Network analysis reveals that acute stress exacerbates gene regulatory responses of the gill to seawater in Atlantic salmon.

M. Y. Monette, Jonathan P. Velotta
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引用次数: 1

Abstract

The transition from freshwater to seawater represents a physiological challenge for Atlantic salmon smolts preparing for downstream migration. Stressors occurring during downstream migration to the ocean impair the ability of smolts to maintain osmotic/ionic homeostasis in seawater. The molecular mechanisms underlying this interaction are not fully understood, especially at the organ-level. We combined RNA-seq with measures of whole animal homeostasis to examine gene expression dynamics in the gills of smolts associated with impaired seawater tolerance after an aquaculture-related stressor. Smolts were given a 24 h seawater tolerance test before and after exposure to an acute handling/confinement stress. RNA-seq followed by Differential Expression and Weighted Gene Correlation Network Analysis (WGCNA) was used to quantify the transcriptional response of the gill to handling/confinement stress, seawater, and their interaction. Exposure to acute stress was associated with a general stress response and impaired osmotic/ionic homeostasis in seawater. We identified gene networks in the gill exhibiting response to acute stress alone, seawater alone, and others exhibiting combined effects of both stress and seawater. Our findings indicate that acute handling/confinement stress increases the intensity of seawater-related gene expression and suggest that increased investment in mechanisms related to ion transport may be part of a compensatory response to impaired seawater tolerance in smolts.
网络分析表明,急性应激加剧了大西洋鲑鱼鳃对海水的基因调控反应。
从淡水到海水的转变对准备下游迁徙的大西洋鲑鱼幼崽来说是一个生理上的挑战。在下游向海洋迁移过程中出现的应激源损害了小鲱鱼在海水中维持渗透/离子平衡的能力。这种相互作用的分子机制尚不完全清楚,特别是在器官水平上。我们将RNA-seq与全动物稳态测量相结合,研究了与水产养殖相关应激源后海水耐受性受损相关的小鳟鱼鳃中的基因表达动态。在暴露于急性处理/禁闭压力前后分别进行24 h海水耐受性试验。采用RNA-seq、差异表达和加权基因相关网络分析(WGCNA)来量化鳃对处理/禁闭胁迫、海水及其相互作用的转录反应。暴露于急性应激与一般应激反应和海水中渗透/离子稳态受损有关。我们发现鳃中的基因网络仅对急性应激或海水作出反应,而其他基因网络则表现出应激和海水的联合作用。我们的研究结果表明,急性处理/禁闭应激增加了海水相关基因表达的强度,并表明增加离子运输相关机制的投资可能是小鲑鱼对海水耐受性受损的补偿性反应的一部分。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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