College of Animal Science and Technology, Northwest A&F University, Yangling 712100, China.
College of Animal Science and Technology, Northwest A&F University, Yangling 712100, China.
Sci Total Environ. 2024 Feb 20;912:169430. doi: 10.1016/j.scitotenv.2023.169430. Epub 2023 Dec 20.
Nanoplastics (NPs) and arsenic (As) are toxic pollutants prevalent on the earth and have gained considerable attention in recent decades. Although numerous studies reported NPs and As can cause neurotoxicity there are still significant knowledge gaps in illustrating their combined toxicity and its mechanism. In this study, the co-exposure of environmentally relevant concentrations of NPs and As caused neurobehavioral toxicity in zebrafish, as evidenced by reduced swimming ability, anxiety and impaired short-term learning memory. Potentially, its toxicity mechanism is through disrupting the homeostasis of microbiota-intestine-brain axis in zebrafish. Specifically, the co-exposure reduced the 5-hydroxytryptamine (5-HT) production in intestine, which led to lower levels of 5-HT transported by the blood circulation to the brain. Ultimately, neurobehavior was adversely affected by the reduced binding of 5-HT to its receptors. Intestine, the primary source of 5-HT, its impaired health (aggravation in oxidative stress, mitochondrial damage and histopathological alterations) induced the dysregulation in the 5-HT system, which may be induced by the increased accumulation of As in the intestine by the co-exposure. Besides, the reduced 5-HT levels were correlated with decreased Firmicutes and Protecbacteria and increased Actinobacteriota and Chloroflexi in intestines. Potentially, intestinal microbiota adversely regulates the intestine-brain axis by reducing SCFAs levels. Thus, the alteration of intestinal microbiota structure may be the other reason for the dysregulation of intestine-brain axis. In summary, co-exposure of NPs and As induced neurobehavior toxicity probably through disrupting the homeostasis of microbiota-intestine-brain axis. This study provides insights into assessing the environmental health risks of the pollution of NPs and As to aquatic organisms.
纳米塑料 (NPs) 和砷 (As) 是地球上普遍存在的有毒污染物,近几十年来受到了相当大的关注。尽管有大量研究报道 NPs 和 As 会导致神经毒性,但对于它们的联合毒性及其机制仍存在重大知识空白。在这项研究中,环境相关浓度的 NPs 和 As 的共同暴露导致斑马鱼出现神经行为毒性,表现为游泳能力下降、焦虑和短期学习记忆受损。其毒性机制可能是通过破坏斑马鱼肠道-大脑轴的微生物群落平衡。具体来说,共同暴露降低了肠道 5-羟色胺 (5-HT) 的产生,导致通过血液循环输送到大脑的 5-HT 水平降低。最终,神经行为受到 5-HT 与受体结合减少的不利影响。肠道是 5-HT 的主要来源,其健康受损(氧化应激加剧、线粒体损伤和组织病理学改变)导致 5-HT 系统失调,这可能是由于共同暴露导致 As 在肠道中的积累增加所致。此外,肠道中 5-HT 水平的降低与厚壁菌门和变形菌门减少以及放线菌门和绿弯菌门增加有关。肠道微生物群可能通过降低 SCFAs 水平来调节肠道-大脑轴,从而导致 5-HT 系统失调。因此,肠道微生物群落结构的改变可能是肠道-大脑轴失调的另一个原因。总之,NPs 和 As 的共同暴露可能通过破坏肠道-大脑轴的微生物群落平衡来诱导神经行为毒性。本研究为评估 NPs 和 As 污染对水生生物的环境健康风险提供了新的见解。
