Fine Tuning Genetic Circuits via Host Context and RBS Modulation

Dennis Tin Chat Chan, Lena Winter, Johan Bjerg, Stina Krsmanovic, Geoff S. Baldwin, Hans C. Bernstein
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Abstract

The choice of organism to host a genetic circuit, the chassis, is often defaulted to model organisms due to their amenability. The chassis-design space has therefore remained underexplored as an engineering variable. In this work, we explored the design space of a genetic toggle switch through variations in nine ribosome binding sites compositions and three host contexts, creating 27 circuit variants. Characterization of performance metrics in terms of toggle switch output and host growth dynamics unveils a spectrum of performance profiles from our circuit library. We find that changes in host-context causes large shifts in overall performance, while modulating ribosome binding sites leads to more incremental changes. We find that a combined ribosome binding site and host-context modulation approach can be used to fine tune the properties of a toggle switch according to user-defined specifications, such as towards greater signaling strength, inducer sensitivity or both. Other auxiliary properties, such as inducer tolerance, are also exclusively accessed through changes in host-context. We demonstrate here that exploration of the chassis-design space can offer significant value, reconceptualizing the chassis-organism as an important part in the synthetic biology toolbox with important implications for the field of synthetic biology.
通过宿主语境和 RBS 调节微调遗传回路
在选择承载基因电路的生物体(即底盘)时,由于模型生物的易接受性,通常被默认为模型生物。因此,底盘设计空间作为一个工程变量仍未得到充分探索。在这项工作中,我们通过改变九个核糖体结合位点的组成和三种宿主环境,探索了基因拨动开关的设计空间,创造了 27 种电路变体。通过对拨动开关输出和宿主生长动态的性能指标进行表征,我们的电路库揭示了一系列性能曲线。我们发现,宿主环境的变化会导致整体性能的巨大变化,而调节核糖体结合位点则会带来更多的渐进变化。我们发现,结合核糖体结合位点和宿主上下文调制的方法可用于根据用户定义的规格微调拨动开关的特性,如更大的信号强度、诱导剂灵敏度或两者兼而有之。其他辅助特性,如诱导剂耐受性,也可以通过改变宿主环境来实现。我们在此证明,探索底盘设计空间具有重要价值,重新认识了底盘生物作为合成生物学工具箱中重要组成部分的概念,对合成生物学领域具有重要意义。
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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