神经毒性
转录组
诱导多能干细胞
基因敲除
生物
活力测定
神经突
药理学
细胞生物学
细胞凋亡
毒性
生物化学
医学
基因表达
体外
基因
内科学
胚胎干细胞
作者
Zhengbao Zhang,Xiang Li,Shuyun Jiang,Chunfang Qiu,Ping Guo,Ziwei Wang,Chi Xu,Liying Zhang,Xingyu Ma,Shen Chen,Xiumei Xing,Liping Chen,Qing Wang,Huimin Ma,Xiao‐Wen Zeng,Wen Chen,Daochuan Li
标识
DOI:10.1016/j.taap.2022.116109
摘要
Airborne nano-scale particulate matter (nPM) exposure is a risk factor for neurological diseases. However, to date, there has been no comprehensive evaluation of ambient nPM's neurotoxicity. We examined the toxic effects of nPM on human neurons derived from induced pluripotent stem cells (iPSCs) at doses ranging from 0 to 200 μg/mL, and employed whole-genome RNA-sequencing in different dose groups to gain further insight into the neurotoxicity of ambient nPM. Our findings showed that nPM was absorbed by neurons, and induced a variety of toxic effects. The apical benchmark dose lower confidence bound (aBMDL) values of each effect endpoint were ranked as follows, in ascending order: mitochondrial membrane potential, neurite length, early apoptosis, cell viability. BMD analysis based on transcriptomic data revealed that the point of departure (PoD) of the 20 pathways with the lowest p -values (0.75 μg/mL), the top 20 upstream regulators (0.79 μg/mL) and the neurological diseases (0.77 μg/mL) could be appropriate for nPM neurotoxicity evaluation. The transcriptomic PoDs (tPoDs) were similar to apical PoDs (aPoDs) since their absolute fold differences were within 10-fold. Further analysis of the transcriptomic data revealed that nPM exposure could disturb the pathways related to ferroptosis, neurotransmitters, xenobiotic metabolism, etc., which might be critical in regulating nPM neurotoxicity. We also found that low-dose nPM induced cytokine signaling pathways, while high doses of nPM activated cell-cycle regulation and DNA repair pathways. Our results indicate that BMD modeling based on transcriptomic data could be useful in illustrating the neurotoxic mechanism, and also could be a promising method for evaluating the potential health risks of nPM. • Established a toxicity testing system based on neurons derived from human iPSC. • Evaluated the neurotoxicity of airborne nano-scale particles (nPM) in neurons. • Transcriptomic PoDs of nPM were highly consistent with apical PoDs. • Ferroptosis and axonal guidance pathways might mediate nPMs’ neurotoxicity.
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