髓过氧化物酶与工业污染物 6-PPD的相互作用:活性代谢物的潜在途径

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC ACS Applied Electronic Materials Pub Date : 2024-10-03 DOI:10.1021/acs.chemrestox.4c0026510.1021/acs.chemrestox.4c00265
Steven Lockhart, Dinesh Babu, Newton H. Tran, Béla Reiz, Lusine Tonoyan and Arno G. Siraki*, 
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引用次数: 0

摘要

据报道,6-PPD(N-[1,3-二甲基丁基]-N′-苯基-对苯二胺)是一种工业抗氧化剂,也是一种环境污染物。研究发现,它对鲑鱼和其他潜在的水生生物有剧毒。然而,6-PPD 对人体的毒性仍然未知。众所周知,中性粒细胞酶髓过氧化物酶(MPO)可催化异生物的新陈代谢;因此,我们使用富含 MPO 的 HL-60 细胞系研究了它在 6-PPD 细胞毒性中的作用。研究人员利用紫外-可见光谱法和液相色谱-质谱法(LC/MS)研究了 MPO 介导的 6-PPD 氧化作用,并确定了在谷胱甘肽(GSH)不存在和存在的情况下可能存在的代谢物。评估了 6-PPD 的细胞毒性、对线粒体膜电位(MMP)的影响以及在 HL-60 细胞中的 GSH 消耗能力。使用电子顺磁共振(EPR)测定了 DMPO 的 GSH 自由基形成,并使用 mito-TEMPO-H 探针评估了线粒体衍生的超氧化物。通过将抗氧化剂和 MPO 抑制剂与 HL-60 细胞预孵育,对 6-PPD 诱导的细胞损伤途径进行了评估。对 MPO 催化的 6-PPD 氧化反应进行的紫外-可见光分析表明,6-PPD 的光谱发生了变化,而 GSH 的加入则改变了光谱,表明可能形成了 GSH 共轭物。LC/MS 显示形成了多种产物,包括 GSH-6-PPD 共轭物和 GSH 与 4-羟基二苯胺(已知的 6-PPD 降解剂)的共轭物,这可能会诱发细胞毒性。6-PPD 显示出浓度依赖性细胞毒性,细胞 GSH 水平因 6-PPD 而降低。同样,MMP 的水平也下降了,这表明线粒体去极化。此外,线粒体超氧化物的 EPR 自旋探针与 6-PPD 的浓度呈正相关,EPR 自旋捕获表明 6-PPD 的浓度与使用 MPO/H2O2 的 GSH 自由基信号强度有关。GSH 前体 NAC 对 6-PPD 有部分细胞保护作用,但 MPO 抑制剂 PF-1355 却没有明显的细胞保护作用。我们的研究结果表明,MPO 可能是 6-PPD 对人体毒性的潜在催化剂。然而,MPO 抑制剂并没有明显影响细胞活力,这表明MPO 是一种独立的毒性途径。这些发现值得进行更深入的研究,以确定 6-PPD 在哺乳动物中的毒性途径。
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The Interaction of Myeloperoxidase with the Industrial Contaminant 6-PPD: A Potential Pathway for Reactive Metabolites

6-PPD (N-[1,3-dimethylbutyl]-N′-phenyl-p-phenylenediamine) is an industrial antioxidant reported to be an environmental contaminant. It was found to be highly toxic to coho salmon and potentially other aquatic organisms. The toxicity of 6-PPD in humans, however, remains unknown. The neutrophil enzyme myeloperoxidase (MPO) is known to catalyze xenobiotic metabolism; therefore, its role in 6-PPD cytotoxicity was investigated using the MPO-rich HL-60 cell line. UV–visible spectroscopy and liquid chromatography–mass spectrometry (LC/MS) were performed to investigate the MPO-mediated oxidation of 6-PPD and identify possible metabolites in the absence and presence of glutathione (GSH). 6-PPD’s cytotoxicity, effect on mitochondrial membrane potential (MMP), and GSH-depleting ability in HL-60 cells were assessed. Electron paramagnetic resonance (EPR) was used to determine GSH radical formation using DMPO, and mitochondrial-derived superoxide was assessed with the mito-TEMPO-H probe. Evaluation of the 6-PPD-induced cellular injury pathways was performed by preincubating an antioxidant and an MPO inhibitor with HL-60 cells. UV–vis analysis of MPO-catalyzed oxidation of 6-PPD demonstrated changes in the 6-PPD spectrum, whereas the addition of GSH altered the spectrum, indicating possible GSH conjugate formation. LC/MS showed the formation of multiple products, including GSH-6-PPD conjugates and a GSH conjugate to a 4-hydroxydiphenylamine (a known 6-PPD degradant), which could potentially induce cytotoxicity. 6-PPD demonstrated concentration-dependent cytotoxicity, and cellular GSH levels were decreased by 6-PPD. Similarly, the level of MMP decreased, suggesting mitochondrial depolarization. Furthermore, the EPR spin probe for mitochondrial superoxide showed a positive relationship with 6-PPD concentration, and EPR spin-trapping demonstrated 6-PPD concentration-dependent GSH radical signal intensity using MPO/H2O2. The GSH precursor, NAC, demonstrated partial cytoprotection against 6-PPD; however, the MPO inhibitor PF-1355 surprisingly showed no significant cytoprotective effect. Our results suggest that MPO could be a potential catalyst for 6-PPD toxicity in humans. However, MPO inhibition did not significantly affect cellular viability, suggesting an MPO-independent toxicity pathway. These findings warrant a deeper investigation to determine 6-PPD mammalian toxicity pathways.

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