Efficient Genetic Code Expansion Without Host Genome Modifications

Abstract

AbstractSupplementing translation with non-canonical amino acids (ncAAs) can yield protein sequences with new-to-nature functions, but existing ncAA incorporation strategies suffer from low efficiency and context dependence. We uncover codon usage as a previously unrecognized contributor to efficient genetic code expansion using non-native codons. Relying only on conventionalE. colistrains with native ribosomes, we develop a novel plasmid-based codon compression strategy that minimizes context dependence and improves ncAA incorporation at quadruplet codons. We confirm that this strategy is compatible with all known genetic code expansion resources, which allows us to identify 12 mutually orthogonal tRNA–synthetase pairs. Enabled by these findings, we evolve and optimize five tRNA–synthetase pairs to incorporate a broad repertoire of ncAAs at orthogonal quadruplet codons. Finally, we extend these resources to anin vivobiosynthesis platform that can readily create >100 new-to-nature peptide macrocycles bearing up to three unique ncAAs. Given the generality of our approach and streamlined resources, our findings will accelerate innovations in multiplexed genetic code expansion and enable the discovery of chemically diverse biomolecules for researcher-defined applications.