The Escherichia coli argU10(Ts) phenotype is caused by a reduction in the cellular level of the argU tRNA for the rare codons AGA and AGG

The Escherichia coli argU10(Ts) mutation in the argU gene, encoding the minor tRNA(Arg) species for the rare codons AGA and AGG, causes pleiotropic defects, including growth inhibition at high temperatures, as well as the Pin phenotype at 30 degrees C. In the present study, we first showed that the codon selectivity and the arginine-accepting activity of the argU tRNA are both essential for complementing the temperature-sensitive growth, indicating that this defect is caused at the level of translation. An in vitro analysis of the effects of the argU10(Ts) mutation on tRNA functions revealed that the affinity with elongation factor Tu-GTP of the argU10(Ts) mutant tRNA is impaired at 30 and 43 degrees C, and this defect is more serious at the higher temperature. The arginine acceptance is also impaired significantly but to similar extents at the two temperatures. An in vivo analysis of aminoacylation levels showed that 30% of the argU10(Ts) tRNA molecules in the mutant cells are actually deacylated at 30 degrees C, while most of the argU tRNA molecules in the wild-type cells are aminoacylated. Furthermore, the cellular level of this mutant tRNA is one-tenth that of the wild-type argU tRNA. At 43 degrees C, the cellular level of the argU10(Ts) tRNA is further reduced to a trace amount, while neither the cellular abundance nor the aminoacylation level of the wild-type argU tRNA changes. We concluded that the phenotypic properties of the argU10(Ts) mutant result from these reduced intracellular levels of the tRNA, which are probably caused by the defective interactions with elongation factor Tu and arginyl-tRNA synthetase.     

Frameshift suppression at tandem AGA and AGG codons by cloned tRNA genes: assigning a codon to argU tRNA and T4 tRNA(Arg).

Arginine is coded for by CGN (N = G, A, U, C), AGA and AGG. In Escherichia coli there is little tRNA for AGA and AGG and the use of these codons is strongly avoided in virtually all genes. Recently, we demonstrated that the presence of tandem AGA or AGG codons in mRNA causes frameshifts with high frequency. Here, we show that phaseshifts can be suppressed when cells are transformed with the gene for tRNA(T4Arg) or E. coli tRNA(argU,Arg) demonstrating that such errors are the result of tRNA depletion. Bacteriophage T4 encoded tRNA(Arg) (anticodon UCU) corrects shifts at AGA-AGA but not at AGG-AGG, suggesting that this tRNA can only read AGA. Similarly, comparison of the translational efficiencies in an argU (Ts) mutant and in its isogenic wild type parent indicates that argU tRNA (anticodon UCU) reads AGA but not AGG. An argU (Ts) mutant barely reads through AGA-AGA at 42 degrees C but translation of AGG-AGG is hardly, if at all, affected. Overexpression of argU+ relaxes the codon specificity. The thermosensitive mutant in argU, previously called dnaY because it is defective in DNA replication, can be complemented for growth by the gene for tRNA(T4Arg). This implies that the sole function of the argU gene product is to sustain protein synthesis and that its role in replication is probably indirect.     

The pair of arginine codons AGA AGG close to the initiation codon of the lambda int gene inhibits cell growth and protein synthesis by accumulating peptidyl-tRNAArg4

To analyse the mechanism by which rare codons near the initiation codon inhibit cell growth and protein synthesis, we used the bacteriophage lambda int gene or early codon substitution derivatives. The lambda int gene has a high frequency of rare ATA, AGA and AGG codons; two of them (AGA AGG) located at positions 3 and 4 of the int open reading frame (ORF). Escherichia coli pth (rap) cells, which are defective in peptidyl-tRNA hydrolase (Pth) activity, are more susceptible to the inhibitory effects of int expression as compared with wild-type cells. Cell growth and Int protein synthesis were enhanced by overexpression of Pth and tRNAArg4 cognate to AGG and AGA but not of tRNAIle2a specific for ATA. The increase of Int protein synthesis also takes place when the rare arginine codons AGA and AGG at positions 3 and 4 are changed to common arginine CGT or lysine AAA codons but not to rare isoleucine ATA codons. In addition, overexpression of int in Pth defective cells provokes accumulation of peptidyl-tRNAArg4 in the soluble fraction. Therefore, cell growth and Int synthesis inhibition may be due to ribosome stalling and premature release of peptidyl-tRNAArg4 from the ribosome at the rare arginine codons of the first tandem, which leads to cell starvation for the specific tRNA.     

