Mistranslation of the mRNA encoding bacteriophage T7 0.3 protein

Quality control of protein synthesis in the early elongation stage

In the early stage of bacterial translation, peptidyl-tRNAs frequently dissociate from the ribosome (pep-tRNA drop-off) and are recycled by peptidyl-tRNA hydrolase. Here, we establish a highly sensitive method for profiling of pep-tRNAs using mass spectrometry, and successfully detect a large number of nascent peptides from pep-tRNAs accumulated in Escherichia coli pthts strain. Based on molecular mass analysis, we found about 20% of the peptides bear single amino-acid substitutions of the N-terminal sequences of E. coli ORFs. Detailed analysis of individual pep-tRNAs and reporter assay revealed that most of the substitutions take place at the C-terminal drop-off site and that the miscoded pep-tRNAs rarely participate in the next round of elongation but dissociate from the ribosome. These findings suggest that pep-tRNA drop-off is an active mechanism by which the ribosome rejects miscoded pep-tRNAs in the early elongation, thereby contributing to quality control of protein synthesis after peptide bond formation.

Reprogramming the genetic code

The encoded biosynthesis of proteins provides the ultimate paradigm for high-fidelity synthesis of long polymers of defined sequence and composition, but it is limited to polymerizing the canonical amino acids. Recent advances have built on genetic code expansion - which commonly permits the cellular incorporation of one type of non-canonical amino acid into a protein - to enable the encoded incorporation of several distinct non-canonical amino acids. Developments include strategies to read quadruplet codons, use non-natural DNA base pairs, synthesize completely recoded genomes and create orthogonal translational components with reprogrammed specificities. These advances may enable the genetically encoded synthesis of non-canonical biopolymers and provide a platform for transforming the discovery and evolution of new materials and therapeutics.

Analysis of Translation Elongation Dynamics in the Context of an Escherichia coli Cell

Understanding the mechanisms behind translation and its rate-limiting steps is crucial for both the development of drug targets and improvement of heterologous protein production with many biotechnological applications, such as in pharmaceutical and biofuel industries. Despite many advances in the knowledge of the ribosome structure and function, there is still much discussion around the determinants of translation elongation with experiments and computational studies pointing in different directions. Here, we use a stochastic framework to simulate the process of translation in the context of an Escherichia coli cell by gathering the available biochemical data into a ribosome kinetics description. Our results from the study of translation in E. coli at different growth rates contradict the increase of mean elongation rate with growth rate established in the literature. We show that both the level of tRNA competition and the type of cognate binding interaction contribute to the modulation of elongation rate, and that optimization of a heterologous transcript for faster elongation rate is achieved by combining the two. We derive an equation that can accurately predict codon elongation rates based on the abundances of free tRNA in the cell, and can be used to assist transcript design. Finally, we show that non-cognate tRNA-ribosome binding has an important weight in translation, and plays an active role in the modulation of mean elongation rate as shown by our amino-acid starvation/surplus studies.

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.

The frequency of translational misreading errors in E. coli is largely determined by tRNA competition

Estimates of missense error rates (misreading) during protein synthesis vary from 10(-3) to 10(-4) per codon. The experiments reporting these rates have measured several distinct errors using several methods and reporter systems. Variation in reported rates may reflect real differences in rates among the errors tested or in sensitivity of the reporter systems. To develop a more accurate understanding of the range of error rates, we developed a system to quantify the frequency of every possible misreading error at a defined codon in Escherichia coli. This system uses an essential lysine in the active site of firefly luciferase. Mutations in Lys529 result in up to a 1600-fold reduction in activity, but the phenotype varies with amino acid. We hypothesized that residual activity of some of the mutant genes might result from misreading of the mutant codons by tRNA(Lys) (UUUU), the cognate tRNA for the lysine codons, AAA and AAG. Our data validate this hypothesis and reveal details about relative missense error rates of near-cognate codons. The error rates in E. coli do, in fact, vary widely. One source of variation is the effect of competition by cognate tRNAs for the mutant codons; higher error frequencies result from lower competition from low-abundance tRNAs. We also used the system to study the effect of ribosomal protein mutations known to affect error rates and the effect of error-inducing antibiotics, finding that they affect misreading on only a subset of near-cognate codons and that their effect may be less general than previously thought.

