Genetic Code Expansion Through Quadruplet Codon Decoding

Noncanonical amino acid mutagenesis has emerged as a powerful tool for the study of protein structure and function. While triplet nonsense codons, especially the amber codon, have been widely employed, quadruplet codons have attracted attention for the potential of creating additional blank codons for noncanonical amino acids mutagenesis. In this review, we discuss methodologies and applications of quadruplet codon decoding in genetic code expansion both in vitro and in vivo.     

Using a quadruplet codon to expand the genetic code of an animal

Genetic code expansion in multicellular organisms is currently limited to the use of repurposed amber stop codons. Here, we introduce a system for the use of quadruplet codons to direct incorporation of non-canonical amino acids in vivo in an animal, the nematode worm Caenorhabditis elegans. We develop hybrid pyrrolysyl tRNA variants to incorporate non-canonical amino acids in response to the quadruplet codon UAGA. We demonstrate the efficiency of the quadruplet decoding system by incorporating photocaged amino acids into two proteins widely used as genetic tools. We use photocaged lysine to express photocaged Cre recombinase for the optical control of gene expression and photocaged cysteine to express photo-activatable caspase for light inducible cell ablation. Our approach will facilitate the routine adoption of quadruplet decoding for genetic code expansion in eukaryotic cells and multicellular organisms.     

In vitro selection for sense codon suppression

The universal genetic code links the 20 naturally occurring amino acids to the 61 sense codons. Previously, the UAG amber stop codon (a nonsense codon) has been used as a blank in the code to insert natural and unnatural amino acids via nonsense suppression. We have developed a selection methodology to investigate whether the unnatural amino acid biocytin could be incorporated into an mRNA display library at sense codons. In these experiments we probed a single randomized NNN codon with a library of 16 orthogonal, biocytin-acylated tRNAs. In vitro selection for efficient incorporation of the unnatural amino acid resulted in templates containing the GUA codon at the randomized position. This sense suppression occurs via Watson-Crick pairing with similar efficiency to UAG-mediated nonsense suppression. These experiments suggest that sense codon suppression is a viable means to expand the chemical and functional diversity of the genetic code.     

Adaptation of an orthogonal archaeal leucyl-tRNA and synthetase pair for four-base,amber, and opal suppression

Recently, it has been shown that an amber suppressor tRNA/aminoacyl-tRNA synthetase pair derived from the tyrosyl-tRNA synthetase of Methanococcus jannaschii can be used to genetically encode unnatural amino acids in response to the amber nonsense codon, TAG. However, we have been unable to modify this pair to decode either the opal nonsense codon, TGA, or the four-base codon, AGGA, limiting us to a 21 amino acid code. To overcome this limitation, we have adapted a leucyl-tRNA synthetase from Methanobacterium thermoautotrophicum and leucyl tRNA derived from Halobacterium sp. NRC-1 as an orthogonal tRNA-synthetase pair in Escherichia coli to decode amber (TAG), opal (TGA), and four-base (AGGA) codons. To improve the efficiency and selectivity of the suppressor tRNA, extensive mutagenesis was performed on the anticodon loop and acceptor stem. The two most significant criteria required for an efficient amber orthogonal suppressor tRNA are a CU(X)XXXAA anticodon loop and the lack of noncanonical or mismatched base pairs in the stem regions. These changes afford only weak suppression of TGA and AGGA. However, this information together with an analysis of sequence similarity of multiple native archaeal tRNA sequences led to efficient, orthogonal suppressors of opal codons and the four-base codon, AGGA. Ultimately, it should be possible to use these additional orthogonal pairs to genetically incorporate multiple unnatural amino acids into proteins.     

Incorporation of nonnatural amino acids into proteins by using various four-base codons in an Escherichia coli in vitro translation system

Incorporation of nonnatural amino acids into proteins is a powerful technique in protein research. Amber suppression has been used to this end, but this strategy does not allow multiple incorporation of nonnatural amino acids into single proteins. In this article, we developed an alternative strategy for nonnatural mutagenesis by using four-base codons. The four-base codons AGGU, CGGU, CCCU, CUCU, CUAU, and GGGU were successfully decoded by the nitrophenylalanyl-tRNA containing the complementary four-base anticodons in an Escherichia coli in vitro translation system. The most efficient four-base decoding was observed for the GGGU codon, which yielded 86% of the full-length protein containing nitrophenylalanine relative to the wild-type protein. Moreover, highly efficient incorporation of two different nonnatural amino acids was achieved by using a set of two four-base codons, CGGG and GGGU. This work shows that the four-base codon strategy is more advantageous than the amber suppression strategy in efficiency and versatility.     

