Site-specific incorporation of an unnatural amino acid into proteins in mammalian cells

Evolved orthogonal ribosomes enhance the efficiency of synthetic genetic code expansion

In vivo incorporation of unnatural amino acids by amber codon suppression is limited by release factor-1-mediated peptide chain termination. Orthogonal ribosome-mRNA pairs function in parallel with, but independent of, natural ribosomes and mRNAs. Here we show that an evolved orthogonal ribosome (ribo-X) improves tRNA(CUA)-dependent decoding of amber codons placed in orthogonal mRNA. By combining ribo-X, orthogonal mRNAs and orthogonal aminoacyl-tRNA synthetase/tRNA pairs in Escherichia coli, we increase the efficiency of site-specific unnatural amino acid incorporation from approximately 20% to >60% on a single amber codon and from <1% to >20% on two amber codons. We hypothesize that these increases result from a decreased functional interaction of the orthogonal ribosome with release factor-1. This technology should minimize the functional and phenotypic effects of truncated proteins in experiments that use unnatural amino acid incorporation to probe protein function in vivo.

Structural basis for recognition of cognate tRNA by tyrosyl-tRNA synthetase from three kingdoms

The specific aminoacylation of tRNA by tyrosyl-tRNA synthetases (TyrRSs) relies on the identity determinants in the cognate tRNA(Tyr)s. We have determined the crystal structure of Saccharomyces cerevisiae TyrRS (SceTyrRS) complexed with a Tyr-AMP analog and the native tRNA(Tyr)(GPsiA). Structural information for TyrRS-tRNA(Tyr) complexes is now full-line for three kingdoms. Because the archaeal/eukaryotic TyrRSs-tRNA(Tyr)s pairs do not cross-react with their bacterial counterparts, the recognition modes of the identity determinants by the archaeal/eukaryotic TyrRSs were expected to be similar to each other but different from that by the bacterial TyrRSs. Interestingly, however, the tRNA(Tyr) recognition modes of SceTyrRS have both similarities and differences compared with those in the archaeal TyrRS: the recognition of the C1-G72 base pair by SceTyrRS is similar to that by the archaeal TyrRS, whereas the recognition of the A73 by SceTyrRS is different from that by the archaeal TyrRS but similar to that by the bacterial TyrRS. Thus, the lack of cross-reactivity between archaeal/eukaryotic and bacterial TyrRS-tRNA(Tyr) pairs most probably lies in the different sequence of the last base pair of the acceptor stem (C1-G72 vs G1-C72) of tRNA(Tyr). On the other hand, the recognition mode of Tyr-AMP is conserved among the TyrRSs from the three kingdoms.

An improved system for the generation and analysis of mutant proteins containing unnatural amino acids in Saccharomyces cerevisiae

We have previously described methodology that makes it possible to genetically encode a wide array of unnatural amino acids in both prokaryotic and eukaryotic organisms. Here, we report the systematic optimization of a Saccharomyces cerevisiae expression system for the production of mutant proteins containing unnatural amino acids. Modifications include significant increases in both the expression levels of the orthogonal Escherichia coli amber suppressor tRNA(CUA) and cognate aminoacyl-tRNA synthetase (aaRS) pair, and expression of the target protein gene using a strong transcriptional promoter, optimized codons and elevated plasmid copy numbers. With this new system, a number of unnatural amino acids, including the photocrosslinkers p-benzoylphenylalanine and p-azidophenylalanine, and the chemically reactive amino acids, p-acetylphenylalanine and p-propargyloxyphenylalanine, were incorporated into human superoxide dismutase (hSOD) in yeast in good yields (maximally approximately 6-8 mg/l of culture in most cases). Mass spectrometric analysis of the hSOD mutants was performed with high dynamic range using multiple reaction monitoring that provided new insights into the factors that control the fidelity of unnatural amino acid incorporation.

