Frontiers in Microbiology (May 2022)

T-G-A Deficiency Pattern in Protein-Coding Genes and Its Potential Reason

  • Yan-Ting Jin,
  • Yan-Ting Jin,
  • Dong-Kai Pu,
  • Hai-Xia Guo,
  • Zixin Deng,
  • Ling-Ling Chen,
  • Feng-Biao Guo

DOI
https://doi.org/10.3389/fmicb.2022.847325
Journal volume & issue
Vol. 13

Abstract

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If a stop codon appears within one gene, then its translation will be terminated earlier than expected. False folding of premature protein will be adverse to the host; hence, all functional genes would tend to avoid the intragenic stop codons. Therefore, we hypothesize that there will be less frequency of nucleotides corresponding to stop codons at each codon position of genes. Here, we validate this inference by investigating the nucleotide frequency at a large scale and results from 19,911 prokaryote genomes revealed that nucleotides coinciding with stop codons indeed have the lowest frequency in most genomes. Interestingly, genes with three types of stop codons all tend to follow a T-G-A deficiency pattern, suggesting that the property of avoiding intragenic termination pressure is the same and the major stop codon TGA plays a dominant role in this effect. Finally, a positive correlation between the TGA deficiency extent and the base length was observed in start-experimentally verified genes of Escherichia coli (E. coli). This strengthens the proof of our hypothesis. The T-G-A deficiency pattern observed would help to understand the evolution of codon usage tactics in extant organisms.

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