Novel Temperature-Sensitive Mutants of Escherichia coli That Are Unable To Grow in the Absence of Wild-Type tRNA6Leu

Escherichia coli has only a single copy of a gene for tRNA₆^Leu (Y. Komine et al., J. Mol. Biol. 212:579–598, 1990). The anticodon of this tRNA is CAA (the wobble position C is modified to O²-methylcytidine), and it recognizes the codon UUG. Since UUG is also recognized by tRNA₄^Leu, which has UAA (the wobble position U is modified to 5-carboxymethylaminomethyl-O²-methyluridine) as its anticodon, tRNA₆^Leu is not essential for protein synthesis. The BT63 strain has a mutation in the anticodon of tRNA₆^Leu with a change from CAA to CUA, which results in the amber suppressor activity of this strain (supP, Su⁺6). We isolated 18 temperature-sensitive (ts) mutants of the BT63 strain whose temperature sensitivity was complemented by introduction of the wild-type gene for tRNA₆^Leu. These tRNA₆^Leu-requiring mutants were classified into two groups. The 10 group I mutants had a mutation in the miaA gene, whose product is involved in a modification of tRNAs that stabilizes codon-anticodon interactions. Overexpression of the gene for tRNA₄^Leu restored the growth of group I mutants at 42°C. Replacement of the CUG codon with UUG reduced the efficiency of translation in group I mutants. These results suggest that unmodified tRNA₄^Leu poorly recognizes the UUG codon at 42°C and that the wild-type tRNA₆^Leu is required for translation in order to maintain cell viability. The mutations in the six group II mutants were complemented by introduction of the gidA gene, which may be involved in cell division. The reduced efficiency of translation caused by replacement of the CUG codon with UUG was also observed in group II mutants. The mechanism of requirement for tRNA₆^Leu remains to be investigated.In the universal genetic code, 61 sense codons correspond to 20 amino acids, and the various tRNA species mediate the flow of information from the genetic code to amino acid sequences. Since codon-anticodon interactions permit wobble pairing at the third position, 32 tRNAs, including tRNA^fMet, should theoretically be sufficient for a complete translation system. Although some organisms have fewer tRNAs (1), most have abundant tRNA species and multiple copies of major tRNAs. For example, Escherichia coli has 86 genes for tRNA (79 genes identified in reference 14, 6 new ones reported in reference 3, and one fMet tRNA at positions 2945406 to 2945482) that encode 46 different amino acid acceptor species. Although abundant genes for tRNAs are probably required for efficient translation, the significance of the apparently nonessential tRNAs has not been examined.E. coli has five isoaccepting species of tRNA^Leu. According to the wobble rule, tRNA₁^Leu recognizes only the CUG codon. The CUG codon is also recognized by tRNA₃^Leu (tRNA₂^Leu) and thus tRNA₁^Leu may not be essential for protein synthesis. Similarly, tRNA₆^Leu is supposed to recognize only the UUG codon, but tRNA₄^Leu can recognize both UUA and UUG codons. Thus, tRNA₆^Leu appears to be dispensable. The existence of an amber suppressor mutation of tRNA₆^Leu (supP, Su⁺6) supports this possibility. tRNA₆^Leu is encoded by a single-copy gene, leuX (supP), and Su⁺6 has a mutation in the anticodon, which suggests loss of the ability to recognize UUG (26). Why are so many species of tRNA^Leu required? Holmes et al. (12) examined the utilization of the isoaccepting species of tRNA^Leu in protein synthesis and showed that utilization differs depending on the growth medium; in minimal medium, isoacceptors tRNA₂^Leu (cited as tRNA₃^Leu; see Materials and Methods) and tRNA₄^Leu are the predominant species that are found bound to ribosomes, but an increased relative level of tRNA₁^Leu is found bound to ribosomes in rich medium. The existence of tRNA₆^Leu is puzzling. This isoaccepting tRNA accounts for approximately 10% of the tRNA^Leu in total-cell extracts. However, little if any tRNA₆^Leu is found on ribosomes in vivo, and it is also only weakly active in protein synthesis in vitro with mRNA from E. coli (12). It thus appears that tRNA₆^Leu is only minimally involved in protein synthesis in E. coli.To investigate the role of tRNA₆^Leu in E. coli, we attempted to isolate tRNA₆^Leu-requiring mutants from an Su⁺6 strain. These mutants required wild-type tRNA₆^Leu for survival at a nonpermissive temperature. We report here the isolation and the characterization of these mutants.     