Site-specific functionalization of proteins by organopalladium reactions

A new carbon-carbon bond has been regioselectively introduced into a target position (position 32 or 174) of the Ras protein by two types of organopalladium reactions (Mizoroki-Heck and Sonogashira reactions). Reaction conditions were screened by using a model peptide, and the stability of the Ras protein under the reaction conditions was examined by using the wild-type Ras protein. Finally, the iF-Ras proteins containing a 4-iodo-L-phenylalanine residue were subjected to organopalladium reactions with vinylated or propargylated biotin. Site-specific biotinylations of the Ras protein were confirmed by Western blot and LC-MS/MS.

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.

A New Protein Engineering Approach Combining Chemistry and Biology, Part I; Site-Specific Incorporation of 4-Iodo-L-phenylalanine in vitro by Using Misacylated Suppressor tRNAPhe

An Escherichia coli suppressor tRNA(Phe) (tRNA(Phe) (CUA)) was misacylated with 4-iodo-L-phenylalanine by using the A294G phenylalanyl-tRNA synthetase mutant (G294-PheRS) from E. coli at a high magnesium-ion concentration. The preacylated tRNA was added to an E. coli cell-free system and a Ras protein that contained the 4-iodo-L-phenylalanine residue at a specific target position was synthesized. Site-specific incorporation of 4-iodo-L-phenylalanine was confirmed by using LC-MS/MS. Free tRNA(Phe) (CUA) was not aminoacylated by aminoacyl-tRNA synthetases (aaRSs) present in the E. coli cell-free system. Our approach will find wide application in protein engineering since an aryl iodide tag on proteins can be used for site-specific functionalization of proteins.

Manipulating proteins for neuroscience

The design and manipulation of proteins has created many tools that have become popular in neurobiological studies, and new developments in protein science will be the fuel for future research. Genetically encoded protein-based biosensors have been developed with a wider range of sensing moieties, enabling detection of changes in localized protein synthesis, voltage, glutamate and/or glucose levels. Existing sensors, such as cameleon, have been modified and improved. Heterologous expression of Channelrhodopsin-2 and other light-gated methods for controlling cellular polarization enable action potentials to be non-invasively evoked, facilitating the study and modulation of behavior in intact animals. Finally, new methods in protein manipulation, including the site-specific incorporation of unnatural amino acids in vivo and the directed evolution of proteins, show promise in elucidating neural function with greater precision and flexibility.

A chemical toolkit for proteins--an expanded genetic code

Recently, a method to encode unnatural amino acids with diverse physicochemical and biological properties genetically in bacteria, yeast and mammalian cells was developed. Over 30 unnatural amino acids have been co-translationally incorporated into proteins with high fidelity and efficiency using a unique codon and corresponding transfer-RNA:aminoacyl-tRNA-synthetase pair. This provides a powerful tool for exploring protein structure and function in vitro and in vivo, and for generating proteins with new or enhanced properties.

Expanding the genetic code

Recently, a general method was developed that makes it possible to genetically encode unnatural amino acids with diverse physical, chemical, or biological properties in Escherichia coli, yeast, and mammalian cells. More than 30 unnatural amino acids have been incorporated into proteins with high fidelity and efficiency by means of a unique codon and corresponding tRNA/aminoacyl-tRNA synthetase pair. These include fluorescent, glycosylated, metal-ion-binding, and redox-active amino acids, as well as amino acids with unique chemical and photochemical reactivity. This methodology provides a powerful tool both for exploring protein structure and function in vitro and in vivo and for generating proteins with new or enhanced properties.

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.

Modular approaches to expanding the functions of living matter

The synthesis of increasingly complex unnatural networks embedded in living matter is an emerging theme in synthetic biology. Synthetic networks have allowed the creation of organisms endowed with toggle switches, logic gates, pattern-forming systems, oscillators, cellular sensors, new modes of gene regulation and expanded genetic codes. A common challenge of this work is the addition of specific new functions to complex living organisms. This requires spatial and temporal control of molecular interactions and fluxes to achieve the desired outcomes. Here we review recent successes in this emerging field and discuss strategies for addressing the challenges of increasing network complexity.

