Comprehensive analysis of hub mRNA, lncRNA and miRNA, and associated ceRNA networks implicated in cobia (Rachycentron canadum) scales under hypoosmotic adaption

IF 2.2 2区生物学 Q4 BIOCHEMISTRY & MOLECULAR BIOLOGY

Comparative Biochemistry and Physiology D-Genomics & Proteomics Pub Date : 2024-11-15 DOI:10.1016/j.cbd.2024.101353

Changgeng Yang , Jingyi Gao , Kailin Gong , Qian Ma , Gang Chen

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引用次数: 0

Abstract

Salinity plays a vital role in fish aquaculture, profoundly influencing the growth and development of fish. Scales, as the protective outer layer of fish, function as a critical defense against external factors. In this study, we employed transcriptome sequencing to analyze the ceRNA expression profiles to reveal the effect of salinity acclimation on transcriptional expression changes in the scales of cobia (Rachycentron canadum). The results revealed that after being exposed to a salinity level of 15 ‰ for just one day (1D), a total of 407 mRNAs/genes were significantly regulated; 66 miRNAs were respectively significantly regulated; and 109 target genes of the differentially expressed miRNAs were significantly regulated; a total of 185 differently expressed lncRNAs and 292 differently expressed target genes (DetGenes) of differently expressed lncRNAs were also identified. After 7 days (7D), a total of 2195 mRNAs/genes were found to be significantly regulated and 82 miRNAs were significantly regulated; among the target genes of the differentially expressed miRNAs, 245 were regulated. Moreover, 438 differently expressed lncRNAs and 681 DetGenes of these lncRNAs were identified. Subsequent analysis through GO, KEGG pathway, in 1D vs. CG (control group), DeGenes, which first respond to changes in salinity, are mainly involved in negative regulation of macrophage differentiation, negative regulation of granulocyte differentiation and negative regulation of phagocytosis, and are mainly related to biological processes related to the immune function of fish. After a 7-day process, DeGenes were enriched in the collagen fibril organization, regulation of nodal signaling pathway and cell recognition biology processes. These biological processes are not only related to the immune function of fish, but more importantly, to the physiological structure of fish. By analyzing the co down-regulated miRNAs of 1D vs. CG, as well as 7D vs. CG, the functions of these miRNAs are mainly related to bone differentiation and development. In addition，ceRNA network uncovered that the effect of salinity is temporal. The first competing lncRNAs mainly regulated genes related to physiological processes and biological development, while target genes related to immunity and body defense were less competitive. On the contrary, after a period of salinity treatment, the types of competing lncRNAs involved changed.

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全面分析与低渗透适应条件下笛鲷(Rachycentron canadum)鳞片相关的中枢 mRNA、lncRNA 和 miRNA 以及相关 ceRNA 网络

盐度在鱼类养殖中起着至关重要的作用，深刻影响着鱼类的生长和发育。鳞片作为鱼类的外保护层，具有抵御外界因素的重要功能。本研究采用转录组测序技术分析了ceRNA的表达谱，以揭示盐度适应对眼镜鲈（Rachycentron canadum）鳞片转录表达变化的影响。结果发现，在盐度为15‰的环境中仅1天（1D），就有407个mRNA/基因被显著调控；分别有66个miRNA被显著调控；109个差异表达的miRNA的靶基因被显著调控；同时还发现了185个差异表达的lncRNA和292个差异表达的lncRNA的靶基因（DetGenes）。7 天后（7D），共发现 2195 个 mRNA/基因受到显著调控，82 个 miRNA 受到显著调控；在差异表达的 miRNA 的靶基因中，245 个受到调控。此外，还发现了 438 个不同表达的 lncRNA 和这些 lncRNA 的 681 个 DetGenes。随后通过GO、KEGG通路分析，在1D与CG（对照组）中，首先对盐度变化做出反应的DeGenes主要参与巨噬细胞分化负调控、粒细胞分化负调控和吞噬作用负调控，主要与鱼类免疫功能相关的生物学过程有关。经过 7 天的处理，DeGenes 在胶原纤维组织、节点信号通路调控和细胞识别生物学过程中富集。这些生物学过程不仅与鱼类的免疫功能有关，更重要的是与鱼类的生理结构有关。通过分析1D与CG、7D与CG共同下调的miRNA，这些miRNA的功能主要与骨分化和发育有关。此外，ceRNA网络发现盐度的影响具有时间性。最初竞争的lncRNA主要调控与生理过程和生物发育相关的基因，而与免疫和机体防御相关的靶基因竞争性较弱。相反，经过一段时间的盐度处理后，参与竞争的lncRNA的类型发生了变化。

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来源期刊

Comparative Biochemistry and Physiology D-Genomics & Proteomics 生物-生化与分子生物学

CiteScore

5.10

自引率

3.30%

发文量

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.