Thiol-based抗氧化剂。

S M Deneke
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引用次数: 416

摘要

细胞内和细胞外区室的硫醇氧化还原状态对蛋白质结构的决定、酶活性的调节以及转录因子活性和结合的控制至关重要。硫醇抗氧化剂通过多种机制起作用,包括(1)作为一般硫醇/二硫化物氧化还原缓冲液的组分,(2)作为金属螯合剂,(3)作为自由基灭灭剂,(4)作为特定氧化还原反应(GSH)的底物,以及(5)作为单个蛋白质二硫酸盐键(硫氧还蛋白)的特定还原剂。在给定的隔室中,有效硫醇的组成和氧化还原状态是高度可变的,必须在决定每个隔室的代谢活性中发挥作用。在氧化应激条件下,增加特定抗氧化剂的可用性通常是有益的。细胞已经设计了许多机制来促进细胞内硫醇水平的增加,如谷胱甘肽和硫氧还蛋白,以应对各种各样的压力。外源性硫醇已成功地用于增加细胞培养、动物模型和人类的细胞和组织硫醇水平。谷胱甘肽和其他硫醇水平的增加与所有这些系统中对氧化应激的耐受性增加有关,在某些情况下,与人类疾病的预防或治疗有关。各种各样的硫醇相关化合物已被用于这些目的。这些包括硫醇,如谷胱甘肽及其衍生物,半胱氨酸和NAC,二硫醇,如硫辛酸,在细胞内被还原为硫醇形式,以及“原硫醇”化合物,如OTC,在细胞内被酶转化为游离硫醇。在选择具有特定功能的硫醇(例如,保护肺免受氧化暴露或保护器官免受缺血再灌注损伤)时,还必须考虑整体效应。例如,循环中游离硫醇的大量增加与毒性作用有关。这些影响可能是巯基自由基介导的反应的结果,但也可能是由于血浆中硫醇/二硫比增加的不稳定效应,血浆通常处于比细胞内区室更氧化的状态。细胞间硫醇氧化还原梯度的变化也可能对任何运输或细胞信号传导过程产生不利影响,这些过程依赖于膜蛋白中二硫键的形成和断裂。治疗性硫醇给药已被证明具有巨大的潜力,应通过选择化合物和递送方法来增加其功效,这些化合物和方法将最大限度地减少对目标区域外区域硫醇状态的干扰。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Thiol-based antioxidants.

The thiol redox status of intracellular and extracellular compartments is critical in the determination of protein structure, regulation of enzyme activity, and control of transcription factor activity and binding. Thiol antioxidants act through a variety of mechanisms, including (1) as components of the general thiol/disulfide redox buffer, (2) as metal chelators, (3) as radical quenchers, (4) as substrates for specific redox reactions (GSH), and (5) as specific reductants of individual protein disulfate bonds (thioredoxin). The composition and redox status of the available thiols in a given compartment is highly variable and must play a part in determining the metabolic activity of each compartment. It is generally beneficial to increase the availability of specific antioxidants under conditions of oxidant stress. Cells have devised a number of mechanisms to promote increased intracellular levels of thiols such as GSH and thioredoxin in response to a wide variety of stresses. Exogenous thiols have been used successfully to increase cell and tissue thiol levels in cell cultures, in animal models, and in humans. Increased levels of GSH and other thiols have been associated with increased tolerance to oxidant stresses in all of these systems and in some cases, with disease prevention or treatment in humans. A wide variety of thiol-related compounds have been used for these purposes. These include thiols such as GSH and its derivatives, cysteine and NAC, dithiols such as lipoic acid, which is reduced to the thiol form intracellularly, and "prothiol" compounds such as OTC, which are enzymatically converted to free thiols within the cell. In choosing a thiol for a specific function (e.g., protection of lung from oxidant exposure or protection of organs from ischemia reperfusion injury), the global effects must also be considered. For example, large increases in free thiols in the circulation are associated with toxic effects. These effects may be the result of thiyl radical-mediated reactions but could also be due to destabilizing effects of increases in thiol/disulfide ratios in the plasma, which normally is in a more oxidized state than intracellular compartments. Changes in the thiol redox gradient across cells could also adversely affect any transport or cell signaling processes, which are dependent on formation and rupture of disulfide linkages in membrane proteins. Therapeutic thiol administration has been shown to have great potential, and its efficacy should be increased by selecting compounds and methods of delivery that will minimize perturbations in the thiol status of regions external to the targeted areas.

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