tRNA Stability Research Articles

Stabilization of tRNA (m1G37) methyltransferase [TrmD] from Aquifex aeolicus by an intersubunit disulfide bond formation

Recombinant Aquifex aeolicus TrmD protein has a Cys20-Cys20 disulfide bond between its two subunits. This was demonstrated by SDS-polyacrylamide gel analysis of wild-type enzyme and C20S mutant protein (in which the Cys20 residue is substituted by serine), in the absence or presence of various concentrations of dithiothreitol. Analytical gel-filtration chromatography revealed that the C20S mutant protein forms a dimer structure even though it is missing the disulfide bond. Western blotting analysis suggests that the Cys20-Cys20 disulfide bond is formed in native TrmD protein in living A. aeolicus cells. Incubation at 85 degrees C for 20 min caused the precipitation of more than half of the C20S protein, while more than 70% of the wild-type enzyme was soluble at that temperature. This assay clearly demonstrates that the disulfide bond enhances the protein stability at 85 degrees C. A kinetic assay showed that the methyl-transfer activity of the C20S mutant protein was slightly less than that of the wild-type enzyme at 70 degrees C. Comparison of the CD-spectra of wild-type and C20S proteins reveals that some of the alpha-helices in the C20S mutant protein are less tightly packed than those of the wild-type enzyme at 70 degrees C.

Perturbation of the tRNA Tertiary Core Differentially Affects Specific Steps of the Elongation Cycle

The tRNA tertiary core region is important for both tRNA stability and activity in the translation elongation cycle. Here we report the effects of mutating each of two highly conserved base pairs in the tertiary core of Phe-tRNA(Phe), 18-55 and 19-56, on rate and equilibrium constants for specific steps of this cycle, beginning with formation of aminoacyl-tRNA.EF-Tu.GTP ternary complexs and culminating with translocation of A-site-bound peptidyl-tRNA into the P-site. We find that codon-dependent binding of aminoacyl-tRNA to the A/T-site and proofreading of near-cognate tRNA are sensitive to perturbation of either base pair; formation of the ternary complex and accommodation from the A/T to the A-site are sensitive to 18-55 perturbation only, and translocation of peptidyl-tRNA from the A- to P-site is insensitive to perturbation of either. These results underline the importance of the core region in promoting the efficiency and accuracy of translation, and they likely reflect different requirements for structural integrity of the core during specific steps of the elongation cycle.

Conserved amino acids in each subunit of the heteroligomeric tRNA m 1 A58 Mtase from Saccharomyces cerevisiae contribute to tRNA binding

In Saccharomyces cerevisiae, a two-subunit methyltransferase (Mtase) encoded by the essential genes TRM6 and TRM61 is responsible for the formation of 1-methyladenosine, a modified nucleoside found at position 58 in tRNA that is critical for the stability of . The crystal structure of the homotetrameric m1A58 tRNA Mtase from Mycobacterium tuberculosis, TrmI, has been solved and was used as a template to build a model of the yeast m1A58 tRNA Mtase heterotetramer. We altered amino acids in TRM6 and TRM61 that were predicted to be important for the stability of the heteroligomer based on this model. Yeast strains expressing trm6 and trm61 mutants exhibited growth phenotypes indicative of reduced m1A formation. In addition, recombinant mutant enzymes had reduced in vitro Mtase activity. We demonstrate that the mutations introduced do not prevent heteroligomer formation and do not disrupt binding of the cofactor S-adenosyl-l-methionine. Instead, amino acid substitutions in either Trm6p or Trm61p destroy the ability of the yeast m1A58 tRNA Mtase to bind , indicating that each subunit contributes to tRNA binding and suggesting a structural alteration of the substrate-binding pocket occurs when these mutations are present.

