Ragusa Antonio, Cristiano Loredana, Di Vinci Pierluigi, Familiari Giuseppe, Nottola Stefania Annarita, Macchiarelli Guido, Svelato Alessandro, De Luca Caterina, Rinaldo Denise, Neri Isabella, Facchinetti Fabio
Department of Obstetrics and Gynecology, Maggiore Hospital Carlo Alberto Pizzardi, Bologna, Italy.
Section of Human Anatomy, Electron Microscopy Laboratory "Pietro M. Motta", Department of Anatomy, Histology, Forensic Medicine and Orthopaedics, Sapienza University, Rome, Italy.
Front Cell Dev Biol. 2025 Feb 24;13:1539600. doi: 10.3389/fcell.2025.1539600. eCollection 2025.
In the human placenta, we have detected the MPs by Raman microspectroscopy analysis and, for the first time, with transmission electron microscopy. MPs fragments have been localized in different compartments of placental tissue, free in the cytoplasm and within organelles like lysosomes. Moreover, their presence has been correlated with ultrastructural alterations of some cell organelles, typical of metabolic stress, mainly dilated rough endoplasmic reticulum and numerous swollen electrodense mitochondria, as well as signs derived from involuting organelles. As a result, we have speculated that microplastics in the placenta could be responsible for pathological traits activation such as oxidative stress, apoptosis, and inflammation causing long-term effects on the health of the mother and child. To demonstrate the cytotoxicity of PS-NPs on the placenta and confirm the results, we performed experiments on a trophoblast human cell line, the HTR8/SVneo cells.
HTR8/SVneo cells were treated, for 24 h and 48h, with increasing concentrations (10, 25, 50, 75, and 100 μg/mL) of 0.05 µm polystyrene (PS) and cellular viability was evaluated by Counting Kit-8. Fluorescent PS-NPs examined under fluorescence/confocal microscopy were used to investigate the internalization of plastics in the placenta cells. Transmission electron microscopy was used to evaluate possible PS-NPs-dependent ultrastructural alterations of cells and organelles.
Our study shows that starting from 24 h exposure, PS-NPs treatment, at 50 μg/mL dose, has a cytotoxic effect on placental cells, causing the death of 40% of cells and affecting the morphology of the surviving cells. In addition, PS-NPs alter the ultrastructure of some organelles in the surviving cells, like those we have already described . We found that NPs enter the cells, affecting the endoplasmic reticulum and mitochondria morphology, accumulating as aggregates within lysosome-like organelles. Interestingly these aggregates become larger as the concentration of NPs increases. We speculated that the accumulation of NPs inside lysosome-like organelles could result from a prolonged and impossible attempt by the cell to remove and destroy PS. This would lead to ER and mitochondrial stress, impairing mitochondria/ER functions and oxidative stress, thus activating the apoptotic pathway and suggesting that PS-NPs could act as a cell stressor, leading to the death of cells. In support of our hypothesis, we also found NPs associated with morphological signs of cellular regression and degeneration, such as the presence of a highly vacuolized cytoplasm, dilatation, and vesiculation of ER, associated with the uncoupling/loss of associated mitochondria, cytoplasmic fragments, and free organelles deriving from cellular lysis.
Based on electron microscopy and immunofluorescence analysis and study, we demonstrate the cytotoxicity of PS-NPs in trophoblast cells together with ultrastructural alterations associated with cellular regression and degeneration typical of metabolic stress. An abnormal amount of NPs in the cells might determine a persistent cellular alarm CDR (cell danger response), the evolutionarily conserved metabolic response that protects the cells and hosts from harm triggered by chemical (as in the case of NPs/MPs), physical, or biological agents that exceed the cellular capacity for homeostasis. This study could further help to demonstrate that the inevitable exposure of MPs/NPs in the environment, which characterizes the modern world, might be partially responsible for the epidemic of non-transmissible disease.
在人胎盘中,我们通过拉曼光谱分析首次借助透射电子显微镜检测到了微塑料。微塑料碎片已定位在胎盘组织的不同区域,游离于细胞质中以及溶酶体等细胞器内。此外,它们的存在与一些细胞器的超微结构改变相关,这些改变是代谢应激的典型表现,主要是扩张的粗面内质网和大量肿胀的电子致密线粒体,以及源自退化细胞器的迹象。因此,我们推测胎盘中的微塑料可能是激活诸如氧化应激、细胞凋亡和炎症等病理特征的原因,从而对母婴健康产生长期影响。为了证明聚苯乙烯纳米颗粒(PS-NPs)对胎盘的细胞毒性并证实结果,我们对人滋养层细胞系HTR8/SVneo细胞进行了实验。
用浓度递增(10、25、50、75和100μg/mL)的0.05μm聚苯乙烯(PS)处理HTR8/SVneo细胞24小时和48小时,并通过细胞计数试剂盒-8评估细胞活力。在荧光/共聚焦显微镜下检查的荧光PS-NPs用于研究塑料在胎盘细胞中的内化情况。透射电子显微镜用于评估细胞和细胞器可能的PS-NPs依赖性超微结构改变。
我们的研究表明,从暴露24小时开始,50μg/mL剂量的PS-NPs处理对胎盘细胞具有细胞毒性,导致40%的细胞死亡并影响存活细胞的形态。此外,PS-NPs改变了存活细胞中一些细胞器的超微结构,就像我们之前描述的那样。我们发现纳米颗粒进入细胞,影响内质网和线粒体形态,在类似溶酶体的细胞器内聚集成聚集体。有趣的是,随着纳米颗粒浓度的增加,这些聚集体变得更大。我们推测纳米颗粒在类似溶酶体的细胞器内的积累可能是由于细胞长时间无法清除和破坏PS所致。这将导致内质网和线粒体应激,损害线粒体/内质网功能和氧化应激,从而激活凋亡途径,并表明PS-NPs可能作为细胞应激源,导致细胞死亡。为支持我们的假设,我们还发现纳米颗粒与细胞退化和变性的形态学迹象相关,例如存在高度空泡化的细胞质、内质网的扩张和泡状化,伴有相关线粒体的解偶联/丧失、细胞质碎片以及源自细胞裂解的游离细胞器。
基于电子显微镜和免疫荧光分析及研究,我们证明了PS-NPs在滋养层细胞中的细胞毒性以及与代谢应激典型的细胞退化和变性相关的超微结构改变。细胞中异常数量的纳米颗粒可能会引发持续的细胞警报CDR(细胞危险反应),这是一种进化上保守的代谢反应,可保护细胞和宿主免受化学物质(如纳米颗粒/微塑料的情况)、物理或生物制剂引发的伤害,这些物质超过了细胞维持体内平衡的能力。这项研究可能进一步有助于证明现代世界环境中不可避免的微塑料/纳米颗粒暴露可能部分导致了非传染性疾病的流行。
