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.     

The potato mitochondrial initiator methionine tRNA gene and its flanking regions: an illustration of the diversity of mitochondrial genome rearrangements among plant species

The initiator methionine transfer RNA (tRNAf ^Met) gene was identified on a 347 bpEco RI-Hind III DNA fragment of the potato mitochondrial (mt) genome. The sequence of this gene shows 1 to 7 nucleotide differences with the other plant mt tRNAsf ^Met or tRNAf ^Met genes studied so far. Whereas the tRNAf ^Met gene is present as a single copy in the potato mt genome, a tRNA pseudogene corresponding to 60% of a complete tRNA (from the 5 end to the variable region) and located at 105 nucleotides upstream of the tRNAf ^Met gene on the opposite strand was shown to be repeated at least three times. Furthermore, the physical environment of the tRNAf ^Met gene in the mt genome is very different among plants, which suggests that the tRNAf ^Met gene region has often been implicated in recombination events of plant mt genomes leading to important rearrangements in gene order.     

Sequences of initiator and elongator methionine tRNAs in bean mitochondria

Summary Two bean mitochondria methionine transfer RNAs, purified by RPC-5 chromatography and two-dimensional gel electrophoresis, have been sequenced usingin vitro post-labeling techniques.One of these tRNAs^Met has been identified by formylation using anE. coli enzyme as the mitochondrial tRNA_F ^Met. It displays strong structural homologies with prokaryotic and chloroplast tRNA_F ^Met sequences (70.1–83.1%) and with putative initiator tRNA_m ^Met genes described for wheat, maize andOenothera mitochondrial genomes (88.3–89.6%).The other tRNA^Met, which is the mitochondrial elongator tRNA_F ^Met, shows a high degree of sequence homology (93.3–96%& with chloroplast tRNA_m ^Met, but a weak homology (40.7%) with a sequenced maize mitochondrial putative elongator tRNA_m ^Met gene.Bean mitochondrial tRNA_F ^Met and tRNA_m ^Met were hybridized to Southern blots of the mitochondrial genomes of wheat and maize, whose maps have been recently published (15, 22), in order to locate the position of their genes.     

Plant nuclear tRNAMet genes are ubiquitously interrupted by introns

We have isolated three independent clones for nuclear elongator tRNA^Met genes from an Arabidopsis DNA library using a tRNA^Met-specific probe generated by PCR. Each of the coding sequences for tRNA^Met in these clones is identical and is interrupted by an identical 11 bp long intervening sequence at the same position in the anticodon loop of the tRNA. Their sequences differ at two positions from the intron in a soybean counterpart. Southern analysis of Arabidopsis DNA demonstrates that a gene family coding for tRNA^Met is dispersed at at least eight loci in the genome. The unspliced precursor tRNA^Met intermediate was detected by RNA analysis using an oligonucleotide probe complementary to the putative intron sequence. In order to know whether introns commonly interrupt plant tRNA^Met genes, their coding sequences were PCR-amplified from the DNAs of eight phylogenetically separate plant species. All 53 sequences determined contain 10 to 13 bp long intervening sequences, always positioned one base downstream from the anticodon. They can all be potentially folded into the secondary structure characteristic for plant intron-containing precursor tRNAs. Surprisingly, GC residues are always present at the 5-distal end of each intron.     

Splicing of Arabidopsis tRNAMet precursors in tobacco cell and wheat germ extracts