Specificity of codon recognition by Escherichia coli tRNALeu isoaccepting species determined by protein synthesis in vitro directed by phage RNA.

Codon-anticodon recognition and transfer RNA utilization for the leucine tRNA isoaccepting species of Escherichia coli have been studied by protein synthesis in vitro directed by sequenced bacteriophage MS2 RNA. We have added radioactive Leu-tRNA^Leu isoaccepting species as tracers, rather than use a tRNA-dependent system, since in the presence of an excess of non-radioactive leucine, there is no transfer of radioactive leucine from one isoaccepting species to another. MS2-specific peptides containing leucine residues encoded by known codons were isolated and identified, and the relative abilities of the Leu-tRNA^Leu isoaccepting species to transfer leucine into these peptides compared. Sequenced tRNA₁^Leu and sequenced tRNA₃^Leu are of roughly equal efficiency in their ability to recognize CUC and CUA codons, while tRNA₃^Leu is highly preferred for the CUU codon; tRNA₄^Leu and tRNA₅^Leu both recognize UUA and UUG codons, with tRNA₄^Leu slightly preferred for the UUA codon. We conclude that: (1) wobble is greater than permitted by the wobble hypothesis; (2) there is still some discrimination in the third code letter, and that the CUX₄ (CUC, CUA, CUU, CUG) portion of the leucine family of six codons is not read by a simple “two out of three” mechanism; (3) a Watson-Crick pair (C · G) between codon and anticodon does not appear to be preferred over an unorthodox pair (C · C) in the wobble position; (4) a standard wobble pair (U · G) between codon and anticodon is preferred over an unorthodox pair (U · C); and (5) the extensive wobble observed in the CUX₄ leucine codon series is not paralleled in the UUX₄ leucine (UUG, UUA) and phenylalanine (UUU, UUC) codon series, where mistranslation would be the consequence of such wobble.     

The yeast cloning vector YEp13 contains a tRNA3Leu gene that can mutate to an amber suppressor

We have shown that the yeast-Escherichia coli shuttle vector YEp 13 contains, as part of its yeast chromosomal segment, a tRNA₃^Leu gene. We have also isolated and characterized a variant of YEp13, namely YEp13-a, which is capable of suppressing a variety of yeast amber-suppressible alleles in vivo. YEp13-a differs from YEp13 by a single point mutation, which changes the three-nucleotide, plus-strand sequence corresponding to the tRNA₃^Leu anticodon from the normal C-A-A to C-T-A. This nucleotide change creates a site for the restriction enzyme XbaI in the suppressor tRNA₃^Leu gene. We have taken advantage of the correlation between the suppressor mutation and the XbaI site formation, to show that the tRNA₃^Leu gene on YEp13 corresponds to the genetically characterized yeast chromosomal amber suppressor SUP53. We have also shown that SUP53 is located just centromere-distal to LEU2 on chromosome III. Finally, comparison of the DNA sequence of SUP53 and its flanking regions with the sequences of other cloned yeast tRNA₃^Leu genes has revealed considerable sequence homology in the immediate 5′-flanking regions of these genes.     