Overexpression of archaeal proteins in Escherichia coli

Six archaeal proteins containing a high number of Escherichia coli rare codons in their genes were not well expressed in E. coli. These genes showed a five to twenty-fold increase in production when expressed in the presence of a plasmid harboring and expressing the argU and ileX genes encoding rare tRNAs (tRNA arg(de)AGA/AGG and tRNA ile(de)AUA. © Rapid Science Ltd. 1998     

Simple and efficient method for heterologous expression of clostridial proteins

Many clostridial proteins are poorly produced in Escherichia coli. It has been suggested that this phenomena is due to the fact that several types of codons common in clostridial coding sequences are rarely used in E. coli and the quantities of the corresponding tRNAs in E. coli are not sufficient to ensure efficient translation of the corresponding clostridial sequences. To address this issue, we amplified three E. coli genes, ileX, argU, and leuW, in E. coli; these genes encode tRNAs that are rarely used in E. coli (the tRNAs for the ATA, AGA, and CTA codons, respectively). Our data demonstrate that amplification of ileX dramatically increased the level of production of most of the clostridial proteins tested, while amplification of argU had a moderate effect and amplification of leuW had no effect. Thus, amplification of certain tRNA genes for rare codons in E. coli improves the expression of clostridial genes in E. coli, while amplification of other tRNAs for rare codons might not be needed for improved expression. We also show that amplification of a particular tRNA gene might have different effects on the level of protein production depending on the prevalence and relative positions of the corresponding codons in the coding sequence. Finally, we describe a novel approach for improving expression of recombinant clostridial proteins that are usually expressed at a very low level in E. coli.     

Expression and characterization of the HMG-CoA reductase of the thermophilic archaeon Sulfolobus solfataricus

The thermostable class I HMG-CoA reductase of Sulfolobus solfataricus offers potential for industrial applications and for the initiation of crystallization trials of a biosynthetic HMG-CoA reductase. However, of the 15 arginine codons of the hmgA gene that encodes S. solfataricus HMG-CoA reductase, 14 (93%) are AGA or AGG, the arginine codons used least frequently by Escherichia coli. The presence of these rare codons in tandem or in the first 20 codons of a gene can complicate expression of that gene in E. coli. Problems include premature chain termination and misincorporation of lysine for arginine. We therefore sought to improve the expression and subsequent yield of S. solfataricus HMG-CoA reductase by expanding the pool size of tRNA(AGA,AGG), the tRNA that recognizes these two rare codons. Coexpression of the S. solfataricus hmgA gene with the argU gene that encodes tRNA(AGA,AGG) resulted in an over 10-fold increase in enzyme yield. This has provided significantly greater quantities of purified enzyme for potential industrial applications and for crystallographic characterization of a stable class I HMG-CoA reductase. It has, in addition, facilitated determination of kinetic parameters and of pH optima for all four catalyzed reactions, for determination of the K(i) for inhibition by the statin drug mevinolin, and for comparison of the properties of the HMG-CoA reductase of this thermophilic archaeon to those of other class I HMG-CoA reductases.     

A single base change in the acceptor stem of tRNA(3Leu) confers resistance upon Escherichia coli to the calmodulin inhibitor, 48/80

We have isolated several classes of spontaneous mutants resistant to the calmodulin inhibitor 48/80 which inhibits cell division in Escherichia coli K12. Several mutants were also temperature sensitive for growth and this property was exploited to clone a DNA fragment from an E. coli gene library restoring growth at 42 degrees C and drug sensitivity at 30 degrees C in one such mutant. Physical and genetic mapping confirmed that both the mutation and the cloned DNA were located at 15.5 min on the E. coli chromosome at a locus designated feeB. By subcloning, complementation analysis and sequencing, the feeB locus was identified as identical to the tRNA(CUALEU) gene. When the mutant locus was isolated and sequenced, the mutation was confirmed as a single base change, C to A, at position 77 in the acceptor stem of this rare Leu tRNA. In other studies we obtained evidence that this mutant tRNA, recognizing the rare Leu codon, CUA, was defective in translation at both permissive and non-permissive temperatures. The feeB1 mutant is defective in division and shows a reduced growth rate at non-permissive temperature. We discuss the possibility that the mutant tRNA(3Leu) is limiting for the synthesis of a polypeptide(s), requiring several CUA codons for translation which in turn regulates in some way the level or activity of the drug target, a putative cell cycle protein.     

