Frode Oppedal, Luke T Barrett, Thomas W K Fraser, Tone Vågseth, Guosong Zhang, Oliver G Andersen, Lea Jacson, Marie-Aida Dieng, Marco A Vindas
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引用次数: 0
Abstract
Introduction: Noise associated with human activities in aquatic environments can affect the physiology and behavior of aquatic species which may have consequences at the population and ecosystem levels. Low-frequency sound is particularly stressful for fish since it is an important factor in predator-prey interactions. Even though behavioral and physiological studies have been conducted to assess the effects of sound on fish species, neurobiological studies are still lacking.
Methods: In this study, we exposed farmed salmon to low-frequency sound for 5 min a day for 30 trials and conducted behavioral observations and tissue sampling before sound exposure (timepoint zero; T0) and after 1 (T1), 10 (T2), 20 (T3), and 30 (T4) exposures, to assess markers of stress. These included plasma cortisol, neuronal activity, monoaminergic signaling, and gene expression in 4 areas of the forebrain.
Results: We found that sound exposure induced an activation of the stress response by eliciting an initial startle behavioral response, together with increased plasma cortisol levels and a decrease in neuronal activity in the hypothalamic tubercular nuclei (TN). At T3 and T4 salmon showed a degree of habituation in their behavioral and cortisol response. However, at T4, salmon showed signs of chronic stress with increased serotonergic activity levels in the dorsolateral and dorsomedial pallium, the preoptic area, and the TN, as well as an inhibition of growth and reproduction transcripts in the TN.
Conclusions: Together, our results suggest that prolonged exposure to sound results in chronic stress that leads to neurological changes which suggest a reduction of life fitness traits.
期刊介绍:
''Brain, Behavior and Evolution'' is a journal with a loyal following, high standards, and a unique profile as the main outlet for the continuing scientific discourse on nervous system evolution. The journal publishes comparative neurobiological studies that focus on nervous system structure, function, or development in vertebrates as well as invertebrates. Approaches range from the molecular over the anatomical and physiological to the behavioral. Despite this diversity, most papers published in ''Brain, Behavior and Evolution'' include an evolutionary angle, at least in the discussion, and focus on neural mechanisms or phenomena. Some purely behavioral research may be within the journal’s scope, but the suitability of such manuscripts will be assessed on a case-by-case basis. The journal also publishes review articles that provide critical overviews of current topics in evolutionary neurobiology.
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