Reprogrammed genetic decoding in cellular gene expression

Reprogrammed genetic decoding signals in mRNAs productively overwrite the normal decoding rules of translation. These "recoding" signals are associated with sites of programmed ribosomal frameshifting, hopping, termination codon suppression, and the incorporation of the unusual amino acids selenocysteine and pyrrolysine. This review summarizes current knowledge of the structure and function of recoding signals in cellular genes, the biological importance of recoding in gene regulation, and ways to identify new recoded genes.     

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.     

Rewiring translation - Genetic code expansion and its applications

With few minor variations, the genetic code is universal to all forms of life on our planet. It is difficult to imagine that one day organisms might exist that use an entirely different code to translate the information of their genome. Recent developments in the field of synthetic biology, however, have opened the gate to their creation. The genetic code of several organisms has been expanded by the heterologous expression of evolved aminoacyl-tRNA synthetase/tRNA(CUA) pairs that mediate the incorporation of unnatural amino acids in response to amber codons. These UAAs introduce exciting new features into proteins, such as spectroscopic probes, UV-inducible crosslinkers, and functional groups for bioorthogonal conjugations or posttranslational modifications. Orthogonal ribosomes provide a parallel translational machinery in Escherichia coli that has lost its evolutionary constraints. Evolved variants of these ribosomes translate amber or quadruplet codons with massively enhanced efficiency. Here, I review these recent developments emphasizing their tremendous potential to facilitate biochemical and cell biological studies.     

Decoding of tandem quadruplets by adjacent tRNAs with eight-base anticodon loops

To expand the genetic code for specification of multiple non-natural amino acids, unique codons for these novel amino acids are needed. As part of a study of the potential of quadruplets as codons, the decoding of tandem UAGA quadruplets by an engineered tRNA^Leu with an eight-base anticodon loop, has been investigated. When GCC is the codon immediately 5′ of the first UAGA quadruplet, and release factor 1 is partially inactivated, the tandem UAGAs specify two leucines with an overall efficiency of at least 10%. The presence of a purine at anticodon loop position 32 of the tRNA decoding the codon 5′ to the first UAGA seems to influence translation of the following codon. Another finding is intraribosomal dissociation of anticodons from codons and their re-pairing to mRNA at overlapping or nearby codons. In one case where GCC is replaced by CGG, only a single Watson–Crick base pair can form upon re-pairing when decoding is resumed. This has implications for the mechanism of some cases of programmed frameshifting.     

Quadruplet codons: implications for code expansion and the specification of translation step size

One of the requirements for engineering expansion of the genetic code is a unique codon which is available for specifying the new amino acid. The potential of the quadruplet UAGA in Escherichia coli to specify a single amino acid residue in the presence of a mutant tRNA(Leu) molecule containing the extra nucleotide, U, at position 33.5 of its anticodon loop has been examined. With this mRNA-tRNA combination and at least partial inactivation of release factor 1, the UAGA quadruplet specifies a leucine residue with an efficiency of 13 to 26 %. The decoding properties of tRNA(Leu) with U at position 33.5 of its eight-membered anticodon loop, and a counterpart with A at position 33.5, strongly suggest that in both cases their anticodon loop bases stack in alternative conformations. The identity of the codon immediately 5' of the UAGA quadruplet influences the efficiency of quadruplet translation via the properties of its cognate tRNA. When there is the potential for the anticodon of this tRNA to dissociate from pairing with its codon and to re-pair to mRNA at a nearby 3' closely matched codon, the efficiency of quadruplet translation at UAGA is reduced. Evidence is presented which suggests that when there is a purine base at position 32 of this 5' flanking tRNA, it influences decoding of the UAGA quadruplet.     

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.     

The influence of the reading context upon the suppression of nonsense codons

Summary One of the basic assumptions of the current views of the genetic code is that the translation machinery reads the messenger RNA one nucleotide triplet codon at a time and that the meaning of a particular codon should not be effected by the surrounding nucleotide sequence (the reading context). Reexamination of existing data shows that this assumption does not hold for the case of suppression of the nonsense codons UAG (amber) and UAA (ochre).The efficiency of amino acid insertion in response to these nonsense codons appears to strongly depend on their location within the message. It is suggested that the translation machinery may interact with a nucleotide sequence longer than three nucleotides when involved in a chain termination reaction.     