Intron-containing tRNA genes are exceptional within nuclear plant genomes. It appears that merely two tRNA gene families coding for tRNA^Tyr _{G A} and elongator tRNA^Met _CmAU contain intervening sequences. We have previously investigated the features required by wheat germ splicing endonuclease for efficient and accurate intron excision from Arabidopsis pre-tRNA^Tyr. Here we have studied the expression of an Arabidopsis elongator tRNA^Met gene in two plant extracts of different origin. This gene was first transcribed either in HeLa or in tobacco cell nuclear extract and splicing of intron-containing tRNA^Met precursors was then examined in wheat germ S23 extract and in the tobacco system. The results show that conversion of pre-tRNA^Met to mature tRNA proceeds very efficiently in both plant extracts. In order to elucidate the potential role of specific nucleotides at the 3 and 5 splice sites and of a structured intron for pre-tRNA^Met splicing in either extract, we have performed a systematic survey by mutational analyses. The results show that cytidine residues at intron-exon boundaries impair pre-tRNA^Met splicing and that a highly structured intron is indispensable for pre-tRNA^Met splicing. tRNA precursors with an extended anticodon stem of three to four base pairs are readily accepted as substrates by wheat and tobacco splicing endonuclease, whereas pre-tRNA molecules that can form an extended anticodon stem of only two putative base pairs are not spliced at all. An amber suppressor, generated from the intron-containing elongator tRNA^Met gene, is efficiently processed and spliced in both plant extracts.     

Construction,aminoacylation and 80 S ribosomal complex formation with a yeast initiator tRNA having an arginine CCU anticodon

The digestion of yeast initiator methionine tRNA with mung bean nuclease and U₂ ribonuclease yielded 5'- and 3'-fragments, respectively. These two fragments together represent the entire tRNA sequence except for A₃₅, the central nucleotide of the anticodon, and the CCA terminus. Using RNA ligase, a cytosine was added and the anticodon loop having a C₃₅ was reformed. Subsequent treatment of this product with CCA-transferase yielded a full-length methionine tRNA having an arginine CCU anticodon. This recombinant tRNA^Met (CCU) was charged with methionine by the yeast tRNA synthetase. Aminoacylation of the recombinant was however less extensive than in the case of native tRNA^Met (CAU). After aminoacylation the recombinant tRNA formed an 80 S ribosomal complex.     

Purification Of Methionine Acceptor tRNA On Arginine-Agarose

Crude E. coli tRNA or enriched methionine acceptor tRNA can be separated into three stiecies on a column of arginine-agarose. The first peak eluted is tRNA^Met and the latter two peaks are two forms of tRNA^Met _f. From crude tRNA, tRNA^Met _m is obtained in approximately 50% purity. Arginine-agarose separates enriched methionine accepting tRNA into three homogeneous fractions.     

Overproduction and purification of Escherichia 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. Project supported by the National Natural Science Foundation of China (Grant No. 39570164).     

Genetic interactions between a null allele of the RIT1 gene encoding an initiator tRNA-specific modification enzyme and genes encoding translation factors in Saccharomyces cerevisiae

The Saccharomyces cerevisiae gene RIT1 encodes a phospho-ribosyl transferase that exclusively modifies the initiator tRNA (tRNA^Met _i) by the addition of a 2′-O-ribosyl phosphate group to Adenosine 64. As a result, tRNA^Met _i is prevented from participating in the elongation steps of protein synthesis. We previously showed that the modification is not essential for the function of tRNA^Met _i in the initiation of translation, since rit1 null strains are viable and show no obvious growth defects. Here, we demonstrate that yeast strains in which a rit1 null allele is combined with mutations in any of the genes for the three subunits of eukaryotic initiation factor-2 (eIF-2), or with disruption alleles of two of the four initiator methionine tRNA (IMT) genes, show synergistic growth defects. A multicopy plasmid carrying an IMT gene can alleviate these defects. On the other hand, introduction of a high-copy-number plasmid carrying the TEF2 gene, which encodes the eukaryotic elongation factor 1α (eEF-1α), into rit1 null strains with two intact IMT genes had the opposite effect, indicating that increased levels of eEF-1α are deleterious to these strains, presumably due to sequestration of the unmodified met-tRNA^Met _i for elongation. Thus, under conditions in which the components of the ternary met-tRNA^Met _i:GTP:eIF-2 complex become limiting or are functionally impaired, the presence of the 2′-O-ribosyl phosphate modification in tRNA^Met _i is important for the provision of adequate amounts of tRNA^Met _i for formation of this ternary complex. Received: 20 November 1998 / Accepted: 7 April 1999     

Recognition of altered E. coli formylmethionine transfer RNA by bacterial T factor