A reduced level of charged tRNAArgmnm5UCU triggers the wild-type peptidyl-tRNA to frameshift

Frameshift mutations can be suppressed by a variety of differently acting external suppressors. The +1 frameshift mutation hisC3072, which has an extra G in a run of Gs, is corrected by the external suppressor mutation sufF44. We have shown that sufF44 and five additional allelic suppressor mutations are located in the gene argU coding for the minor tRNAArgmnm5UCU and alter the secondary and/or tertiary structure of this tRNA. The C61U, G53A, and C32U mutations influence the stability, whereas the C56U, C61U, G53A, and G39A mutations decrease the arginylation of tRNAArgmnm5UCU. The T-10C mutant has a base substitution in the -10 consensus sequence of the argU promoter that reduces threefold the synthesis of tRNAArgmnm5UCU . The lower amount of tRNAArgmnm5UCU or impaired arginylation, either independently or in conjunction, results in inefficient reading of the cognate AGA codon that, in turn, induces frameshifts. According to the sequence of the peptide produced from the suppressed -GGG-GAA-AGA- frameshift site, the frameshifting tRNA in the argU mutants is tRNAGlumnm5s2UUC, which decodes the GAA codon located upstream of the AGA arginine codon, and not the mutated tRNAArgmnm5UCU. We propose that an inefficient decoding of the AGA codon by a defective tRNAArgmnm5UCU stalls the ribosome at the A-site codon allowing the wild-type form of peptidyl-tRNAGlumnm5s2UUC to slip forward 1 nucleotide and thereby re-establish the ribosome in the 0-frame. Similar frame-shifting events could be the main cause of various phenotypes associated with environmental or genetically induced changes in the levels of aminoacylated tRNA.     

High-level expression and single-step purification of leucyl-tRNA synthetase from Aquifex aeolicus

Aquifex aeolicus leucyl-tRNA synthetase is the only known heterodimeric LeuRS, consisting of two subunits with molecular masses of 74.0 and 33.5 kDa, and named alphabeta-LeuRS. The gene encoding alpha subunit was cloned into pSBET-b vector. Synthetic oligonucleotide encoding six histidine residues was also inserted in front of alpha subunit. PSBET-b vector contains argU gene, which encodes a rare Escherichia coli tRNA(Arg)(AGA/AGG). The argU gene helps A. aeolicus LeuRS, which contains AGA/AGG codons in exceptionally high frequency, express well in E. coli. The gene encoding beta subunit was inserted into pET-15b vector. E. coli BL21-CodonPlus (DE3) cells were transformed with the two recombinant plasmids to produce alphabeta-LeuRS with a His6 tag at the N-terminus of alpha subunit. The enzyme was purified by affinity chromatography on Ni-NTA Superflow. About 7 mg purified alphabeta-LeuRS was obtained from 250 ml culture. The His6-tag at the N-terminus did not affect the aminoacylation activity of the enzyme.     

Functional defects in transfer RNAs lead to the accumulation of ribosomal RNA precursors

Normal expression and function of transfer RNA (tRNA) are of paramount importance for translation. In this study, we show that tRNA defects are also associated with increased levels of immature ribosomal RNA (rRNA). This association was first shown in detail for a mutant strain that underproduces tRNA(Arg2) in which unprocessed 16S and 23S rRNA levels were increased several-fold. Ribosome profiles indicated that unprocessed 23S rRNA in the mutant strain accumulates in ribosomal fractions that sediment with altered mobility. Underproduction of tRNA(Arg2) also resulted in growth defects under standard laboratory growth conditions. Interestingly, the growth and rRNA processing defects were attenuated when cells were grown in minimal medium or at low temperatures, indicating that the requirement for tRNA(Arg2) may be reduced under conditions of slower growth. Other tRNA defects were also studied, including a defect in RNase P, an enzyme involved in tRNA processing; a mutation in tRNA(Trp) that results in its degradation at elevated temperatures; and the titration of the tRNA that recognizes rare AGA codons. In all cases, the levels of unprocessed 16S and 23S rRNA were enhanced. Thus, a range of tRNA defects can indirectly influence translation via effects on the biogenesis of the translation apparatus.     

