Mieyal John J, Gallogly Molly M, Qanungo Suparna, Sabens Elizabeth A, Shelton Melissa D
Department of Pharmacology, Case Western Reserve University, Cleveland, Ohio 44106-4965, USA.
Antioxid Redox Signal. 2008 Nov;10(11):1941-88. doi: 10.1089/ars.2008.2089.
Sulfhydryl chemistry plays a vital role in normal biology and in defense of cells against oxidants, free radicals, and electrophiles. Modification of critical cysteine residues is an important mechanism of signal transduction, and perturbation of thiol-disulfide homeostasis is an important consequence of many diseases. A prevalent form of cysteine modification is reversible formation of protein mixed disulfides (protein-SSG) with glutathione (GSH). The abundance of GSH in cells and the ready conversion of sulfenic acids and S-nitroso derivatives to S-glutathione mixed disulfides suggests that reversible S-glutathionylation may be a common feature of redox signal transduction and regulation of the activities of redox sensitive thiol-proteins. The glutaredoxin enzyme has served as a focal point and important tool for evolution of this regulatory mechanism, because it is a specific and efficient catalyst of protein-SSG deglutathionylation. However, mechanisms of control of intracellular Grx activity in response to various stimuli are not well understood, and delineation of specific mechanisms and enzyme(s) involved in formation of protein-SSG intermediates requires further attention. A large number of proteins have been identified as potentially regulated by reversible S-glutathionylation, but only a few studies have documented glutathionylation-dependent changes in activity of specific proteins in a physiological context. Oxidative stress is a hallmark of many diseases which may interrupt or divert normal redox signaling and perturb protein-thiol homeostasis. Examples involving changes in S-glutathionylation of specific proteins are discussed in the context of diabetes, cardiovascular and lung diseases, cancer, and neurodegenerative diseases.
巯基化学在正常生物学过程以及细胞抵御氧化剂、自由基和亲电试剂的过程中发挥着至关重要的作用。关键半胱氨酸残基的修饰是信号转导的重要机制,而硫醇-二硫键稳态的扰动是许多疾病的重要后果。半胱氨酸修饰的一种普遍形式是与谷胱甘肽(GSH)可逆地形成蛋白质混合二硫键(蛋白质-SSG)。细胞内谷胱甘肽的丰富含量以及亚磺酸和S-亚硝基衍生物向S-谷胱甘肽混合二硫键的快速转化表明,可逆的S-谷胱甘肽化可能是氧化还原信号转导以及氧化还原敏感硫醇蛋白活性调节的共同特征。谷氧还蛋白作为这种调节机制演变的焦点和重要工具,因为它是蛋白质-SSG去谷胱甘肽化的特异性高效催化剂。然而,对细胞内谷氧还蛋白活性响应各种刺激的控制机制尚不清楚,并且对参与蛋白质-SSG中间体形成的具体机制和酶的描述需要进一步关注。大量蛋白质已被确定可能受可逆S-谷胱甘肽化调节,但只有少数研究记录了在生理背景下特定蛋白质活性的谷胱甘肽化依赖性变化。氧化应激是许多疾病的标志,可能会中断或改变正常的氧化还原信号并扰乱蛋白质硫醇稳态。在糖尿病、心血管疾病、肺部疾病、癌症和神经退行性疾病的背景下讨论了涉及特定蛋白质S-谷胱甘肽化变化的实例。