使用分割 mVenus 方法在植物系统中实施 Ribo-BiFC 方法

Karel Raabe, Alena Náprstková, Janto Pieters, Elnura Torutaeva, Veronika Jirásková, Zahra Kahrizi, Christos Michailidis, David Honys
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摘要

翻译是每个生物体的基本过程。在植物中,翻译速率在生长发育过程中受到严格调控,并对环境线索做出反应。然而,很难测量体内组织的实际翻译状态。在此,我们报告了一种基于双分子荧光互补的体内翻译标记--Ribo-BiFC。我们将最初为果蝇开发的方法与之前在植物中描述的改进型低背景分裂-mVenus BiFC 系统相结合。我们用 mVenus 荧光蛋白片段标记拟南芥小亚基核糖体蛋白(RPS)和大亚基核糖体蛋白(RPL)。在组装 80S 核糖体时,mVenus 片段与之互补,并通过荧光显微镜进行检测。我们的研究表明,这些重组蛋白在烟草表皮细胞中距离很近,尽管与已知相互作用体的 BiFC 信号相比,信号有所减弱。这种 Ribo-BiFC 方法系统可用于稳定的转基因品系,以实现植物组织中翻译速率的可视化,并可用于研究植物发育过程中、非生物胁迫下或不同遗传背景下的翻译动态及其变化。
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Implementation of Ribo-BiFC method to plant systems using a split mVenus approach
Translation is a fundamental process for every living organism. In plants, the rate of translation is tightly modulated during development and in response to environmental cues. However, it is difficult to measure the actual translation state of the tissues in vivo. Here, we report the implementation of an in vivo translation marker based on bimolecular fluorescence complementation, the Ribo-BiFC. We combined method originally developed for fruit-fly with an improved low background split-mVenus BiFC system previously described in plants. We labelled Arabidopsis thaliana small subunit ribosomal protein (RPS) and large subunit ribosomal protein (RPL) with fragments of the mVenus fluorescent protein. Upon the assembly of the 80S ribosome, the mVenus fragments complemented and were detected by fluorescent microscopy. We show that these recombinant proteins are in close proximity in the tobacco epidermal cells, although the signal is reduced when compared to BiFC signal from known interactors. This Ribo-BiFC method system can be used in stable transgenic lines to enable visualisation of translational rate in plant tissues and could be used to study translation dynamics and its changes during plant development, under abiotic stress or in different genetic backgrounds.
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