Ribosome can resume the translation in both +1 or -1 frames after encountering an AGA cluster in Escherichia coli

In Escherichia coli the rare codons AGG, AGA and CGA are reported to have a detrimental effect on protein synthesis, especially during the expression of heterologous proteins. In the present work, we have studied the impact of successive clusters of these rare codons on the accuracy of mRNA translation in E. coli. For this purpose, we have analyzed the expression of an mRNA which contains in its 3' region a triplet and a tandem of AGA codons. This mRNA is derived from the human hepatitis B virus (HBV) preC gene. Both in eukaryotic cells and in eukaryotic cell-free translation system, this mRNA, directs the synthesis of a single 25 kDa protein. However, in a conventional E. coli strain BL 21 (DE3), transformed with a plasmid expressing this protein the synthesis of four polypeptides ranging from 30 to 21.5 kDa can be observed. Using different approaches, notably expression of i) precore mutated proteins or ii) chimeric proteins containing HA- and Myc-tags downstream of the AGA clusters (respectively in the -1 or +1 frame), we have found that when the ribosome encounters the AGA clusters, it can then resume the translation in both +1 and -1 frames. This result is in agreement with the model proposed recently by Baranov et al. (Baranov, P.V., Gesteland, R.F., Atkins, J.F., 2004. P-site tRNA is a crucial initiator of ribosomal frameshifting. RNA 10, 221-230), thus confirming that AGA/AGG codons can serve as sites for -1 frameshifting events. Only +1 frameshifting was suggested previously to occur at the AGA/AGG clusters.     

Rare codon clusters at 5'-end influence heterologous expression of archaeal gene in Escherichia coli

Proteins from hyperthermophilic microorganisms are attractive candidates for novel biocatalysts because of their high resistance to temperature extremes. However, archaeal genes are usually poorly expressed in Escherichia coli because of differences in codon usage. Genes from the thermoacidophilic archaea Sulfolobus solfataricus and Thermoplasma acidophilum contain high proportions of rare codons for arginine, isoleucine, and leucine, which are recognized by the tRNAs encoded by the argU, ileY, and leuW genes, respectively, and which are rarely used in E. coli. To examine the effects of these rare codons on heterologous expression, we expressed the Sso_gnaD and Tac_gnaD genes from S. solfataricus and T. acidophilum, respectively, in E. coli. The Sso_gnaD product was expressed at very low levels when the open reading frame (ORF) was cloned in pRSET and expressed in E. coli BL21(DE3), and was expressed at much higher levels in the E. coli BL21(DE3)-CodonPlus RIL strain, which contains extra copies of the argU, ileY, and leuW tRNA genes. In contrast, Tac_gnaD was expressed at similar levels in both E. coli strains. Comparison of the Sso_gnaD and Tac_gnaD gene sequences revealed that the 5'-end of the Sso_gnaD sequence was rich in AGA(arg) and ATA(Ile) codons. These codons were replaced with the codons commonly used in E. coli by polymerase chain reaction-mediated site-directed mutagenesis. The results of expression studies showed that a non-tandem repeat of rare codons is critical in the observed interference in heterologous expression of this gene. We concluded that the level of heterologous expression of Sso_gnaD in E. coli was limited by the clustering of the rare codons in the ORF, rather than on the rare codon frequency.     

Translation efficiencies of synonymous codons for arginine differ dramatically and are not correlated with codon usage in chloroplasts

Codon usage in chloroplast mRNAs is different from that in prokaryotic and cytosolic mRNAs. We previously devised an in vitro assay for translation efficiencies using synthetic mRNAs, and measured translation efficiencies of five synonymous codon groups in tobacco chloroplasts. Using this assay, we here report our analysis of four additional synonymous codon groups in tobacco chloroplasts. We found that translation efficiencies of three arginine codons AGA, CGU and CGA differ dramatically, ca. 10-fold difference although the three arginine codons possess similar codon usage. Translation of AGA is very high, while CGA is translated extremely low. CGA is used frequently in chloroplasts but rare in Escherichia coli. The single tRNA species reads two histidine codons (CAU and CAC) and this is also the case for two glutamic acid codons (GAA and GAG) and two arginine codons (GCU and GCA). Their translation efficiencies, however, differ significantly. These observations suggest that individual codons posses their intrinsic efficiencies.     

In vivo misreading by tRNA overdose

Rpb5-H147R is an AT-GC transition replacing CAC(His) by CGC(Arg) at a conserved and critical position of ABC27 (Rpb5p), one of the five common and essential subunits shared by all three eukaryotic RNA polymerases. This mutation is viable at 25 degrees C, but has a lethal phenotype at 34 degrees C. A search for dosage-dependent suppressors identified five distinct clones that all bear a copy of the tRNA(His)GUG gene. Suppression was also observed with a small genomic insert bearing this tRNA gene and no other coding sequences, under conditions where there is a sevenfold increase in the cellular concentration of tRNA(His)GUG. Overexpressing tRNA(Arg)ICG, which normally decodes the suppressed CGC codon, counteracted suppression. Suppression is codon specific because it was abolished when replacing CGC by its synonymous codons CGA, CGU, or AGA, but was not detectably affected by several nucleotide substitutions modifying the surrounding sequence and is thus largely insensitive to the nucleotide context. It is proposed that overexpressing tRNA(His)GUG extends its decoding properties from CAC(His) to the noncognate CGC(Arg) codon through an illegitimate U x G pairing at the middle base of the anticodon. Accordingly, tRNA(His)GUG would compete with tRNA(Arg)ICG for chain elongation and generate a significant level of misreading errors under normal growth conditions.     

