Abstract
BackgroundProtein synthesis is one of the extremely important anabolic pathways in the yeast expression system Pichia pastoris. Codon optimization is a commonly adopted strategy for improved protein expression, although unexpected failures did appear sometimes waiting for further exploration. Recently codon bias has been studied to regulate protein folding and activity in many other organisms.ResultsHere the codon bias profile of P. pastoris genome was examined first and a direct correlation between codon translation efficiency and usage frequency was identified. By manipulating the codon choices of both endogenous and heterologous signal peptides, secretion abilities of N-terminal signal peptides were shown to be tolerant towards codon changes. Then two gene candidates with different levels of structural disorder were studied, and full-length codon optimization was found to affect their expression profiles differentially. Finally, more evidences were provided to support possible protein conformation change brought by codon optimization in structurally disordered proteins.ConclusionOur results suggest that codon bias regulates gene expression by modulating several factors including transcription and translation efficiency, protein folding and activity. Because of sequences difference, the extent of affection may be gene specific. For some genes, special codon optimization strategy should be adopted to ensure appropriate expression and conformation.
Highlights
IntroductionThere are 64 codons coding for 20 amino acids plus three stop codons
In the nuclear genome, there are 64 codons coding for 20 amino acids plus three stop codons
Codon adaptation index (CAI) [38] is calculated from relative codon usage frequency (ω), which suggests the chance of a codon being chosen by highly expressed genes. tRNA adaptation index [36] is based on tRNA copy number, and tRNA abundance. tAI mainly describes the chance of a tRNA arriving at the A site among all tRNAs carrying the same amino acid
Summary
There are 64 codons coding for 20 amino acids plus three stop codons. Amino acids except Met and Trp are coded with 2–6 synonymous codons, and the codon selection in coding sequences (CDS) is not random. This is considered as codon usage bias, which appears in almost all genomes [1]. Codon usage bias has been believed to regulate the rate of protein synthesis [2]. More frequent codons are used in highly expressed genes, which help to accelerate translation rate because of the high abundance of the decoding tRNAs [3]. Rare codons slow down protein translation and always accumulate in lowly expressed genes [3, 4]. Codon bias has been studied to regulate protein folding and activity in many other organisms
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