Chemically Acylated tRNAs are Functional in Zebrafish Embryos.

Genetic code expansion has pushed protein chemistry past the canonical 22 amino acids. The key enzymes that make this possible are engineered aminoacyl tRNA synthetases. However, as the number of genetically encoded amino acids has increased over the years, obvious limits in the type and size of novel side chains that can be accommodated by the synthetase enzyme become apparent. Here, we show that chemically acylating tRNAs allow for robust, site-specific incorporation of unnatural amino acids into proteins in zebrafish embryos, an important model organism for human health and development. We apply this approach to incorporate a unique photocaged histidine analogue for which synthetase engineering efforts have failed. Additionally, we demonstrate optical control over different enzymes in live embryos by installing photocaged histidine into their active sites.

Small-Molecule Phosphine Activation of Protein Function in Zebrafish Embryos with an Expanded Genetic Code.

Conditional control of protein function in a living model organism is an important tool for studying the effects of that protein during development and disease. In this chapter, we walk through the steps to generate a small-molecule-activatable enzyme in zebrafish embryos through the incorporation of a noncanonical amino acid into the protein active site. This method can be applied to many enzyme classes, which we highlight with temporal control of a luciferase and a protease. We demonstrate that strategic placement of the noncanonical amino acid completely blocks enzyme activity, which is then promptly restored after addition of the nontoxic small molecule inducer to the embryo water.