低剂量吡虫啉诱导蚯蚓氧化应激和神经细胞破坏

IF 0.3
A. Huslystyi, V. Nedzvetsky, S. Yermolenko, V. Gasso, V. Petrushevskyi, E. Sukharenko
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引用次数: 4

摘要

吡虫啉是一种应用广泛的新烟碱类农药。越来越多的证据表明,新烟碱类化合物对非靶生物(包括哺乳动物等脊椎动物)具有细胞毒性作用。尽管如此,对新烟碱类药物的剂量限制毒性和有害作用的分子机制仍知之甚少。根据吡虫啉在环境中的命运,大部分使用过的农药被吸收在土壤中。因此,蚯蚓是主要的土壤生物,可以被认为是新烟碱类药物毒性的目标。蚯蚓的简单神经系统是神经毒性生态学研究的一个前瞻性模型。在纸张接触试验中,我们将蚯蚓暴露于吡虫啉,剂量范围为0.1-0.4µg/cm2,持续14天。在本工作中,我们研究了吡虫啉对氧化应激产生和神经元标志物神经元特异性烯醇化酶(NSE)表达的影响。吡虫啉暴露诱导NSE呈剂量依赖性降低。活性氧的产生和脂质过氧化水平也上调。观察到的NSE下降表明吡虫啉引起了蚯蚓神经元细胞的紊乱。所获得的数据表明,相对低剂量的吡虫啉对诱导神经元细胞毒性是有效的。此外,神经毒性可以被认为是吡虫啉一般毒性的一种单独情况。因此,所提出的结果表明吡虫啉低剂量对非靶标生物的细胞毒性,并假设NSE下调可被估计为非昆虫物种神经系统中新烟碱类细胞毒性的生物标志物。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Low Doses of Imidacloprid Induce Oxidative Stress and Neural Cell Disruption in Earthworm Eisenia fetida
Imidacloprid is a widely used pesticide that belongs to the class of neonicotinoids. There is a piece of rising evidence that neonicotinoids exert cytotoxic effects in non-target organisms including vertebrate species such as mammals. Nevertheless, dose-limiting toxicity and molecular mechanisms of neonicotinoids' deleterious effects are still poorly understood. In accord to imidacloprid fate in the environment, the most of used pesticide is absorbed in the soil. Therefore, earthworms, which are prevailing soil organisms, could be considered as a target of neonicotinoids toxicity. The earthworm’s simple nervous system is a prospective model for neurotoxicological studies. We exposed earthworms to imidacloprid in a paper contact test with a doses range of 0.1‑0.4 µg/cm2 for 14 days. In the present work, we studied the imidacloprid effect on oxidative stress generation and neuronal marker neuron-specific enolase (NSE) expression. The exposure to imidacloprid induced a dose-dependent decrease in NSE. Both reactive oxygen species production and lipid peroxidation level were upregulated as well. Observed NSE decline suggests imidacloprid-caused disturbance in earthworm neuron cells. Obtained data have shown that relatively low doses of imidacloprid are potent to induce cytotoxicity in neurons. Furthermore, neurotoxicity could be recognized as one of an individual scenario of the general imidacloprid toxicity. Thus, presented results suggest the cytotoxicity of imidacloprid low doses in non-target organisms and hypothesize that NSE downregulation could be estimated as a biomarker of neonicotinoid cytotoxicity in a nervous system of non-insect species.
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来源期刊
International Letters of Natural Sciences
International Letters of Natural Sciences MULTIDISCIPLINARY SCIENCES-
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