a Central Ohio Poison Center , Columbus , OH , USA.
b Department of Pediatrics , College of Medicine, Ohio State University , Columbus , OH , USA.
Clin Toxicol (Phila). 2018 May;56(5):313-326. doi: 10.1080/15563650.2017.1400555. Epub 2017 Nov 10.
There is increasing evidence that the pathophysiological target of mercury is in fact selenium, rather than the covalent binding of mercury to sulfur in the body's ubiquitous sulfhydryl groups. The role of selenium in mercury poisoning is multifaceted, bidirectional, and central to understanding the target organ toxicity of mercury.
An initial search was performed using Medline/PubMed, Toxline, Google Scholar, and Google for published work on mercury and selenium. These searches yielded 2018 citations. Publications that did not evaluate selenium status or evaluated environmental status (e.g., lake or ocean sediment) were excluded, leaving approximately 500 citations. This initial selection was scrutinized carefully and 117 of the most relevant and representative references were selected for use in this review. Binding of mercury to thiol/sulfhydryl groups: Mercury has a lower affinity for thiol groups and higher affinity for selenium containing groups by several orders of magnitude, allowing for binding in a multifaceted way. The established binding of mercury to thiol moieties appears to primarily involve the transport across membranes, tissue distribution, and enhanced excretion, but does not explain the oxidative stress, calcium dyshomeostasis, or specific organ injury seen with mercury. Effects of mercury on selenium and the role this plays in the pathophysiology of mercury toxicity: Mercury impairs control of intracellular redox homeostasis with subsequent increased intracellular oxidative stress. Recent work has provided convincing evidence that the primary cellular targets are the selenoproteins of the thioredoxin system (thioredoxin reductase 1 and thioredoxin reductase 2) and the glutathione-glutaredoxin system (glutathione peroxidase). Mercury binds to the selenium site on these proteins and permanently inhibits their function, disrupting the intracellular redox environment. A number of other important possible target selenoproteins have been identified, including selenoprotein P, K, and T. Impairment of the thioredoxin and glutaredoxin systems allows for proliferation intracellular reactive oxygen species which leads to glutamate excitosis, calcium dyshomeostasis, mitochondrial injury/loss, lipid peroxidation, impairment of protein repair, and apoptosis. Methylmercury is a more potent inhibitor of the thioredoxin system, partially explaining its increased neurotoxicity. A second important mechanism is due to the high affinity of mercury for selenium and the subsequent depletion of selenium stores needed for insertion into de novo generation of replacement selenoproteins. This mercury-induced selenium deficiency state inhibits regeneration of the selenoproteins to restore the cellular redox environment. The effects of selenium on mercury and the role this plays in biological response to mercury: Early research suggested selenium may provide a protective role in mercury poisoning, and with limitations this is true. The roles selenium plays in this reduction of mercury toxicity partially depends on the form of mercury and may be multifaceted including: 1) facilitating demethylation of organic mercury to inorganic mercury; 2) redistribution of mercury to less sensitive target organs; 3) binding to inorganic mercury and forming an insoluble, stable and inert Hg:Se complex; 4) reduction of mercury absorption from the GI tract; 5) repletion of selenium stores (reverse selenium deficiency); and 6) restoration of target selenoprotein activity and restoring the intracellular redox environment. There is conflicting evidence as to whether selenium increases or hinders mercury elimination, but increased mercury elimination does not appear to be a major role of selenium. Selenium supplementation has been shown to restore selenoprotein function and reduce the toxicity of mercury, with several significant limitations including: the form of mercury (methylmercury toxicity is less responsive to amelioration) and mercury dose.
The interaction with selenium is a central feature in mercury toxicity. This interaction is complex depending on a number of features such as the form of mercury, the form of selenium, the organ and dose. The previously suggested "protective effect" of selenium against mercury toxicity may in fact be backwards. The effect of mercury is to produce a selenium deficiency state and a direct inhibition of selenium's role in controlling the intracellular redox environment in organisms. Selenium supplementation, with limitations, may have a beneficial role in restoring adequate selenium status from the deficiency state and mitigating the toxicity of mercury.
