Ahmad Saheem, Khan Hamda, Shahab Uzma, Rehman Shahnawaz, Rafi Zeeshan, Khan Mohd Yasir, Ansari Ahsanullah, Siddiqui Zeba, Ashraf Jalaluddin Mohammad, Abdullah Saleh M S, Habib Safia, Uddin Moin
Department of Biosciences, Integral University, Lucknow-226026,
Department of Biosciences, Integral University, Lucknow- 226026, India.
Front Biosci (Schol Ed). 2017 Jan 1;9(1):71-87. doi: 10.2741/s474.
The available data suggest that among cellular constituents, proteins are the major target for oxidation primarily because of their quantity and high rate of interactions with ROS. Proteins are susceptible to ROS modifications of amino acid side chains which alter protein structure. Among the amino acids, Cysteine (Cys) is more prone to oxidation by ROS because of its high nucleophilic property. The reactivity of Cys with ROS is due to the presence of thiol group. In the oxidised form, Cys forms disulfide bond, which are primary covalent cross-link found in proteins, and which stabilize the native conformation of a protein. Indirect evidence suggests that thiol modifications by ROS may be involved in neurodegenerative disorders, but the significance and precise extent of the contributions are poorly understood. Here, we review the role of oxidized Cys in different pathological consequences and its biochemistry may increase the research in the discovery of new therapies. The purpose of this review is to re-examine the role and biochemistry of oxidised Cys residues.
现有数据表明,在细胞成分中,蛋白质是氧化的主要靶点,主要是因为其数量以及与活性氧(ROS)的高相互作用率。蛋白质易受ROS对氨基酸侧链的修饰影响,从而改变蛋白质结构。在氨基酸中,半胱氨酸(Cys)因其高亲核性而更容易被ROS氧化。Cys与ROS的反应性归因于硫醇基团的存在。在氧化形式下,Cys形成二硫键,这是蛋白质中发现的主要共价交联,可稳定蛋白质的天然构象。间接证据表明,ROS引起的硫醇修饰可能与神经退行性疾病有关,但这些作用的重要性和确切程度尚不清楚。在此,我们综述氧化型Cys在不同病理后果中的作用,其生物化学特性可能会增加新疗法发现方面的研究。本综述的目的是重新审视氧化型Cys残基的作用和生物化学特性。