A new selective force driving metabolic gene clustering.

IF 5 2区生物学 Q1 MICROBIOLOGY

mSystems Pub Date : 2024-10-28 DOI:10.1128/msystems.00960-24

Marco Fondi, Francesco Pini, Christopher Riccardi, Pietro Gemo, Matteo Brilli

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引用次数: 0

Abstract

The evolution of operons has puzzled evolutionary biologists since their discovery, and many theories exist to explain their emergence, spreading, and evolutionary conservation. In this work, we suggest that DNA replication introduces a selective force for the clustering of functionally related genes on chromosomes, which we interpret as a preliminary and necessary step in operon formation. Our reasoning starts from the observation that DNA replication produces copy number variations of genomic regions, and we propose that such changes perturb metabolism. The formalization of this effect by exploiting concepts from metabolic control analysis suggests that the minimization of such perturbations during evolution could be achieved through the formation of gene clusters and operons. We support our theoretical derivations with simulations based on a realistic metabolic network, and we confirm that present-day genomes have a degree of compaction of functionally related genes, which is significantly correlated to the proposed perturbations introduced by replication. The formation of clusters of functionally related genes in microbial genomes has puzzled microbiologists since their first discovery. Here, we suggest that replication, and the copy number variations due to the replisome passage, might play a role in the process through a perturbation in metabolite homeostasis. We provide theoretical support to this hypothesis, and we found that both simulations and genomic analysis support our hypothesis.

Importance: The formation of clusters of functionally related genes in microbial genomes has puzzled microbiologists since their discovery. Here, we suggest that replication, and the copy number variations due to the replisome passage, might play a role in the process through a perturbation in metabolite homeostasis. We provide theoretical support to this hypothesis, and we found that both simulations and genomic analysis support our hypothesis.

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驱动代谢基因聚类的新选择性力量

操作子的进化自发现以来一直困扰着进化生物学家，有许多理论可以解释操作子的出现、传播和进化保护。在这项工作中，我们认为 DNA 复制为染色体上功能相关基因的聚类引入了一种选择性力量，我们将其解释为操作子形成的初步和必要步骤。我们的推理源于对 DNA 复制会导致基因组区域拷贝数变化的观察，并提出这种变化会扰乱新陈代谢。通过利用代谢控制分析中的概念对这种效应进行形式化，我们认为在进化过程中，可以通过形成基因簇和操作子来尽量减少这种扰动。我们通过基于现实代谢网络的模拟来支持我们的理论推导，并证实现今的基因组在一定程度上存在功能相关基因的压缩，这与所提出的复制带来的扰动显著相关。微生物基因组中功能相关基因簇的形成自首次发现以来就一直困扰着微生物学家。在这里，我们认为复制以及复制体通过时产生的拷贝数变化可能会通过扰乱代谢平衡在这一过程中发挥作用。我们为这一假设提供了理论支持，并发现模拟和基因组分析都支持我们的假设：重要意义：微生物基因组中功能相关基因簇的形成自发现以来一直困扰着微生物学家。在这里，我们认为复制以及复制体通过时产生的拷贝数变化可能会通过扰乱代谢平衡在这一过程中发挥作用。我们为这一假设提供了理论支持，并发现模拟和基因组分析都支持我们的假设。

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

mSystems Biochemistry, Genetics and Molecular Biology-Biochemistry

CiteScore

10.50

自引率

3.10%

发文量

308

审稿时长

13 weeks

期刊介绍： mSystems™ will publish preeminent work that stems from applying technologies for high-throughput analyses to achieve insights into the metabolic and regulatory systems at the scale of both the single cell and microbial communities. The scope of mSystems™ encompasses all important biological and biochemical findings drawn from analyses of large data sets, as well as new computational approaches for deriving these insights. mSystems™ will welcome submissions from researchers who focus on the microbiome, genomics, metagenomics, transcriptomics, metabolomics, proteomics, glycomics, bioinformatics, and computational microbiology. mSystems™ will provide streamlined decisions, while carrying on ASM''s tradition of rigorous peer review.