Encoding latent SuFEx reactive meta-fluorosulfate tyrosine to expand covalent bonding of proteins.

The introduction of new covalent bonds into proteins is affording novel avenues for protein research and applications, yet it remains difficult to generate covalent linkages at all possible sites and across diverse protein classes. Herein, we genetically encoded meta-fluorosulfate-L-tyrosine (mFSY) to selectively react with lysine, tyrosine, and histidine via proximity-enabled SuFEx reaction. mFSY was able to target residues that were elusive for previous unnatural amino acids, and permitted engineering of various proteins including affibody, nanobody, and Fab into covalent binders that irreversibly cross-linked EGFR and HER2. mFSY is thus valuable for developing covalent proteins for biological research, synthetic biology, and biotherapeutics.

A Genetically Encoded Fluorosulfonyloxybenzoyl-l-lysine for Expansive Covalent Bonding of Proteins via SuFEx Chemistry.

Genetically introducing novel chemical bonds into proteins provides innovative avenues for biochemical research, protein engineering, and biotherapeutic applications. Recently, latent bioreactive unnatural amino acids (Uaas) have been incorporated into proteins to covalently target natural residues through proximity-enabled reactivity. Aryl fluorosulfate is particularly attractive due to its exceptional biocompatibility and multitargeting capability via sulfur(VI) fluoride exchange (SuFEx) reaction. Thus far, fluorosulfate-l-tyrosine (FSY) is the only aryl fluorosulfate-containing Uaa that has been genetically encoded. FSY has a relatively rigid and short side chain, which restricts the diversity of proteins targetable and the scope of applications. Here we designed and genetically encoded a new latent bioreactive Uaa, fluorosulfonyloxybenzoyl-l-lysine (FSK), in E. coli and mammalian cells. Due to its long and flexible aryl fluorosulfate-containing side chain, FSK was particularly useful in covalently linking protein sites that are unreachable with FSY, both intra- and intermolecularly, in vitro and in live cells. In addition, we created covalent nanobodies that irreversibly bound to epidermal growth factor receptors (EGFR) on cells, with FSK and FSY targeting distinct positions on EGFR to counter potential mutational resistance. Moreover, we established the use of FSK and FSY for genetically encoded chemical cross-linking to capture elusive enzyme-substrate interactions in live cells, allowing us to target residues aside from Cys and to cross-link at the binding periphery. FSK complements FSY to expand target diversity and versatility. Together, they provide a powerful, genetically encoded, latent bioreactive SuFEx system for creating covalent bonds in diverse proteins in vitro and in vivo, which will be widely useful for biological research and applications.

Covalent peptides and proteins for therapeutics.

Drugs with a covalent mechanism of action benefit from enhanced potency, selectivity, and in vivo efficacy. Historically, the only covalent drugs on the market have been covalent small molecules. However, many proteins and protein-protein interactions cannot be targeted by small molecules due to their lack of small molecule binding pockets, and are thus deemed "undruggable." In order to drug the undruggable, peptide and protein therapeutics that can better bind to flat protein surfaces have been developed. Until recently, peptide and protein therapeutics have had noncovalent mechanisms of action. The recent advancement of unnatural amino acid chemistry, along with the development of better and more specific electrophilic warheads, has allowed for the application of covalent mechanisms to peptide and protein drugs. Covalent peptide and protein therapeutics have the potential to benefit from the same advantages that covalent small molecules have over their noncovalent counterparts. Here we provide a brief overview of the chemistry that makes this advancement possible, as well as examples of covalent peptides and the first covalent protein drug. These examples successfully crosslink their target proteins and have beneficial therapeutic effects.