Treatment of $\text{E.}\text{coli}$ formylmethionine tRNA with sodium bisulfite produces six C → U base changes in the tRNA structure. Four of these modifications have no effect on the ability of tRNA_f^Met to be aminoacylated or formylated. Prior to bisulfite treatment, Met-tRNA_f^Met is not able to form a ternary complex with bacterial T factor and GTP, as measured by Sephadex G-50 gel filtration. After bisulfite treatment, a large portion of the modified tRNA is bound as T-GTP-Met-tRNA_f^Met. Formylation of bisulfite-modified Met-tRNA_f^Met completely eliminates T factor binding. Unmodified tRNA_f^Met is unique among the tRNAs sequenced to date in having a non-hydrogen-bonded base at the 5′ terminus. Bisulfite-catalyzed conversion of this unpaired C₁ to U₁ results in formation of a normal U₁-A₇₃ base pair at the end of the acceptor stem. It is likely that this structural alteration is responsible for the recognition of bisulfite-modified Met-tRNA_f^Met by T factor.     

Function of Y in codon-anticodon interaction of tRNA Phe

Molar association constants of binding oligonucleotides to the anticodon loops of (yeast) tRNA^Phe, (yeast) tRNA_HCl^Phe and (E. coli) tRNA_F^Met have been determined by equilibrium dialysis. From the temperature dependence of the molar association constants, ΔF, ΔH and ΔS of oligomer-anticodon loop interaction have been determined. The data indicate that the free energy change of codon-anticodon interaction is highly influenced by the presence of a modified purine (tRNA^Phe), of an unmodified purine (tRNA_F^Met) or its absence (tRNA_HCl^Phe). Excision of the modified purine Y in the anticodon loop of tRNA^Phe results in a conformational change of the anticodon loop, which is discussed on the basis of the corresponding changes in ΔF, ΔH and ΔS.     

Genetic interactions between a null allele of the RIT1 gene encoding an initiator tRNA-specific modification enzyme and genes encoding translation factors in Saccharomyces cerevisiae

The Saccharomyces cerevisiae gene RIT1 encodes a phospho-ribosyl transferase that exclusively modifies the initiator tRNA (tRNA^Met _i) by the addition of a 2′-O-ribosyl phosphate group to Adenosine 64. As a result, tRNA^Met _i is prevented from participating in the elongation steps of protein synthesis. We previously showed that the modification is not essential for the function of tRNA^Met _i in the initiation of translation, since rit1 null strains are viable and show no obvious growth defects. Here, we demonstrate that yeast strains in which a rit1 null allele is combined with mutations in any of the genes for the three subunits of eukaryotic initiation factor-2 (eIF-2), or with disruption alleles of two of the four initiator methionine tRNA (IMT) genes, show synergistic growth defects. A multicopy plasmid carrying an IMT gene can alleviate these defects. On the other hand, introduction of a high-copy-number plasmid carrying the TEF2 gene, which encodes the eukaryotic elongation factor 1α (eEF-1α), into rit1 null strains with two intact IMT genes had the opposite effect, indicating that increased levels of eEF-1α are deleterious to these strains, presumably due to sequestration of the unmodified met-tRNA^Met _i for elongation. Thus, under conditions in which the components of the ternary met-tRNA^Met _i:GTP:eIF-2 complex become limiting or are functionally impaired, the presence of the 2′-O-ribosyl phosphate modification in tRNA^Met _i is important for the provision of adequate amounts of tRNA^Met _i for formation of this ternary complex.     

Antico-operative binding of bacterial and mammalian initiator tRNAMet to methionyl-tRNA synthetase from Escherichia coli