Localization of four genes for three tRNALeu's on the physical map of the soybean (Glycine max L.) chloroplast genome

Three tRNAs^Leu from soybean chloroplasts were isolated and hybridized to restriction fragments of soybean chloroplast DNA. Based on the hybridization pattern, the locations of four genes coding for tRNA₁^Ley, tRNA₂^Leu (two genes tRNA_2a^Ley and tRNA_2b^Leu, are present in the inverted repeat region) and tRNA₃^Leu were determined on the physical map of the soybean chloroplast genome.     

Overproduction and purification ofEscherichia coli tRNALeu

Chemically synthesized genes encodingEscherichia coli tRNA ₁ ^Leu and tRNA ₂ ^Leu were ligated into the plasmid pTrc99B. then transformed intoEscherichia coli MT102, respectively. The positive transformants, named MT-Leu1 and MT-Leu2, were confirmed by DNA sequencing, and the conditions of cultivation for the two transformants were optimized. As a result, leucinc accepting activity of their total tRNA reached 810 and 560 pmol/A₂₆₀, respectively: the content of tRNA ₁ ^Leu was 50% of total tRNA from MT-Leu1, while that of tRNA ₂ ^Leu was 30% of total tRNA from MT-Leu2. Both tRNA^Leus from their rotal tRNs were fractionated to 1 600 pmol/A₂₆₀ after DEAE-Sepharose and BD-cellulose column chromatography. The accurate kinetic constants of aminoacylation of the two isoacceptors of tRNA^Leu catalyzed by leucyl-tRNA synthetase were determined.     

In vivo identification of essential nucleotides in tRNALeu to its functions by using a constructed yeast tRNALeu knockout strain

The fidelity of protein biosynthesis requires the aminoacylation of tRNA with its cognate amino acid catalyzed by aminoacyl-tRNA synthetase with high levels of accuracy and efficiency. Crucial bases in tRNA^Leu to aminoacylation or editing functions of leucyl-tRNA synthetase have been extensively studied mainly by in vitro methods. In the present study, we constructed two Saccharomyces cerevisiae tRNA^Leu knockout strains carrying deletions of the genes for tRNA^Leu(GAG) and tRNA^Leu(UAG). Disrupting the single gene encoding tRNA^Leu(GAG) had no phenotypic consequence when compared to the wild-type strain. While disrupting the three genes for tRNA^Leu(UAG) had a lethal effect on the yeast strain, indicating that tRNA^Leu(UAG) decoding capacity could not be compensated by another tRNA^Leu isoacceptor. Using the triple tRNA knockout strain and a randomly mutated library of tRNA^Leu(UAG), a selection to identify critical tRNA^Leu elements was performed. In this way, mutations inducing in vivo decreases of tRNA levels or aminoacylation or editing ability by leucyl-tRNA synthetase were identified. Overall, the data showed that the triple tRNA knockout strain is a suitable tool for in vivo studies and identification of essential nucleotides of the tRNA.     

Effects of tRNALeu1 overproduction in Escherichia coli

Strains of Escherichia coli have been produced which express very high levels of the tRNA^leu₁ isoacceptor. This was accomplished by transforming cells with plasmids containing the leuV operon which encodes three copies of the tRNA^Leu₁ gene. Most transformants grew very slowly and exhibited a 15-fold increase in cellular concentrations of tRNA^Leu₁ As a result, total cellular tRNA concentration was approximately doubled and 56% of the total was tRNA^Leu₁. We examined a number of parameters which might be expected to be affected by imbalances in tRNA concentration: in vivo tRNA charging levels, misreading, ribosome step time, and tRNA modification. Surprisingly, no increase in intracellular ppGpp levels was detected even though only about 40% of total leucyl tRNA was found to be charged in vivo. Gross ribosomal misreading was not detected, and it was shown that ribosomal step times were reduced between two- and threefold. Analyses of leucyl tRNA isolated from these slow-growing strains showed that at least 90% of the detectable tRNA^Leu₁ was hypomodified as judged by altered mobility on RPC-5 reverse-phase columns, and by specific modification assays using tRNA(m¹G)-methyltransferase and pseudo-uridylate synthetase. Analysis of fast-growing revertants demonstrated that tRNA concentration per se may not explain growth inhibition because selected revertants which grew at wild-type growth rates displayed levels of tRNA comparable to that of control strains bearing the leuV operon. A synthetic tRNA^Leu₁ operon under the control of the T7 promoter was prepared which, when induced, produced six- to sevenfold increases in tRNA^Leu₁ levels. This level of tRNA^Leu₁ titrated the modification system as judged by RPC-5 column chromatography. Overall, our results suggest that hypomodified tRNA may explain, in part, the observed effects on growth, and that the protein-synthesizing system can tolerate an enormous increase in the concentration of a single tRNA.     

