Matthias P. Exner

Site-Directed and Global Incorporation of Orthogonal and Isostructural Noncanonical Amino Acids into the Ribosomal Lasso Peptide Capistruin

Expansion of the structural diversity of peptide antibiotics was performed through two different methods. Supplementation‐based incorporation (SPI) and stop‐codon suppression (SCS) approaches were used for co‐translational incorporation of isostructural and orthogonal noncanonical amino acids (ncAAs) into the lasso peptide capistruin. Two ncAAs were employed for the SPI method and five for the SCS method; each of them probing the incorporation of ncAAs in strategic positions of the molecule. Evaluation of the assembly by HR‐ESI‐MS proved more successful for the SCS method. Bio‐orthogonal chemistry was used for post‐biosynthetic modification of capistruin congener Cap_Alk10 containing the ncAA Alk (Nε‐Alloc‐L‐lysine) instead of Ala. A second‐generation Hoveyda–Grubbs catalyst was used for an in vitro metathesis reaction with Cap_Alk10 and an allyl alcohol, which offers options for post‐biosynthetic modifications. The use of synthetic biology allows for the in vivo production of new peptide‐based antibiotics from an expanded amino acid repertoire.

Design of an S-Allylcysteine in situ production and incorporation system based on a novel pyrrolysyl-tRNA synthetase variant

The noncanonical amino acid S‐allyl cysteine (Sac) is one of the major compounds of garlic extract and exhibits a range of biological activities. It is also a small bioorthogonal alkene tag capable of undergoing controlled chemical modifications, such as photoinduced thiol‐ene coupling or Pd‐mediated deprotection. Its small size guarantees minimal interference with protein structure and function. Here, we report a simple protocol efficiently to couple in‐situ semisynthetic biosynthesis of Sac and its incorporation into proteins in response to amber (UAG) stop codons. We exploited the exceptional malleability of pyrrolysyl‐tRNA synthetase (PylRS) and evolved an S‐allylcysteinyl‐tRNA synthetase (SacRS) capable of specifically accepting the small, polar amino acid instead of its long and bulky aliphatic natural substrate. We succeeded in generating a novel and inexpensive strategy for the incorporation of a functionally versatile amino acid. This will help in the conversion of orthogonal translation from a standard technique in academic research to industrial biotechnology.

Cell-free expression with the toxic amino acid canavanine.

Canavanine is a naturally occurring noncanonical amino acid, which is analogous to arginine. It is a potent antimetabolite and natural allelochemic agent, capable of affecting or blocking regulatory and catalytic reactions that involve arginine. Incorporated into proteins at arginine positions, canavanine can be detrimental to protein stability and functional integrity. Although incorporation of canavanine into proteins has long been documented, due to its toxicity, expression in Escherichia coli and other common hosts remains a considerable challenge. Here, we present a simple, cell-free expression system with markedly improved performance compared to heterologous expression. The cell-free expression system does not require any tuning besides substitution of arginine by canavanine. We show that our technique enables highly efficient protein expression in small volumes with arginine being fully replaced by canavanine for functional and structural studies.

One-Pot Synthesis of Unprotected Anomeric Glycosyl Thiols in Water for Glycan Ligation Reactions with Highly Functionalized Sugars.

Chemical synthesis of oligosaccharide conjugates is essential for studying the functional relevance of carbohydrates, and this task would be facilitated considerably if reliable methods for the anomeric ligation of unprotected sugars in water were available. Here, a method for the preparation of anomeric glycosyl thiols from complex unprotected mono-, di-, and oligosaccharides is presented. By exploiting the neighboring-group effect of the 2-acetamido-group, 1,2-oxazolines are generated and converted into 1-glycosyl thioesters through treatment with 1-thioacids. The unprotected anomeric glycosyl thiolates released in situ were conjugated to Michael acceptors, aliphatic halogenides, and aziridines to furnish versatile glycoconjugates. Conjugation of amino acids and proteins was accomplished using the thiol-ene reaction with terminal olefins. This method gives efficient access to anomeric glycosyl thiols and thiolates, which enables anomeric ligations of complex unprotected glycans in water.

Incorporation of Amino Acids with Long-Chain Terminal Olefins into Proteins

The increasing need for site-specific protein decorations that mimic natural posttranslational modifications requires access to a variety of noncanonical amino acids with moieties enabling bioorthogonal conjugation chemistry. Here we present the incorporation of long-chain olefinic amino acids into model proteins with rational variants of pyrrolysyl-tRNA synthetase (PylRS). Nε-heptenoyl lysine was incorporated for the first time using the known promiscuous variant PylRS(Y306A/Y384F), and Nε-pentenoyl lysine was incorporated in significant yields with the novel variant PylRS(C348A/Y384F). This is the only example of rational modification at position C348 to enlarge the enzyme’s binding pocket. Furthermore, we demonstrate the feasibility of our chosen amino acids in the thiol-ene conjugation reaction with a thiolated polysaccharide.

Residue-specific Incorporation of Noncanonical Amino Acids into Model Proteins Using an Escherichia coli Cell-free Transcription-translation System

The canonical set of amino acids leads to an exceptionally wide range of protein functionality. Nevertheless, the set of residues still imposes limitations on potential protein applications. The incorporation of noncanonical amino acids can enlarge this scope. There are two complementary approaches for the incorporation of noncanonical amino acids. For site-specific incorporation, in addition to the endogenous canonical translational machineries, an orthogonal aminoacyl-tRNA-synthetase-tRNA pair must be provided that does not interact with the canonical ones. Consequently, a codon that is not assigned to a canonical amino acid, usually a stop codon, is also required. This genetic code expansion enables the incorporation of a noncanonical amino acid at a single, given site within the protein. The here presented work describes residue-specific incorporation where the genetic code is reassigned within the endogenous translational system. The translation machinery accepts the noncanonical amino acid as a surrogate to incorporate it at canonically prescribed locations, i.e., all occurrences of a canonical amino acid in the protein are replaced by the noncanonical one. The incorporation of noncanonical amino acids can change the protein structure, causing considerably modified physical and chemical properties. Noncanonical amino acid analogs often act as cell growth inhibitors for expression hosts since they modify endogenous proteins, limiting in vivo protein production. In vivo incorporation of toxic noncanonical amino acids into proteins remains particularly challenging. Here, a cell-free approach for a complete replacement of L-arginine by the noncanonical amino acid L-canavanine is presented. It circumvents the inherent difficulties of in vivo expression. Additionally, a protocol to prepare target proteins for mass spectral analysis is included. It is shown that L-lysine can be replaced by L-hydroxy-lysine, albeit with lower efficiency. In principle, any noncanonical amino acid analog can be incorporated using the presented method as long as the endogenous in vitro translation system recognizes it.

Orthogonal Protein Translation Using Pyrrolysyl-tRNA Synthetases for Single- and Multiple-Noncanonical Amino Acid Mutagenesis

To date, the two systems most extensively used for noncanonical amino acid (ncAA) incorporation via orthogonal translation are based on the Methanococcus jannaschii TyrRS/tRNA CUATyr and the Methanosarcina barkeri/Methanosarcina mazei PylRS/tRNA CUAPyl pairs. Here, we summarize the development and usage of the pyrrolysine-based system for orthogonal translation, a process that allows for the recombinant production of site-specifically labeled proteins and peptides. Via stop codon suppression in Escherichia coli and mammalian cells, genetically encoded biomolecules can be equipped with a great diversity of chemical functionalities including click chemistry handles, post-translational modifications, and photocaged sidechains.