Metabolic Flux Is a Determinant of the Evolutionary Rates of Enzyme-Encoding Genes

Colombo, Martino; Laayouni, Hafid; Invergo, Brandon M.; Bertranpetit, Jaume; Montanucci, Ludovica

doi:10.1111/evo.12262

Cited by 17 publications

(15 citation statements)

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“…Despite the appeal of these broad patterns, experimentally determining a causal link between dN/dS and standard metabolic rate appears to be difficult, and the relevant literature seems sparse. However, one recent study examined metabolic flux in three enzyme systems of human erythrocytes (flux is based on the production rate of metabolites), and found that enzymes with high fluxes were under the greatest purifying selection (Colombo et al, 2013). Mitogenomes of salamanders, which have the lowest energy needs among tetrapods, show relaxed purifying selection when compared with frogs (Chong and Mueller, 2013); although there is considerable debate about the influence of metabolic rate on molecular evolution, given complications presented by body size and temperature (reviewed by Glazier (2014)).…”

Section: Discussionmentioning

confidence: 99%

Fast fish face fewer mitochondrial mutations: Patterns of dN/dS across fish mitogenomes

Strohm

Gwiazdowski

Hanner

2015

Gene

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Section: Discussionmentioning

confidence: 99%

Fast fish face fewer mitochondrial mutations: Patterns of dN/dS across fish mitogenomes

Strohm

Gwiazdowski

Hanner

2015

Gene

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“…Additionally, enzymes catalyzing reactions with a high metabolic flux—the rate at which a reaction transforms substrates into products—tend to evolve slowly ( Vitkup et al. 2006 ; Colombo et al. 2014) , and enzymatic domains with a greater influence on the dynamics of a metabolic pathway also tend to be more selectively constrained ( Mannakee and Gutenkunst 2016) .…”

Section: Introductionmentioning

confidence: 99%

Metabolic determinants of enzyme evolution in a genome-scale bacterial metabolic network

Aguilar‐Rodríguez

Wagner

2018

Genome Biology and Evolution

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Different genes and proteins evolve at very different rates. To identify the factors that explain these differences is an important aspect of research in molecular evolution. One such factor is the role a protein plays in a large molecular network. Here, we analyze the evolutionary rates of enzyme-coding genes in the genome-scale metabolic network of Escherichia coli to find the evolutionary constraints imposed by the structure and function of this complex metabolic system. Central and highly connected enzymes appear to evolve more slowly than less connected enzymes, but we find that they do so as a by-product of their high abundance, and not because of their position in the metabolic network. In contrast, enzymes catalyzing reactions with high metabolic flux—high substrate to product conversion rates—evolve slowly even after we account for their abundance. Moreover, enzymes catalyzing reactions that are difficult to by-pass through alternative pathways, such that they are essential in many different genetic backgrounds, also evolve more slowly. Our analyses show that an enzyme’s role in the function of a metabolic network affects its evolution more than its place in the network’s structure. They highlight the value of a system-level perspective for studies of molecular evolution.

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“…This model is based upon an expectation that enzyme function will account for a sizeable fraction of selective constraint on a protein. Several previous studies have examined the relationship between evolutionary rate and pathway flux, including examination of the effects of network topology [ 2 – 5 ], although a picture linked to underlying evolutionary processes has not yet fully emerged.…”

Section: Introductionmentioning

confidence: 99%

Characterizing selective pressures on the pathway for de novo biosynthesis of pyrimidines in yeast

et al. 2015

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BackgroundSelection on proteins is typically measured with the assumption that each protein acts independently. However, selection more likely acts at higher levels of biological organization, requiring an integrative view of protein function. Here, we built a kinetic model for de novo pyrimidine biosynthesis in the yeast Saccharomyces cerevisiae to relate pathway function to selective pressures on individual protein-encoding genes.ResultsGene families across yeast were constructed for each member of the pathway and the ratio of nonsynonymous to synonymous nucleotide substitution rates (dN/dS) was estimated for each enzyme from S. cerevisiae and closely related species. We found a positive relationship between the influence that each enzyme has on pathway function and its selective constraint.ConclusionsWe expect this trend to be locally present for enzymes that have pathway control, but over longer evolutionary timescales we expect that mutation-selection balance may change the enzymes that have pathway control.Electronic supplementary materialThe online version of this article (doi:10.1186/s12862-015-0515-x) contains supplementary material, which is available to authorized users.

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Metabolic Flux Is a Determinant of the Evolutionary Rates of Enzyme-Encoding Genes

Cited by 17 publications

References 50 publications

Fast fish face fewer mitochondrial mutations: Patterns of dN/dS across fish mitogenomes

Fast fish face fewer mitochondrial mutations: Patterns of dN/dS across fish mitogenomes

Metabolic determinants of enzyme evolution in a genome-scale bacterial metabolic network

Characterizing selective pressures on the pathway for de novo biosynthesis of pyrimidines in yeast

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