Codon-specific and general inhibition of protein synthesis by the tRNA-sequestering minigenes

The expression of minigenes in bacteria inhibits protein synthesis and cell growth. Presumably, the translating ribosomes, harboring the peptides as peptidyl-tRNAs, pause at the last sense codon of the minigene directed mRNAs. Eventually, the peptidyl-tRNAs drop off and, under limiting activity of peptidyl-tRNA hydrolase, accumulate in the cells reducing the concentration of specific aminoacylable tRNA. Therefore, the extent of inhibition is associated with the rate of starvation for a specific tRNA. Here, we used minigenes harboring various last sense codons that sequester specific tRNAs with different efficiency, to inhibit the translation of reporter genes containing, or not, these codons. A prompt inhibition of the protein synthesis directed by genes containing the codons starved for their cognate tRNA (hungry codons) was observed. However, a non-specific in vitro inhibition of protein synthesis, irrespective of the codon composition of the gene, was also evident. The degree of inhibition correlated directly with the number of hungry codons in the gene. Furthermore, a tRNA(Arg4)-sequestering minigene promoted the production of an incomplete beta-galactosidase polypeptide interrupted, during bacterial polypeptide chain elongation at sites where AGA codons were inserted in the lacZ gene suggesting ribosome pausing at the hungry codons.     

SsrA-mediated peptide tagging caused by rare codons and tRNA scarcity.

SsrA RNA mediates the addition of a C-terminal peptide tag (AANDENYALAA) to bacterial proteins translated from mRNAs without in-frame stop codons. This process involves both tRNA- and mRNA-like functions of SsrA and targets the tagged proteins for degradation. By designing an SsrA variant that adds a peptide tag (AANDENYALDD) that does not result in rapid degradation, we show that tagging of a model protein synthesized from an mRNA without stop codons can be detected both in vivo and in vitro. We also use this assay to demonstrate that ribosome stalling at clusters of rare arginine codons in mRNA is sufficient to recruit and activate the SsrA peptide tagging system. An essential requirement for tagging at rare AGA codons is a scarcity of the cognate tRNA; supplemental tRNA(AGA) suppresses tagging, and depleting the available pool of tRNA(AGA) enhances tagging and reveals tagging caused by single rare AGA codons. Protein tagging at sites corresponding to rare codons appears to involve SsrA action at an internal mRNA site rather than at the 3' end of a cleaved mRNA.     

Suppression of the negative effect of minor arginine codons on gene expression; preferential usage of minor codons within the first 25 codons of the Escherichia coli genes.

AGA and AGG codons for arginine are the least used codons in Escherichia coli, which are encoded by a rare tRNA, the product of the dnaY gene. We examined the positions of arginine residues encoded by AGA/AGG codons in 678 E. coli proteins. It was found that AGA/AGG codons appear much more frequently within the first 25 codons. This tendency becomes more significant in those proteins containing only one AGA or AGG codon. Other minor codons such as CUA, UCA, AGU, ACA, GGA, CCC and AUA are also found to be preferentially used within the first 25 codons. The effects of the AGG codon on gene expression were examined by inserting one to five AGG codons after the 10th codon from the initiation codon of the lacZ gene. The production of beta-galactosidase decreased as more AGG codons were inserted. With five AGG codons, the production of beta-galactosidase (Gal-AGG5) completely ceased after a mid-log phase of cell growth. After 22 hr induction of the lacZ gene, the overall production of Gal-AGG5 was 11% of the control production (no insertion of arginine codons). When five CGU codons, the major arginine codon were inserted instead of AGG, the production of beta-galactosidase (Gal-CGU5) continued even after stationary phase and the overall production was 66% of the control. The negative effect of the AGG codons on the Gal-AGG5 production was found to be dependent upon the distance between the site of the AGG codons and the initiation codon. As the distance was increased by inserting extra sequences between the two codons, the production of Gal-AGG5 increased almost linearly up to 8 fold. From these results, we propose that the position of the minor codons in an mRNA plays an important role in the regulation of gene expression possibly by modulating the stability of the initiation complex for protein synthesis.