Silver Nanoparticle Cytotoxicity and Antidote Proteins against Silver Toxicity in Paramecium

Q4 Engineering
Taiki Abe, K. Haneda, N. Haga
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引用次数: 2

Abstract

35 Introduction Silver has been deeply associated with human life in areas including tableware, accessories and both surgical and dental materials. In the recent advancement of nanotechnology, silver nanoparticles have been used as chemical catalysis, in medical and electronic devices and as antimicrobial agents. On the other hand, the cytotoxicity of silver nanoparticles have been increasingly reported in many organisms [1]; for instance, apoptosis with DNA degradation in human alveolar epithelial cells [2], a decrease in dopamine production in PC-12 (cultured neuronal phenotype) [3], a decrease in mitochondrial functions in a rat liver derived cell [4], an antimicrobial agent against Escherichia coli [5], and bio-concentration in Psudomonas aeroginosa [6]. For the analysis of molecular events associated with silver cytotoxicity, rat alveolar macrophages were selected as a model assay system system and reactive oxygen species (ROS) were found as one of the potent candidates. The production of ROS was nanoparticle-size dependent and oxidative stress was considered as a predominant mechanism of the cytotoxicity [7]. In this study, we used Paramecium, a free-living unicellular eukaryotic organism in fresh water, as a bioassay system for silver cytotoxicity. The Paramecium system (P system) provides several advantages, 1) P system enables us to examine single cell behavior involving excitable membrane and ciliary movement, 2) P system enables us to examine cytotoxicity by application to the inside of a cell, 3) P system has various types of cellular functions giving a stable and sensitive bioassay. In this study, we will demonstrate that silver nanoparticles produce silver ions which associate with the main cause of cytotoxicity and, in addition, the discovery of some proteins which decrease the cytotoxicity of silver ions. Silver Nanoparticle Cytotoxicity and Antidote Proteins against Silver Toxicity in Paramecium
银纳米粒子对草履虫的细胞毒性和银毒性解毒剂蛋白
银在餐具、配件以及外科和牙科材料等领域与人类生活密切相关。在纳米技术的最新进展中,纳米银已被用作化学催化剂、医疗和电子设备以及抗菌剂。另一方面,银纳米颗粒的细胞毒性在许多生物体中被越来越多地报道。例如,人肺泡上皮细胞[2]中DNA降解的凋亡,PC-12(培养的神经元表型)[3]中多巴胺产生的减少,大鼠肝源性细胞[4]中线粒体功能的降低,抗大肠杆菌[5]的抗菌药物,以及气产假单胞菌[6]的生物浓度。为了分析与银细胞毒性相关的分子事件,我们选择大鼠肺泡巨噬细胞作为模型实验系统,发现活性氧(ROS)是一个强有力的候选系统。活性氧的产生依赖于纳米颗粒大小,氧化应激被认为是细胞毒性[7]的主要机制。在本研究中,我们使用淡水中自由生活的单细胞真核生物草履虫作为银细胞毒性的生物测定系统。草履虫系统(P系统)提供了几个优点,1)P系统使我们能够检查单个细胞的行为,包括可兴奋膜和纤毛运动,2)P系统使我们能够通过应用于细胞内部来检查细胞毒性,3)P系统具有各种类型的细胞功能,提供稳定和敏感的生物测定。在这项研究中,我们将证明银纳米颗粒产生的银离子与细胞毒性的主要原因有关,此外,还发现了一些降低银离子细胞毒性的蛋白质。银纳米粒子对草履虫的细胞毒性和银毒性解毒剂蛋白
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来源期刊
Nano Biomedicine
Nano Biomedicine Engineering-Biomedical Engineering
CiteScore
0.30
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