Abstract
Translation using four-base codons occurs in both natural and synthetic systems. What constraints contributed to the universal adoption of a triplet codon, rather than quadruplet codon, genetic code? Here, we investigate the tolerance of the Escherichia coli genetic code to tRNA mutations that increase codon size. We found that tRNAs from all 20 canonical isoacceptor classes can be converted to functional quadruplet tRNAs (qtRNAs). Many of these selectively incorporate a single amino acid in response to a specified four-base codon, as confirmed with mass spectrometry. However, efficient quadruplet codon translation often requires multiple tRNA mutations. Moreover, while tRNAs were largely amenable to quadruplet conversion, only nine of the twenty aminoacyl tRNA synthetases tolerate quadruplet anticodons. These may constitute a functional and mutually orthogonal set, but one that sharply limits the chemical alphabet available to a nascent all-quadruplet code. Our results suggest that the triplet codon code was selected because it is simpler and sufficient, not because a quadruplet codon code is unachievable. These data provide a blueprint for synthetic biologists to deliberately engineer an all-quadruplet expanded genetic code.
Highlights
The genetic code is determined by a combination of tRNAs and aminoacyl tRNA synthetases (AARSs)
Many known examples of frameshift suppressors contain single base 113 insertions in the anticodon that convert a triplet tRNA into a quadruplet tRNA
We initially tested whether tRNAs can evolve into qtRNAs115 through simple point insertions
Summary
The genetic code is determined by a combination of tRNAs and aminoacyl tRNA synthetases (AARSs). Codons are dictated by the three 52 bases in the center of the anticodon loop of each tRNA, which undergo. Watson-Crick base pairing to an mRNA transcript during translation, enabling accurate codon recognition. The correspondence between codons and amino acids — one tRNA isoacceptor class for each canonical amino acid — is dictated by the twenty AARSs which recognize bases (identity elements) in the tRNAs, and attach 58 the cognate amino acid onto only the CCA 3’ terminus of the cognate tRNA. Anticodon mutations frequently alter or abolish 61 selective charging with the cognate amino acid because most AARSs rely[62] on bases in the anticodon to identify the cognate tRNA. Certain[63] natural anticodon mutations generate ‘suppressor’ tRNAs that insert their 64 cognate amino acid in response to 5’-UAG-3’ stop codons pairing with its
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