绿水螅野生型品系及无藻品系对聚苯乙烯纳米颗粒胁迫差异化响应的转录组分析

TRANSCRIPTOMIC ANALYSIS OF DIFFERENTIATED RESPONSES BETWEEN SYMBIOTIC AND APOSYMBIOTIC STRAIN OF HYDRA SINENSIS TO POLYSTYRENE NANOPARTICLES

  • 摘要: 为探究中国绿水螅(Hydra sinensis)体内有或无共生藻是否影响水螅宿主对聚苯乙烯纳米颗粒(Polystyrene nanoparticles, PS NPs)的耐受性, 研究首先对绿水螅野生型品系(体内有共生藻)及绿水螅无藻品系(体内无共生藻)分别进行PS NPs (粒径20 nm) 48h急性毒理实验, 结果显示野生型品系48h半致死浓度(3.36×102 mg/L)明显高于无藻品系(1.39×102 mg/L), 这表明与无藻品系相比, 野生型品系对PS NPs具有较强的耐受性。随后采用含75 mg/L PS NPs的培养液对绿水螅野生型品系及无藻品系处理48h后分别进行转录组分析(对照组PS NPs浓度为0 mg/L), 在野生型品系的PS NPs处理组与对照组间共筛选到1532个差异表达基因(Differentially expressed genes, DEGs), 其中763个DEGs表达上调, 769个DEGs表达下调; 而无藻品系的PS NPs处理组与对照组间共筛选到1079个DEGs, 其中476个DEGs表达上调, 603个DEGs表达下调。基于PS NPs胁迫下无藻品系的DEGs显著富集的病态指征相关的14个KEGG (Kyoto Encyclopedia of Genes and Genomes)代谢通路中, 有9个通路包含的DEGs全部表达上调; 而基于PS NPs胁迫下野生型品系的DEGs显著富集的病态指征相关的21个KEGG代谢通路中, 只有1个通路包含的DEGs全部表达上调。由此可见, PS NPs胁迫下无藻品系病态指征的激活水平显著高于野生型品系, 此现象从分子水平证明了野生型品系对PS NPs胁迫的耐受性强于无藻品系。此外, 从PS NPs胁迫下无藻品系显著富集的免疫应答相关KEGG代谢通路中的21个DEGs全部表达上调, 而从PS NPs胁迫下野生型品系显著富集的免疫应答相关KEGG代谢通路中的27个DEGs仅约一半表达上调, 说明PS NPs胁迫下野生型品系免疫应答的激活水平明显低于无藻品系, 这反映了野生型品系对PS NPs的免疫应答敏感性低于无藻品系。总之, 绿水螅两个品系在对PS NPs的免疫应答敏感性上的差异应是两个品系对PS NPs胁迫耐受性差异的分子基础; 而相对于绿水螅无藻品系而言, 野生型品系对PS NPs具有较低的免疫应答敏感性可能与水螅-单细胞藻共生体系中水螅宿主为维持与共生藻的共生关系而进行的免疫水平调整(即水螅宿主为“容留”共生藻而“调低”了对外来异物的免疫水平)的机制相关。研究为探讨纳米级塑料颗粒的生物毒性及分子机理提供了基础数据。

     

    Abstract: To investigate the impact of symbiotic algae presence or absence on the tolerance of Hydra sinensis to polystyrene nanoparticles (PS NPs), we conducted a 48h acute toxicity experiment on both symbiotic and aposymbiotic strain of H. sinensis using different PS NPs concentrations (20 nm in diameter). The results showed that the 48h half-lethal concentration (48h LC50) for the symbiotic strain (3.36×102 mg/L) was significantly higher than that of the aposymbiotic strain (1.39×102 mg/L). Subsequently, following exposure to a medium containing 75 mg/L PS NPs for 48h, both symbiotic and aposymbiotic strains underwent transcriptomic analysis, respectively (with a control group having 0 PS NPs). A total of 1532 differentially expressed genes (DEGs) were identified in the symbiotic strain between the PS NPs-treated and control groups, with 763 were up-regulated and 769 down-regulated genes. Similarly, 1079 differentially expressed genes (DEGs) were obtained between PS NPs-treated and control group of the symbiotic strain, with 476 up-regulated and 603 down-regulated genes. KEGG enrichment analysis revealed significant enrichment (P<0.05) of metabolic pathways in both strains, encompassing immune response, pathological indications, material metabolism, cellular processes, organic systems, environmental information processing, and genetic information processing. Among the pathways related to pathological indications, all DEGs were upregulated in only one out of 21 significant pathways for the symbiotic strain, while for the aposymbiotic strain, all DEGs were upregulated in 9 out of 14 significant pathways. This suggests a significantly higher activation level of pathological indicators in the aposymbiotic strain under PS NPs stress compared to the symbiotic strain, indicating a superior tolerance at the molecular level. In addition, all DEGs related to immune response in the aposymbiotic strain treated with PS NPs were upregulated, while only approximately half of the DEGs in the symbiotic strain were upregulated. This suggests a lower immune response sensibility to PS NPs in the symbiotic strain compared to the aposymbiotic strain. In summary, the difference in immune response sensibility to PS NPs between the two H. sinensis strains may underlie their differing tolerance to PS NPs stress at the molecular level. In addition, the symbiotic strain exhibits lower immune response sensitivity to PS NPs, possibly due to the host downregulating immune levels against foreign invaders to accommodate symbiotic algae. The study provides basic data for revealing the biotoxicity and molecular mechanism of nano-sized plastic particles.

     

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