ABSTRACT
The wide range of moieties installed in ribosomally synthesized and post-translationally modified peptides (RiPPs) suggests largely untapped potential for protein engineering. However, many RiPP maturases recognize target peptide precursors through an N-terminal leader sequence that is challenging to adapt to proteins. We have recently reported a family of enzymes that splice XYG sites in RiPPs to install α-keto-ß-amino acids. Backbone modifications influence diverse protein properties, yet the toolkit to install ß-amino acids is limited. Here we report their leader-independent incorporation into proteins in E. coli. Integrating an 11-residue splice tag into six different proteins permitted the site-selective introduction of ß-residues in vivo. The motif fusion at C-, N-terminal, and internal positions yielded various ß-residues. Our approach complements the few existing methods to introduce ß-amino acids or ketone-bearing moieties, suggesting diverse applications in chemical biology.