The La protein functions redundantly with tRNA modification enzymes to ensure tRNA structural stability

Although the La protein stabilizes nascent pre-tRNAs from nucleases, influences the pathway of pre-tRNA maturation, and assists correct folding of certain pre-tRNAs, it is dispensable for growth in both budding and fission yeast. Here we show that the Saccharomyces cerevisiae La shares functional redundancy with both tRNA modification enzymes and other proteins that contact tRNAs during their biogenesis. La is important for growth in the presence of mutations in either the arginyl tRNA synthetase or the tRNA modification enzyme Trm1p. In addition, two pseudouridine synthases, PUS3 and PUS4, are important for growth in strains carrying a mutation in tRNA(Arg)(CCG) and are essential when La is deleted in these strains. Depletion of Pus3p results in accumulation of the aminoacylated mutant tRNA(Arg)(CCG) in nuclei, while depletion of Pus4p results in decreased stability of the mutant tRNA. Interestingly, the degradation of mutant unstable forms of tRNA(Arg)(CCG) does not require the Trf4p poly(A) polymerase, suggesting that yeast cells possess multiple pathways for tRNA decay. These data demonstrate that La functions redundantly with both tRNA modifications and proteins that associate with tRNAs to achieve tRNA structural stability and efficient biogenesis.

Identification of Two tRNA Thiolation Genes Required for Cell Growth at Extremely High Temperatures

Thermostability of tRNA in thermophilic bacteria is effected by post-transcriptional modifications, such as 2-thioribothymidine (s2T) at position 54. Using a proteomics approach, we identified two genes (ttuA and ttuB; tRNA-two-thiouridine) that are essential for the synthesis of s2T in Thermus thermophilus. Mutation of either gene completely abolishes thio-modification of s2T, and these mutants exhibit a temperature-sensitive phenotype. These results suggest that bacterial growth at higher temperatures is achieved through the thermal stabilization of tRNA by a 2-thiolation modification. TtuA (TTC0106) is possibly an ATPase possessing a P-loop motif. TtuB (TTC0105) is a putative thio-carrier protein that exhibits significant sequence homology with ThiS of the thiamine synthesis pathway. Both TtuA and TtuB are required for in vitro s2T formation in the presence of cysteine and ATP. The addition of cysteine desulfurases such as IscS (TTC0087) or SufS (TTC1373) enhances the sulfur transfer reaction in vitro.

Modified View of tRNA: Stability amid Sequence Diversity

In a recent issue of Molecular Cell, a report from the Phizicky lab challenges two commonly held notions regarding tRNAs: (1) tRNAs are stable molecules shielded from the machinery that cause other RNAs to have short half-lives, and (2) the many modifications found on tRNAs serve only subtle biological functions. Alexandrov et al. (2006) show that tRNA modifications can play an important role in tRNA stability, as without particular modifications, tRNA half-life can be reduced from hours to minutes by a new turnover pathway.

Rapid tRNA Decay Can Result from Lack of Nonessential Modifications

The biological role of many nonessential tRNA modifications outside of the anticodon remains elusive despite their evolutionary conservation. We show here that m7G46 methyltransferase Trm8p/Trm82p acts as a hub of synthetic interactions with several tRNA modification enzymes, resulting in temperature-sensitive growth. Analysis of three double mutants indicates reduced levels of tRNA(Val(AAC)), consistent with a role of the corresponding modifications in maintenance of tRNA levels. Detailed examination of a trm8-delta trm4-delta double mutant demonstrates rapid degradation of preexisting tRNA(Val(AAC)) accompanied by its de-aminoacylation. Multiple copies of tRNA(Val(AAC)) suppress the trm8-delta trm4-delta growth defect, directly implicating this tRNA in the phenotype. These results define a rapid tRNA degradation (RTD) pathway that is independent of the TRF4/RRP6-dependent nuclear surveillance pathway. The degradation of an endogenous tRNA species at a rate typical of mRNA decay demonstrates a critical role of nonessential modifications for tRNA stability and cell survival.

Comparative analysis of the pathogenic mechanisms associated with the G8363A and A8296G mutations in the mitochondrial tRNALys gene

Two mutations (G8363A and A8296G) in the mtDNA (mitochondrial DNA) tRNA(Lys) gene have been associated with severe mitochondrial diseases in a number of reports. Their functional significance, however, remains unknown. We have already shown that homoplasmic cybrids harbouring the A8296G mutation display normal oxidative phosphorylation, although the possibility of a subtle change in mitochondrial respiratory capacity remains an open issue. We have now investigated the pathogenic mechanism of another mutation in the tRNA(Lys) gene (G8363A) by repopulating an mtDNA-less human osteosarcoma cell line with mitochondria harbouring either this genetic variant alone or an unusual combination of the two mutations (A8296G+G8363A). Cybrids homoplasmic for the single G8363A or the A8296G+G8363A mutations have defective respiratory-chain enzyme activities and low oxygen consumption, indicating a severe impairment of the oxidative phosphorylation system. Generation of G8363A cybrids within a wild-type or the A8296G mtDNA genetic backgrounds resulted in an important alteration in the conformation of the tRNA(Lys), not affecting tRNA steady-state levels. Moreover, mutant cybrids have an important decrease in the proportion of amino-acylated tRNA(Lys) and, consequently, mitochondrial protein synthesis is greatly decreased. Our results demonstrate that the pathogenicity of the G8363A mutation is due to a change in the conformation of the tRNA that severely impairs aminoacylation in the absence of changes in tRNA stability. The only effect detected in the A8296G mutation is a moderate decrease in the aminoacylation capacity, which does not affect mitochondrial protein biosynthesis.

