Replacement of anticodon loop nucleotides to produce functional tRNAs: amber suppressors derived from yeast tRNAPhe

Engineering tRNAs for the Ribosomal Translation of Non-proteinogenic Monomers

Ribosome-dependent protein biosynthesis is an essential cellular process mediated by transfer RNAs (tRNAs). Generally, ribosomally synthesized proteins are limited to the 22 proteinogenic amino acids (pAAs: 20 l-α-amino acids present in the standard genetic code, selenocysteine, and pyrrolysine). However, engineering tRNAs for the ribosomal incorporation of non-proteinogenic monomers (npMs) as building blocks has led to the creation of unique polypeptides with broad applications in cellular biology, material science, spectroscopy, and pharmaceuticals. Ribosomal polymerization of these engineered polypeptides presents a variety of challenges for biochemists, as translation efficiency and fidelity is often insufficient when employing npMs. In this Review, we will focus on the methodologies for engineering tRNAs to overcome these issues and explore recent advances both in vitro and in vivo. These efforts include increasing orthogonality, recruiting essential translation factors, and creation of expanded genetic codes. After our review on the biochemical optimizations of tRNAs, we provide examples of their use in genetic code manipulation, with a focus on the in vitro discovery of bioactive macrocyclic peptides containing npMs. Finally, an analysis of the current state of tRNA engineering is presented, along with existing challenges and future perspectives for the field.

Functional analysis of human tRNA isodecoders

tRNA isodecoders share the same anticodon but have differences in their body sequence. An unexpected result from genome sequencing projects is the identification of a large number of tRNA isodecoder genes in mammalian genomes. In the reference human genome, more than 270 isodecoder genes are present among the approximately 450 tRNA genes distributed among 49 isoacceptor families. Whether sequence diversity among isodecoder tRNA genes reflects functional variability is an open question. To address this, we developed a method to quantify the efficiency of tRNA isodecoders in stop-codon suppression in human cell lines. First, a green fluorescent protein (GFP) gene that contains a single UAG stop codon at two distinct locations is introduced. GFP is only produced when a tRNA suppressor containing CUA anticodon is co-transfected with the GFP gene. The suppression efficiency is examined for 31 tRNA isodecoders (all contain CUA anticodon), 21 derived from four isoacceptor families of tRNASer genes, 7 from five families of tRNALeu genes, and 3 from three families of tRNAAla genes. We found that isodecoder tRNAs display a large difference in their suppression efficiency. Among those with above background suppression activity, differences of up to 20-fold were observed. We were able to tune tRNA suppression efficiency by subtly adjusting the tRNA sequence and inter-convert poor suppressors into potent ones. We also demonstrate that isodecoder tRNAs with varying suppression efficiencies have similar stability and exhibit similar levels of aminoacylation in vivo. Our results indicate that naturally occurring tRNA isodecoders can have large functional variations and suggest that some tRNA isodecoders may perform a function distinct from translation.

Non-bridging phosphate oxygen atoms within the tRNA anticodon stem-loop are essential for ribosomal A site binding and translocation

The conformation of the anticodon stem-loop of tRNAs required for correct decoding by the ribosome depends on intramolecular and intermolecular interactions that are independent of the tRNA nucleotide sequence. Non-bridging phosphate oxygen atoms have been shown to be critical for the structure and function of several RNAs. However, little is known about the role they play in ribosomal A site binding and translocation of tRNA to the P site. Here, we show that non-bridging phosphate oxygen atoms within the tRNA anticodon stem-loop at positions 33, 35, and 37 are important for A site binding. Those at positions 34 and 36 are not necessary for binding, but are essential for translocation. Our results correlate with structural data, indicating that position 34 interacts with the highly conserved 16S rRNA base G966 and position 36 interacts with the universally conserved tRNA base U33 during translocation to the P site.

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.

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.

Monitoring mis-acylated tRNA suppression efficiency in mammalian cells via EGFP fluorescence recovery

A reporter assay was developed to detect and quantify nonsense codon suppression by chemically aminoacylated tRNAs in mammalian cells. It is based on the cellular expression of the enhanced green fluorescent protein (EGFP) as a reporter for the site-specific amino acid incorporation in its sequence using an orthogonal suppressor tRNA derived from Escherichia coli. Suppression of an engineered amber codon at position 64 in the EGFP run-off transcript could be achieved by the incorporation of a leucine via an in vitro aminoacylated suppressor tRNA. Microinjection of defined amounts of mutagenized EGFP mRNA and suppressor tRNA into individual cells allowed us to accurately determine suppression efficiencies by measuring the EGFP fluorescence intensity in individual cells using laser-scanning confocal microscopy. Control experiments showed the absence of natural suppression or aminoacylation of the synthetic tRNA by endogenous aminoacyl-tRNA synthetases. This reporter assay opens the way for the optimization of essential experimental parameters for expanding the scope of the suppressor tRNA technology to different cell types.