In vivo incorporation of multiple unnatural amino acids through nonsense and frameshift suppression

Site-specific incorporation of unnatural amino acids (UAAs) into proteins is a valuable tool for studying structure-function relationships, incorporating biophysical probes, and elucidating protein-protein interactions. In higher eukaryotic cells, the methodology is currently limited to incorporation of a single UAA in response to a stop codon, which is known as nonsense suppression. Frameshift suppression is a unique methodology for incorporating UAAs in response to quadruplet codons, but currently, it is mostly limited to in vitro protein translation systems. Here, we evaluate the viability of frameshift suppression in Xenopus oocytes. We demonstrate UAA incorporation by using yeast phenylalanine frameshift suppressor (YFFS) tRNAs that recognize two different quadruplet codons (CGGG and GGGU) in vivo. Suppression efficiency of the YFFS tRNAs increases nonlinearly with the amount of injected tRNA, suggesting a significant competition with endogenous, triplet-recognizing tRNA. Both frameshift suppressor tRNAs are less efficient than the amber suppressor tRNA THG73 (Tetrahymena thermophila G73), which has been used extensively for UAA incorporation in Xenopus oocytes. However, the two YFFS tRNAs are more "orthogonal" to the Xenopus system than THG73, and they offer a viable replacement when suppressing at promiscuous sites. To illustrate the potential of combining nonsense and frameshift suppression, we have site-specifically incorporated two and three UAAs simultaneously into a neuroreceptor expressed in vivo.

Regioselective carbon-carbon bond formation in proteins with palladium catalysis; new protein chemistry by organometallic chemistry

Palladium-catalyzed reactions have contributed to the advancement of many areas of organic chemistry, in particular, the synthesis of organic compounds such as natural products and polymeric materials. In this study, we have used a Mizoroki-Heck reaction for site-specific carbon-carbon bond formation in the Ras protein. This was performed by the following two steps: 1) the His6-fused Ras protein containing 4-iodo-L-phenylalanine at position 32 (iF32-Ras-His) was prepared by genetic engineering and 2) the aryl iodide group on the iF32-Ras-His was coupled with vinylated biotin in the presence of a palladium catalyst. The biotinylation was confirmed by Western blotting and liquid chromatography-mass spectrometry (LC-MS). The regioselectivity of the Mizoroki-Heck reaction was furthermore confirmed by LC-MS/MS analysis. However, in addition to the biotinylated product (bF32-Ras-His), a dehalogenated product (F32-Ras-His) was detected by LC-MS/MS. This dehalogenation resulted from the undesired termination of the Mizoroki-Heck reaction due to steric and electrostatic hindrance around residue 32. The biotinylated Ras showed binding activity for the Ras-binding domain as its downstream target, Raf-1, with no sign of decomposition. This study is the first report of an application of organometallic chemistry in protein chemistry.

Adding amino acids to the genetic repertoire

Considerable progress has been made in expanding the number and nature of genetically encoded amino acids in Escherichia coli, yeast and mammalian cells in the past four years. To date, over 30 unnatural amino acids have been cotranslationally incorporated into proteins with high fidelity and efficiency by means of a unique codon and corresponding orthogonal tRNA-aminoacyl-tRNA synthetase pair. The incorporated amino acids contain spectroscopic probes, post-translational modifications, metal chelators, photoaffinity labels and unique functional groups. The ability to genetically encode additional amino acids, beyond the common 20, provides a powerful approach for probing protein structure and function both in vitro and in vivo, as well as generating proteins with new or enhanced properties.

An expanding genetic code

A general method was recently developed that makes it possible to genetically encode unnatural amino acids (UAAs) with diverse physical, chemical or biological properties in Escherichia coli, yeast, and mammalian cells. Over 30 UAAs have been cotranslationally incorporated into proteins with high fidelity and efficiency by means of a unique codon and corresponding tRNA-synthetase pair. A key feature of this methodology is the orthogonality between the new translational components and their endogenous host counterparts. Specifically, the codon for the UAA should not encode a common amino acid; neither the new tRNA nor cognate aminoacyl tRNA synthetase should cross-react with any endogenous tRNA-synthetase pairs; and the new synthetase should recognize only the UAA and not any of the 20 common amino acids. This methodology provides a powerful tool for exploring protein structure and function both in vitro and in vivo, as well as generating proteins with new or enhanced properties.