Pyrrolysyl-tRNA synthetase: An ordinary enzyme but an outstanding genetic code expansion tool

The genetic incorporation of the 22nd proteinogenic amino acid, pyrrolysine (Pyl) at amber codon is achieved by the action of pyrrolysyl-tRNA synthetase (PylRS) together with its cognate tRNA^Pyl. Unlike most aminoacyl-tRNA synthetases, PylRS displays high substrate side chain promiscuity, low selectivity toward its substrate α-amine, and low selectivity toward the anticodon of tRNA^Pyl. These unique but ordinary features of PylRS as an aminoacyl-tRNA synthetase allow the Pyl incorporation machinery to be easily engineered for the genetic incorporation of more than 100 non-canonical amino acids (NCAAs) or α-hydroxy acids into proteins at amber codon and the reassignment of other codons such as ochre UAA, opal UGA, and four-base AGGA codons to code NCAAs.     

Rationalization and prediction of selective decoding of pseudouridine-modified nonsense and sense codons

A stop or nonsense codon is an in-frame triplet within a messenger RNA that signals the termination of translation. One common feature shared among all three nonsense codons (UAA, UAG, and UGA) is a uridine present at the first codon position. It has been recently shown that the conversion of this uridine into pseudouridine (Ψ) suppresses translation termination, both in vitro and in vivo. Furthermore, decoding of the pseudouridylated nonsense codons is accompanied by the incorporation of two specific amino acids in a nonsense codon-dependent fashion. Ψ differs from uridine by a single N1H group at the C5 position; how Ψ suppresses termination and, more importantly, enables selective decoding is poorly understood. Here, we provide molecular rationales for how pseudouridylated stop codons are selectively decoded. Our analysis applies crystal structures of ribosomes in varying states of translation to consider weakened interaction of Ψ with release factor; thermodynamic and geometric considerations of the codon-anticodon base pairs to rank and to eliminate mRNA-tRNA pairs; the mechanism of fidelity check of the codon-anticodon pairing by the ribosome to evaluate noncanonical codon-anticodon base pairs and the role of water. We also consider certain tRNA modifications that interfere with the Ψ-coordinated water in the major groove of the codon-anticodon mini-helix. Our analysis of nonsense codons enables prediction of potential decoding properties for Ψ-modified sense codons, such as decoding ΨUU potentially as Cys and Tyr. Our results provide molecular rationale for the remarkable dynamics of ribosome decoding and insights on possible reprogramming of the genetic code using mRNA modifications.     

Forced Ambiguity of the Leucine Codons for Multiple-Site-Specific Incorporation of a Noncanonical Amino Acid

Multiple-site-specific incorporation of a noncanonical amino acid into a recombinant protein would be a very useful technique to generate multiple chemical handles for bioconjugation and multivalent binding sites for the enhanced interaction. Previously combination of a mutant yeast phenylalanyl-tRNA synthetase variant and the yeast phenylalanyl-tRNA containing the AAA anticodon was used to incorporate a noncanonical amino acid into multiple UUU phenylalanine (Phe) codons in a site-specific manner. However, due to the less selective codon recognition of the AAA anticodon, there was significant misincorporation of a noncanonical amino acid into unwanted UUC Phe codons. To enhance codon selectivity, we explored degenerate leucine (Leu) codons instead of Phe degenerate codons. Combined use of the mutant yeast phenylalanyl-tRNA containing the CAA anticodon and the yPheRS_naph variant allowed incorporation of a phenylalanine analog, 2-naphthylalanine, into murine dihydrofolate reductase in response to multiple UUG Leu codons, but not to other Leu codon sites. Despite the moderate UUG codon occupancy by 2-naphthylalaine, these results successfully demonstrated that the concept of forced ambiguity of the genetic code can be achieved for the Leu codons, available for multiple-site-specific incorporation.     

