Synthetase polyspecificity as a tool to modulate protein function

The site-specific incorporation of unnatural amino acids (UAAs) into proteins in bacteria is made possible by the evolution of aminoacyl-tRNA synthetases that selectively recognize and aminoacylate the amino acid of interest. Recently we have discovered that some of the previously evolved aaRSs display a degree of polyspecificity and are capable of recognizing multiple UAAs. Herein we report the polyspecificity of an aaRS evolved to encode a comarin containing amino acid. This polyspecificity was then exploited to introduce several UAAs into the fluorophore of GFP, altering its photophysical properties.     

Translational incorporation of multiple unnatural amino acids in a cell-free protein synthesis system

Nature uses 20 canonical amino acids as the standard building blocks of proteins; however, the incorporation of unnatural amino acids (Uaas) can endow polypeptide sequences with new structural and functional features. Although aminoacyl-tRNA synthetases (aaRSs) can accept an array of Uaas in place of their natural counterparts, Uaas generally are charged to tRNAs with substantially lower efficiencies. This particularly makes it difficult to incorporate multiple Uaas into a protein sequence. In this study, we discuss the use of a cell-free protein synthesis system as a versatile platform for the efficient incorporation of multiple Uaas into proteins. Taking advantage of the open nature of cell-free protein synthesis that allows flexible manipulation of its ingredients, we explored the application of Uaas in 10 mM range of concentrations to kinetically overcome the low affinity of aaRSs towards unnatural amino acids. Supplementation of recombinant aaRSs was also investigated to further increase the Uaa-tRNA pools. As a result, under the modified reaction conditions, as many as five different Uaas could be incorporated into a single protein without compromising the yield of protein synthesis.     

Novel tRNA aminoacylation mechanisms

In nature, ribosomally synthesized proteins can contain at least 22 different amino acids: the 20 common amino acids as well as selenocysteine and pyrrolysine. Each of these amino acids is inserted into proteins codon-specifically via an aminoacyl-transfer RNA (aa-tRNA). In most cases, these aa-tRNAs are biosynthesized directly by a set of highly specific and accurate aminoacyl-tRNA synthetases (aaRSs). However, in some cases aaRSs with relaxed or novel substrate specificities cooperate with other enzymes to generate specific canonical and non-canonical aminoacyl-tRNAs.     

Enzymatic tRNA acylation by acid and alpha-hydroxy acid analogues of amino acids

Incorporation of unnatural amino acids with unique chemical functionalities has proven to be a valuable tool for expansion of the functional repertoire and properties of proteins as well as for structure-function analysis. Incorporation of alpha-hydroxy acids (primary amino group is substituted with hydroxyl) leads to the synthesis of proteins with peptide bonds being substituted by ester bonds. Practical application of this modification is limited by the necessity to prepare corresponding acylated tRNA by chemical synthesis. We investigated the possibility of enzymatic incorporation of alpha-hydroxy acid and acid analogues (lacking amino group) of amino acids into tRNA using aminoacyl-tRNA synthetases (aaRSs). We studied direct acylation of tRNAs by alpha-hydroxy acid and acid analogues of amino acids and corresponding chemically synthesized analogues of aminoacyl-adenylates. Using adenylate analogues we were able to enzymatically acylate tRNA with amino acid analogues which were otherwise completely inactive in direct aminoacylation reaction, thus bypassing the natural mechanisms ensuring the selectivity of tRNA aminoacylation. Our results are the first demonstration that the use of synthetic aminoacyl-adenylates as substrates in tRNA aminoacylation reaction may provide a way for incorporation of unnatural amino acids into tRNA, and consequently into proteins.     

The joint evolution of defence and inducibility against natural enemies

The aminoacyl-tRNA synthetases (aaRSs) ensure the fidelity of the translation of the genetic code, covalently attaching appropriate amino acids to the corresponding nucleic acid adaptor molecules-tRNA. The fundamental role of aminoacylation reaction catalysed by aaRSs implies that representatives of the family are thought to be among the earliest proteins to appear. Based on sequence analysis and catalytic domain structure, aaRSs have been partitioned into two classes of 10 enzymes each. However, based on the structural and sequence data only, it will not be easily understood that the present partitioning is not governed by chance. Our findings suggest that organization of amino acid biosynthetic pathways and clustering of aaRSs into different classes are intimately related to one another. A plausible explanation for such a relationship is dictated by early link between aaRSs and amino acids biosynthetic proteins. The aaRSs catalytic cores are highly relevant to the ancient metabolic reactions, namely, amino acids and cofactors biosynthesis. In particular we show that class II aaRSs mostly associated with the primordial amino acids, while class I aaRSs are usually related to amino acids evolved lately. Reasoning from this we propose a possible chronology of genetic code evolution.     

