GA-based Design Algorithms for the Robust Synthetic Genetic Oscillators with Prescribed Amplitude, Period and Phase.

Bor-Sen Chen, Po-Wei Chen
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引用次数: 28

Abstract

In the past decade, the development of synthetic gene networks has attracted much attention from many researchers. In particular, the genetic oscillator known as the repressilator has become a paradigm for how to design a gene network with a desired dynamic behaviour. Even though the repressilator can show oscillatory properties in its protein concentrations, their amplitudes, frequencies and phases are perturbed by the kinetic parametric fluctuations (intrinsic molecular perturbations) and external disturbances (extrinsic molecular noises) of the environment. Therefore, how to design a robust genetic oscillator with desired amplitude, frequency and phase under stochastic intrinsic and extrinsic molecular noises is an important topic for synthetic biology.In this study, based on periodic reference signals with arbitrary amplitudes, frequencies and phases, a robust synthetic gene oscillator is designed by tuning the kinetic parameters of repressilator via a genetic algorithm (GA) so that the protein concentrations can track the desired periodic reference signals under intrinsic and extrinsic molecular noises. GA is a stochastic optimization algorithm which was inspired by the mechanisms of natural selection and evolution genetics. By the proposed GA-based design algorithm, the repressilator can track the desired amplitude, frequency and phase of oscillation under intrinsic and extrinsic noises through the optimization of fitness function.The proposed GA-based design algorithm can mimic the natural selection in evolutionary process to select adequate kinetic parameters for robust genetic oscillators. The design method can be easily extended to any synthetic gene network design with prescribed behaviours.

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基于遗传算法的定幅、定周期、定相位鲁棒合成遗传振荡器设计算法。
在过去的十年中,合成基因网络的发展受到了许多研究者的关注。特别是,基因振荡器被称为再压子已经成为一个范例,如何设计一个基因网络与期望的动态行为。尽管再压剂可以在其蛋白质浓度中显示振荡特性,但它们的振幅、频率和相位受到环境的动力学参数波动(内在分子扰动)和外部干扰(外在分子噪声)的干扰。因此,如何在随机分子内外噪声条件下设计具有理想振幅、频率和相位的鲁棒遗传振荡器是合成生物学研究的重要课题。本研究以任意振幅、频率和相位的周期参考信号为基础,通过遗传算法调整调控器的动力学参数,设计了一个鲁棒的合成基因振荡器,使蛋白质浓度在内源和外源分子噪声下都能跟踪所需的周期参考信号。遗传算法是一种受自然选择和进化遗传学机制启发的随机优化算法。通过对适应度函数的优化,在所提出的基于遗传算法的设计算法中,稳压器能够在内外噪声条件下跟踪期望的振荡幅度、频率和相位。提出的基于遗传算法的设计算法可以模拟进化过程中的自然选择,为鲁棒遗传振子选择合适的动力学参数。该设计方法可以很容易地扩展到任何具有规定行为的合成基因网络设计。
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