Codon Size Reduction as the Origin of the Triplet Genetic Code

The genetic code appears to be optimized in its robustness to missense errors and frameshift errors. In addition, the genetic code is near-optimal in terms of its ability to carry information in addition to the sequences of encoded proteins. As evolution has no foresight, optimality of the modern genetic code suggests that it evolved from less optimal code variants. The length of codons in the genetic code is also optimal, as three is the minimal nucleotide combination that can encode the twenty standard amino acids. The apparent impossibility of transitions between codon sizes in a discontinuous manner during evolution has resulted in an unbending view that the genetic code was always triplet. Yet, recent experimental evidence on quadruplet decoding, as well as the discovery of organisms with ambiguous and dual decoding, suggest that the possibility of the evolution of triplet decoding from living systems with non-triplet decoding merits reconsideration and further exploration. To explore this possibility we designed a mathematical model of the evolution of primitive digital coding systems which can decode nucleotide sequences into protein sequences. These coding systems can evolve their nucleotide sequences via genetic events of Darwinian evolution, such as point-mutations. The replication rates of such coding systems depend on the accuracy of the generated protein sequences. Computer simulations based on our model show that decoding systems with codons of length greater than three spontaneously evolve into predominantly triplet decoding systems. Our findings suggest a plausible scenario for the evolution of the triplet genetic code in a continuous manner. This scenario suggests an explanation of how protein synthesis could be accomplished by means of long RNA-RNA interactions prior to the emergence of the complex decoding machinery, such as the ribosome, that is required for stabilization and discrimination of otherwise weak triplet codon-anticodon interactions.     

Predominance of six different hexanucleotide recoding signals 3' of read-through stop codons

Redefinition of UAG, UAA and UGA to specify a standard amino acid occurs in response to recoding signals present in a minority of mRNAs. This ‘read-through’ is in competition with termination and is utilized for gene expression. One of the recoding signals known to stimulate read-through is a hexanucleotide sequence of the form CARYYA 3′ adjacent to the stop codon. The present work finds that of the 91 unique viral sequences annotated as read-through, 90% had one of six of the 64 possible codons immediately 3′ of the read-through stop codon. The relative efficiency of these read-through contexts in mammalian tissue culture cells has been determined using a dual luciferase fusion reporter. The relative importance of the identity of several individual nucleotides in the different hexanucleotides is complex.     

The genetic code--40 years on

The genetic code discovered 40 years ago, consists of 64 triplets (codons) of nucleotides. The genetic code is almost universal. The same codons are assigned to the same amino acids and to the same START and STOP signals in the vast majority of genes in animals, plants, and microorganisms. Each codon encodes for one of the 20 amino acids used in the synthesis of proteins. That produces some redundancy in the code and most of the amino acids being encoded by more than one codon. The two cases have been found where selenocysteine or pyrrolysine, that are not one of the standard 20 is inserted by a tRNA into the growing polypeptide.     

Recoding in archaea

Standard decoding of the genetic information into polypeptides is performed by one of the most sophisticated cell machineries, the translating ribosome, which, by following the genetic code, ensures the correspondence between the mature mRNA and the protein sequence. However, the expression of a minority of genes requires programmed deviations from the standard decoding rules, globally named recoding. This includes ribosome programmed -/+1 frameshifting, ribosome hopping, and stop codon readthrough. Recoding in Archaea was unequivocally demonstrated only for the translation of the UGA stop codon into the amino acid selenocysteine. However, a new recoding event leading to the 22nd amino acid pyrrolysine and the preliminary reports on a gene regulated by programmed -1 frameshifting have been recently described in Archaea. Therefore, it appears that the study of this phenomenon in Archaea is still at its dawn and that most of the genes whose expression is regulated by recoding are still uncharacterized.     

An archaebacteria-derived glutamyl-tRNA synthetase and tRNA pair for unnatural amino acid mutagenesis of proteins in Escherichia coli

The addition of novel amino acids to the genetic code of Escherichia coli involves the generation of an aminoacyl-tRNA synthetase and tRNA pair that is ‘orthogonal’, meaning that it functions independently of the synthetases and tRNAs endogenous to E.coli. The amino acid specificity of the orthogonal synthetase is then modified to charge the corresponding orthogonal tRNA with an unnatural amino acid that is subsequently incorporated into a polypeptide in response to a nonsense or missense codon. Here we report the development of an orthogonal glutamic acid synthetase and tRNA pair. The tRNA is derived from the consensus sequence obtained from a multiple sequence alignment of archaeal tRNA^Glu sequences. The glutamyl-tRNA synthetase is from the achaebacterium Pyrococcus horikoshii. The new orthogonal pair suppresses amber nonsense codons with an efficiency roughly comparable to that of the orthogonal tyrosine pair derived from Methanococcus jannaschii, which has been used to selectively incorporate a variety of unnatural amino acids into proteins in E.coli. Development of the glutamic acid orthogonal pair increases the potential diversity of unnatural amino acid structures that may be incorporated into proteins in E.coli.