Computational design of a modular protein sense-response system

Glasgow Anum A.; Huang Yao-Ming; Mandell Daniel J.; Thompson Michael; Ritterson Ryan; Loshbaugh Amanda L.; Pellegrino Jenna; Krivacic Cody; Pache Roland A.; Barlow Kyle A.; Ollikainen Noah; Jeon Deborah; Kelly Mark J. S.; Fraser James S.; Kortemme Tanja

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Computational design of a modular protein sense-response system

机译：模块化蛋白质感应系统的计算设计

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Sensing and responding to signals is a fundamental ability of living systems, but despite substantial progress in the computational design of new protein structures, there is no general approach for engineering arbitrary new protein sensors. Here, we describe a generalizable computational strategy for designing sensor-actuator proteins by building binding sites de novo into heterodimeric protein-protein interfaces and coupling ligand sensing to modular actuation through split reporters. Using this approach, we designed protein sensors that respond to farnesyl pyrophosphate, a metabolic intermediate in the production of valuable compounds. The sensors are functional in vitro and in cells, and the crystal structure of the engineered binding site closely matches the design model. Our computational design strategy opens broad avenues to link biological outputs to new signals.

机译：传感和响应信号是生命系统的基本能力，但是尽管在新蛋白质结构的计算设计中取得了重大进展，但尚无用于设计任意新蛋白质传感器的通用方法。在这里，我们描述了通过建立从头到异二聚体蛋白质-蛋白质界面的结合位点，并将配体传感通过拆分的报道分子偶联至模块驱动，来设计传感器-致动器蛋白质的通用计算策略。使用这种方法，我们设计了对法呢基焦磷酸有反应的蛋白质传感器，法呢基焦磷酸是有价值的化合物生产中的代谢中间产物。传感器在体外和细胞中均具有功能，工程结合位点的晶体结构与设计模型紧密匹配。我们的计算设计策略为生物输出与新信号的连接开辟了广阔的渠道。

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《Science》 |2019年第6468期|1024-1028|共5页
作者
Glasgow Anum A.; Huang Yao-Ming; Mandell Daniel J.; Thompson Michael; Ritterson Ryan; Loshbaugh Amanda L.; Pellegrino Jenna; Krivacic Cody; Pache Roland A.; Barlow Kyle A.; Ollikainen Noah; Jeon Deborah; Kelly Mark J. S.; Fraser James S.; Kortemme Tanja;
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作者单位

Univ Calif San Francisco Dept Bioengn & Therapeut Sci San Francisco CA 94143 USA;

Univ Calif San Francisco Dept Bioengn & Therapeut Sci San Francisco CA 94143 USA|23andMe Inc Therapeut San Francisco CA USA;

Univ Calif San Francisco Dept Bioengn & Therapeut Sci San Francisco CA 94143 USA|Univ Calif San Francisco Bioinformat Grad Program San Francisco CA 94143 USA|GRO Biosci Boston MA USA;

Univ Calif San Francisco Dept Bioengn & Therapeut Sci San Francisco CA 94143 USA|Gryphon Sci LLC Takoma Pk MA USA;

Univ Calif San Francisco Dept Bioengn & Therapeut Sci San Francisco CA 94143 USA|Univ Calif San Francisco Biophys Grad Program San Francisco CA 94143 USA;

Univ Calif San Francisco Dept Bioengn & Therapeut Sci San Francisco CA 94143 USA|Univ Calif San Francisco UC Berkeley UCSF Grad Program Bioengn San Francisco CA 94143 USA;

Univ Calif San Francisco Dept Bioengn & Therapeut Sci San Francisco CA 94143 USA|Novozymes AS Biologiens Vej 2 DK-2800 Lyngby Denmark;

Univ Calif San Francisco Dept Bioengn & Therapeut Sci San Francisco CA 94143 USA|Univ Calif San Francisco Bioinformat Grad Program San Francisco CA 94143 USA|Adimab LLC Palo Alto CA USA;

Univ Calif San Francisco Dept Bioengn & Therapeut Sci San Francisco CA 94143 USA|Univ Calif San Francisco Bioinformat Grad Program San Francisco CA 94143 USA;

Univ Calif San Francisco Dept Pharmaceut Chem San Francisco CA 94143 USA;

Univ Calif San Francisco Dept Bioengn & Therapeut Sci San Francisco CA 94143 USA|Univ Calif San Francisco Biophys Grad Program San Francisco CA 94143 USA|Univ Calif San Francisco Quantitat Biosci Inst San Francisco CA 94143 USA;

Univ Calif San Francisco Dept Bioengn & Therapeut Sci San Francisco CA 94143 USA|Univ Calif San Francisco Bioinformat Grad Program San Francisco CA 94143 USA|Univ Calif San Francisco Biophys Grad Program San Francisco CA 94143 USA|Univ Calif San Francisco UC Berkeley UCSF Grad Program Bioengn San Francisco CA 94143 USA|Univ Calif San Francisco Quantitat Biosci Inst San Francisco CA 94143 USA|Chan Zuckerberg Biohub San Francisco CA 94158 USA;

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收录信息美国《科学引文索引》(SCI);美国《工程索引》(EI);美国《生物学医学文摘》(MEDLINE);美国《化学文摘》(CA);
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入库时间 2022-08-18 05:17:18

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3. Rosetta:MSF: a modular framework for multi-state computational protein design [J] . Patrick L?ffler, Samuel Schmitz, Enrico Hupfeld, PLoS Computational Biology . 2017,第6期

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5. Microfluidic, computational, and recombinant protein design for the analysis of the molecular properties of dynamic cell capture systems. [D] . Schmidt, Brian James. 2009

机译：微流体，计算和重组蛋白质设计，用于分析动态细胞捕获系统的分子特性。
6. Rosetta:MSF: a modular framework for multi-state computational protein design [O] . Patrick Löffler, Samuel Schmitz, Enrico Hupfeld, 2018

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7. Computational design of a modular protein sense-response system [O] . Anum A. Glasgow, Yao-Ming Huang, Daniel J. Mandell, 2019

机译：模块化蛋白感测响应系统的计算设计

Computational design of a modular protein sense-response system

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