Genetic encoding of a highly photostable, long lifetime fluorescent amino acid for imaging in mammalian cells.

Acridonylalanine (Acd) is a fluorescent amino acid that is highly photostable, with a high quantum yield and long fluorescence lifetime in water. These properties make it superior to existing genetically encodable fluorescent amino acids for monitoring protein interactions and conformational changes through fluorescence polarization or lifetime experiments, including fluorescence lifetime imaging microscopy (FLIM). Here, we report the genetic incorporation of Acd using engineered pyrrolysine tRNA synthetase (RS) mutants that allow for efficient Acd incorporation in both E. coli and mammalian cells. We compare protein yields and amino acid specificity for these Acd RSs to identify an optimal construct. We also demonstrate the use of Acd in FLIM, where its long lifetime provides strong contrast compared to endogenous fluorophores and engineered fluorescent proteins, which have lifetimes less than 5 ns.

Access to Faster Eukaryotic Cell Labeling with Encoded Tetrazine Amino Acids.

Labeling of biomolecules in live eukaryotic cells has been limited by low component stability and slow reaction rates. We show that genetically encoded tetrazine amino acids in proteins reach reaction rates of 8 × 104 M-1 s-1 with sTCO reagents, making them the fastest site-specific bioorthogonal labels in eukaryotic systems. We demonstrate that tetrazine amino acids are stable on proteins and are capable of quantitative labeling with sTCO reagents. The exceptionally high reaction rate of this ligation minimizes label concentration, allowing for substoichiometric in vivo eukaryotic protein labeling where the concentration of the label is less than the concentration of the protein. This approach offers unprecedented control over the composition and stability of the protein tag. We anticipate that this system will have a broad impact on labeling and imaging studies because it can be used where all generally orthogonal PylRS/tRNA pairs are employed.

Site-Specific Protein Labeling with Tetrazine Amino Acids.

Genetic code expansion is commonly used to introduce bioorthogonal reactive functional groups onto proteins for labeling. In recent years, the inverse electron demand Diels-Alder reaction between tetrazines and strained trans-cyclooctenes has increased in popularity as a bioorthogonal ligation for protein labeling due to its fast reaction rate and high in vivo stability. We provide methods for the facile synthesis of a tetrazine containing amino acid, Tet-v2.0, and the site-specific incorporation of Tet-v2.0 into proteins via genetic code expansion. Furthermore, we demonstrate that proteins containing Tet-v2.0 can be quickly and efficiently reacted with strained alkene labels at low concentrations. This chemistry has enabled the labeling of protein surfaces with fluorophores, inhibitors, or common posttranslational modifications such as glycosylation or lipidation.

Improving target amino acid selectivity in a permissive aminoacyl tRNA synthetase through counter-selection.

The amino acid acridon-2-ylalanine (Acd) can be a valuable probe of protein dynamics, either alone or as part of a Förster resonance energy transfer (FRET) or photo-induced electron transfer (eT) probe pair. We have previously reported the genetic incorporation of Acd by an aminoacyl tRNA synthetase (RS). However, this RS, developed from a library of permissive RSs, also incorporates N-phenyl-aminophenylalanine (Npf), a trace byproduct of one Acd synthetic route. We have performed negative selections in the presence of Npf and analyzed the selectivity of the resulting AcdRSs by in vivo protein expression and detailed kinetic analyses of the purified RSs. We find that selection conferred a ∼50-fold increase in selectivity for Acd over Npf, eliminating incorporation of Npf contaminants, and allowing one to use a high yielding Acd synthetic route for improved overall expression of Acd-containing proteins. More generally, our report also provides a cautionary tale on the use of permissive RSs, as well as a strategy for improving selectivity for the target amino acid.

Ideal Bioorthogonal Reactions Using A Site-Specifically Encoded Tetrazine Amino Acid.

Bioorthogonal reactions for labeling biomolecules in live cells have been limited by slow reaction rates or low component selectivity and stability. Ideal bioorthogonal reactions with high reaction rates, high selectivity, and high stability would allow for stoichiometric labeling of biomolecules in minutes and eliminate the need to wash out excess labeling reagent. Currently, no general method exists for controlled stoichiometric or substoichiometric labeling of proteins in live cells. To overcome this limitation, we developed a significantly improved tetrazine-containing amino acid (Tet-v2.0) and genetically encoded Tet-v2.0 with an evolved aminoacyl-tRNA synthetase/tRNA(CUA) pair. We demonstrated in cellulo that protein containing Tet-v2.0 reacts selectively with cyclopropane-fused trans-cyclooctene (sTCO) with a bimolecular rate constant of 72,500 ± 1660 M(-1) s(-1) without reacting with other cellular components. This bioorthogonal ligation of Tet-v2.0-protein reacts in cellulo with substoichiometric amounts of sTCO-label fast enough to remove the labeling reagent from media in minutes, thereby eliminating the need to wash out label. This ideal bioorthogonal reaction will enable the monitoring of a larger window of cellular processes in real time.

1,2,4-Triazines Are Versatile Bioorthogonal Reagents.

A new class of bioorthogonal reagents, 1,2,4-triazines, is described. These scaffolds are stable in biological media and capable of robust reactivity with trans-cyclooctene (TCO). The enhanced stability of the triazine scaffold enabled its direct use in recombinant protein production. The triazine-TCO reaction can also be used in tandem with other bioorthogonal cycloaddition reactions. These features fill current voids in the bioorthogonal toolkit.