Can tRNAs act as antisense RNA? The case of mutA and dnaQ

Many mutator genes have been characterized in E. coli, but the realization that mutA, the most recent mutator pathway described, encodes for a missense suppressor glycine tRNA caused a real surprise. The connection between expression of mutA and a 10 times increase in the spontaneous mutation rate is not readily explainable. The first attempt to describe the mechanism of action suggested a direct mistranslation of one subunit of polymerase III (PolIII) and the ideal candidate was the epsilon subunit carrying the 3'-->5' exonuclease activity. This subunit increases PolIII accuracy about 100 times. However, such direct mistranslation of epsilon was later ruled out when it became clear that all mutA cells express an error-prone form of PolIII. This result could not be reconciled with the very low level of mistranslation (1%) caused by mutA. But there is no need to invoke amino acid misincorporation in epsilon to destroy its activity. On the contrary, I suggest a new way to regulate epsilon amount, based on the reinterpretation of the mutA pathway through the new and puzzling observation that several tRNAs (including mutA which encodes for a glycine missense suppressor tRNA) are complementary to the 5' end of dnaQ mRNA. Accordingly, I propose that uncharged tRNAs can act as antisense RNAs, decreasing translation of dnaQ and possibly other genes. This could represent a new regulatory function for tRNAs and of course gives a direct and unrecognized link between starvation and mutation rate.

Kinetic determinants of high-fidelity tRNA discrimination on the ribosome

The ribosome selects aminoacyl-tRNA (aa-tRNA) matching to the mRNA codon from the bulk of non-matching aa-tRNAs in two consecutive selection steps, initial selection and proofreading. Here we report the kinetic analysis of selection taking place under conditions where the overall selectivity was close to values observed in vivo and initial selection and proofreading contributed about equally. Comparison of the rate constants shows that the 350-fold difference in stabilities of cognate and near-cognate codon-anticodon complexes is not used for tRNA selection due to high rate of GTP hydrolysis in the cognate complex. tRNA selection at the initial selection step is entirely kinetically controlled and is due to much faster (650-fold) GTP hydrolysis of cognate compared to near-cognate substrate.

Fidelity of aminoacyl-tRNA selection on the ribosome: kinetic and structural mechanisms

The ribosome discriminates between correct and incorrect aminoacyl-tRNAs (aa-tRNAs), or their complexes with elongation factor Tu (EF-Tu) and GTP, according to the match between anticodon and mRNA codon in the A site. Selection takes place at two stages, prior to GTP hydrolysis (initial selection) and after GTP hydrolysis but before peptide bond formation (proofreading). In part, discrimination results from different rejection rates that are due to different stabilities of the respective codon-anticodon complexes. An important additional contribution is provided by induced fit, in that only correct codon recognition leads to acceleration of rate-limiting rearrangements that precede chemical steps. Recent elucidation of ribosome structures and mutational analyses suggest which residues of the decoding center may be involved in signaling formation of the correct codon-anticodon duplex to the functional centers of the ribosome. In utilizing induced fit for substrate discrimination, the ribosome resembles other nucleic acid-programmed polymerases.

Measurement of translational accuracy in vivo: missense reporting using inactive enzyme mutants

The measurement and potential technological significance of in vivo missense errors are briefly reviewed. A recently developed approach is described in which reporter enzyme activity is generated by mistranslation of a gene coding for an inactive mutant form of the enzyme. Initial results obtained using the alpha subunit of E coli tryptophan synthetase and bacterial luciferase are discussed, as well as the prospects for further development of this method.

Mistranslation in twelve Escherichia coli ribosomal proteins. Cysteine misincorporation at neutral amino acid residues other than tryptophan