The Saccharomyces cerevisiae TAN1 gene is required for N4-acetylcytidine formation in tRNA.

The biogenesis of transfer RNA is a process that requires many different factors. In this study, we describe a genetic screen aimed to identify gene products participating in this process. By screening for mutations lethal in combination with a sup61-T47:2C allele, coding for a mutant form of, the nonessential TAN1 gene was identified. We show that the TAN1 gene product is required for formation of the modified nucleoside N(4)-acetylcytidine (ac(4)C) in tRNA. In Saccharomyces cerevisiae, ac(4)C is present at position 12 in tRNAs specific for leucine and serine as well as in 18S ribosomal RNA. Analysis of RNA isolated from a tan1-null mutant revealed that ac(4)C was absent in tRNA, but not rRNA. Although no tRNA acetyltransferase activity by a GST-Tan1 fusion protein was detected, a gel-shift assay revealed that Tan1p binds tRNA, suggesting a direct role in synthesis of ac(4)C(12). The absence of the TAN1 gene in the sup61-T47:2C mutant caused a decreased level of mature, indicating that ac(4)C(12) and/or Tan1p is important for tRNA stability.

The 7472insC Mitochondrial DNA Mutation Impairs the Synthesis and Extent of Aminoacylation of tRNASer(UCN) but Not Its Structure or Rate of Turnover

The 7472insC mitochondrial DNA mutation in the tRNA(Ser(UCN)) gene is associated with sensorineural deafness combined, in some patients, with a wider neurological syndrome. In cultured cybrid cells it causes a 70% decrease in tRNA(Ser(UCN)) abundance and mild respiratory impairment, previously suggested to be due to decreased tRNA stability. When mitochondrial transcription was blocked by ethidium bromide treatment, the half-life of the mutant tRNA was not significantly different from that of wild-type tRNA(Ser(UCN)). Over-expression of mitochondrial translational elongation factor EF-Tu also had no effect on the mutant phenotype. However, during recovery from prolonged ethidium bromide treatment, the synthesis of the mutant tRNA(Ser(UCN)) was specifically impaired, without polarity effects on downstream tRNAs of the light strand transcription unit. We infer that the mutation acts posttranscriptionally to decrease tRNA(Ser(UCN)) abundance by affecting its synthesis rather than its stability. The extent of aminoacylation of the mutant tRNA was also decreased by approximately 25%. In contrast, the mutation had no detectable effect on tRNA(Ser(UCN)) base modification or structure other than the insertion of an extra guanosine templated by the mutation, which was structurally protected from nuclease digestion like the surrounding nucleotides. These findings indicate a common molecular process underlying sensorineural deafness caused by mitochondrial tRNA(Ser(UCN)) mutations.

Dual function of the tRNA(m(5)U54)methyltransferase in tRNA maturation.

A 5-methyluridine (m(5)U) residue at position 54 is a conserved feature of bacterial and eukaryotic tRNAs. The methylation of U54 is catalyzed by the tRNA(m5U54)methyltransferase, which in Saccharomyces cerevisiae is encoded by the nonessential TRM2 gene. In this study, we identified four different strains with mutant forms of tRNA(Ser)CGA. The absence of the TRM2 gene in these strains decreased the stability of tRNA(Ser)CGA and induced lethality. Two alleles of TRM2 encoding catalytically inactive tRNA(m5U54)methyltransferases were able to stabilize tRNA(Ser)CGA in one of the mutants, revealing a role for the Trm2 protein per se in tRNA maturation. Other tRNA modification enzymes interacting with tRNA(Ser)CGA in the maturation process, such as Pus4p, Trm1 p, and Trm3p were essential or important for growth of the tRNA(Ser)CGA mutants. Moreover, Lhp1p, a protein binding RNA polymerase III transcripts, was required to stabilize the mutant tRNAs. Based on our results, we suggest that tRNA modification enzymes might have a role in tRNA maturation not necessarily linked to their known catalytic activity.

