基于宿主电路模型预测细胞负荷。

Prediction of Cellular Burden with Host-Circuit Models.

机构信息

School of Biological Sciences, University of Edinburgh, Edinburgh, UK.

School of Informatics, University of Edinburgh, Edinburgh, UK.

出版信息

Methods Mol Biol. 2021;2229:267-291. doi: 10.1007/978-1-0716-1032-9_13.

DOI:10.1007/978-1-0716-1032-9_13

PMID:33405227

Abstract

Heterologous gene expression draws resources from host cells. These resources include vital components to sustain growth and replication, and the resulting cellular burden is a widely recognized bottleneck in the design of robust circuits. In this tutorial we discuss the use of computational models that integrate gene circuits and the physiology of host cells. Through various use cases, we illustrate the power of host-circuit models to predict the impact of design parameters on both burden and circuit functionality. Our approach relies on a new generation of computational models for microbial growth that can flexibly accommodate resource bottlenecks encountered in gene circuit design. Adoption of this modeling paradigm can facilitate fast and robust design cycles in synthetic biology.

摘要

异源基因表达从宿主细胞中汲取资源。这些资源包括维持生长和复制所需的重要组成部分，而由此产生的细胞负担是设计稳健电路的一个公认瓶颈。在本教程中，我们讨论了使用整合基因电路和宿主细胞生理学的计算模型。通过各种用例，我们说明了宿主电路模型在预测设计参数对负担和电路功能的影响方面的强大功能。我们的方法依赖于新一代可灵活适应基因电路设计中资源瓶颈的微生物生长计算模型。采用这种建模范例可以促进合成生物学中的快速稳健设计周期。

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基于宿主电路模型预测细胞负荷。

Prediction of Cellular Burden with Host-Circuit Models.

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