1 Protein Crystallography Section, Radiation Biology & Health Sciences Division, Bhabha Atomic Research Centre , Mumbai, India .
2 Molecular Biology Division, Bhabha Atomic Research Centre , Mumbai, India .
Antioxid Redox Signal. 2018 Feb 1;28(4):296-310. doi: 10.1089/ars.2016.6960. Epub 2017 Oct 16.
Living cells employ thioredoxin and glutaredoxin disulfide oxido-reductases to protect thiol groups in intracellular proteins. FrnE protein of Deinococcus radiodurans (drFrnE) is a disulfide oxido-reductase that is induced in response to Cd exposure and is involved in cadmium and radiation tolerance. The aim of this study is to probe structure, function, and cellular localization of FrnE class of proteins.
Here, we show drFrnE as a novel cytoplasmic oxido-reductase that could be functional in eubacteria under conditions where thioredoxin/glutaredoxin systems are inhibited or absent. Crystal structure analysis of drFrnE reveals thioredoxin fold with an alpha helical insertion domain and a unique, flexible, and functionally important C-terminal tail. The C-tail harbors a novel 239-CXC-244 motif that interacts with the active site 22-CXXC-25 motif. Crystal structures with different active site redox states, including mixed disulfide (Cys22-Cys244), are reported here. The biochemical data show that 239-CXC-244 motif channels electrons to the active site cysteines. drFrnE is more stable in the oxidized form, compared with the reduced form, supporting its role as a disulfide reductase. Using bioinformatics analysis and fluorescence microscopy, we show cytoplasmic localization of drFrnE. We have found "true" orthologs of drFrnE in several eubacterial phyla and, interestingly, all these groups apparently lack a functional glutaredoxin system. Innovation and Conclusion: We show that drFrnE represents a new class of hitherto unknown intracellular oxido-reductases that are abundantly present in eubacteria. Unlike other well-known oxido-reductases, FrnE harbors an additional dithiol motif that acts as a conduit to channel electrons to the active site during catalytic turnover. Antioxid. Redox Signal. 28, 296-310.
活细胞利用硫氧还蛋白和谷氧还蛋白二硫氧化还原酶来保护细胞内蛋白质中的巯基。来自耐辐射球菌(drFrnE)的 FrnE 蛋白是一种二硫氧化还原酶,它可以响应 Cd 暴露而被诱导,并参与镉和辐射耐受性。本研究的目的是探测 FrnE 类蛋白的结构、功能和细胞定位。
我们展示了 drFrnE 作为一种新型的细胞质氧化还原酶,在硫氧还蛋白/谷氧还蛋白系统被抑制或不存在的情况下,可能在真细菌中具有功能。drFrnE 的晶体结构分析揭示了其具有硫氧还蛋白折叠结构,带有一个α螺旋插入结构域和一个独特的、灵活的、功能上重要的 C 末端尾巴。C 末端尾巴带有一个新的 239-CXC-244 基序,该基序与活性位点 22-CXXC-25 基序相互作用。这里报告了具有不同活性位点氧化还原状态的晶体结构,包括混合二硫键(Cys22-Cys244)。生化数据表明,239-CXC-244 基序将电子输送到活性位点半胱氨酸。与还原形式相比,drFrnE 在氧化形式下更稳定,支持其作为二硫键还原酶的作用。通过生物信息学分析和荧光显微镜,我们显示了 drFrnE 的细胞质定位。我们在几个真细菌门中发现了 drFrnE 的“真正”同源物,有趣的是,所有这些群体显然缺乏功能性谷氧还蛋白系统。创新和结论:我们表明,drFrnE 代表了一类新的、迄今未知的细胞内氧化还原酶,在真细菌中大量存在。与其他已知的氧化还原酶不同,FrnE 具有一个额外的二硫基序,该基序在催化循环过程中充当将电子输送到活性位点的通道。抗氧化还原信号。28,296-310。