Localization of Two Recognition Sites in Yeast Valine tRNA I

AS a part of our research on the structure–function relationships of tRNA^val_I we have been mapping the regions that take part in the recognition of valyl tRNA ligase. Using the “dissected molecule” method¹, we have shown that associated molecules consisting of tRNA^Val_I fragments lacking nucleotides in the anticodon loop, the dihydrouridine loop (D) or the thymidine loop (T) retain their acceptor activity. By contrast, dissected molecules devoid of the pentanucleotide A₃₆CACGp (the sequence A₃₆C belongs to the anticodon T₃₅AC) or lacking any quarter (F_1–19, F_17–35 or F_36–57) are inactive^2–4. Here we report a study of the acceptor activity of other incomplete tRNA^val_I molecules. The principal inference is that the dinucleotides A₃₆Cp in the anticodon loop and 5′-terminal pG₁Gp in the CCA stem are at least parts of two different recognition sites of this tRNA.     

Toxicity of a heterologous leucyl-tRNA (anticodon CAG) in the pathogen Candida albicans: in vivo evidence for non-standard decoding of CUG codons

Plasmids containing derivatives of the Saccharomyces cerevisiae leucyl-tRNA (tRNA3 ₃ ^Leu ) gene that vary in anticodon sequence were constructed and transformed into the pathogen Candida albicans and S. cerevisiae. C. albicans could readily be transformed with plasmids encoding leucyl-tRNA genes with the anticodons CAA and UAA (recognizing the codons UUG and UUA) and expression of the heterologous tRNA^Leu could be demonstrated by Northern RNA blotting. In contrast, no transformants were obtained if the anticodons were UAG (codons recognized CUN, UUR) and CAG (codon CUG), indicating that the insertion of leucine at CUG codons is toxic for C. albicans. All tRNA^Leu-encoding plasmids transformed S. cerevisiae with equally high efficiencies. These results provide in vivo evidence that non-standard decoding of CUG codons is essential for the viability of C. albicans.     

Characterization of an Escherichia coli mutant, feeA, displaying resistance to the calmodulin inhibitor 48/80 and reduced expression of the rare tRNA3Leu

We previously described a mutation feeB1 conferring a temperature-sensitive filamentation phenotype and resistance to the calmodulin inhibitor 48/80 in Escherichia coli, which constitutes a single base change in the acceptor stem of the rare tRNA₃^Leu recognizing CUA codons. We now describe a second mutant, feeA1, unlinked to feeB, but displaying a similar phenotype, 48/80 resistance and a reduced growth rate at the permissive temperature, 30°C, and temperature-sensitive, forming short filaments at 42°C. In the feeA mutant, tRNA₃^Leu expression (but not that of tRNA₁^Leu) was reduced approximately fivefold relative to the wild type. We previously showed that the synthesis of β-galactosidase, which unusually requires the translation of 6-CUA codons, was substantially reduced, particularly at 42°C, in feeB mutants. The feeA mutant also shows drastically reduced synthesis of β-galactosidase at the non-permissive temperature and reduced levels even at the permissive temperature. We also show that increased copy numbers of the abundant tRNA₁^Leu, which can also read CUA codons at low efficiency, suppressed the effects of feeA1 under some conditions, providing further evidence that the mutant was deficient in CUA translation. This, and the previous study, demonstrates that mutations which either reduce the activity of tRNA₃^Leu or the cellular amount of tRNA₃^Leu confer resistance to the drug 48/80, with concomitant inhibition of cell division at 42°C.     