Conversion of cysteinyl residues to unnatural amino acid analogs. Examination in a model system

Improved and efficient techniques have led to an explosive growth in the application of site-directed mutagenesis to the study of enzymes. However, the limited availability of only those 20 amino acids that are translated by the genetic code has prevented the systematic variation of an amino acid's properties in order to define more precisely its role in the catalytic mechanism of an enzyme. An approach is being examined that combines the high specificity of site-directed mutagenesis with the flexibility of chemical modification to overcome these limitations. A set of reagents has been synthesized and reacted with a cysteine model to produce a series of amino acid structural analogs at appreciable rates and in good overall yields. The selective incorporation of these analogs in place of important functional amino acids in a protein will allow a more detailed examination of the role of that amino acid.

Probing the structure and function of the tachykinin neurokinin-2 receptor through biosynthetic incorporation of fluorescent amino acids at specific sites

A general method for understanding the mechanisms of ligand recognition and activation of G protein-coupled receptors has been developed. A study of ligand-receptor interactions in the prototypic seven-transmembrane neurokinin-2 receptor (NK2) using this fluorescence-based approach is presented. A fluorescent unnatural amino acid was introduced at known sites into NK2 by suppression of UAG nonsense codons with the aid of a chemically misacylated synthetic tRNA specifically designed for the incorporation of unnatural amino acids during heterologous expression in Xenopus oocytes. Fluorescence-labeled NK2 mutants containing an unique 3-N-(7-nitrobenz-2-oxa-1,3-diazol-4-yl)-2,3-diaminopropionic acid (NBD-Dap) residue at either site 103, in the first extracellular loop, or 248, in the third cytoplasmic loop, were functionally active. The fluorescent NK2 mutants were investigated by microspectrofluorimetry in a native membrane environment. Intermolecular distances were determined by measuring the fluorescence resonance energy transfer (FRET) between the fluorescent unnatural amino acid and a fluorescently labeled NK2 heptapeptide antagonist. These distances, calculated by the theory of Förster, permit to fix the ligand in space and define the structure of the receptor in a molecular model for NK2 ligand-receptor interactions. Our data are the first report of the incorporation of a fluorescent unnatural amino acid into a membrane protein in intact cells by the method of nonsense codon suppression, as well as the first measurement of experimental distances between a G protein-coupled receptor and its ligand by FRET. The method presented here can be generally applied to the analysis of spatial relationships in integral membrane proteins such as receptors or channels.

In vitro suppression of an amber mutation by a chemically aminoacylated transfer RNA prepared by runoff transcription

An amber suppressor tRNA was prepared in vitro by runoff transcription with T7 RNA polymerase. Both full-length tRNA and truncated tRNA lacking the 3' terminal pCpA from the acceptor stem could be synthesized from the same DNA template. Truncated runoff suppressor tRNA could be enzymatically ligated to phenylalanyl-pCpA to generate aminoacylated full-length suppressor tRNA (Phe-tRNA(CUA)). Phe-tRNA(CUA) is capable of suppressing an amber (UAG) mutation in vitro with equivalent efficiency as suppressor prepared by anticodon-loop replacement of a naturally-isolated tRNA. The ease of suppressor tRNA preparation using this method, compared to anticodon-loop replacement, greatly facilitates the use of chemically acylated suppressor tRNA's for site-specifically incorporating unnatural amino acids into proteins.

tRNA anticodon replacement experiments show that ribosomal frameshifting can be caused by doublet decoding

The expression of certain normal genes requires a specific ribosomal frameshift event because the mRNA has the coding information for one protein in two different reading frames. One of several possible mechanisms for this involves recognition of a nontriplet codon by a noncognate tRNA. The AGUC-decoding Escherichia coli tRNASer3 reads a GCA alanine codon to cause a -1 frameshift. Replacement of the anticodon of tRNAPhe with the anticodon of tRNASer3 allows the constructed tRNA to cause this frameshifting. By altering the anticodon loop nucleotides at positions 33-36 in the constructed tRNAPhe molecules, the tRNA was found to recognize a 2-base codon. Instead of the usual anticodon, positions 34-36, the nucleotides in positions 34 and 35 form essential base pairs with the first two positions of the alanine codon. The uridine in position 36 is also required but not for base pairing.

