基于相分离的合成细胞器对转录的代谢物响应控制

Carolina Jerez-Longres, Wilfried Weber
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摘要

有生命的天然材料具有非凡的传感能力,能将外部线索转化为材料的功能变化。在自下而上的合成生物学中重建这种传感材料,为开发具有类似生命的传感和适应能力的合成材料提供了机会。这些功能的关键是将特定输入信号转化为生物分子反应的材料模块。在这里,我们设计了一种基于液-液相分离的合成细胞器,它能将代谢信号转化为基因转录调控。为此,我们设计了丙酮酸依赖性抑制因子 PdhR,通过与固有无序区融合,在体外进行液-液相分离。我们证明,由此产生的共凝胶能以丙酮酸剂量依赖性和可逆的方式结合含有 PdhR 响应操作位点的 DNA。我们观察到,DNA 上的转录单元在被共聚物吸附后,其活性会强烈减弱。然而,丙酮酸的加入会导致转录活性的可逆和剂量依赖性重建。基于共凝胶的合成细胞器将代谢线索与转录信号联系起来,代表了一种将刺激响应性赋予最小自下而上合成生物系统的材料方法,并为传感器应用材料带来了机遇。
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Metabolite-responsive Control of Transcription by Phase Separation-based Synthetic Organelles
Living natural materials have remarkable sensing abilities that translate external cues into functional changes of the material. The reconstruction of such sensing materials in bottom-up synthetic biology provides the opportunity to develop synthetic materials with life-like sensing and adaptation ability. Key to such functions are material modules that translate specific input signals into a biomolecular response. Here, we engineer a synthetic organelle based on liquid-liquid phase separation that translates a metabolic signal into the regulation of gene transcription. To this aim, we engineer the pyruvate-dependent repressor PdhR to undergo liquid-liquid phase separation in vitro by fusion to intrinsically disordered regions. We demonstrate that the resulting coacervates bind DNA harbouring PdhR-responsive operator sites in a pyruvate dose-dependent and reversible manner. We observed that the activity of transcription units on the DNA was strongly attenuated following recruitment to the coacervates. However, the addition of pyruvate resulted in a reversible and dose-dependent reconstitution of transcriptional activity. The coacervate-based synthetic organelles linking metabolic cues to transcriptional signals represent a materials approach to confer stimulus-responsiveness to minimal bottom-up synthetic biological systems and open opportunities in materials for sensor applications.
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