Post-transcriptional modification in archaeal tRNAs: identities and phylogenetic relations of nucleotides from mesophilic and hyperthermophilic Methanococcales.

Post-transcriptional modifications in archaeal RNA are known to be phylogenetically distinct but relatively little is known of tRNA from the Methanococci, a lineage of methanogenic marine euryarchaea that grow over an unusually broad temperature range. Transfer RNAs from Methanococcus vannielii, Methanococcus maripaludis, the thermophile Methanococcus thermolithotrophicus, and hyperthermophiles Methanococcus jannaschii and Methanococcus igneus were studied to determine whether modification patterns reflect the close phylogenetic relationships inferred from small ribosomal subunit RNA sequences, and to examine modification differences associated with temperature of growth. Twenty-four modified nucleosides were characterized, including the complex tricyclic nucleoside wyosine characteristic of position 37 in tRNA(Phe) and known previously only in eukarya, plus two new wye family members of presently unknown structure. The hypermodified nucleoside 5-methylaminomethyl-2-thiouridine, reported previously only in bacterial tRNA at the first position of the anticodon, was identified by liquid chromatography-electrospray ionization mass spectrometry in four of the five organisms. The ribose-methylated nucleosides, 2'-O-methyladenosine, N(2),2'-O-dimethylguanosine and N(2),N(2),2'-O-trimethylguanosine, were found only in hyperthermophile tRNA, consistent with their proposed roles in thermal stabilization of tRNA.

A pathogenic point mutation reduces stability of mitochondrial mutant tRNA(Ile).

Point mutations in mitochondrial tRNA genes are responsible for individual subgroups of mitochondrial encephalomyopathies. We have recently reported that point mutations in the tRNA(Leu)(UUR) and tRNA(Lys) genes cause a defect in the normal modification at the first nucleotide of the anticodon. As part of a systematic analysis of pathogenic mutant mitochondrial tRNAs, we purified tRNA(Ile) with a point mutation at nucleotide 4269 to determine its nucleotide sequence, including modified nucleotides. We found that, instead of causing a defect in the post-transcriptional modification, a pathogenic point mutation in the mitochondrial tRNA(Ile) reduced the stability of the mutant tRNA molecule, resulting in a low steady-state level of aminoacyl-tRNA. The reduced stability was confirmed by examining the life-span of the mutant tRNA(Ile) both in vitro and in vivo, as well as by monitoring its melting profile. Our finding indicates that the mutant tRNA(Ile) itself is intrinsically unstable.

The Gcd10p/Gcd14p complex is the essential two-subunit tRNA(1-methyladenosine) methyltransferase of Saccharomyces cerevisiae

The modified nucleoside 1-methyladenosine (m(1)A) is found at position 58 in the TPsiC loop of many eukaryotic tRNAs. The absence of m(1)A from all tRNAs in Saccharomyces cerevisiae mutants lacking Gcd10p elicits severe defects in processing and stability of initiator methionine tRNA (tRNA(i)(Met)). Gcd10p is found in a complex with Gcd14p, which contains conserved motifs for binding S-adenosylmethionine (AdoMet). These facts, plus our demonstration that gcd14Delta cells lacked m(1)A, strongly suggested that Gcd10p/Gcd14p complex is the yeast tRNA(m(1)A)methyltransferase [(m(1)A)MTase]. Supporting this prediction, affinity-purified Gcd10p/Gcd14p complexes used AdoMet as a methyl donor to synthesize m(1)A in either total tRNA or purified tRNA(i)(Met) lacking only this modification. Kinetic analysis of the purified complex revealed K(M) values for AdoMet or tRNA(i)(Met) of 5.0 microM and 2.5 nM, respectively. Mutations in the predicted AdoMet-binding domain destroyed GCD14 function in vivo and (m(1)A)MTase activity in vitro. Purified Flag-tagged Gcd14p alone had no enzymatic activity and was severely impaired for tRNA-binding compared with the wild-type complex, suggesting that Gcd10p is required for tight binding of the tRNA substrate. Our results provide a demonstration of a two-component tRNA MTase and suggest that binding of AdoMet and tRNA substrates depends on different subunits of the complex.

