Lee Hyerim, Yeo Hyunjae, Park Jihye, Kang Keunsoo, Yi Sun-Ju, Kim Kyunghwan
Department of Biological Sciences and Biotechnology, Chungbuk National University, Cheongju, Republic of Korea.
Department of Microbiology, Dankook University, Cheonan, Republic of Korea.
Anim Cells Syst (Seoul). 2025 Jan 18;29(1):84-99. doi: 10.1080/19768354.2025.2451413. eCollection 2025.
Osmoregulation is essential for the survival of aquatic organisms, particularly teleost fish facing osmotic challenges in environments characterized by variable salinity. While the gills are known for ion exchange, the intestine's role in water and salt absorption is gaining attention. Here, we investigated the adaptive responses of the intestine to salinity stress in guppies (), observing significant morphological and transcriptomic alterations. Guppies showed superior salt tolerance compared to zebrafish (). Increasing salinity reduced villus length and intestinal diameter in guppies, while zebrafish exhibited damage to villus structure and loss of goblet cells. Transcriptomic analysis identified key genes involved in osmoregulation, tissue remodeling, and immune modulation. Upregulated genes included the solute carrier transporters and , which facilitate ion and water transport, as well as a transcription factor AP-1 subunit and phosphatidylinositol-4,5-bisphosphate 3-kinase catalytic subunit beta, both of which participate in tissue repair and growth responses. In contrast, many genes related to the innate immune system (such as ) were downregulated, suggesting a shift toward the prioritization of osmoregulatory functions over immune responses. Interestingly, the differential expression of adaptation genes was linked to variations in epigenetic modifications and transcription factor activity. Transcription factors crucial for adapting to salt stress, such as , , and were progressively upregulated in guppies but remained downregulated in zebrafish. Our findings highlight the intricate mechanisms of adaptation to salinity stress in , providing insights into osmoregulatory mechanisms involving the intestine in aquatic organisms.
渗透调节对于水生生物的生存至关重要,尤其是对于在盐度多变的环境中面临渗透挑战的硬骨鱼。虽然鳃以离子交换而闻名,但肠道在水和盐吸收中的作用正受到越来越多的关注。在这里,我们研究了孔雀鱼肠道对盐度胁迫的适应性反应,观察到显著的形态和转录组变化。与斑马鱼相比,孔雀鱼表现出更强的耐盐性。盐度增加会降低孔雀鱼的绒毛长度和肠道直径,而斑马鱼则表现出绒毛结构受损和杯状细胞丢失。转录组分析确定了参与渗透调节、组织重塑和免疫调节的关键基因。上调的基因包括溶质载体转运蛋白和,它们促进离子和水的运输,以及转录因子AP-1亚基和磷脂酰肌醇-4,5-二磷酸3-激酶催化亚基β,两者都参与组织修复和生长反应。相比之下,许多与先天免疫系统相关的基因(如)被下调,这表明在功能优先级上,渗透调节功能超过了免疫反应。有趣的是,适应基因的差异表达与表观遗传修饰和转录因子活性的变化有关。对盐胁迫适应至关重要的转录因子,如、和,在孔雀鱼中逐渐上调,但在斑马鱼中仍被下调。我们的研究结果突出了孔雀鱼适应盐度胁迫的复杂机制,为水生生物中涉及肠道的渗透调节机制提供了见解。