越来越多的证据表明,汞的病理生理靶标实际上是硒,而不是汞与体内无处不在的巯基基团中的硫的共价结合。硒在汞中毒中的作用是多方面的、双向的,是理解汞的靶器官毒性的核心。
最初使用 Medline/PubMed、Toxline、Google Scholar 和 Google 搜索了关于汞和硒的已发表文献。这些搜索产生了 2018 条引文。排除了未评估硒状态或评估环境状态(例如,湖泊或海洋沉积物)的出版物,留下了大约 500 条引文。仔细审查了这一初步选择,并选择了最相关和最具代表性的 117 篇参考文献用于本综述。汞与硫醇/巯基的结合:汞与硫醇基团的亲和力较低,与含硒基团的亲和力高几个数量级,允许以多种方式结合。汞与巯基部分的结合似乎主要涉及跨膜运输、组织分布和增强排泄,但不能解释与汞一起看到的氧化应激、钙动态失衡或特定器官损伤。汞对硒的影响及其在汞毒性病理生理学中的作用:汞破坏了细胞内氧化还原稳态的控制,随后导致细胞内氧化应激增加。最近的工作提供了令人信服的证据,表明主要的细胞靶标是硫氧还蛋白系统(硫氧还蛋白还原酶 1 和硫氧还蛋白还原酶 2)和谷胱甘肽-谷胱甘肽系统(谷胱甘肽过氧化物酶)的硒蛋白。汞与这些蛋白质上的硒结合位点结合,永久性地抑制其功能,破坏细胞内氧化还原环境。已经确定了许多其他重要的可能靶硒蛋白,包括硒蛋白 P、K 和 T。硫氧还蛋白和谷胱甘肽系统的损伤允许细胞内活性氧的增殖,导致谷氨酸兴奋、钙动态失衡、线粒体损伤/丧失、脂质过氧化、蛋白质修复受损和细胞凋亡。甲基汞是更有效的硫氧还蛋白系统抑制剂,部分解释了其增加的神经毒性。第二个重要机制是由于汞与硒的高亲和力,随后耗尽了生成新硒蛋白所需的硒储存,从而抑制了细胞内氧化还原环境的恢复。这种汞诱导的硒缺乏状态抑制了硒蛋白的再生,以恢复细胞内的氧化还原环境。硒对汞的影响及其在生物对汞的反应中的作用:早期研究表明,硒可能在汞中毒中提供保护作用,在一定程度上是这样。硒在降低汞毒性中的作用部分取决于汞的形式,可能是多方面的,包括:1)促进有机汞向无机汞的去甲基化;2)将汞重新分配到敏感性较低的靶器官;3)与无机汞结合形成不溶、稳定和惰性的 Hg:Se 复合物;4)减少从胃肠道吸收汞;5)补充硒储存(逆转硒缺乏);6)恢复靶硒蛋白的活性并恢复细胞内氧化还原环境。关于硒是否增加或阻碍汞的消除,存在相互矛盾的证据,但增加汞的消除似乎不是硒的主要作用。硒补充剂已被证明可以恢复硒蛋白的功能并降低汞的毒性,但存在几个显著的限制,包括:汞的形式(甲基汞毒性对改善的反应较少)和汞的剂量。
与硒的相互作用是汞毒性的一个核心特征。这种相互作用是复杂的,取决于许多因素,如汞的形式、硒的形式、器官和剂量。以前认为硒对汞毒性有“保护作用”,事实上可能是相反的。汞的作用是产生硒缺乏状态,并直接抑制硒在控制生物体内细胞内氧化还原环境中的作用。硒补充剂,具有一定的局限性,可能在恢复硒缺乏状态下的足够硒状态和减轻汞的毒性方面发挥有益作用。