Evolution of the tRNATyr/TyrRS aminoacylation systems

The tRNA identity rules ensuring fidelity of translation are globally conserved throughout evolution except for tyrosyl-tRNA synthetases (TyrRSs) that display species-specific tRNA recognition. This discrimination originates from the presence of a conserved identity pair, G1-C72, located at the top of the acceptor stem of tRNA(Tyr) from eubacteria that is invariably replaced by an unusual C1-G72 pair in archaeal and eubacterial tRNA(Tyr). In addition to the key role of pair 1-72 in tyrosylation, discriminator base A73, the anticodon triplet and the large variable region (present in eubacterial tRNA(Tyr) but not found in eukaryal tRNA(Tyr)) contribute to tyrosylation with variable strengths. Crystallographic structures of two tRNA(Tyr)/TyrRS complexes revealed different interaction modes in accordance with the phylum-specificity. Recent functional studies on the human mitochondrial tRNA(Tyr)/TyrRS system indicates strong deviations from the canonical tyrosylation rules. These differences are discussed in the light of the present knowledge on TyrRSs.

A two-unnatural-base-pair system toward the expansion of the genetic code

Toward the site-specific incorporation of amino acid analogues into proteins, a two-unnatural-base-pair system was developed for coupled transcription-translation systems with the expanded genetic code. A previously designed unnatural base pair between 2-amino-6-(2-thienyl)purine (denoted by s) and pyridin-2-one (denoted by y) was used for the site-specific incorporation of yTP into RNA opposite s in templates by T7 RNA polymerase. For the site-specific incorporation of sTP into RNA, a newly developed unnatural base, imidazolin-2-one (denoted by z), is superior to y as a template base for pairing with s in T7 transcription. The combination of the s-y and s-z pairs provides a powerful tool to prepare both y-containing mRNA and s-containing tRNA for efficient coupled transcription-translation systems, in which the genetic code is expanded by the codon-anticodon interactions mediated by the s-y pair. In addition, the nucleoside of s is strongly fluorescent, and thus the s-z pair enables the site-specific fluorescent labeling of RNA molecules. These unnatural-base-pair studies provide valuable information for understanding the mechanisms of replication and transcription.

Photo-leucine and photo-methionine allow identification of protein-protein interactions in living cells

Protein-protein interactions are the key to organizing cellular processes in space and time. The only direct way to identify such interactions in their cellular environment is by photo-cross-linking. Here we present a new strategy for photo-cross-linking proteins in living cells. We designed two new photoactivatable amino acids that we termed photo-methionine and photo-leucine based on their structures and properties closely resembling the natural amino acids methionine and leucine, respectively. This similarity allows them to escape the stringent identity control mechanisms during protein synthesis and be incorporated into proteins by the unmodified mammalian translation machinery. Activation by ultraviolet light induces covalent cross-linking of the interacting proteins, which can be detected with high specificity by simple western blotting. Applying this technology to membrane protein complexes, we discovered a previously unknown direct interaction of the progesterone-binding membrane protein PGRMC1 with Insig-1, a key regulator of cholesterol homeostasis.

Protein photo-cross-linking in mammalian cells by site-specific incorporation of a photoreactive amino acid

We report a method of photo-cross-linking proteins in mammalian cells, which is based on site-specific incorporation of a photoreactive amino acid, p-benzoyl-L-phenylalanine (pBpa), through the use of an expanded genetic code. To analyze the cell signaling interactions involving the adaptor protein Grb2, pBpa was incorporated in its Src homology 2 (SH2) domain. The human GRB2 gene with an amber codon was introduced into Chinese hamster ovary (CHO) cells, together with the genes for the Bacillus stearothermophilus suppressor tRNA(Tyr) and a pBpa-specific variant of Escherichia coli tyrosyl-tRNA synthetase (TyrRS). The Grb2 variant with pBpa in the amber position was synthesized when pBpa was included in the growth medium. Upon exposure of cells to 365-nm light, protein variants containing pBpa in the positions proximal to the ligand-binding pocket were cross-linked with the transiently expressed epidermal growth factor (EGF) receptor in the presence of an EGF stimulus. Cross-linked complexes with endogenous proteins were also detected. In vivo photo-cross-linking with pBpa incorporated in proteins will be useful for studying protein-protein interactions in mammalian cells.

