Dynamical Modularity of the Genotype-Phenotype Map

Evolutionary Systems Biology Pub Date : 2021-02-02 DOI:10.31219/osf.io/vfz4t

Johannes Jaeger, Nick Monk

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引用次数: 5

Abstract

An organism’s phenotype can be thought of as consisting of a set of discrete traits, able to evolve relatively independently of each other. This implies that the developmental processes generating these traits—the underlying genotype-phenotype map—must also be functionally organised in a modular manner. The genotype-phenotype map lies at the heart of evolutionary systems biology. Recently, it has become popular to define developmental modules in terms of the structure of gene regulatory networks. This approach is inherently limited: gene networks often do not have structural modularity. More generally, the connection between structure and function is quite loose. In this chapter, we discuss an alternative approach based on the concept of dynamical modularity, which overcomes many of the limitations of structural modules. A dynamical module consists of the activities of a set of genes and their interactions that generate a specific dynamic behaviour. These modules can be identified and characterised by phase-space analysis of data-driven models. We showcase the power and the promise of this new approach using several case studies. Dynamical modularity forms an important component of a general theory of the evolution of regulatory systems and the genotype-phenotype map they define.

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基因型-表型图谱的动态模块化

一个生物体的表型可以被认为是由一组离散的特征组成，这些特征能够相对独立地进化。这意味着产生这些特征的发育过程——潜在的基因型-表型图谱——也必须以模块化的方式在功能上组织起来。基因型-表现型图谱是进化系统生物学的核心。近年来，从基因调控网络结构的角度来定义发育模块已成为一种流行的观点。这种方法具有固有的局限性:基因网络通常不具有结构模块化。更一般地说，结构和功能之间的联系是相当松散的。在本章中，我们讨论了一种基于动态模块化概念的替代方法，它克服了结构模块的许多限制。动态模块由一组基因的活动和它们之间产生特定动态行为的相互作用组成。这些模块可以通过数据驱动模型的相空间分析来识别和表征。我们通过几个案例研究展示了这种新方法的力量和前景。动态模块化构成了调控系统进化的一般理论和它们定义的基因型-表型图谱的重要组成部分。

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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Evolutionary Systems Biology

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