表型设计空间提供了一个机制框架,将分子参数与可用于选择的表型多样性联系起来。

IF 2.1 3区 生物学 Q4 BIOCHEMISTRY & MOLECULAR BIOLOGY
Journal of Molecular Evolution Pub Date : 2023-10-01 Epub Date: 2023-08-25 DOI:10.1007/s00239-023-10127-y
Michael A Savageau
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引用次数: 0

摘要

理论群体遗传学和进化中的两个长期挑战是预测突变产生的可供选择的表型多样性的分布,以及确定突变、选择和漂移的相互作用,以表征进化平衡和动力学。实现这种预测的更根本原因是目前无法将基因型与表型因果联系起来。这种连接需要三个主要的机制映射——遗传序列与分子过程的动力学参数,动力学参数与生化系统表型,以及生化表型与生物体表型。本文介绍了一个理论框架,表型设计空间(PDS)框架,通过专注于动力学参数与生化系统表型的映射来应对这些挑战。它提供了一种定量理论,其关键特征包括(1)基于生物化学动力学对表型进行数学上严格的定义,(2)完整表型库的计数,以及(3)独立于其上下文相关选择或适应度贡献的每个表型的功能表征。该框架建立在设计空间方法的基础上,该方法将系统表型与遗传决定的参数和环境决定的变量联系起来。它还具有自动化预测经历稳态指数增长的微生物种群中表型特异性突变速率常数和表型多样性平衡分布的潜力,这为比较更现实的情况提供了理想的参考。尽管该框架非常通用和灵活,但对于不同的功能、组织和环境,细节无疑会有所不同。在这里,一个假设的案例研究涉及一个小分子系统,一个原始昼夜节律钟,用来介绍这个框架,并说明它在特定情况下的用途。该框架建立在基本的生物化学动力学基础上。因此,该基础基于线性代数和合理的物理假设,这为实验测试和进一步阐述提供了许多机会,以应对目前超出其范围的复杂多细胞生物。该讨论将PDS框架的结果与其他理论群体遗传学方法的结果进行了比较。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Phenotype Design Space Provides a Mechanistic Framework Relating Molecular Parameters to Phenotype Diversity Available for Selection.

Phenotype Design Space Provides a Mechanistic Framework Relating Molecular Parameters to Phenotype Diversity Available for Selection.

Two long-standing challenges in theoretical population genetics and evolution are predicting the distribution of phenotype diversity generated by mutation and available for selection, and determining the interaction of mutation, selection and drift to characterize evolutionary equilibria and dynamics. More fundamental for enabling such predictions is the current inability to causally link genotype to phenotype. There are three major mechanistic mappings required for such a linking - genetic sequence to kinetic parameters of the molecular processes, kinetic parameters to biochemical system phenotypes, and biochemical phenotypes to organismal phenotypes. This article introduces a theoretical framework, the Phenotype Design Space (PDS) framework, for addressing these challenges by focusing on the mapping of kinetic parameters to biochemical system phenotypes. It provides a quantitative theory whose key features include (1) a mathematically rigorous definition of phenotype based on biochemical kinetics, (2) enumeration of the full phenotypic repertoire, and (3) functional characterization of each phenotype independent of its context-dependent selection or fitness contributions. This framework is built on Design Space methods that relate system phenotypes to genetically determined parameters and environmentally determined variables. It also has the potential to automate prediction of phenotype-specific mutation rate constants and equilibrium distributions of phenotype diversity in microbial populations undergoing steady-state exponential growth, which provides an ideal reference to which more realistic cases can be compared. Although the framework is quite general and flexible, the details will undoubtedly differ for different functions, organisms and contexts. Here a hypothetical case study involving a small molecular system, a primordial circadian clock, is used to introduce this framework and to illustrate its use in a particular case. The framework is built on fundamental biochemical kinetics. Thus, the foundation is based on linear algebra and reasonable physical assumptions, which provide numerous opportunities for experimental testing and further elaboration to deal with complex multicellular organisms that are currently beyond its scope. The discussion provides a comparison of results from the PDS framework with those from other approaches in theoretical population genetics.

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来源期刊
Journal of Molecular Evolution
Journal of Molecular Evolution 生物-进化生物学
CiteScore
5.50
自引率
2.60%
发文量
36
审稿时长
3 months
期刊介绍: Journal of Molecular Evolution covers experimental, computational, and theoretical work aimed at deciphering features of molecular evolution and the processes bearing on these features, from the initial formation of macromolecular systems through their evolution at the molecular level, the co-evolution of their functions in cellular and organismal systems, and their influence on organismal adaptation, speciation, and ecology. Topics addressed include the evolution of informational macromolecules and their relation to more complex levels of biological organization, including populations and taxa, as well as the molecular basis for the evolution of ecological interactions of species and the use of molecular data to infer fundamental processes in evolutionary ecology. This coverage accommodates such subfields as new genome sequences, comparative structural and functional genomics, population genetics, the molecular evolution of development, the evolution of gene regulation and gene interaction networks, and in vitro evolution of DNA and RNA, molecular evolutionary ecology, and the development of methods and theory that enable molecular evolutionary inference, including but not limited to, phylogenetic methods.
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