Toeholder: a software for automated design and in silico validation of toehold riboswitches

PeerJ physical chemistry Pub Date : 2023-06-09 DOI:10.7717/peerj-pchem.28

Angel F. Cisneros, Francois D. Rouleau, Carla Bautista, Pascale Lemieux, Nathan Dumont-Leblond

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Abstract

Synthetic biology aims to engineer biological circuits, which often involve gene expression. A particularly promising group of regulatory elements are riboswitches because of their versatility with respect to their targets, but early synthetic designs were not as attractive because of a reduced dynamic range with respect to protein regulators. Only recently, the creation of toehold switches helped overcome this obstacle by also providing an unprecedented degree of orthogonality. However, a lack of automated design and optimization tools prevents the widespread and effective use of toehold switches in high throughput experiments. To address this, we developed Toeholder, a comprehensive open-source software for toehold design and in silico comparison. Toeholder takes into consideration sequence constraints from experimentally tested switches, as well as data derived from molecular dynamics simulations of a toehold switch. We describe the software and its in silico validation results, as well as its potential applications and impacts on the management and design of toehold switches.

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Toeholder:一个用于自动设计和在计算机上验证Toeholder核开关的软件

合成生物学的目标是设计生物电路，这通常涉及基因表达。一组特别有前途的调控元件是核糖体开关，因为它们的靶标具有多功能性，但早期的合成设计并不具有吸引力，因为相对于蛋白质调节剂而言，其动态范围较低。直到最近，脚点开关的发明才通过提供前所未有的正交度帮助克服了这一障碍。然而，缺乏自动化设计和优化工具阻碍了在高通量实验中广泛和有效地使用支点开关。为了解决这个问题，我们开发了Toeholder，这是一个全面的开源软件，用于支撑点设计和硅比较。Toeholder考虑了来自实验测试开关的序列约束，以及来自Toeholder开关分子动力学模拟的数据。我们描述了该软件及其在计算机上的验证结果，以及其潜在的应用和对脚开关管理和设计的影响。

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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来源期刊

PeerJ physical chemistry

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0.00%

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审稿时长

16 weeks