Table 1.
Translation-dependent and translation-independent effects of codon usage
| Translation-dependent cell function | Effect of codon usage |
|---|---|
| Translation elongation | Optimal codons speed up the translation elongation rate, while rare codons slow it down, due to differential expression levels of corresponding tRNAs. |
| Translation efficiency | Codon usage regulates protein synthesis by affecting the amount of protein produced per mRNA in a given time. |
| Translation initiation | Rare codons can cause ribosome stalling and may inhibit translation initiation, whereas optimal codons may result in rapid liberation of start codons and high initiation rates. |
| Translation fidelity | Codon usage regulates the fidelity of amino acid incorporation and maintenance of the translation reading frame. |
| Premature termination | Rare codons can cause ribosome stalling and promote eRF1-mediated premature translation termination at sense codons. |
| tRNA expression, modification, and charging | Differential tRNA expression levels and tRNA modification and charging levels determine codon usage-biased mRNA translation in different tissues and cell types. |
| Cotranslational protein folding | The effect of codon usage on translation elongation speed affects the time available for the cotranslational protein folding process, thus affecting protein structure and function. |
| Cotranslational mRNA decay | Rare codons can cause ribosome stalling and promote translation-dependent mRNA decay mediated by the CCR4-NOT complex. |
| Translation-independent cell function | Effect of codon usage |
| Transcription | Codon optimality determines gene transcription levels from fungi to mammalian cells. |
| Chromatin structure | Codon composition affects chromatin structures by affecting transcription activation and suppression-related histone modification marks. |
| Transcription termination | Rare codons promote premature transcription termination through the formation of noncanonical poly(A) signals within open reading frames. |
| mRNA structure | Codon usage changes can result in mRNA structure changes, which may influence RNA stability and translation. |
| Splicing | Codon composition can influence splice site and exonic splicing enhancer and silencer sequences. |
| mRNA localization/transport | Codon usage profiles can influence mRNA cellular transport and localization. |
| mRNA toxicity | mRNAs with certain codon usage profiles can cause cellular toxicity in Escherischia coli. |