Maryoung Lindley A, Lavado Ramon, Bammler Theo K, Gallagher Evan P, Stapleton Patricia L, Beyer Richard P, Farin Federico M, Hardiman Gary, Schlenk Daniel
Department of Environmental Sciences, University of California, 2258 Geology Building, 900 University Ave, Riverside, CA, 92521, USA.
Department of Environmental and Occupational Health Sciences, University of Washington, Seattle, WA, 98195, USA.
Mar Biotechnol (NY). 2015 Dec;17(6):703-17. doi: 10.1007/s10126-015-9649-5. Epub 2015 Aug 11.
Most Pacific salmonids undergo smoltification and transition from freshwater to saltwater, making various adjustments in metabolism, catabolism, osmotic, and ion regulation. The molecular mechanisms underlying this transition are largely unknown. In the present study, we acclimated coho salmon (Oncorhynchus kisutch) to four different salinities and assessed gene expression through microarray analysis of gills, liver, and olfactory rosettes. Gills are involved in osmotic regulation, liver plays a role in energetics, and olfactory rosettes are involved in behavior. Between all salinity treatments, liver had the highest number of differentially expressed genes at 1616, gills had 1074, and olfactory rosettes had 924, using a 1.5-fold cutoff and a false discovery rate of 0.5. Higher responsiveness of liver to metabolic changes after salinity acclimation to provide energy for other osmoregulatory tissues such as the gills may explain the differences in number of differentially expressed genes. Differentially expressed genes were tissue- and salinity-dependent. There were no known genes differentially expressed that were common to all salinity treatments and all tissues. Gene ontology term analysis revealed biological processes, molecular functions, and cellular components that were significantly affected by salinity, a majority of which were tissue-dependent. For liver, oxygen binding and transport terms were highlighted. For gills, muscle, and cytoskeleton-related terms predominated and for olfactory rosettes, immune response-related genes were accentuated. Interaction networks were examined in combination with GO terms and determined similarities between tissues for potential osmosensors, signal transduction cascades, and transcription factors.
大多数太平洋鲑科鱼类会经历幼鱼向成鱼的转变,并从淡水过渡到咸水,在此过程中它们会在新陈代谢、分解代谢、渗透压调节和离子调节方面做出各种调整。然而,这种转变背后的分子机制在很大程度上仍然未知。在本研究中,我们将银大麻哈鱼(Oncorhynchus kisutch)驯化到四种不同的盐度,并通过对鳃、肝脏和嗅叶进行微阵列分析来评估基因表达。鳃参与渗透压调节,肝脏在能量代谢中发挥作用,而嗅叶则与行为有关。在所有盐度处理之间,以1.5倍变化阈值和0.5的错误发现率计算,肝脏中差异表达基因的数量最多,为1616个,鳃中有1074个,嗅叶中有924个。肝脏对盐度适应后代谢变化的更高反应性,可为鳃等其他渗透调节组织提供能量,这可能解释了差异表达基因数量的差异。差异表达基因具有组织和盐度依赖性。在所有盐度处理和所有组织中,没有已知的共同差异表达基因。基因本体术语分析揭示了受盐度显著影响的生物学过程、分子功能和细胞成分,其中大多数是组织依赖性的。对于肝脏,突出显示了氧结合和运输相关术语。对于鳃,肌肉和细胞骨架相关术语占主导地位,而对于嗅叶,免疫反应相关基因更为突出。结合基因本体术语对相互作用网络进行了研究,并确定了组织之间在潜在的渗透压感受器、信号转导级联和转录因子方面的相似性。