Absolute concentration robustness and multistationarity in reaction networks: Conditions for coexistence

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS

ACS Applied Bio Materials Pub Date : 2024-01-02 DOI:10.1017/s0956792523000335

Nidhi Kaihnsa, Tung Nguyen, Anne Shiu

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Abstract

Many reaction networks arising in applications are multistationary, that is, they have the capacity for more than one steady state, while some networks exhibit absolute concentration robustness (ACR), which means that some species concentration is the same at all steady states. Both multistationarity and ACR are significant in biological settings, but only recently has attention focused on the possibility for these properties to coexist. Our main result states that such coexistence in at-most-bimolecular networks (which encompass most networks arising in biology) requires at least three species, five complexes and three reactions. We prove additional bounds on the number of reactions for general networks based on the number of linear conservation laws. Finally, we prove that, outside of a few exceptional cases, ACR is equivalent to non-multistationarity for bimolecular networks that are small (more precisely, one-dimensional or up to two species). Our proofs involve analyses of systems of sparse polynomials, and we also use classical results from chemical reaction network theory.

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反应网络中的绝对浓度稳健性和多稳定性：共存的条件

应用中出现的许多反应网络都是多稳态的，也就是说，它们有能力出现不止一种稳态，而有些网络则表现出绝对浓度稳健性（ACR），这意味着某些物种的浓度在所有稳态下都是相同的。多稳态和绝对浓度鲁棒性在生物环境中都很重要，但直到最近，人们才开始关注这两种特性共存的可能性。我们的主要结果表明，在最多双分子网络（包括生物学中出现的大多数网络）中，这种共存需要至少三个物种、五个复合物和三个反应。我们还根据线性守恒定律的数量证明了一般网络中反应数量的额外界限。最后，我们证明，除少数例外情况外，对于小型（更准确地说，一维或最多两个物种）双分子网络来说，ACR 等同于非多重性。我们的证明涉及稀疏多项式系统的分析，我们还使用了化学反应网络理论的经典结果。

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 Chemistry-Chemistry (all)

CiteScore

9.40

自引率

2.10%

发文量

464