New Platforms to Diversify the Chemical Space of the Expanding Genetic Code

Abstract

Genetic code expansion (GCE) is an enabling technology whereby noncanonical amino acids (ncAAs) can be site-specifically incorporated into proteins of interest, allowing for vast applications and an improved understanding of structure-function relationships in biology. GCE stands out as a versatile platform due to the use of a variety of engineered aminoacyl-tRNA synthetase (aaRS)/transfer RNA (tRNA) pairs, and it has endowed proteins with over 200 distinct ncAAs in both prokaryotic and eukaryotic systems. My dissertation outlines endeavors aimed at broadening the chemical diversity of α-amino side chains and substrates beyond α-amino acids in both prokaryotic and eukaryotic organisms through the utilization of GCE technology. This was achieved by creating universal GCE platforms called altered translational machinery (ATM) strains, which eliminate the limitations of orthogonality for the evolution of aaRS/tRNA pairs. This expansion enables the use of the same aaRS/tRNA pair for ncAA incorporation functionalities into multiple domains of life. Moreover, the diversity of ncAAs that can be genetically encoded in eukaryotic cells was enhanced by evolving the E. coli leucyl-tRNA synthetase (EcLeuRS)/tRNA pair using a yeast-based selection system. This advancement facilitated the incorporation of novel ncAAs into proteins within mammalian cells. Additionally, I worked toward developing a platform for introducing monomers into the genetic code beyond α-amino acids. This involved developing an aaRS evolution platform that doesn't rely on translation as a selectable readout. Finally, I worked towards the creation of polyester-polyamide oligomers with sequence control as a step towards the goal of generating sequence-defined biopolymers with new-to-nature backbone chemistries.