An expanding genetic code

More than 30 novel amino acids have been genetically encoded in response to unique triplet and quadruplet codons including fluorescent, photoreactive and redox active amino acids, glycosylated and heavy atom derived amino acids in addition to those with keto, azido and acetylenic chains. In this article, we describe recent advances that make it possible to add new building blocks systematically to the genetic codes of bacteria, yeast and mammalian cells. Taken together these tools will enable the detailed investigation of protein structure and function, which is not possible with conventional mutagenesis. Moreover, by lifting the constraints of the existing 20-amino-acid code, it should be possible to generate proteins and perhaps entire organisms with new or enhanced properties.

Structural basis of nonnatural amino acid recognition by an engineered aminoacyl-tRNA synthetase for genetic code expansion

The genetic code in a eukaryotic system has been expanded by the engineering of Escherichia coli tyrosyl-tRNA synthetase (TyrRS) with the Y37V and Q195C mutations (37V195C), which specifically recognize 3-iodo-L-tyrosine rather than L-tyrosine. In the present study, we determined the 3-iodo-L-tyrosine- and L-tyrosine-bound structures of the 37V195C mutant of the E. coli TyrRS catalytic domain at 2.0-A resolution. The gamma-methyl group of Val-37 and the sulfur atom of Cys-195 make van der Waals contacts with the iodine atom of 3-iodo-L-tyrosine. The Val-37 and Cys-195 side chains are rigidly fixed by the neighboring residues forming the hydrophobic core of the TyrRS. The major roles of the two mutations are different for the 3-iodo-L-tyrosine-selective recognition in the first step of the aminoacylation reaction (the amino acid activation step): the Y37V mutation eliminates the fatal steric repulsion with the iodine atom, and the Q195C mutation reduces the L-tyrosine misrecognition. The structure of the 37V195C mutant TyrRS complexed with an L-tyrosyladenylate analogue was also solved, indicating that the 3-iodo-L-tyrosine and L-tyrosine side chains are similarly discriminated in the second step (the aminoacyl transfer step). These results demonstrate that the amino acid-binding pocket on the 37V195C mutant is optimized for specific 3-iodo-L-tyrosine recognition.

Manipulating proteins with chemistry: a cross-section of chemical biology

Chemistry-driven strategies for modifying, controlling and monitoring protein function in vitro and in vivo have attracted widespread interest among chemists in recent years. Several strategies have now emerged that complement standard genetics-based approaches, and they are being increasingly adopted by biologists to address issues in relevant contexts from cells to animals. With the development of these chemical biology tools, we might be approaching a time when detailed quantitative analysis of protein function, to a degree previously available only in reconstituted systems, is attainable in an in vivo setting.

Expanding the Genetic Code

Although chemists can synthesize virtually any small organic molecule, our ability to rationally manipulate the structures of proteins is quite limited, despite their involvement in virtually every life process. For most proteins, modifications are largely restricted to substitutions among the common 20 amino acids. Herein we describe recent advances that make it possible to add new building blocks to the genetic codes of both prokaryotic and eukaryotic organisms. Over 30 novel amino acids have been genetically encoded in response to unique triplet and quadruplet codons including fluorescent, photoreactive, and redox-active amino acids, glycosylated amino acids, and amino acids with keto, azido, acetylenic, and heavy-atom-containing side chains. By removing the limitations imposed by the existing 20 amino acid code, it should be possible to generate proteins and perhaps entire organisms with new or enhanced properties.

Structural snapshots of the KMSKS loop rearrangement for amino acid activation by bacterial tyrosyl-tRNA synthetase

