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tRNA copy number and codon usage in the sea cucumber genome provide insights into adaptive translation for saponin biosynthesis.

Chengzhang LiuJianbo YuanXiaojun ZhangSongjun JinFuhua LiJianhai Xiang
Published in: Open biology (2021)
Genomic tRNA copy numbers determine cytoplasmic tRNA abundances, which in turn influence translation efficiency, but the underlying mechanism is not well understood. Using the sea cucumber Apostichopus japonicus as a model, we combined genomic sequence, transcriptome expression and ecological food resource data to study its codon usage adaptation. The results showed that, unlike intragenic non-coding RNAs, transfer RNAs (tRNAs) tended to be transcribed independently. This may be attributed to their specific Pol III promoters that lack transcriptional regulation, which may underlie the correlation between genomic copy number and cytoplasmic abundance of tRNAs. Moreover, codon usage optimization was mostly restrained by a gene's amino acid sequence, which might be a compromise between functionality and translation efficiency for stress responses were highly optimized for most echinoderms, while enzymes for saponin biosynthesis (LAS, CYPs and UGTs) were especially optimized in sea cucumbers, which might promote saponin synthesis as a defence strategy. The genomic tRNA content of A. japonicus was positively correlated with amino acid content in its natural food particles, which should promote its efficiency in protein synthesis. We propose that coevolution between genomic tRNA content and codon usage of sea cucumbers facilitates their saponin synthesis and survival using food resources with low nutrient content.
Keyphrases
  • copy number
  • mitochondrial dna
  • genome wide
  • amino acid
  • dna methylation
  • human health
  • poor prognosis
  • gene expression
  • climate change
  • risk assessment
  • big data
  • electronic health record
  • data analysis
  • single cell