Design Principles for Perfect Adaptation in Biological Networks with Nonlinear Dynamics.

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Priyan Bhattacharya, Karthik Raman, Arun K Tangirala
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Abstract

Establishing a mapping between the emergent biological properties and the repository of network structures has been of great relevance in systems and synthetic biology. Adaptation is one such biological property of paramount importance that promotes regulation in the presence of environmental disturbances. This paper presents a nonlinear systems theory-driven framework to identify the design principles for perfect adaptation with respect to external disturbances of arbitrary magnitude. Based on the prior information about the network, we frame precise mathematical conditions for adaptation using nonlinear systems theory. We first deduce the mathematical conditions for perfect adaptation for constant input disturbances. Subsequently, we translate these conditions to specific necessary structural requirements for adaptation in networks of small size and then extend to argue that there exist only two classes of architectures for a network of any size that can provide local adaptation in the entire state space, namely, incoherent feed-forward (IFF) structure and negative feedback loop with buffer node (NFB). The additional positiveness constraints further narrow the admissible set of network structures. This also aids in establishing the global asymptotic stability for the steady state given a constant input disturbance. The proposed method does not assume any explicit knowledge of the underlying rate kinetics, barring some minimal assumptions. Finally, we also discuss the infeasibility of certain IFF networks in providing adaptation in the presence of downstream connections. Moreover, we propose a generic and novel algorithm based on non-linear systems theory to unravel the design principles for global adaptation. Detailed and extensive simulation studies corroborate the theoretical findings.

Abstract Image

非线性动态生物网络完美适应的设计原则
在新兴生物特性和网络结构库之间建立映射关系,对系统生物学和合成生物学具有重要意义。适应性就是这样一种至关重要的生物特性,它能在环境干扰下促进调节。本文提出了一个非线性系统理论驱动的框架,以确定完美适应任意程度外部干扰的设计原则。基于网络的先验信息,我们利用非线性系统理论构建了精确的适应性数学条件。我们首先推导出针对恒定输入干扰的完美适应的数学条件。随后,我们将这些条件转化为对小规模网络适应性的特定必要结构要求,并进而论证,对于任何规模的网络,只有两类结构能在整个状态空间中提供局部适应性,即不连贯前馈(IFF)结构和带缓冲节点的负反馈回路(NFB)。附加的正向性约束进一步缩小了可容许网络结构的范围。这也有助于在输入干扰不变的情况下,建立稳定状态的全局渐近稳定性。除了一些最低限度的假设之外,所提出的方法并不假定对基本速率动力学有任何明确的了解。最后,我们还讨论了某些 IFF 网络在存在下游连接的情况下提供适应性的不可行性。此外,我们还提出了一种基于非线性系统理论的通用新算法,以揭示全局适应的设计原理。详细而广泛的模拟研究证实了理论发现。
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
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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