Covalent and Non-Covalent Associations Mediate MED28 Homo-Oligomerization

Jehad Shaikhali, N. Rouhier, Arnaud Hecker, K. Brännström, G. Wingsle
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引用次数: 1

Abstract

The Mediator is a multi-protein complex that plays a key role in modulating gene expression. Our previous studies suggested that the MED10a, MED28, MED32 complex subunits could be subject to redox regulation. In this study we tested the capacity of different thioredoxins (TRXs) from poplar (TRX-H3 and TRX-H5) and Arabidopsis thaliana (TPR repeat-containing thioredoxin, TDX) as well as glutaredoxins (GRXs) from poplar (GRX-C3 and GRX-C4) to reduce MED28 oligomers in vitro and found that these proteins were less efficient than the the previously tested poplar TRX-H1 and Arabidopsis GRX-C1. Concerning the susceptibility of MED28 to oxidation, both hydrogen peroxide (H2O2) and glutathione disulfide (GSSG) are efficiently mediating the formation of intermolecular disulfides. In fact, MED28 forms homo- oligomers in vivo as assessed by yeast two-hybrid experiments but also in vitro in solution as shown by size-exclusion chromatography, the latter also demonstrated the formation of noncovalent homo-oligomers. These findings suggest that both the redox-dependent and - independent MED28 oligomerization could regulate its biological activities, could it be linked or not to the Mediator. In particular, it would be important to assess MED28 oligomerization state during senescence considering the previously observed phenotype of med28 plants.
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共价和非共价结合介导MED28同源寡聚化
中介体是一种多蛋白复合物,在调节基因表达中起关键作用。我们之前的研究表明,MED10a, MED28, MED32复合体亚基可能受到氧化还原调控。在本研究中,我们在体外测试了杨树(TRX-H3和TRX-H5)和拟南芥(TPR重复序列-containing thioredoxin, TDX)和杨树(GRX-C3和GRX-C4)中不同的硫氧还毒素(TRXs)对MED28寡聚物的还原能力,发现这些蛋白的还原效率低于之前测试的杨树TRX-H1和拟南芥GRX-C1。关于MED28的氧化敏感性,过氧化氢(H2O2)和谷胱甘肽二硫化物(GSSG)都能有效地介导分子间二硫化物的形成。事实上,在酵母双杂交实验中,MED28在体内可以形成低聚物,但在体外溶液中,通过尺寸排除色谱也可以形成非共价低聚物。这些发现提示,氧化还原依赖性和非依赖性MED28寡聚化都可以调节其生物活性,它是否与介质有关。特别是,考虑到先前观察到的MED28植物的表型,评估衰老过程中MED28寡聚化状态将是重要的。
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