Toxicity of a heterologous leucyl-tRNA (anticodon CAG) in the pathogen Candida albicans: in vivo evidence for non-standard decoding of CUG codons

Plasmids containing derivatives of the Saccharomyces cerevisiae leucyl-tRNA (tRNA3 ₃ ^Leu ) gene that vary in anticodon sequence were constructed and transformed into the pathogen Candida albicans and S. cerevisiae. C. albicans could readily be transformed with plasmids encoding leucyl-tRNA genes with the anticodons CAA and UAA (recognizing the codons UUG and UUA) and expression of the heterologous tRNA^Leu could be demonstrated by Northern RNA blotting. In contrast, no transformants were obtained if the anticodons were UAG (codons recognized CUN, UUR) and CAG (codon CUG), indicating that the insertion of leucine at CUG codons is toxic for C. albicans. All tRNA^Leu-encoding plasmids transformed S. cerevisiae with equally high efficiencies. These results provide in vivo evidence that non-standard decoding of CUG codons is essential for the viability of C. albicans.     

Structural insights into translational recoding by frameshift suppressor tRNASufJ

The three-nucleotide mRNA reading frame is tightly regulated during translation to ensure accurate protein expression. Translation errors that lead to aberrant protein production can result from the uncoupled movement of the tRNA in either the 5′ or 3′ direction on mRNA. Here, we report the biochemical and structural characterization of +1 frameshift suppressor tRNA^SufJ, a tRNA known to decode four, instead of three, nucleotides. Frameshift suppressor tRNA^SufJ contains an insertion 5′ to its anticodon, expanding the anticodon loop from seven to eight nucleotides. Our results indicate that the expansion of the anticodon loop of either ASL^SufJ or tRNA^SufJ does not affect its affinity for the A site of the ribosome. Structural analyses of both ASL^SufJ and ASL^Thr bound to the Thermus thermophilus 70S ribosome demonstrate both ASLs decode in the zero frame. Although the anticodon loop residues 34–37 are superimposable with canonical seven-nucleotide ASLs, the single C31.5 insertion between nucleotides 31 and 32 in ASL^SufJ imposes a conformational change of the anticodon stem, that repositions and tilts the ASL toward the back of the A site. Further modeling analyses reveal that this tilting would cause a distortion in full-length A-site tRNA^SufJ during tRNA selection and possibly impede gripping of the anticodon stem by 16S rRNA nucleotides in the P site. Together, these data implicate tRNA distortion as a major driver of noncanonical translation events such as frameshifting.     

Conformation effects of base modification on the anticodon stem-loop of Bacillus subtilis tRNA(Tyr)

tRNA molecules contain 93 chemically unique nucleotide base modifications that expand the chemical and biophysical diversity of RNA and contribute to the overall fitness of the cell. Nucleotide modifications of tRNA confer fidelity and efficiency to translation and are important in tRNA-dependent RNA-mediated regulatory processes. The three-dimensional structure of the anticodon is crucial to tRNA-mRNA specificity, and the diverse modifications of nucleotide bases in the anticodon region modulate this specificity. We have determined the solution structures and thermodynamic properties of Bacillus subtilis tRNA^Tyr anticodon arms containing the natural base modifications N⁶-dimethylallyl adenine (i⁶A₃₇) and pseudouridine (ψ₃₉). UV melting and differential scanning calorimetry indicate that the modifications stabilize the stem and may enhance base stacking in the loop. The i⁶A₃₇ modification disrupts the hydrogen bond network of the unmodified anticodon loop including a C₃₂-A₃₈⁺ base pair and an A₃₇-U₃₃ base-base interaction. Although the i⁶A₃₇ modification increases the dynamic nature of the loop nucleotides, metal ion coordination reestablishes conformational homogeneity. Interestingly, the i⁶A₃₇ modification and Mg²⁺ are sufficient to promote the U-turn fold of the anticodon loop of Escherichia coli tRNA^Phe, but these elements do not result in this signature feature of the anticodon loop in tRNA^Tyr.     