Design, characterization and testing of tRNA3Lys-based hammerhead ribozymes.

A hammerhead ribozyme targeted against the HIV-1 env coding region was expressed as part of the anticodon loop of human tRNA3Lys without sacrificing tRNA stability or ribozyme catalytic activity. These tRNA-ribozymes were isolated from a library which was designed to contain linkers (sequences connecting the ribozyme to the anticodon loop) of random sequence and variable length. The ribozyme target site was provided in cis during selection and in trans during subsequent characterization. tRNA-ribozymes that possessed ideal combinations of linkers were expected to recognize the cis target site more freely and undergo cleavage. The cleaved molecules were isolated, cloned and characterized. Active tRNA-ribozymes were identified and the structural features conducive to cleavage were defined. The selected tRNA-ribozymes were stable, possessed cleavage rates lower or similar to the linear hammerhead ribozyme, and could be transcribed by an extract containing RNA polymerase III. Retroviral vectors expressing tRNA-ribozymes were tested in a human CD4+ T cell line and were shown to inhibit HIV-1 replication. These tRNA3Lys-based hammerhead ribozymes should therefore prove to be valuable for both basic and applied research. Special application is sought in HIV-1 or HIV-2 gene therapy.

The Role of Posttranscriptional Modification in Stabilization of Transfer RNA from Hyperthermophiles

The influence of posttranscriptional modification on structural stabilization of tRNA from hyperthermophilic archaea was studied, using Pyrococcus furiosus (growth optimum 100 degrees C) as a primary model. Optical melting temperatures (Tm) of unfractionated tRNA in 20 mM Mg2+ are 97 degrees C for P. furiosus and 101.5 degrees C for Pyrodictium occultum (growth optimum, 105 degrees C). These values are approximately 20 degrees C higher than predicted solely from G-C content and are attributed primarily to posttranscriptional modification. Twenty-three modified nucleosides were determined in total digests of P. furiosus tRNA by combined HPLC-mass spectrometry. From cells cultured at 70, 85, and 100 degrees C, progressively increased levels of modification were observed within three families of nucleosides, the most highly modified forms of which were N4-acetyl-2'-O-methylcytidine (ac4Cm), N2,N2,2'-O-trimethylguanosine (m2(2)Gm), and 5-methyl-2-thiouridine (m5s2U). Nucleosides ac4Cm and m2(2)Gm, which are unique to the archaeal hyperthermophiles, were shown in earlier NMR studies to exhibit unusually high conformational stabilities that favor the C3'-endo form [Kawai, G., et al. (1991) Nucleic Acids Symp. Ser. 21, 49-50; (1992) Nucleosides Nucleotides 11, 759-771]. The sequence location of m5s2U was determined by mass spectrometry to be primarily at tRNA position 54, a site of known thermal stabilization in the bacterial thermophile Thermus thermophilus [Horie, N., et al. (1985) Biochemistry 24, 5711-5715]. It is concluded that selected posttranscriptional modifications in archaeal thermophiles play major stabilizing roles beyond the effects of Mg2+ binding and G-C content, and are proportionally more important and have evolved with greater structural diversity at the nucleoside level in the bacterial thermophiles.

Crystal Structure of Unmodified tRNAGln Complexed with Glutaminyl-tRNA Synthetase and ATP Suggests a Possible Role for Pseudo-Uridines in Stabilization of RNA Structure

tRNA(2Gln) made in vitro by transcription with T7 RNA polymerase does not contain the pseudouridines at positions 38, 39, and 55, the 4-thiouridine at position 8, or any of the methylated bases found in the tRNA(2Gln) made in vivo. Cocrystals of unmodified tRNA(2Gln) complexed with glutaminyl-tRNA synthetase from Escherichia coli are isomorphous with those of the complex with modified tRNA(2Gln). A difference electron density map between the complexes with modified and unmodified tRNAs calculated at 2.5-A resolution shows no differences in the protein or tRNA structures, except for some very small shifts in atoms contacting the thiol at the 4 position of uridine 8 that are required to accommodate the smaller oxygen in the unmodified tRNA. Perhaps the most functionally significant change in the unmodified tRNA is the absence of the specifically bound water molecules that are observed to cross-link the N5 of the pseudo-uridines to their 5' phosphate. This suggests a possible role for pseudouridinylation in stabilization of the tRNA through water-mediated linking of these modified bases to the backbone, which is consistent with the lower thermal stability of the unmodified tRNA. An identical water-bridging structure is possible at four of the five other psuedo-uridines in known tRNA structures.