Genetic incorporation of unnatural amino acids into proteins in mammalian cells

We developed a general approach that allows unnatural amino acids with diverse physicochemical and biological properties to be genetically encoded in mammalian cells. A mutant Escherichia coli aminoacyl-tRNA synthetase (aaRS) is first evolved in yeast to selectively aminoacylate its tRNA with the unnatural amino acid of interest. This mutant aaRS together with an amber suppressor tRNA from Bacillus stearothermophilus is then used to site-specifically incorporate the unnatural amino acid into a protein in mammalian cells in response to an amber nonsense codon. We independently incorporated six unnatural amino acids into GFP expressed in CHO cells with efficiencies up to 1 mug protein per 2 x 10(7) cells; mass spectrometry confirmed a high translational fidelity for the unnatural amino acid. This methodology should facilitate the introduction of biological probes into proteins for cellular studies and may ultimately facilitate the synthesis of therapeutic proteins containing unnatural amino acids in mammalian cells.     

Cytosolic aminoacyl-tRNA synthetases: Unanticipated relocations for unexpected functions

Prokaryotic and eukaryotic cytosolic aminoacyl-tRNA synthetases (aaRSs) are essentially known for their conventional function of generating the full set of aminoacyl-tRNA species that are needed to incorporate each organism's repertoire of genetically-encoded amino acids during ribosomal translation of messenger RNAs. However, bacterial and eukaryotic cytosolic aaRSs have been shown to exhibit other essential nonconventional functions. Here we review all the subcellular compartments that prokaryotic and eukaryotic cytosolic aaRSs can reach to exert either a conventional or nontranslational role. We describe the physiological and stress conditions, the mechanisms and the signaling pathways that trigger their relocation and the new functions associated with these relocating cytosolic aaRS. Finally, given that these relocating pools of cytosolic aaRSs participate to a wide range of cellular pathways beyond translation, but equally important for cellular homeostasis, we mention some of the pathologies and diseases associated with the dis-regulation or malfunctioning of these nontranslational functions.     

Reprogramming the amino-acid substrate specificity of orthogonal aminoacyl-tRNA synthetases to expand the genetic code of eukaryotic cells

The genetic code of living organisms has been expanded to allow the site-specific incorporation of unnatural amino acids into proteins in response to the amber stop codon UAG. Numerous amino acids have been incorporated including photo-crosslinkers, chemical handles, heavy atoms and post-translational modifications, and this has created new methods for studying biology and developing protein therapeutics and other biotechnological applications. Here we describe a protocol for reprogramming the amino-acid substrate specificity of aminoacyl-tRNA synthetase enzymes that are orthogonal in eukaryotic cells. The resulting aminoacyl-tRNA synthetases aminoacylate an amber suppressor tRNA with a desired unnatural amino acid, but no natural amino acids, in eukaryotic cells. To achieve this change of enzyme specificity, a library of orthogonal aminoacyl-tRNA synthetase is generated and genetic selections are performed on the library in Saccharomyces cerevisiae. The entire protocol, including characterization of the evolved aminoacyl-tRNA synthetase in S. cerevisiae, can be completed in approximately 1 month.     

On the classes of aminoacyl-tRNA synthetases and the error minimization in the genetic code

As a consequence of the existence of two classes of aminoacyl-tRNA synthetases (aaRSs), we defined two types of mutations: g (mutations that do not change the class of the involved amino acids) and u (those which change the class). We have found that the mean chemical distance resulting from g mutations is smaller than that corresponding to u mutations, indicating that g mutations are responsible for most of the known minimization of the genetic code. This supports models for the origin and evolution of the code, in which new amino acids were added after duplications or modification of existing aaRSs.     

Site-specific labeling of proteins with NMR-active unnatural amino acids

A large number of amino acids other than the canonical amino acids can now be easily incorporated in vivo into proteins at genetically encoded positions. The technology requires an orthogonal tRNA/aminoacyl-tRNA synthetase pair specific for the unnatural amino acid that is added to the media while a TAG amber or frame shift codon specifies the incorporation site in the protein to be studied. These unnatural amino acids can be isotopically labeled and provide unique opportunities for site-specific labeling of proteins for NMR studies. In this perspective, we discuss these opportunities including new photocaged unnatural amino acids, outline usage of metal chelating and spin-labeled unnatural amino acids and expand the approach to in-cell NMR experiments.     

Relationship of the CCA sequence of tRNA with the early evolutional aspect of aminoacyl-tRNA synthetases.