Conformational Change of the L-Shaped tRNAPhe Molecule

Abstract

Fluorophore of proflavine was introduced onto the 3′-terminal ribose moiety of yeast tRNA^Phe. The distance between the fluorophore and the fluorescent Y base in the anticodon of yeast tRNA^Phe was measured by a singlet-singlet energy transfer. Conformational changes of tRNA^Phe with binding of tRNA^Glu ₂, which has the anticodon UUC complementary to the anticodon GAA of tRNA^Phe, were investigated. The distance obtained at the ionic strength of 100 mM K⁺ and 10 mM Mg²⁺ is very close to the distance from x-ray diffraction, while the distance obtained in the presence of tRNA^Glu ₂ is significantly smaller. Further, using a fluorescent probe of 4-bromomethl-7-methoxycoumarin introduced onto pseudouridine residue Ψ₅₅ in the TΨC loop of tRNA^Phe, Stern-Volmer quenching experiments for the probe with or without added tRNA^Glu ₂were carried out. The results showed greater access of the probe to the quencher with added tRNA^Glu ₂. These results suggest that both arms of the L-shaped tRNA structure tend to bend inside with binding of tRNA^Glu ₂ and some structural collapse occurs at the corner of the L-shaped structure.     

Tritium exchange studies of transfer RNA in native and denaturated conformations

Tritium exchange was used as a probe of transfer RNA structure in experiments with unfractionated tRNA (tRNA^Unfrac and homogeneous tRNA₃^Leu from bakers' yeast. Exchange kinetics were measured over a range of ionic conditions that vary in ability to stabilize the secondary and tertiary structure of tRNA. The native conformations of both samples show the same kinetics of exchange. The kinetics for tRNA₃^Leu trapped in a denatured state in a “native” solvent are much faster, reflecting the conformation and not the ionic medium. In 0.1 M-Na⁺, where tRNA₃^Leu is denatured, the kinetics for tRNA^Unfrac are intermediate between those for native and denatured tRNA₃^Leu, suggesting that in this solvent at 0 °C some tRNAs are denatured whereas other are still native. Upon further lowering of Na⁺ concentration, tRNA^Unfrac shows increasingly faster exchange, suggesting complete electrostatic denaturation of the tertiary structure of all the tRNAs in the sample, and even disruption of secondary structure.Extrapolation of the essentially linear early-time kinetics to zero time provides minimal estimates of the number of slowly exchanging hydrogens. For native tRNA₃^Leu the number is 111±2 hydrogens, whereas for the trapped denatured conformation it is only 95±2. This difference reflects a smaller number of hydrogen-bonded bases in the denatured conformation. In 1 M-Na⁺, 101±2 slowly exchanging hydrogens are found for the native tRNA₃^Leu conformation, suggesting an incompletely formed native structure. For native tRNA^Unfrac the comparable number is 101±3. These numbers of slowly exchanging hydrogens in the native conformations are consistent with tertiary structural hydrogen-bonding. Furthermore, this tertiary structure must be responsible for the slower exchange by native tRNA. The observed numbers of exchangeable hydrogens provide a basis for comparison of hydrogen-bonding interactions in native and denatured tRNA conformations.The mechanism of renaturation was also investigated, using tritium exchange as a monitor of perturbation of base pairing during the transition. When tRNA^Unfrac in low Na⁺ is renatured by addition of Mg²⁺ during tritium exchangeout, a burst of exchange or “spillage” of tritium is detected. This suggests that a fraction of the base pairs of the rapidly renaturing tRNAs in the mixture is disrupted during renaturation. In that event, and by analogy with tRNA₃^Leu, part of the base-pairing arrangement of the denatured conformations may not be preserved in the native state; and if the native conformation includes the full “cloverleaf” pattern of secondary structure, that pattern may not be intact in some denatured conformations.     