Construction of a systematic set of tRNA mutants by ligation of synthetic oligonucleotides into defined single-stranded gaps

A series of mutant tRNA genes has been constructed by site-directed mutagenesis in pOP203, a colE1 derivative carrying a transcription unit under control of the lacUV5 promoter. These mutant genes include all possible amber suppressing variants of tRNATrp with single nucleotide substitutions at anticodon loop positions 32, 37, and 38 (numbered from the 5' end), and all possible paired base substitutions in the three base pairs nearest the anticodon loop. G at position 38 was not recovered as a single mutation, but rather in conjunction with an undirected mutation to T at position 32. The singly mutated G38 tRNA may not be active, though all the other tRNA derivatives are functional in the translation of amber codons. To construct the mutants, we ligated a synthetic deoxyoligonucleotide into a precisely formed single-stranded gap covering the anticodon arm region DNA, in an otherwise double-stranded fragment containing the tRNATrp gene. The resulting heteroduplex was then ligated into the plasmid and introduced into Escherichia coli. This method of mutagenesis is simple, reproducible, and highly tolerant of varying degrees of heteroduplex in the gap, variations in temperature of ligation, and changes in the oligonucleotide concentration. Mutagenesis does not require a 5'-phosphorylated oligonucleotide. These qualities suit the gap method for intensive study of a region by site-directed mutagenesis.

Replacement and insertion of nucleotides at the anticodon loop of E. coli tRNAMetf by ligation of chemically synthesized ribooligonucleotides

Insertion of the four major nucleotides at the 5'-side of the anticodon triplet of E. coli tRNAMetf was performed by joining of the half molecules obtained by limited digestion with RNase A and the chemically synthesized tetranucleotide pN-C-A-U using RNA ligase. Insertion of U-U at the 5'-side or A and A-A at the 3'-side of the anticodon were also performed using U-U-C-A-U, C-A-U-A and C-A-U-A-A. The constant U next to the 5'-side of the anticodon was replaced with A and C by ligation of A-C-A-U and C-C-A-U to the 5'-half molecule which had been treated with periodate plus lysine, followed by joining to the 3'-half. These modified tRNAs were tested for their ability to accept methionine with the methionyl-tRNA synthetase of E. coli. The affinity of these analogs for the synthetase decreased more extensively when the insertion was at the 3'-side of the anticodon triplet. Insertion of mononucleotides at the 5'-side or replacement of the constant U next to the 5'-side of the anticodon did not affect aminoacylation drastically. This may mean that the 3'-side of the anticodon loop of tRNA is one of the major recognition sites for the methionyl-tRNA synthetase.

Construction of a UGA suppressor tRNA by modification in vitro of yeast tRNACys

In this paper we describe the construction of a yeast tRNACys UGA suppressor. After specific hydrolysis of the parent molecule, the first base of the anticodon GCA was replaced by a uracil. The resulting molecule, harboring a UCA anticodon, was injected into Xenopus laevis oocytes in order to test its biological activities. The level of aminoacylation was similar to that of the parent molecule. Readthrough of the UGA termination codon in beta-globin mRNA, coinjected with the tRNA, indicated suppressor activity; however, tRNACys (anticodon UCA) was a much less efficient suppressor than others tested under the same conditions. We see no post-transcriptional modification of the uracil in the anticodon wobble position after injection into oocytes. This may be related to the low suppressor activity; however, it is also possible that other features of tRNACys structure may be unadapted to efficient UCA anticodon function.

Uridine-33 in yeast tRNA not essential for amber suppression

The nucleotide at position 33 on the 5' side of the anticodon of almost all tRNAs is a uridine. Crystallographic studies of different tRNAs reveal that although the precise orientation of uridine-33 is not always the same, it connects the anticodon stacked along the 3' side of the loop with the pyrimidine-32 stacked on the 5' side of the loop. The remarkably conserved nature of uridine-33 and its unique position in the anticodon loop structure has led to suggestions that this nucleotide has an essential role in the translational mechanism. We have developed a biochemical procedure to replace nucleotides 33-35 in yeast tRNATyr with any desired sequence and used it to construct amber suppressor tRNAs having different nucleotides at position 33. As all of these synthetic amber suppressor tRNAs functioned well in eukaryotic in vitro suppression assays, we conclude that uridine-33 does not have an obligatory role in the translation mechanism.