Tyrosyl-tRNA synthetase (TyrRS) has been studied extensively by mutational and structural analyses to elucidate its catalytic mechanism. TyrRS has the HIGH and KMSKS motifs that catalyze the amino acid activation with ATP. In the present study, the crystal structures of the Escherichia coli TyrRS catalytic domain, in complexes with l-tyrosine and a l-tyrosyladenylate analogue, Tyr-AMS, were solved at 2.0A and 2.7A resolution, respectively. In the Tyr-AMS-bound structure, the 2'-OH group and adenine ring of the Tyr-AMS are strictly recognized by hydrogen bonds. This manner of hydrogen-bond recognition is conserved among the class I synthetases. Moreover, a comparison between the two structures revealed that the KMSKS loop is rearranged in response to adenine moiety binding and hydrogen-bond formation, and the KMSKS loop adopts the more compact ("semi-open") form, rather than the flexible, open form. The HIGH motif initially recognizes the gamma-phosphate, and then the alpha and gamma-phosphates of ATP, with a slight rearrangement of the residues. The other residues around the substrate also accommodate the Tyr-AMS. This induced-fit form presents a novel "snapshot" of the amino acid activation step in the aminoacylation reaction by TyrRS. The present structures and the T.thermophilus TyrRS ATP-free and bound structures revealed that the extensive induced-fit conformational changes of the KMSKS loop and the local conformational changes within the substrate binding site form the basis for driving the amino acid activation step: the KMSKS loop adopts the open form, transiently shifts to the semi-open conformation according to the adenosyl moiety binding, and finally assumes the rigid ATP-bound, closed form. After the amino acid activation, the KMSKS loop adopts the semi-open form again to accept the CCA end of tRNA for the aminoacyl transfer reaction.

Prolegomena to Future Experimental Efforts on Genetic Code Engineering by Expanding Its Amino Acid Repertoire

Protein synthesis and its relation to the genetic code was for a long time a central issue in biology. Rapid experimental progress throughout the past decade, crowned with the recently elucidated ribosomal structures, provided an almost complete description of this process. In addition important experiments provided solid evidence that the natural protein translation machinery can be reprogrammed to encode genetically a vast number of non-coded (i.e. noncanonical) amino acids. Indeed, in the set of 20 canonical amino acids as prescribed by the universal genetic code, many desirable functionalities, such as halogeno, keto, cyano, azido, nitroso, nitro, and silyl groups, as well as C=C or C[triple bond]C bonds, are absent. The ability to encode genetically such chemical diversity will enable us to reprogram living cells, such as bacteria, to express tailor-made proteins exhibiting functional diversity. Accordingly, genetic code engineering has developed into an exciting emerging research field at the interface of biology, chemistry, and physics.

Complete set of orthogonal 21st aminoacyl-tRNA synthetase-amber, ochre and opal suppressor tRNA pairs: concomitant suppression of three different termination codons in an mRNA in mammalian cells

We describe the generation of a complete set of orthogonal 21st synthetase-amber, ochre and opal suppressor tRNA pairs including the first report of a 21st synthetase-ochre suppressor tRNA pair. We show that amber, ochre and opal suppressor tRNAs, derived from Escherichia coli glutamine tRNA, suppress UAG, UAA and UGA termination codons, respectively, in a reporter mRNA in mammalian cells. Activity of each suppressor tRNA is dependent upon the expression of E.coli glutaminyl-tRNA synthetase, indicating that none of the suppressor tRNAs are aminoacylated by any of the twenty aminoacyl-tRNA synthetases in the mammalian cytoplasm. Amber, ochre and opal suppressor tRNAs with a wide range of activities in suppression (increases of up to 36, 156 and 200-fold, respectively) have been generated by introducing further mutations into the suppressor tRNA genes. The most active suppressor tRNAs have been used in combination to concomitantly suppress two or three termination codons in an mRNA. We discuss the potential use of these 21st synthetase-suppressor tRNA pairs for the site-specific incorporation of two or, possibly, even three different unnatural amino acids into proteins and for the regulated suppression of amber, ochre and opal termination codons in mammalian cells.

The site-specific incorporation of p-iodo-L-phenylalanine into proteins for structure determination

A recently developed method makes it possible to genetically encode unnatural amino acids with diverse physical, chemical or biological properties in Escherichia coli and yeast. We now show that this technology can be used to efficiently and site-specifically incorporate p-iodo-L-phenylalanine (iodoPhe) into proteins in response to an amber TAG codon. The selective introduction of the anomalously scattering iodine atom into proteins should facilitate single-wavelength anomalous dispersion experiments on in-house X-ray sources. To illustrate this, we generated a Phe153 --> iodoPhe mutant of bacteriophage T4 lysozyme and determined its crystal structure using considerably less data than are needed for the equivalent experiment with cysteine and methionine. The iodoPhe residue, although present in the hydrophobic core of the protein, did not perturb the protein structure in any meaningful way. The ability to selectively introduce this and other heavy atom-containing amino acids into proteins should facilitate the structural study of proteins.

