ROS/mtROS promotes TNTs formation via the PI3K/AKT/mTOR pathway to protect against mitochondrial damages in glial cells induced by engineered nanomaterials

IF 7.2 1区 医学 Q1 TOXICOLOGY Particle and Fibre Toxicology Pub Date : 2024-01-15 DOI:10.1186/s12989-024-00562-0
Xinpei Lin, Wei Wang, Xiangyu Chang, Cheng Chen, Zhenkun Guo, Guangxia Yu, Wenya Shao, Siying Wu, Qunwei Zhang, Fuli Zheng, Huangyuan Li
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Abstract

As the demand and application of engineered nanomaterials have increased, their potential toxicity to the central nervous system has drawn increasing attention. Tunneling nanotubes (TNTs) are novel cell–cell communication that plays a crucial role in pathology and physiology. However, the relationship between TNTs and nanomaterials neurotoxicity remains unclear. Here, three types of commonly used engineered nanomaterials, namely cobalt nanoparticles (CoNPs), titanium dioxide nanoparticles (TiO2NPs), and multi-walled carbon nanotubes (MWCNTs), were selected to address this limitation. After the complete characterization of the nanomaterials, the induction of TNTs formation with all of the nanomaterials was observed using high-content screening system and confocal microscopy in both primary astrocytes and U251 cells. It was further revealed that TNT formation protected against nanomaterial-induced neurotoxicity due to cell apoptosis and disrupted ATP production. We then determined the mechanism underlying the protective role of TNTs. Since oxidative stress is a common mechanism in nanotoxicity, we first observed a significant increase in total and mitochondrial reactive oxygen species (namely ROS, mtROS), causing mitochondrial damage. Moreover, pretreatment of U251 cells with either the ROS scavenger N-acetylcysteine or the mtROS scavenger mitoquinone attenuated nanomaterial-induced neurotoxicity and TNTs generation, suggesting a central role of ROS in nanomaterials-induced TNTs formation. Furthermore, a vigorous downstream pathway of ROS, the PI3K/AKT/mTOR pathway, was found to be actively involved in nanomaterials-promoted TNTs development, which was abolished by LY294002, Perifosine and Rapamycin, inhibitors of PI3K, AKT, and mTOR, respectively. Finally, western blot analysis demonstrated that ROS and mtROS scavengers suppressed the PI3K/AKT/mTOR pathway, which abrogated TNTs formation. Despite their biophysical properties, various types of nanomaterials promote TNTs formation and mitochondrial transfer, preventing cell apoptosis and disrupting ATP production induced by nanomaterials. ROS/mtROS and the activation of the downstream PI3K/AKT/mTOR pathway are common mechanisms to regulate TNTs formation and mitochondrial transfer. Our study reveals that engineered nanomaterials share the same molecular mechanism of TNTs formation and intercellular mitochondrial transfer, and the proposed adverse outcome pathway contributes to a better understanding of the intercellular protection mechanism against nanomaterials-induced neurotoxicity.
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ROS/mtROS通过PI3K/AKT/mTOR途径促进TNTs的形成,从而保护神经胶质细胞免受工程纳米材料诱导的线粒体损伤
随着工程纳米材料需求和应用的增加,其对中枢神经系统的潜在毒性也引起了越来越多的关注。隧道纳米管(TNTs)是一种新型的细胞间通信方式,在病理学和生理学中发挥着至关重要的作用。然而,TNTs 与纳米材料神经毒性之间的关系仍不清楚。本文选择了三种常用的工程纳米材料,即钴纳米颗粒(CoNPs)、二氧化钛纳米颗粒(TiO2NPs)和多壁碳纳米管(MWCNTs)来解决这一局限性。在对纳米材料进行完整表征后,利用高含量筛选系统和共聚焦显微镜在原代星形胶质细胞和 U251 细胞中观察了所有纳米材料诱导 TNTs 形成的情况。研究进一步发现,TNT的形成可保护细胞免受纳米材料诱导的神经毒性,这种毒性是由于细胞凋亡和ATP生成紊乱引起的。随后,我们确定了 TNTs 发挥保护作用的机制。由于氧化应激是纳米毒性的常见机制,我们首先观察到总活性氧和线粒体活性氧(即 ROS,mtROS)显著增加,导致线粒体损伤。此外,用ROS清除剂N-乙酰半胱氨酸或mtROS清除剂线粒体醌预处理U251细胞,可减轻纳米材料诱导的神经毒性和TNTs的生成,这表明ROS在纳米材料诱导的TNTs形成中起着核心作用。此外,研究还发现 ROS 的一个重要下游通路--PI3K/AKT/mTOR 通路--积极参与了纳米材料促进 TNTs 的形成,而 PI3K、AKT 和 mTOR 的抑制剂 LY294002、Perifosine 和雷帕霉素分别抑制了这一通路。最后,Western 印迹分析表明,ROS 和 mtROS 清除剂抑制了 PI3K/AKT/mTOR 通路,从而抑制了 TNTs 的形成。尽管各种纳米材料具有生物物理特性,但它们会促进TNTs的形成和线粒体转移,阻止细胞凋亡并破坏纳米材料诱导的ATP生成。ROS/mtROS和下游PI3K/AKT/mTOR通路的激活是调控TNTs形成和线粒体转移的常见机制。我们的研究揭示了工程纳米材料具有相同的TNTs形成和细胞间线粒体转移的分子机制,所提出的不良后果途径有助于更好地理解纳米材料诱导的神经毒性的细胞间保护机制。
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来源期刊
CiteScore
15.90
自引率
4.00%
发文量
69
审稿时长
6 months
期刊介绍: Particle and Fibre Toxicology is an online journal that is open access and peer-reviewed. It covers a range of disciplines such as material science, biomaterials, and nanomedicine, focusing on the toxicological effects of particles and fibres. The journal serves as a platform for scientific debate and communication among toxicologists and scientists from different fields who work with particle and fibre materials. The main objective of the journal is to deepen our understanding of the physico-chemical properties of particles, their potential for human exposure, and the resulting biological effects. It also addresses regulatory issues related to particle exposure in workplaces and the general environment. Moreover, the journal recognizes that there are various situations where particles can pose a toxicological threat, such as the use of old materials in new applications or the introduction of new materials altogether. By encompassing all these disciplines, Particle and Fibre Toxicology provides a comprehensive source for research in this field.
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