Structure and gene expression changes of the gill and liver in juvenile black porgy (Acanthopagrus schlegelii) under different salinities

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Tangjian Zhou , Qian Meng , Ruijian Sun , Dafeng Xu , Fei Zhu , Chaofeng Jia , Shimiao Zhou , Shuyin Chen , Yunxia Yang
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Abstract

Black porgy (Acanthopagrus schlegelii) is an important marine aquaculture species in China. It is an ideal object for the cultivation of low-salinity aquaculture strains in marine fish and the study of salinity tolerance mechanisms in fish because of its strong low-salinity tolerance ability. Gill is the main osmoregulatory organ in fish, and the liver plays an important role in the adaptation of the organism to stressful environments. In order to understand the coping mechanisms of the gills and livers of black porgy in different salinity environments, this study explored these organs after 30 days of culture in hypoosmotic (0.5 ppt), isosmotic (12 ppt), and normal seawater (28 ppt) at histologic, physiologic, and transcriptomic levels. The findings indicated that gill exhibited a higher number of differentially expressed genes than the liver, emphasizing the gill's heightened sensitivity to salinity changes. Protein interaction networks and enrichment analyses highlighted energy metabolism as a key regulatory focus at both 0.5 ppt and 12 ppt salinity in gills. Additionally, gills showed enrichment in ions, substance transport, and other metabolic pathways, suggesting a more direct regulatory response to salinity stress. The liver's regulatory patterns at different salinities exhibited significant distinctions, with pathways and genes related to metabolism, immunity, and antioxidants predominantly activated at 0.5 ppt, and molecular processes linked to cell proliferation taking precedence at 12 ppt salinity. Furthermore, the study revealed a reduction in the volume of the interlamellar cell mass (ILCM) of the gills, enhancing the contact area of the gill lamellae with water. At 0.5 ppt salinity, hepatic antioxidant enzyme activity increased, accompanied by oxidative stress damage. Conversely, at 12 ppt salinity, gill NKA activity significantly decreased without notable changes in liver structure. These results underscore the profound impact of salinity on gill structure and function, highlighting the crucial role of the liver in adapting to salinity environments.

Abstract Image

不同盐度条件下黑鲷幼鱼鳃和肝脏的结构及基因表达变化
黑鲷(Acanthopagrus schlegelii)是我国重要的海水养殖品种。它具有很强的耐低盐能力,是海水鱼类低盐养殖品系培育和鱼类耐盐机制研究的理想对象。鳃是鱼类的主要渗透调节器官,肝脏在机体对应激环境的适应过程中起着重要作用。为了了解黑鲷鳃和肝脏在不同盐度环境下的应对机制,本研究从组织学、生理学和转录组学水平探讨了在低渗透(0.5 ppt)、等渗透(12 ppt)和正常海水(28 ppt)中养殖 30 天后这些器官的变化。研究结果表明,与肝脏相比,鳃表现出更多的差异表达基因,强调了鳃对盐度变化的高度敏感性。蛋白质相互作用网络和富集分析突出表明,能量代谢是鳃在 0.5 ppt 和 12 ppt 盐度条件下的关键调控重点。此外,鳃中的离子、物质转运和其他代谢途径也出现了富集,这表明它们对盐度胁迫做出了更直接的调控响应。肝脏在不同盐度下的调控模式有显著差异,在0.5 ppt盐度下,与新陈代谢、免疫和抗氧化剂有关的途径和基因主要被激活,而在12 ppt盐度下,与细胞增殖有关的分子过程优先被激活。此外,研究还发现,鳃的层间细胞团(ILCM)体积缩小,增加了鳃片与水的接触面积。盐度为 0.5 ppt 时,肝脏抗氧化酶活性增加,并伴有氧化应激损伤。相反,在 12 ppt 的盐度条件下,鳃的 NKA 活性显著下降,而肝脏结构没有明显变化。这些结果强调了盐度对鳃结构和功能的深刻影响,突出了肝脏在适应盐度环境中的关键作用。
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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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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