Conformational Rigidity of N4-Acetyl-2′-O-methylcytidine Found in tRNA of Extremely Thermophilic Archaebacteria (Archaea)

Abstract The conformational characteristics of N 4-acetyl-2′-O-methylcytidine (ac4Cm), which is one of the modified cytidines unique to the tRNA of extremely thermophilic archaebacteria, and related nucleosides, N 4-acetylcytidine (ac4C), 2′-O-methylcytidine (Cm) and cytidine, were analyzed by proton nuclear magnetic resonance spectroscopy. Ribose methylation and N 4-acylation were found to confer high conformational rigidity to the ribose moiety, suggesting that these post-transcriptional modifications play a role in structural stabilization of tRNA, which is of particular importance at high temperature.

Physical mapping of large DNA by chromosome fragmentation.

A technique is described for physically positioning any cloned DNA on a native or artificial Saccharomyces cerevisiae chromosome. The technique involves splitting a chromosome at a specific site by transformation with short linear molecules containing the cloned DNA at one end and telomeric sequences at the other. Recombination between the end of the linear molecules and homologous chromosomal sequences gives rise to chromosome fragments comprising all sequences distal or proximal to the mapping site depending on the orientation of the cloned DNA. The recombinant products are recovered by screening for stabilization of a suppressor tRNA on the linear molecules using a colony color assay. The cloned DNA is positioned relative to the chromosome ends by sizing the chromosomal fragments using alternating contour-clamped homogeneous electric field gel electrophoresis. Application of this technique to organisms other than S. cerevisiae and to the analysis of exogenous DNA cloned in yeast is discussed.

Temperature jump relaxation studies on the interactions between transfer RNAs with complementary anticodons. The effect of modified bases adjacent to the anticodon triplet.

We have used the temperature-jump relaxation technique to determine the kinetic and thermodynamic parameters for the association between the following tRNAs pairs having complementary anticodons: tRNA(Ser) with tRNA(Gly), tRNA(Cys) with tRNA(Ala) and tRNA(Trp) with tRNA(Pro). The anticodon sequence of E. coli tRNA(Ser), GGA, is complementary to the U*CC anticodon of E. coli tRNA(Gly(2] (where U* is a still unknown modified uridine base) and A37 is not modified in none of these two tRNAs. E. coli tRNA(Ala) has a VGC anticodon (V is 5-oxyacetic acid uridine) while tRNA(Cys) has the complementary GCA anticodon with a modified adenine on the 3' side, namely 2-methylthio N6-isopentenyl adenine (mS2i6A37) in E. Coli tRNA(Cys) and N6-isopentenyl adenine (i6A37) in yeast tRNA(Cys). The brewer yeast tRNA(Trp) (anticodon CmCA) differs from the wild type E. coli tRNA(Trp) (anticodon CCA) in several positions of the nucleotide sequence. Nevertheless, in the anticodon loop, only two interesting differences are present: A37 is not modified while C34 at the first anticodon position is modified into a ribose 2'-O methyl derivative (Cm). The corresponding complementary tRNA is E.coli tRNA(Pro) with the VGG anticodon. Our results indicate a dominant effect of the nature and sequence of the anticodon bases and their nearest neighbor in the anticodon loop (particularly at position 37 on the 3' side); no detectable influence of modifications in the other tRNA stems has been detected. We found a strong stabilizing effect of the methylthio group on i6A37 as compared to isopentenyl modification of the same residue. We have not been able so far to assess the effect of isopentenyl modification alone in comparison to unmodified A37. The results obtained with the complex yeast tRNA(Trp)-E.coli tRNA(Pro) also suggest that a modification of C34 to Cm34 does not significantly increase the stability of tRNA(Trp) association with its complementary anticodon in tRNA(Pro). The observations are discussed in the light of inter- and intra-strand stacking interactions among the anticodon triplets and with the purine base adjacent to them, and of possible biological implications.