The misincorporation of cysteine (codon: UGU/C) into twelve ribosomal proteins devoid of cysteine has been studied. Although it is generally assumed that cysteine is misincorporated at arginine and tryptophan residues (codons: CGU/U and UGG respectively), our results are consistent with the idea that cysteine is also misincorporated at phenylalanine residues (codon: UUU/C) through a second-position C:U mismatch. Cysteine was found in ribosomal proteins L29, L32/L33 and S10, under conditions where only its misincorporation at neutral residues was measured. Since these proteins contain no tryptophan, the date imply that cysteine has replaced a neutral amino acid other than tryptophan. Because there was a statistically significant correlation between the total level of cysteine in the twelve proteins under study and their content of phenylalanine and arginine residues, we conclude that there is a likelihood of cysteine misincorporation at phenylalanine residues, in addition to its misincorporation at arginine and tryptophan residues. Our measurements are consistent with the existence of a cluster of ribosomal proteins having an average mistranslation frequency of 2.5 X 10(-4)/residue and another having an average mistranslation frequency of 10(-3)/residue. There was three times less cysteine misincorporated into ribosomal protein L1 than into L7/L12, although the L1 mRNA contains eleven CGU/C codons and four UUU/C codons while the L7/L12 mRNA contains only one arginine and two phenylalanine codons (both proteins are free of tryptophan). Furthermore, the mRNAs for both L1 and L7/L12 contain a CGU codon located in the context GUA-codon-GG and there was as much cysteine incorporated at this codon in L7/L12 [Bouadloun, F., Donner, D. and Kurland, C.G. (1983) EMBO J. 2, 1351-1356] than in the whole of L1. This suggests that, relatively speaking, little cysteine is to be found at the phenylalanine and the other ten arginine positions of L1 and that the phenylalanine residues of L7/L12 are particularly error-prone.

Identification of sites of cysteine misincorporation during in vivo synthesis of bacteriophage T7 0.3 protein

The 0.3 protein encoded by coliphage T7 does not normally contain cysteine residues. Incorporation of [35S]cysteine can therefore be used to assay mistranslation. We have purified 0.3 protein, synthesized in the presence of [35S]cysteine, from T7 infected cells of E. coli and determined the locations of misincorporated cysteine residues. Analysis of the molecular weights (Mr) of [35S]cysteine-labeled tryptic peptides of 0.3 protein demonstrated that cysteine (encoded by UGU or UGC) is not extensively misincorporated, as might be predicted by substitution for arginine residues (encoded by CGU or CGC). Edman degradation of the amino-terminal 50 residues of [35S]cysteine-labeled 0.3 protein determined that cysteine was most frequently misincorporated at position 15, which is correctly occupied by a tyrosine residue (encoded by UAC). There are four other tyrosine codons (1 UAU; 3 UAC) in the region of the 0.3 protein studied, but these were not mistranslated. The context in which a codon is located must therefore be more important in causing mistranslation than the sequence of the codon itself. Misincorporation of [35S]cysteine was also found at positions 9 (ACC, asparagine), 16 (GAA, glutamic acid), 41 (GCC, alanine) and 42 (GAU, aspartic acid). One mistranslation event appears to increase the likelihood that the following codon will also be mistranslated. This clustering of misincorporated [35S]cysteine residues was accentuated in 0.3 protein synthesized in the presence of streptomycin.

Effect of polyamines on translation fidelity in vivo

Polyamines, when added to cell-free protein-synthesizing systems, have been shown either to reduce mistranslation or to increase it depending upon the composition of the reaction mixture. To study this question under conditions as natural as possible we investigated the effects of polyamines on the fidelity of protein synthesis in intact Escherichia coli bacterial cells, using strains which were auxotrophic for polyamine synthesis. Error was measured in two ways: the incorporation of [3H]histidine into coat protein of bacteriophage MS2, the gene of which does not code for histidine, and the synthesis of a basic variant of MS2 coat protein in which a lysine erroneously replaces an asparagine, causing a change in isoelectric point. We found that when cell cultures were supplemented with polyamines there was no effect on the first type of error and the second type decreased twofold. The measured errors occurred at the level of translation because their frequency increased in the presence of streptomycin and decreased in cells bearing a streptomycin-resistance mutation known to lower the occurrence of translational misreading. The average erroneous incorporation per mol coat protein in the presence of polyamines was 1.43 +/- 0.59 mmol histidine and 25-34 mmol lysine/asparagine substitution. The reason for the different effect of polyamines on the two types of error is not known but could be related to the difference between their corresponding frequencies or to codon-specific effects.

Expression of coliphage T7 in aging anucleate minicells of Escherichia coli

Anucleate minicells produced by a mutated strain of Escherichia coli remain metabolically active for up to 48 h at 37 degrees C. Minicells of increasing age have been infected with the coliphage T7. Infection results in the onset of transcription and translation producing T7 encoded polypeptides. Quantitative and qualitative changes in T7 gene expression result from infection of increasingly old minicells. There is no detectable increase in the frequency of error occurrence in the synthesis of T7 polypeptides in infected old minicells as compared to infected young minicells.