The reaction scheme of methionyl-tRNA synthetase from Escherichia coli with the initiator tRNA_s^Met from E. coli and rabbit liver, respectively, has been resolved. The statistical rate constants for the formation, k_R, and for the dissociation, k_D, of the 1:1 complex of these tRNAs with the dimeric enzyme have been calculated. Identical k_R values of 250 μm^?1 s^?1 reflect similar behaviour for antico-operative binding of both tRNA_s^Met to native methionyl-tRNA synthetase. Advantage was taken of the difference in extent of tryptophan fluorescence-quenching induced by the bacterial and mammalian initiator tRNA_s^Met to measure the mode of exchange of these tRNAs antico-operatively bound to the enzyme. Analysis of the results reveals that antico-operativity does not arise from structural asymmetric assembly of the enzyme subunits. Indeed, both subunits can potentially bind a tRNA molecule. Exchange between tRNA molecules can occur via a transient complex in which both sites are occupied. Either strong and weak sites reciprocate between subunits on the transient complex or occupation of the weak site induces symmetry of this complex. While in the present case, these two alternatives are kinetically indistinguishable, they do account for the observation that, upon increasing the concentration of the competing mammalian tRNA, the rate of exchange of the E. coli initiator tRNA^Met is enhanced, due to its faster rate of dissociation from the transient complex. Finally, it has been verified that in the case of the trypsin-modified methionyl-tRNA synthetase which cannot provide more than one binding site for tRNA, exchange of enzymebound bacterial tRNA by mammalian tRNA does proceed to a limiting rate independent of the mammalian tRNA concentration present in the solution.     

Studies on the ribothymidine content of specific rat and human tRNAs: a postulated role for 5-methyl cytosine in the regulation of ribothymidine biosynthesis.

Total mammalian tRNAs contain on the average less than one mole of ribothymidine per mole of tRNA. Mammalian tRNAs can be grouped into at least four classes, depending upon their ribothymidine content at position 23 from the 3′ terminus. Class A contains tRNA in which a nucleoside other than uridine replaces ribothymidine (tRNA_i^Met); Class B contains tRNA in which one mole of a modified uridine (rT, ψ, or 2′-O-methylribothymidine) is found per mole of tRNA (tRNA^Ser, tRNA^Trp, and tRNA^Lys, respectively). Class C contains tRNA in which there is a partial conversion of uridine to ribothymidine (tRNA^Phe, tRNA₁^Gly, tRNA₂^Gly); Class D contains tRNA which totally lacks ribothymidine (tRNA^Val). Only those tRNAs in Class C are acceptable substrates for $\text{E.}\text{coli}$ uridine methylase, under the conditions used in these studies. These observations cannot be adequately explained solely on the basis of the presence or absence of a specific “universal” nucleoside other than U or rT at position 23 from the 3′ terminus. However, correlations can be made between the ribothymidine and 5-methylcytosine content of eucaryotic tRNA. We postulate that the presence of one or more 5-methylcytosines in and adjacent to loop III (minor loop) in individual tRNAs act to regulate the amount of ribothymidine formed by uridine methylase. Several experiments are proposed as tests for this hypothesis.     

AIMP3/p18 Controls Translational Initiation by Mediating the Delivery of Charged Initiator tRNA to Initiation Complex

Aminoacyl-tRNA synthetase-interacting multifunctional proteins (AIMPs) are nonenzymatic scaffolding proteins that comprise multisynthetase complex (MSC) with nine aminoacyl-tRNA synthetases in higher eukaryotes. Among the three AIMPs, AIMP3/p18 is strongly anchored to methionyl-tRNA synthetase (MRS) in the MSC. MRS attaches methionine (Met) to initiator tRNA (tRNA_i^Met) and plays an important role in translation initiation. It is known that AIMP3 is dispatched to nucleus or nuclear membrane to induce DNA damage response or senescence; however, the role of AIMP3 in translation as a component of MSC and the meaning of its interaction with MRS are still unclear. Herein, we observed that AIMP3 specifically interacted with Met-tRNA_i^Metin vitro, while it showed little or reduced interaction with unacylated or lysine-charged tRNA_i^Met. In addition, AIMP3 discriminates Met-tRNA_i^Met from Met-charged elongator tRNA based on filter-binding assay. Pull‐down assay revealed that AIMP3 and MRS had noncompetitive interaction with eukaryotic initiation factor 2 (eIF2) γ subunit (eIF2γ), which is in charge of binding with Met-tRNA_i^Met for the delivery of Met-tRNA_i^Met to ribosome. AIMP3 recruited active eIF2γ to the MRS-AIMP3 complex, and the level of Met-tRNA_i^Met bound to eIF2 complex was reduced by AIMP3 knockdown resulting in reduced protein synthesis. All these results suggested the novel function of AIMP3 as a critical mediator of Met-tRNA_i^Met transfer from MRS to eIF2 complex for the accurate and efficient translation initiation.     

