Interior Operators and Their Relationship to Autocatalytic Networks

IF 1.4 4区生物学 Q4 MATHEMATICAL & COMPUTATIONAL BIOLOGY

Acta Biotheoretica Pub Date : 2023-10-27 DOI:10.1007/s10441-023-09472-8

Mike Steel

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引用次数: 1

Abstract

The emergence of an autocatalytic network from an available set of elements is a fundamental step in early evolutionary processes, such as the origin of metabolism. Given the set of elements, the reactions between them (chemical or otherwise), and with various elements catalysing certain reactions, a Reflexively Autocatalytic F-generated (RAF) set is a subset R\('\) of reactions that is self-generating from a given food set, and with each reaction in R\('\) being catalysed from within R\('\). RAF theory has been applied to various phenomena in theoretical biology, and a key feature of the approach is that it is possible to efficiently identify and classify RAFs within large systems. This is possible because RAFs can be described as the (nonempty) subsets of the reactions that are the fixed points of an (efficiently computable) interior map that operates on subsets of reactions. Although the main generic results concerning RAFs can be derived using just this property, we show that for systems with at least 12 reactions there are generic results concerning RAFs that cannot be proven using the interior operator property alone.

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内部算子及其与自催化网络的关系。

从一组可用的元素中出现自催化网络是早期进化过程中的一个基本步骤，例如新陈代谢的起源。给定元素集、它们之间的反应（化学或其他），以及催化某些反应的各种元素，反射自催化F-生成（RAF）集是从给定食物集自发生成的反应的子集R[公式：见正文]，R中的每个反应都是从R中催化的[公式：参见正文]。RAF理论已应用于理论生物学中的各种现象，该方法的一个关键特征是可以在大型系统中有效地识别和分类RAF。这是可能的，因为RAF可以被描述为反应的（非空）子集，它们是对反应子集进行操作的（有效可计算的）内部映射的不动点。尽管关于RAF的主要通用结果可以仅使用该性质得出，但我们表明，对于至少有12个反应的系统，关于RAF，存在无法单独使用内部算子性质证明的通用结果。请检查并确认标题中的编辑。我确认编辑是好的。

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

Acta Biotheoretica 生物-生物学

CiteScore

2.70

自引率

7.70%

发文量

审稿时长

3 months

期刊介绍： Acta Biotheoretica is devoted to the promotion of theoretical biology, encompassing mathematical biology and the philosophy of biology, paying special attention to the methodology of formation of biological theory. Papers on all kind of biological theories are welcome. Interesting subjects include philosophy of biology, biomathematics, computational biology, genetics, ecology and morphology. The process of theory formation can be presented in verbal or mathematical form. Moreover, purely methodological papers can be devoted to the historical origins of the philosophy underlying biological theories and concepts. Papers should contain clear statements of biological assumptions, and where applicable, a justification of their translation into mathematical form and a detailed discussion of the mathematical treatment. The connection to empirical data should be clarified. Acta Biotheoretica also welcomes critical book reviews, short comments on previous papers and short notes directing attention to interesting new theoretical ideas.