A possible approach to site-specific insertion of two different unnatural amino acids into proteins in mammalian cells via nonsense suppression

The site-specific insertion of an unnatural amino acid into proteins in vivo via nonsense suppression has resulted in major advances in recent years. The ability to incorporate two different unnatural amino acids in vivo would greatly increase the scope and impact of unnatural amino acid mutagenesis. Here, we show the concomitant suppression of an amber and an ochre codon in a single mRNA in mammalian cells by importing a mixture of aminoacylated amber and ochre suppressor tRNAs. This result provides a possible approach to site-specific insertion of two different unnatural amino acids into any protein of interest in mammalian cells. To our knowledge, this result also represents the only demonstration of concomitant suppression of two different termination codons in a single gene in vivo.

Asymmetric Synthesis and Translational Competence of l-α-(1-Cyclobutenyl)glycine

[reaction: see text] L-alpha-(1-Cyclobutenyl)glycine (1-Cbg) was targeted as a potentially translatable analogue of isoleucine and valine and as a useful building block for peptides. An enantioselective synthesis was executed in which the key step was diastereoselective addition of 1-cyclobutenylmagnesium bromide to the sulfinimine 2b derived from (S)-t-butanesulfinimide and tert-butyl glyoxylate. 1-Cbg was found to substitute efficiently for isoleucine and valine, but not leucine, in the translation of green fluorescent protein in vitro.

Non-canonical amino acids in protein engineering

Methods for engineering proteins that contain non-canonical amino acids have advanced rapidly in the past few years. Novel amino acids can be introduced into recombinant proteins in either a residue-specific or site-specific fashion. The methods are complementary: residue-specific incorporation allows engineering of the overall physical and chemical behavior of proteins and protein-like macromolecules, whereas site-specific methods allow mechanistic questions to be probed in atomistic detail. Challenges remain in the engineering of the translational apparatus and in the design of schemes that can be used to encode both canonical and non-canonical amino acids.

Selective incorporation of 5-hydroxytryptophan into proteins in mammalian cells

An orthogonal tryptophanyl-transfer RNA (tRNA) synthetase (TrpRS)-mutant opal suppressor tRNA(Trp) (mutRNA(UCA)(Trp)) pair was generated for use in mammalian cells. The anticodon loop of the Bacillus subtilis tRNA(Trp) was mutated to UCA, three positions in the D arm were mutated to generate an internal promoter sequence, and the mutRNA(UCA)(Trp) gene was inserted between the 5' and 3' flanking sequences of the tRNA(Trp-1) gene from Arabidopsis to enhance its expression in mammalian cells. In vitro aminoacylation assays and in vivo opal suppression assays showed that B. subtilis TrpRS (BsTrpRS) charges only the cognate mutRNA(UCA)(Trp) and no endogenous mammalian tRNAs. Similarly, the mutRNA(UCA)(Trp) is specifically charged by B. subtilis TrpRS and not by endogenous synthetases in mammalian cells. Site-directed mutagenesis was then used to alter the specificity of BsTrpRS to uniquely charge 5-hydoxy-l-tryptophan. The resulting mutant BsTrpRS-mutRNA(UCA)(Trp) pair allows the efficient and selective incorporation of 5-hydroxy-l-tryptophan into mammalian proteins in response to the codon, TGA. This amino acid can be used as a fluorescence probe and also undergoes electrochemical oxidation in situ to generate an efficient protein crosslinking.

Incorporation of Nonnatural Amino Acids Into Proteins

The genetic code is established by the aminoacylation of transfer RNA, reactions in which each amino acid is linked to its cognate tRNA that, in turn, harbors the nucleotide triplet (anticodon) specific to the amino acid. The accuracy of aminoacylation is essential for building and maintaining the universal tree of life. The ability to manipulate and expand the code holds promise for the development of new methods to create novel proteins and to understand the origins of life. Recent efforts to manipulate the genetic code have fulfilled much of this potential. These efforts have led to incorporation of nonnatural amino acids into proteins for a variety of applications and have demonstrated the plausibility of specific proposals for early evolution of the code.

