Codon Usage Bias Covaries with Expression Breadth and the Rate of Synonymous Evolution in Humans, but This is Not Evidence for Selection

Overview

Journal Genetics

Publisher Oxford University Press

Specialty Genetics

Date 2001 Dec 1

PMID 11729162

Citations 79

Authors

A O Urrutia

L D Hurst

Affiliations

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Abstract

In numerous species, from bacteria to Drosophila, evidence suggests that selection acts even on synonymous codon usage: codon bias is greater in more abundantly expressed genes, the rate of synonymous evolution is lower in genes with greater codon bias, and there is consistency between genes in the same species in which codons are preferred. In contrast, in mammals, while nonequal use of alternative codons is observed, the bias is attributed to the background variance in nucleotide concentrations, reflected in the similar nucleotide composition of flanking noncoding and exonic third sites. However, a systematic examination of the covariants of codon usage controlling for background nucleotide content has yet to be performed. Here we present a new method to measure codon bias that corrects for background nucleotide content and apply this to 2396 human genes. Nearly all (99%) exhibit a higher amount of codon bias than expected by chance. The patterns associated with selectively driven codon bias are weakly recovered: Broadly expressed genes have a higher level of bias than do tissue-specific genes, the bias is higher for genes with lower rates of synonymous substitutions, and certain codons are repeatedly preferred. However, while these patterns are suggestive, the first two patterns appear to be methodological artifacts. The last pattern reflects in part biases in usage of nucleotide pairs. We conclude that we find no evidence for selection on codon usage in humans.

Citing Articles

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Fan K, Li Y, Chen Z, Fan L BMC Bioinformatics. 2024; 25(1):309.

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Codon Usage Bias: A Potential Factor Affecting VGLUT Developmental Expression and Protein Evolution.

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The protein domains of vertebrate species in which selection is more effective have greater intrinsic structural disorder.

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The protein domains of vertebrate species in which selection is more effective have greater intrinsic structural disorder.

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The Patterns of Codon Usage between Chordates and Arthropods are Different but Co-evolving with Mutational Biases.

Kotari I, Kosiol C, Borges R Mol Biol Evol. 2024; 41(5).

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