Engineered Domain Swapping as an On/Off Switch for Protein Function.

Chemistry & biology Pub Date : 2015-10-22 DOI:10.1016/j.chembiol.2015.09.007

Jeung-Hoi Ha, Joshua M Karchin, Nancy Walker-Kopp, Carlos A Castañeda, Stewart N Loh

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引用次数: 26

Abstract

Domain swapping occurs when identical proteins exchange segments in reciprocal fashion. Natural swapping mechanisms remain poorly understood, and engineered swapping has the potential for creating self-assembling biomaterials that encode for emergent functions. We demonstrate that induced swapping can be used to regulate the function of a target protein. Swapping is triggered by inserting a "lever" protein (ubiquitin) into one of four loops of the ribose binding protein (RBP) target. The lever splits the target, forcing RBP to refold in trans to generate swapped oligomers. Identical RBP-ubiquitin fusions form homo-swapped complexes with the ubiquitin domain acting as the hinge. Surprisingly, some pairs of non-identical fusions swap more efficiently with each other than they do with themselves. Nuclear magnetic resonance experiments reveal that the hinge of these hetero-swapped complexes maps to a region of RBP distant from both ubiquitins. This design is expected to be applicable to other proteins to convert them into functional switches.

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工程结构域交换作为蛋白质功能的开关。

当相同的蛋白质以互惠的方式交换片段时，就会发生结构域交换。自然交换机制仍然知之甚少，而工程交换有可能创造出自组装的生物材料，为紧急功能编码。我们证明了诱导交换可以用来调节靶蛋白的功能。交换是通过将“杠杆”蛋白(泛素)插入核糖结合蛋白(RBP)靶标的四个环中的一个来触发的。杠杆分裂目标，迫使RBP在反式中重新折叠以产生交换的低聚物。相同的rbp -泛素融合形成同源交换复合物，泛素结构域作为铰链。令人惊讶的是，一些不相同的融合体相互交换比它们自己交换更有效。核磁共振实验显示，这些异交换复合物的铰链映射到远离两种泛素的RBP区域。该设计有望应用于其他蛋白质，将其转化为功能开关。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Chemistry & biology 生物-生化与分子生物学

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4-8 weeks