An expanded eukaryotic genetic code

We describe a general and rapid route for the addition of unnatural amino acids to the genetic code of Saccharomyces cerevisiae. Five amino acids have been incorporated into proteins efficiently and with high fidelity in response to the nonsense codon TAG. The side chains of these amino acids contain a keto group, which can be uniquely modified in vitro and in vivo with a wide range of chemical probes and reagents; a heavy atom-containing amino acid for structural studies; and photocrosslinkers for cellular studies of protein interactions. This methodology not only removes the constraints imposed by the genetic code on our ability to manipulate protein structure and function in yeast, it provides a gateway to the systematic expansion of the genetic codes of multicellular eukaryotes.

Death, taxes, and the genetic code?

The genetic code is an enduring feature of biology: only rare circumstances result in changes to translation of the code, at least in nature. Researchers are devising methods to engineer ribosome-synthesized polypeptides containing novel and potentially useful amino acids.

Structural basis for orthogonal tRNA specificities of tyrosyl-tRNA synthetases for genetic code expansion

The archaeal/eukaryotic tyrosyl-tRNA synthetase (TyrRS)-tRNA(Tyr) pairs do not cross-react with their bacterial counterparts. This 'orthogonal' condition is essential for using the archaeal pair to expand the bacterial genetic code. In this study, the structure of the Methanococcus jannaschii TyrRS-tRNA(Tyr)-L-tyrosine complex, solved at a resolution of 1.95 A, reveals that this archaeal TyrRS strictly recognizes the C1-G72 base pair, whereas the bacterial TyrRS recognizes the G1-C72 in a different manner using different residues. These diverse tRNA recognition modes form the basis for the orthogonality. The common tRNA(Tyr) identity determinants (the discriminator, A73 and the anticodon residues) are also recognized in manners different from those of the bacterial TyrRS. Based on this finding, we created a mutant TyrRS that aminoacylates the amber suppressor tRNA with C34 65 times more efficiently than does the wild-type enzyme.

Site-specific incorporation of unnatural amino acids into receptors expressed in Mammalian cells

We describe an approach to achieve unnatural amino acid incorporation into channels and receptors expressed in mammalian cells. We show that microelectroporation provides a general method to deliver DNA, mRNA, and tRNA simultaneously. In both CHO cells and cultured neurons, microelectroporation efficiently delivers an in vitro transcribed, serine amber suppressor tRNA, leading to nonsense suppression in a mutant EGFP gene. In CHO cells, both natural and unnatural amino acids chemically appended to a suppressor tRNA are site specifically incorporated into the nicotinic acetylcholine receptor (nAChR). Electrophysiology confirms the expected functional consequences of the unnatural residue. The microelectroporation strategy described here is more general, less tedious, and less damaging to mammalian neuronal and nonneuronal cells than previous approaches to nonsense suppression in small cells and provides the first example of unnatural amino acid incorporation in mammalian cells using chemically aminoacylated tRNA.

Progress toward an expanded eukaryotic genetic code

Expanding the eukaryotic genetic code to include unnatural amino acids with novel properties would provide powerful tools for manipulating protein function in eukaryotic cells. Toward this goal, a general approach with potential for isolating aminoacyl-tRNA synthetases that incorporate unnatural amino acids with high fidelity into proteins in Saccharomyces cerevisiae is described. The method is based on activation of GAL4-responsive HIS3, URA3, or lacZ reporter genes by suppression of amber codons in GAL4. The optimization of GAL4 reporters is described, and the positive and negative selection of active Escherichia coli tyrosyl-tRNA synthetase (EcTyrRS)/tRNA(CUA) is demonstrated. Importantly, both selections can be performed on a single cell and with a range of stringencies. This method will facilitate the isolation of a range of aminoacyl-tRNA synthetase (aaRS)/tRNA(CUA) activities from large libraries of mutant synthetases.