Kidney transcriptome analysis reveals the molecular responses to salinity adaptation in largemouth bass (Micropterus salmoides)

IF 2.2 2区 生物学 Q4 BIOCHEMISTRY & MOLECULAR BIOLOGY Comparative Biochemistry and Physiology D-Genomics & Proteomics Pub Date : 2024-11-16 DOI:10.1016/j.cbd.2024.101362
Yichun Zhang , Jinxin Zhang , Yafang Tan , Xinxin Wang , Huapeng Chen , Haoran Yu , Feiyang Chen , Xinling Yan , Junlong Sun , Jian Luo , Feibiao Song
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Abstract

Recently, against the background of increasing land salinization and global warming, many studies have examined the mechanisms of freshwater fish adaptation to elevated salinity. However, the mechanisms underlying salinity tolerance in the kidney of Micropterus salmoides, a popular saline aquaculture species, remain poorly understood. We used RNA-seq to explore the differentially expressed genes (DEGs) in the kidney of M. salmoides at 0 ‰, 5 ‰, and 10 ‰ salinity for 24 d and 48 d. These DEGs mainly affected metabolism-related pathways, such as secondary metabolite biosynthesis, arachidonic acid metabolism, etc., and immunity-related pathways, such as IL-17 signaling and ECM-receptor interaction. Trend analysis on days 24 and 48 showed that, as salinity increased, the up-regulated genes were notably enriched in the cytochrome P450 xenobiotic metabolic pathway, and down-regulated genes substantially linked to cell cycle, phagosome, etc. More importantly, we identified a total of 22 genes enriched in the cytochrome P450 xenobiotic metabolic pathway, including seven UDP-glucuronosyltransferase genes (UGTs) and five glutathione S-transferase genes (GSTs). We speculated that M. salmoides kidneys removed toxic substances produced due to salinity stress and mitigated oxidative damage by up-regulating UGTs and GSTs, hence maintaining normal physiological function. In addition, genes such as Cystatin A1, significantly up-regulated with increasing salinity stress and duration, favoured the recovery of kidney injury. This research delved into the molecular processes involved in the adaptability of M. salmoides to high salinity stress and provided valuable information for the future breeding of salinity-tolerant strains.

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肾脏转录组分析揭示了大口鲈鱼(Micropterus salmoides)对盐度适应的分子反应。
近来,在土地盐碱化加剧和全球变暖的背景下,许多研究探讨了淡水鱼类对盐度升高的适应机制。然而,人们对常用的盐碱地水产养殖鱼类--鳙鱼(Micropterus salmoides)肾脏的耐盐机制仍然知之甚少。我们利用RNA-seq研究了沼鲤肾脏在0‰、5‰和10‰盐度条件下24天和48天的差异表达基因(DEGs),这些差异表达基因主要影响代谢相关通路,如次级代谢产物的生物合成、花生四烯酸代谢等,以及免疫相关通路,如IL-17信号传导和ECM-受体相互作用。第 24 天和第 48 天的趋势分析表明,随着盐度的增加,上调基因明显富集于细胞色素 P450 异生物代谢途径,而下调基因则与细胞周期、吞噬体等密切相关。更重要的是,我们共发现了 22 个富集于细胞色素 P450 异生物代谢途径的基因,其中包括 7 个 UDP-葡萄糖醛酸转移酶基因(UGTs)和 5 个谷胱甘肽 S 转移酶基因(GSTs)。我们推测,鲑鱼肾脏通过上调 UGTs 和 GSTs 清除盐胁迫产生的有毒物质,减轻氧化损伤,从而维持正常的生理功能。此外,胱抑素 A1 等基因随着盐度胁迫和持续时间的增加而显著上调,有利于肾损伤的恢复。这项研究深入探讨了沼泽鱼适应高盐度胁迫的分子过程,为今后培育耐盐菌株提供了宝贵信息。
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来源期刊
CiteScore
5.10
自引率
3.30%
发文量
69
审稿时长
33 days
期刊介绍: Comparative Biochemistry & Physiology (CBP) publishes papers in comparative, environmental and evolutionary physiology. Part D: Genomics and Proteomics (CBPD), focuses on “omics” approaches to physiology, including comparative and functional genomics, metagenomics, transcriptomics, proteomics, metabolomics, and lipidomics. Most studies employ “omics” and/or system biology to test specific hypotheses about molecular and biochemical mechanisms underlying physiological responses to the environment. We encourage papers that address fundamental questions in comparative physiology and biochemistry rather than studies with a focus that is purely technical, methodological or descriptive in nature.
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