The Levels of a Universally Conserved tRNA Modification Regulate Cell Growth

N⁶-Threonylcarbamoyl-adenosine (t⁶A) is a universal modification occurring at position 37 in nearly all tRNAs that decode A-starting codons, including the eukaryotic initiator tRNA (tRNA_i^Met). Yeast lacking central components of the t⁶A synthesis machinery, such as Tcs3p (Kae1p) or Tcs5p (Bud32p), show slow-growth phenotypes. In the present work, we show that loss of the Drosophila tcs3 homolog also leads to a severe reduction in size and demonstrate, for the first time in a non-microbe, that Tcs3 is required for t⁶A synthesis. In Drosophila and in mammals, tRNA_i^Met is a limiting factor for cell and animal growth. We report that the t⁶A-modified form of tRNA_i^Met is the actual limiting factor. We show that changing the proportion of t⁶A-modified tRNA_i^Met, by expression of an un-modifiable tRNA_i^Met or changing the levels of Tcs3, regulate target of rapamycin (TOR) kinase activity and influences cell and animal growth in vivo. These findings reveal an unprecedented relationship between the translation machinery and TOR, where translation efficiency, limited by the availability of t⁶A-modified tRNA, determines growth potential in eukaryotic cells.     

Selective modification of cytidine, uridine, guanosine and pseudouridine residues in Escherichia coli leucine transfer ribonucleic acid

The specificity of methoxyamine for the cytidine residues in an Escherichia coli leuoine transfer RNA (tRNA₁^leu is described in detail. Of the six non-hydrogen-bonded cytidine residues in the clover-leaf model of this tRNA, four are very reactive (C-35, 53, 85 and 86) and two are unreactive (C-67 and 79).The specificity of l-cyclohexyl-3-[2-morpholino-(4)-ethyl]carbodiimide methotosylate for the uridine, guanosine and pseudouridine residues in the leucine tRNA was also investigated. The carbodiimide completely modified four uridine residues (U-33, 34, 50 and 51) and partially modified G-37 and Ψ-39. For technical reasons, the sites of partial modification in loop I of the tRNA were difficult to establish. There was no modification of base residues in loop IV nor of U-59 at the base of stem e of the tRNA.The modification patterns described for the leucine tRNA are compared with those observed for the E. coli initiator tRNA₁^met and su⁺_III tyrosine tRNA. Several general conclusions regarding tRNA conformation are made. In particular, the evidence supporting a diversity of anticodon loop structures amongst tRNAs is discussed.     

New chromatographic and biochemical strategies for quick preparative isolation of tRNA

A combination of hydrophobic chromatography on phenyl-Sepharose and reversed phase HPLC was used to purify individual tRNAs with high specific activity. The efficiency of chromatographic separation was enhanced by biochemical manipulations of the tRNA molecule, such as aminoacylation, formylation of the aminoacyl moiety and enzymatic deacylation. Optimal combinations are presented for three different cases. (i) tRNA^Phe from Escherichia coli. This species was isolated by a combination of low pressure phenyl-Sepharose hydrophobic chromatography with RP-HPLC. (ii) tRNA^Ile from E.coli. Aminoacylation increases the retention time for this tRNA in RP-HPLC. The recovered acylated intermediate is deacylated by reversion of the aminoacylation reaction and submitted to a second RP-HPLC run, in which deacylated tRNA^Ile is recovered with high specific activity. (iii) tRNA_i^Met from Saccharomyces cerevisiae. The aminoacylated form of this tRNA is unstable. To increase stability, the aminoacylated form was formylated using E.coli enzymes and, after one RP-HPLC step, the formylated derivative was deacylated using peptidyl-tRNA hydrolase from E.coli. The tRNA_i^Met recovered after a second RP-HPLC run exhibited electrophoretic homogeneity and high specific activity upon aminoacylation. These combinations of chromatographic separation and biochemical modification can be readily adapted to the large-scale isolation of any particular tRNA.