Department of Physics, Osaka University, Toyonaka, Japan.
Cybermedia Center, Osaka University, Toyonaka, Japan.
PLoS Comput Biol. 2020 Jun 29;16(6):e1007969. doi: 10.1371/journal.pcbi.1007969. eCollection 2020 Jun.
Gene regulatory networks (GRNs) are complex systems in which many genes regulate mutually to adapt the cell state to environmental conditions. In addition to function, the GRNs possess several kinds of robustness. This robustness means that systems do not lose their functionality when exposed to disturbances such as mutations or noise, and is widely observed at many levels in living systems. Both function and robustness have been acquired through evolution. In this respect, GRNs utilized in living systems are rare among all possible GRNs. In this study, we explored the fitness landscape of GRNs and investigated how robustness emerged in highly-fit GRNs. We considered a toy model of GRNs with one input gene and one output gene. The difference in the expression level of the output gene between two input states, "on" and "off", was considered as fitness. Thus, the determination of the fitness of a GRN was based on how sensitively it responded to the input. We employed the multicanonical Monte Carlo method, which can sample GRNs randomly in a wide range of fitness levels, and classified the GRNs according to their fitness. As a result, the following properties were found: (1) Highly-fit GRNs exhibited bistability for intermediate input between "on" and "off". This means that such GRNs responded to two input states by using different fixed points of dynamics. This bistability emerges necessarily as fitness increases. (2) These highly-fit GRNs were robust against noise because of their bistability. In other words, noise robustness is a byproduct of high fitness. (3) GRNs that were robust against mutations were not extremely rare among the highly-fit GRNs. This implies that mutational robustness is readily acquired through the evolutionary process. These properties are universal irrespective of the evolutionary pathway, because the results do not rely on evolutionary simulation.
基因调控网络(GRNs)是一种复杂的系统,其中许多基因相互调节,以使细胞状态适应环境条件。除了功能外,GRNs 还具有多种鲁棒性。这种鲁棒性意味着系统在受到突变或噪声等干扰时不会失去其功能,并且在生命系统的许多层次上都广泛观察到。功能和鲁棒性都是通过进化获得的。在这方面,在生命系统中使用的 GRNs 在所有可能的 GRNs 中是罕见的。在这项研究中,我们探索了 GRNs 的适应度景观,并研究了高度适应的 GRNs 中鲁棒性是如何出现的。我们考虑了一个具有一个输入基因和一个输出基因的 GRN 的玩具模型。输出基因在两种输入状态“开”和“关”之间的表达水平差异被认为是适应度。因此,GRN 的适应度的确定是基于它对输入的敏感程度。我们采用了多正则蒙特卡罗方法,该方法可以在广泛的适应度范围内随机采样 GRN,并根据其适应度对 GRN 进行分类。结果发现:(1)高度适应的 GRN 在“开”和“关”之间的中间输入处表现出双稳性。这意味着这些 GRN 通过使用不同的动力学固定点来响应两种输入状态。这种双稳性必然随着适应度的增加而出现。(2)这些高度适应的 GRN 由于其双稳性而具有抗噪声能力。换句话说,噪声鲁棒性是高适应性的副产品。(3)在高度适应的 GRN 中,对突变具有鲁棒性的 GRN 并不是极其罕见的。这意味着突变鲁棒性可以通过进化过程很容易地获得。这些特性是普遍的,不依赖于进化途径,因为结果不依赖于进化模拟。
