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多环芳烃吸附于纳米塑料及“特洛伊木马”效应作为斑马鱼线粒体毒性和多环芳烃定位的驱动因素

PAH SORPTION TO NANOPLASTICS AND THE TROJAN HORSE EFFECT AS DRIVERS OF MITOCHONDRIAL TOXICITY AND PAH LOCALIZATION IN ZEBRAFISH.

作者信息

Trevisan Rafael, Uzochukwu Daniel, Di Giulio Richard T

机构信息

Nicholas School of the Environment, Duke University, Durham, NC, USA.

出版信息

Front Environ Sci. 2020 Jul;8. doi: 10.3389/fenvs.2020.00078. Epub 2020 Jul 24.

DOI:10.3389/fenvs.2020.00078
PMID:34322495
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8315355/
Abstract

Plastics are world-wide pollutants that pose a potential threat to wildlife and human health. Small plastic particles, such as microplastics and nanoplastics, are easily ingested, and can act as a Trojan Horse by carrying microorganisms and pollutants. This study investigated the potential role of the Trojan Horse effect in the toxicity of nanoplastics to the vertebrate model organism, zebrafish (Danio rerio). First, we investigated if this effect could affect the toxicity of nanoplastics. Second, we analyzed if it could contribute to the biodistribution of the associated contaminants. And third, we focused on its effect on the mitochondrial toxicity of nanoplastics. We incubated 44 nm polystyrene nanoparticles with a real-world mixture of polycyclic aromatic hydrocarbons (PAHs) for 7 days and removed the free PAHs by ultrafiltration. We dosed embryos with 1 ppm of nanoplastics (NanoPS) or PAH-sorbed nanoplastics (PAH-NanoPS). Neither type of plastic particle caused changes in embryonic and larval development. Fluorescence microscopy and increased EROD activity suggested the uptake of PAHs in larvae exposed to PAH-NanoPS. This coincided with higher concentrations in the yolk sac and the brain. However, PAH-only exposure leads to their accumulation in the yolk sac but not in the brain, suggesting that that the spatial distribution of bioaccumulated PAHs can differ depending on their source of exposure. Both nanoplastic particles affected mitochondrial energy metabolism but caused different adverse effects. While NanoPS decreased NADH production, PAH-NanoPS decreased mitochondrial coupling efficiency and spare respiratory capacity. In summary, the addition of PAHs to the surface of nanoplastics did not translate into increased developmental toxicity. Low levels of PAHs were accumulated in the organisms, and the transfer of PAHs seems to happen in tissues and possibly organelles where nanoplastics accumulate. Disruption of the energy metabolism in the mitochondria may be a key factor in the toxicity of nanoplastics, and the Trojan Horse effect may amplify this effect.

摘要

塑料是全球性污染物,对野生动物和人类健康构成潜在威胁。小塑料颗粒,如微塑料和纳米塑料,很容易被摄入,并可能通过携带微生物和污染物而起到特洛伊木马的作用。本研究调查了特洛伊木马效应在纳米塑料对脊椎动物模式生物斑马鱼(Danio rerio)毒性中的潜在作用。首先,我们研究了这种效应是否会影响纳米塑料的毒性。其次,我们分析了它是否会影响相关污染物的生物分布。第三,我们关注其对纳米塑料线粒体毒性的影响。我们将44纳米的聚苯乙烯纳米颗粒与多环芳烃(PAHs)的实际混合物孵育7天,然后通过超滤去除游离的PAHs。我们给胚胎投喂1 ppm的纳米塑料(NanoPS)或吸附了PAH的纳米塑料(PAH-NanoPS)。两种类型的塑料颗粒都未引起胚胎和幼体发育的变化。荧光显微镜检查和EROD活性增加表明,暴露于PAH-NanoPS的幼体中PAHs被摄取。这与卵黄囊和大脑中较高的浓度相吻合。然而,仅PAH暴露会导致其在卵黄囊中积累,但不会在大脑中积累,这表明生物累积的PAHs的空间分布可能因其暴露源而异。两种纳米塑料颗粒都影响线粒体能量代谢,但产生了不同的不利影响。虽然NanoPS降低了NADH的产生,但PAH-NanoPS降低了线粒体偶联效率和备用呼吸能力。总之,在纳米塑料表面添加PAHs并没有转化为更高的发育毒性。低水平的PAHs在生物体中积累,并且PAHs的转移似乎发生在纳米塑料积累的组织甚至可能是细胞器中。线粒体能量代谢的破坏可能是纳米塑料毒性的关键因素,而特洛伊木马效应可能会放大这种影响。

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