The yfiC gene of E. coli encodes an adenine-N6 methyltransferase that specifically modifies A37 of tRNA1Val(cmo5UAC)

Transfer RNA is highly modified. Nucleotide 37 of the anticodon loop is represented by various modified nucleotides. In Escherichia coli, the valine-specific tRNA (cmo⁵UAC) contains a unique modification, N⁶-methyladenosine, at position 37; however, the enzyme responsible for this modification is unknown. Here we demonstrate that the yfiC gene of E. coli encodes an enzyme responsible for the methylation of A37 in tRNA₁^Val. Inactivation of yfiC gene abolishes m⁶A formation in tRNA₁^Val, while expression of the yfiC gene from a plasmid restores the modification. Additionally, unmodified tRNA₁^Val can be methylated by recombinant YfiC protein in vitro. Although the methylation of m⁶A in tRNA₁^Val by YfiC has little influence on the cell growth under standard conditions, the yfiC gene confers a growth advantage under conditions of osmotic and oxidative stress.     

Interactions of yeast valyl-tRNA synthetase with RNAs and conformational changes of the enzyme.

Different conformations have been identified for the enzyme valyl-tRNA synthetase from yeast inside its complex with one tRNA molecule by neutron scattering. One form is identical to that of the free enzyme in solution; the other form is more contracted, having a radius of gyration which is smaller by 10% and a specific volume which is smaller by 1%. The contracted conformation has been found for the complexes with tRNA^Val and tRNA^Asp in phosphate buffer (pH 6.3) provided the ionic strength is lower than about 150 mm. In higher ionic strength (up to about 500 mm) the enzyme still forms a complex with tRNA^Val but its conformation remains that of the free protein in solution. In the complex with tRNA₃^Leu, the enzyme conformation is that of the free state even at the lowest ionic strength examined (that of the phosphate buffer, 60 mm). The free enzyme is an elongated molecule of radius of gyration 40 Å (a compact protein of the same molecular weight would have a radius of gyration of 30 Å).The positioning within the complex of tRNA^Val, on the one hand, and tRNA₃^Leu, on the other, is very different. The first tRNA is intimately associated with the enzyme, lying predominantly closer to the centre of mass of the complex than the protein. In the complex with tRNA₃^Leu, the tRNA lies further away from the centre of mass of the complex than the protein.Small concentrations of tRNA^Val, tRNA^Asp, tRNA₃^Leu or Escherichia coli 5 S ribosomal RNA cause the enzyme to aggregate into dimers, trimers and higher aggregates provided the ionic strength of the buffer is below 150 mm. In higher ionic strength or for [RNA]: [enzyme] > 1 the aggregates are dissociated to yield the one-to-one RNA-enzyme complex.     

Recognition of tRNALeu by Aquifex aeolicus leucyl-tRNA synthetase during the aminoacylation and editing steps

Recognition of tRNA by the cognate aminoacyl-tRNA synthetase during translation is crucial to ensure the correct expression of the genetic code. To understand tRNA^Leu recognition sets and their evolution, the recognition of tRNA^Leu by the leucyl-tRNA synthetase (LeuRS) from the primitive hyperthermophilic bacterium Aquifex aeolicus was studied by RNA probing and mutagenesis. The results show that the base A73; the core structure of tRNA formed by the tertiary interactions U8–A14, G18–U55 and G19–C56; and the orientation of the variable arm are critical elements for tRNA^Leu aminoacylation. Although dispensable for aminoacylation, the anticodon arm carries discrete editing determinants that are required for stabilizing the conformation of the post-transfer editing state and for promoting translocation of the tRNA acceptor arm from the synthetic to the editing site.