The CCA sequence is common to the 3'-ends of all tRNAs. We investigated the requirement of the CCA sequence in aminoacylation with the cognate aminoacyl-tRNA synthetases (aaRSs) and several interesting conclusions could be drawn. In tRNAs belonging to the class I aaRSs, decreased aminoacylation activities resulted from the substitution of A76 with a pyrimidine, whereas in tRNAs belonging to the class II aaRSs, decreased aminoacylation activities resulted from the substitution with guanine. The results suggest that aminoacylation of proto-tRNA might have started through the direct hydrophobic (or stacking) interaction between the large, hydrophobic amino acid residue (now utilizing a class I aaRS) of aminoacyl-AMP and the 3'-terminal adenine. The shorter distance between the adenine and the 2'-OH position than the 3'-OH position, and the bulkiness and hydrophobicity of amino acids may be important reasons why class I aaRSs select the 2'-OH position in aminoacylation. Molecular mechanics-based conformation modeling also indicated that the resulting positioning of the adenine and the amino acid residue of 2'-aminoacyl-adenosine for large amino acid is in the vicinity. In contrast, in the case of small amino acids (with class II aaRSs) which would not be able to use the hydrophobic interaction, a protein enzyme might have participated in the aminoacylation reaction from an early stage. The active-site folds of aaRSs belonging to each class reflect the history of evolution: typical nucleotide-binding fold (Rossman fold) in the case of class I aaRSs, and primitive fold which is found also among the family of nonribosomal peptide synthetases in the case of class II aaRSs.     

Low modularity of aminoacyl-tRNA substrates in polymerization by the ribosome

Aminoacyl-transfer RNAs contain four standardized units: amino acids, an invariant 3′-terminal CCA, trinucleotide anticodons and tRNA bodies. The degree of interchangeability of the three variable modules is poorly understood, despite its role in evolution and the engineering of translation to incorporate unnatural amino acids. Here, a purified translation system is used to investigate effects of various module swaps on the efficiency of multiple ribosomal incorporations of unnatural aminoacyl-tRNA substrates per peptide product. The yields of products containing three to five adjacent l-amino acids with unnatural side chains are low and cannot be improved by optimization or explained simply by any single factor tested. Though combinations of modules that allow quantitative single unnatural incorporations are found readily, finding combinations that enable efficient synthesis of products containing multiple unnatural amino acids is challenging. This implies that assaying multiple, as opposed to single, incorporations per product is a more stringent assay of substrate activity. The unpredictability of most results illustrates the multifactorial nature of substrate recognition and the value of synthetic biology for testing our understanding of translation. Data indicate that the degree of interchangeability of the modules of aminoacyl-tRNAs is low.     

Phage selection for site-specific incorporation of unnatural amino acids into proteins in vivo.

The development of a method for the site-specific incorporation of unnatural amino acids into proteins in vivo would significantly facilitate studies of the cellular function of proteins, as well as make possible the synthesis of proteins with novel structures and activities. Our approach to this problem consists of the generation of amber suppressor tRNA/aminoacyl-tRNA synthetase pairs that are not catalytically competent with all the endogenous Escherichia coli tRNAs and aminoacyl-tRNA synthetases, followed by directed evolution of such orthogonal aminoacyl-tRNA synthetases to alter their amino acid specificities. To evolve the desired amino acid specificity, a direct selection for site-specific incorporation of unnatural amino acids into a reporter epitope displayed on the surface of M13 phage has been developed and characterized. Under simulated selection conditions, phage particles displaying aspartate were enriched over 300-fold from a pool of phage displaying asparagine using monoclonal antibodies raised against the aspartate-containing epitope. The direct phage selection offers high specificity for the amino acid of interest, eliminating the potential for contamination with synthetases active towards wild-type amino acids in multiple rounds of selection.     

A high-throughput competitive scintillation proximity aminoacyl-tRNA synthetase charging assay to measure amino acid concentration

