Andrew Schoenrock, Daniel J. Burnside, H. Moteshareie, A. Wong, A. Golshani, F. Dehne
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引用次数: 5
摘要
工程蛋白是合成的新型蛋白质(不存在于自然界中),旨在实现预定的生物功能。这些蛋白质可用作分子标记、抑制剂或药物。例如,合成蛋白可以与病原体的关键蛋白结合,从而抑制目标蛋白的功能并潜在地减少病原体的影响。在本文中,我们介绍了In- silicon Protein Synthesizer (insps),这是IBM Blue Gene/Q的大规模并行计算工具,旨在设计抑制蛋白。更准确地说,insps设计的蛋白质可以与给定的靶蛋白相互作用(并可能抑制靶蛋白的细胞功能),而不影响非靶蛋白(以减少副作用)。作为概念验证,两种insps设计的蛋白质已经在实验室合成,并通过湿实验室实验验证了它们的抑制特性。
Engineering inhibitory proteins with InSiPS: the in-silico protein synthesizer
Engineered proteins are synthetic novel proteins (not found in nature) that are designed to fulfill a predetermined biological function. Such proteins can be used as molecular markers, inhibitory agents, or drugs. For example, a synthetic protein could bind to a critical protein of a pathogen, thereby inhibiting the function of the target protein and potentially reducing the impact of the pathogen. In this paper we present the In-Silico Protein Synthesizer (InSiPS), a massively parallel computational tool for the IBM Blue Gene/Q that is aimed at designing inhibitory proteins. More precisely, InSiPS designs proteins that are predicted to interact with a given target protein (and may inhibit the target's cellular functions) while leaving non-target proteins unaffected (to minimize side-effects). As proof-of-concepts, two InSiPS designed proteins have been synthesized in the lab and their inhibitory properties have been experimentally verified through wet-lab experimentation.
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