通噪声的蝌蚪最初会失去质量,A. crepitans会恢复质量,但R. berlandieri不会。当较早暴露于交通噪声时,R. berlandieri在转向白噪声处理时活动量增加,而A. crepitans的活动量没有显著变化。与R. berlandieri相比,A. creptians的皮质酮释放率更高,而且在这两个物种中,更早接触噪声的蝌蚪释放率更高。寿命较长的贝氏蝌蚪将更多的能量资源分配给了活动,而寿命较短的克氏蝌蚪则将能量用于生长。贝氏蝌蚪和克氏蝌蚪利用不同的应对策略来应对早期暴露于交通噪声的情况,这可能是由于它们的生活史不同造成的。我们的研究结果表明,这些蝌蚪在噪声污染环境中采用了不同的应对机制来调节应激反应,而这些机制可能会影响它们日后的健康状况。要了解对更敏感的蝌蚪物种的影响,还需要进一步的研究。
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Traffic Noise Impacts Glucocorticoid Response, Activity, and Growth in Two Species of Tadpoles.

There is a large body of evidence linking increased noise to negative health effects for animals. Anthropogenic noise induces behavioral and physiological reactions across a range of taxa and increased traffic noise affects glucocorticoid (GC) hormones associated with the stress response in amphibians. GCs help to maintain homeostasis while balancing energetic trade-offs between reproduction, growth, and activity. Stressors during early development can impact fitness at later life stages. We measured growth, activity, and GCs in response to high levels of traffic noise in two tadpole species that differ in life history: Acris crepitans and Rana berlandieri. We predicted that earlier exposures to traffic noise will slow down the development and alter the behavior and GC concentrations differently than later exposures. Subjects were initially either exposed to natural levels of traffic noise for 8 days (early exposure) or a white noise control (later exposure), then the treatment was switched. Activity was measured via focal sampling and tadpoles were categorized as active if movement was detected. Tadpoles exposed to white noise initially maintained mass and activity throughout the experiment and early exposure to traffic noise had a greater impact on mass, activity, and GCs. Tadpoles exposed to traffic noise initially lost mass, with A. crepitans regaining mass but not R. berlandieri. When exposed earlier to traffic noise, R. berlandieri increased movement when shifted to the white noise treatment while A. crepitans did not significantly change activity. Acris creptians had higher corticosterone release rates compared to R. berlandieri, and in both species, release rates were higher for tadpoles exposed to noise earlier. The longer-lived R. berlandieri allocated more of their energetic resources into activity, while the shorter-lived A. crepitans allocated energy toward growth. Rana berlandieri and A. crepitans utilized different coping strategies to contend with early exposure to traffic noise, potentially due to differences in life histories. Our findings suggest that these tadpoles employ different coping mechanisms to modulate stress responses in noise-polluted environments, and these mechanisms could influence their fitness later in life. Further study is needed to understand the impact in more sensitive tadpole species.

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来源期刊
CiteScore
4.70
自引率
7.70%
发文量
150
审稿时长
6-12 weeks
期刊介绍: Integrative and Comparative Biology ( ICB ), formerly American Zoologist , is one of the most highly respected and cited journals in the field of biology. The journal''s primary focus is to integrate the varying disciplines in this broad field, while maintaining the highest scientific quality. ICB''s peer-reviewed symposia provide first class syntheses of the top research in a field. ICB also publishes book reviews, reports, and special bulletins.
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