Insights on the Evolution of Metabolic Networks of Unicellular Translationally Biased Organisms from Transcriptomic Data and Sequence Analysis

Carbone, Alessandra; Madden, Richard H.

doi:10.1007/s00239-004-0317-z

Cited by 13 publications

(10 citation statements)

References 50 publications

(72 reference statements)

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“…The most prominent trend in our results is consistent with previous research [28], [33], with translational selection readily acting on genes involved in protein production and in energy metabolism. Genes that are rarely OCU are involved in regulation, DNA replication and repair, sensing of stimuli, and most kinds of transport, except the electron transport chain and ATP synthesis-coupled H + transport.…”

Section: Resultssupporting

confidence: 92%

“…If organisms defined by a specific lifestyle show a tendency contrary to the general trend, and this tendency is constrained to a gene functional category, this correlation could be biologically meaningful. An example illustrative of this principle was previously brought forward in work by Karlin [40] and Carbone [28], where the glycolysis genes were claimed to be more frequently codon-optimized in anaerobic bacteria. Indeed, we detected this association (GO∶6096, enrichment = 2.1x, p = 10 −33 ) alongside with a – not unexpected – increase in OCU frequency of carbohydrate transporters (GO∶8643, enrichment = 1.8x, p = 10 −14 ).…”

Section: Resultsmentioning

confidence: 99%

“…Interestingly, several authors that relied on a codon distance measure have found that gene functions close in codon usage to RP genes in E. coli also have RP-like codon usage in some of the organisms which are supposed to lack translational selection, see e.g. the glycolysis genes in H. pylori [28] or respiration and ATP synthase genes in B. floridanus [29].…”

Section: Introductionmentioning

confidence: 99%

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Translational Selection Is Ubiquitous in Prokaryotes

et al. 2010

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Codon usage bias in prokaryotic genomes is largely a consequence of background substitution patterns in DNA, but highly expressed genes may show a preference towards codons that enable more efficient and/or accurate translation. We introduce a novel approach based on supervised machine learning that detects effects of translational selection on genes, while controlling for local variation in nucleotide substitution patterns represented as sequence composition of intergenic DNA. A cornerstone of our method is a Random Forest classifier that outperformed previous distance measure-based approaches, such as the codon adaptation index, in the task of discerning the (highly expressed) ribosomal protein genes by their codon frequencies. Unlike previous reports, we show evidence that translational selection in prokaryotes is practically universal: in 460 of 461 examined microbial genomes, we find that a subset of genes shows a higher codon usage similarity to the ribosomal proteins than would be expected from the local sequence composition. These genes constitute a substantial part of the genome—between 5% and 33%, depending on genome size—while also exhibiting higher experimentally measured mRNA abundances and tending toward codons that match tRNA anticodons by canonical base pairing. Certain gene functional categories are generally enriched with, or depleted of codon-optimized genes, the trends of enrichment/depletion being conserved between Archaea and Bacteria. Prominent exceptions from these trends might indicate genes with alternative physiological roles; we speculate on specific examples related to detoxication of oxygen radicals and ammonia and to possible misannotations of asparaginyl–tRNA synthetases. Since the presence of codon optimizations on genes is a valid proxy for expression levels in fully sequenced genomes, we provide an example of an “adaptome” by highlighting gene functions with expression levels elevated specifically in thermophilic Bacteria and Archaea.

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Section: Resultssupporting

confidence: 92%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Translational Selection Is Ubiquitous in Prokaryotes

et al. 2010

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“…They organize in two different positional networks, which occupy distinguished chromosomal ‘facets' over the same period (Figure 5A; Supplementary Figure 8). It might appear striking that the set of genes involved in E. coli K12 metabolism is periodically organized in the same way as the set of core genes (compare violet and red curves in Figure 5A), but in fact, core genes have been used already in Carbone and Madden (2005) to identify key metabolic networks for a number of bacteria, including E. coli K12 , and to highlight that genes involved in metabolism are subject to a strong evolutionary pressure on their codon bias. Our current finding adds a new insight on our understanding of the evolutionary pressure undergoing metabolic pathways, reporting that these genes need also to preserve a regular positional distribution along the chromosome.…”

Section: Discussionmentioning

confidence: 99%

Chromosomal periodicity and positional networks of genes in Escherichia coli

Mathelier

Carbone

2010

Molecular Systems Biology

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Escherichia coli periodic gene distribution is identified for a periodic interval of 33 kb.Two positional networks of genes are discovered by studying gene periodic distribution: one is driven by metabolic genes and the other by genes involved in cellular processing and signaling.A functional core of Escherichia coli genes drives gene periodic distribution.A few chromosomal regions that preserve gene transcription profiles across environmental changes are identified.This single genome analysis approach can be taken as a footprint for a large-scale bacterial and archaeal periodic distribution analysis.

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“…However, the analysis of many genomes has revealed that there is a fraction of genes that show no evidence for translational selection linked to codon usage (Carbone and Madden 2005; dos Reis et al 2004; Sharp et al 2005). This observation is not supported by recent, multi-genome, studies indicating that the translational selection for codon usage seems universal, at least in prokaryotes (Hershberg and Petrov 2008; Supek et al 2010) and plastids (Suzuki and Morton 2016).…”

mentioning

confidence: 99%

The Impact of Selection at the Amino Acid Level on the Usage of Synonymous Codons

Błażej

Wnętrzak

Mackiewicz

2017

G3 Genes|Genomes|Genetics

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There are two main forces that affect usage of synonymous codons: directional mutational pressure and selection. The effectiveness of protein translation is usually considered as the main selectional factor. However, biased codon usage can also be a byproduct of a general selection at the amino acid level interacting with nucleotide replacements. To evaluate the validity and strength of such an effect, we superimposed >3.5 billion unrestricted mutational processes on the selection of nonsynonymous substitutions based on the differences in physicochemical properties of the coded amino acids. Using a modified evolutionary optimization algorithm, we determined the conditions in which the effect on the relative codon usage is maximized. We found that the effect is enhanced by mutational processes generating more adenine and thymine than guanine and cytosine, as well as more purines than pyrimidines. Interestingly, this effect is observed only under an unrestricted model of nucleotide substitution, and disappears when the mutational process is time-reversible. Comparison of the simulation results with data for real protein coding sequences indicates that the impact of selection at the amino acid level on synonymous codon usage cannot be neglected. Furthermore, it can considerably interfere, especially in AT-rich genomes, with other selections on codon usage, e.g., translational efficiency. It may also lead to difficulties in the recognition of other effects influencing codon bias, and an overestimation of protein coding sequences whose codon usage is subjected to adaptational selection.

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Insights on the Evolution of Metabolic Networks of Unicellular Translationally Biased Organisms from Transcriptomic Data and Sequence Analysis

Cited by 13 publications

References 50 publications

Translational Selection Is Ubiquitous in Prokaryotes

Translational Selection Is Ubiquitous in Prokaryotes

Chromosomal periodicity and positional networks of genes in Escherichia coli

The Impact of Selection at the Amino Acid Level on the Usage of Synonymous Codons

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