Universidade Federal do Pará, Laboratório de Biologia Estrutural e Funcional, Belém, Pará, Brazil.
Instituto Evandro Chagas, Laboratório de Citogenética e Cultura de Tecidos-SAMAM, Ananindeua, Pará, Brazil.
Oxid Med Cell Longev. 2019 Nov 22;2019:8470857. doi: 10.1155/2019/8470857. eCollection 2019.
Human exposure to mercury (Hg) is primary associated with its organic form, methylmercury (MeHg), through the ingestion of contaminated seafood. However, Hg contamination is also positively correlated with the number of dental restorations, total surface of amalgam, and organic mercury concentration in the saliva. Among the cells existing in the oral cavity, human periodontal ligament fibroblast (hPLF) cells are important cells responsible for the production of matrix and extracellular collagen, besides sustentation, renewal, repair, and tissue regeneration. In this way, the present study is aimed at investigating the potential oxidative effects caused by MeHg on hPLF. Firstly, we analyzed the cytotoxic effects of MeHg (general metabolism status, cell viability, and mercury accumulation) followed by the parameters related to oxidative stress (total antioxidant capacity, GSH levels, and DNA damage). Our results demonstrated that MeHg toxicity increased in accordance with the rise of MeHg concentration in the exposure solutions (1-7 M) causing 100% of cell death at 7 M MeHg exposure. The general metabolism status was firstly affected by 2 M MeHg exposure (43.8 ± 1.7%), while a significant decrease of cell viability has arisen significantly only at 3 M MeHg exposure (68.7 ± 1.4%). The ratio among these two analyses (named fold change) demonstrated viable hPLF with compromised cellular machinery along with the range of MeHg exposure. Subsequently, two distinct MeHg concentrations (0.3 and 3 M) were chosen based on LC50 value (4.2 M). hPLF exposed to these two MeHg concentrations showed an intracellular Hg accumulation as a linear-type saturation curve indicating that metal accumulated diffusively in the cells, typical for metal organic forms such as methyl. The levels of total GSH decreased 50% at exposure to 3 M MeHg when compared to control. Finally, no alteration in the DNA integrity was observed at 0.3 M MeHg exposure, but 3 M MeHg caused significant damage. In conclusion, it was observed that MeHg exposure affected the general metabolism status of hPLF with no necessary decrease on the cell death. Additionally, although the oxidative imbalance in the hPLF was confirmed only at 3 M MeHg through the increase of total GSH level and DNA damage, the lower concentration of MeHg used (0.3 M) requires attention since the intracellular mercury accumulation may be toxic at chronic exposures.
人类接触汞(Hg)主要与其有机形式,甲基汞(MeHg)有关,通过摄入受污染的海鲜。然而,Hg 污染也与牙修复体数量、汞合金总表面积以及唾液中的有机汞浓度呈正相关。在口腔中存在的细胞中,人牙周韧带成纤维细胞(hPLF)是除了维持、更新、修复和组织再生外,负责产生基质和细胞外胶原的重要细胞。因此,本研究旨在研究 MeHg 对 hPLF 可能产生的氧化作用。首先,我们分析了 MeHg 的细胞毒性(一般代谢状态、细胞活力和汞积累),然后分析了与氧化应激相关的参数(总抗氧化能力、GSH 水平和 DNA 损伤)。我们的结果表明,MeHg 毒性随着暴露溶液中 MeHg 浓度的升高而增加(1-7μM),在 7μM MeHg 暴露时导致 100%的细胞死亡。一般代谢状态首先受到 2μM MeHg 暴露的影响(43.8±1.7%),而只有在 3μM MeHg 暴露时,细胞活力才显著下降(68.7±1.4%)。这两种分析的比值(称为倍数变化)显示了具有受损细胞机制的存活 hPLF,同时还显示了 MeHg 暴露的范围。随后,根据 LC50 值(4.2μM)选择了两个不同的 MeHg 浓度(0.3 和 3μM)。暴露于这两种 MeHg 浓度的 hPLF 显示出细胞内 Hg 积累呈线性饱和曲线,表明金属以扩散方式在细胞内积累,这是金属有机形式的典型特征,如甲基。当与对照组相比,暴露于 3μM MeHg 时,总 GSH 水平下降了 50%。最后,在 0.3μM MeHg 暴露时,未观察到 DNA 完整性的改变,但 3μM MeHg 导致了明显的损伤。总之,研究结果表明,MeHg 暴露影响 hPLF 的一般代谢状态,而不会导致细胞死亡。此外,尽管只有在 3μM MeHg 时才通过增加总 GSH 水平和 DNA 损伤证实 hPLF 中的氧化失衡,但使用较低浓度的 MeHg(0.3μM)也需要注意,因为慢性暴露时细胞内汞积累可能有毒。