An enhanced method to measure the concentration of individual naturally occurring free amino acids in solution is described. This relatively simple but robust method combines two previously reported procedures: the use of scintillation proximity assay (SPA) technology to measure aminoacyl-tRNA synthetase (aaRS) activity and the use of aaRS activity to measure amino acid concentration using the enzymatic isotope dilution technique. The format described is called an aaRS competitive scintillation proximity assay (cSPA). This cSPA takes advantage of competition between a fixed concentration of radiolabeled amino acid and an unknown concentration of the same nonradiolabeled amino acid for its cognate tRNA catalyzed by the aaRS specific for that amino acid. Under equilibrium conditions, in the case of limiting tRNA, the rate of the enzyme-catalyzed reaction relative to substrate concentration becomes irrelevant and the enzymatic isotopic dilution technique becomes the simple isotopic dilution technique. Due to the exquisite specificity of the reaction, a crude mixture of tRNAs and aaRSs can be used to detect the concentration of a particular amino acid without interference from noncognate amino acids. When used to monitor aminopeptidase M activity, this assay produced similar results in time course and inhibition experiments as compared with a traditional fluorescent assay. High-throughput compatibility was demonstrated by screening 12,000 compounds against aminopeptidase M in 384-well microtiter plates with Z factors ranging from 0.53 to 0.70. This competitive assay can be used as a general method to detect amino acids at concentrations less than 100 nM and to monitor enzyme activity in biological samples, and it is amenable to high-throughput screening.     

An efficient protocol for incorporation of an unnatural amino acid in perdeuterated recombinant proteins using glucose-based media

The in vivo incorporation of unnatural amino acids into proteins is a well-established technique requiring an orthogonal tRNA/aminoacyl-tRNA synthetase pair specific for the unnatural amino acid that is incorporated at a position encoded by a TAG amber codon. Although this technology provides unique opportunities to engineer protein structures, poor protein yields are usually obtained in deuterated media, hampering its application in the protein NMR field. Here, we describe a novel protocol for incorporating unnatural amino acids into fully deuterated proteins using glucose-based media (which are relevant to the production, for example, of amino acid-specific methyl-labeled proteins used in the study of large molecular weight systems). The method consists of pre-induction of the pEVOL plasmid encoding the tRNA/aminoacyl-tRNA synthetase pair in a rich, H₂O-based medium prior to exchanging the culture into a D₂O-based medium. Our protocol results in high level of isotopic incorporation (~95%) and retains the high expression level of the target protein observed in Luria–Bertani medium.     

Unnatural amino acid replacement in a yeast G protein-coupled receptor in its native environment

Ste2p is the G protein-coupled receptor (GPCR) for the tridecapeptide pheromone alpha factor of Saccharomyces cerevisiae. This receptor-pheromone pair has been used extensively as a paradigm for investigating GPCR structure and function. Expression in yeast harboring a cognate tRNA/aminoacyl-tRNA synthetase pair specifically evolved to incorporate p-benzoyl- l-phenylalanine (Bpa) in response to the amber codon allowed the biosynthesis of Bpa-substituted Ste2p in its native cell. We replaced natural amino acid residues in Ste2p with Bpa by engineering amber TAG stop codons into STE2 encoded on a plasmid. Several of the expressed Bpa-substituted Ste2p receptors exhibited high-affinity ligand binding, and incorporation of Bpa into Ste2p influenced biological activity as measured by growth arrest of whole cells in response to alpha factor. We found that, at concentrations of 0.1-0.5 mM, a dipeptide containing Bpa could be used to enhance delivery of Bpa into the cell, while at 2 mM, both dipeptide and Bpa were equally effective. The application of a peptide delivery system for unnatural amino acids will extend the use of the unnatural amino acid replacement methodology to amino acids that are impermeable to yeast. Incorporation of Bpa into Ste2p was verified by mass spectrometric analysis, and two Bpa-Ste2p mutants were able to selectively capture alpha factor into the ligand-binding site after photoactivation. To our knowledge, this is the first experimental evidence documenting an unnatural amino acid replacement in a GPCR expressed in its native environment and the use of a mutated receptor to photocapture a peptide ligand.     

Misacylation of yeast amber suppressor tRNA(Tyr) by E. coli lysyl-tRNA synthetase and its effective repression by genetic engineering of the tRNA sequence

Through an exhaustive search for Escherichia coli aminoacyl-tRNA synthetase(s) responsible for the misacylation of yeast suppressor tRNA(Tyr), E. coli lysyl-tRNA synthetase was found to have a weak activity to aminoacylate yeast amber suppressor tRNA(Tyr) (CUA) with L-lysine. Since our protein-synthesizing system for site-specific incorporation of unnatural amino acids into proteins is based on the use of yeast suppressor tRNA(Tyr)/tyrosyl-tRNA synthetase (TyrRS) pair as the "carrier" of unusual amino acid in E. coli translation system, this misacylation must be repressed as low as possible. We have succeeded in effectively repressing the misacylation by changing several nucleotides in this tRNA by genetic engineering. This "optimized" tRNA together with our mutant TyrRS should serve as an efficient and faithful tool for site-specific incorporation of unnatural amino acids into proteins in a protein-synthesizing system in vitro or in vivo.