Biochemical and physical characterization of an unmodified yeast phenylalanine transfer RNA transcribed in vitro

Anticodon-dependent aminoacylation of RNA minisubstrate by lysyl-tRNA synthetase

Specific inhibition of mammalian lysyl-tRNA synthetase by polyU is shown. Inhibition of the enzyme is dependent on the length of the oligonucleotide, since oligoU molecules with a length of less than 8 residues do not inhibit the aminoacylation, whilst the effect of oligoU molecules with a length of about 30 residues is the same as that of polyU. Inhibition is a result of recognition by the enzyme of the tRNALys anticodon sequence (UUU) coded by polyU. Aminoacylation of the oligoU molecule with attached CCA sequence (G(U)20-CCA) by yeast and mammalian lysyl-tRNA synthetases is demonstrated.

Assignment of the magnetic resonances of the imino protons and methyl protons of Bombyx mori tRNA(GlyGCC) and the effect of ion binding on its structure

The magnetic resonances in the low-field H-NMR spectra of Bombyx mori tRNA(GlyGCC), corresponding to the hydrogen-bonded imino protons of the helical stems and tertiary base pairs, could be tentatively assigned by means of the sequential nuclear Overhauser effects. While B. mori tRNA(GlyGCC) does not contain the G19C56 tertiary base pair, the D20G57 base pair exists between the D and T loops, which was not found in the X-ray crystal structure of yeast tRNA(Phe). The effects of Mg2+, spermine and temperature on the conformation of this tRNA have also been examined based on the behavior of the assigned resonance signals. Mg2+ stabilize the D and T stems and the tertiary structure between the D and T loops. Spermine affects the resonances of the D and anticodon stems, and A23G9, but does not stabilize them. While the acceptor stem melts sequentially from both ends (G7C66 and G1C72) with increasing temperature, the anticodon stem melts from only one end (G39C31) and the G26C44 base pair is the most stable. In the tertiary structure between the variable loop and D stem, G10G45 melts first and G22G46 last. Yeast tRNA(Phe) has also been examined, and the results were compared with those for B. mori tRNA(Gly).

Analytical study of avian reticuloendotheliosis virus dimeric RNA generated in vivo and in vitro

The retroviral genome consists of two identical RNA molecules associated at their 5' ends by a stable structure called the dimer linkage structure. The dimer linkage structure, while maintaining the dimer state of the retroviral genome, might also be involved in packaging and reverse transcription, as well as recombination during proviral DNA synthesis. To study the dimer structure of the retroviral genome and the mechanism of dimerization, we analyzed features of the dimeric genome of reticuloendotheliosis virus (REV) type A and identified elements required for its dimerization. Here we report that the REV dimeric genome extracted from virions and infected cells, as well as that synthesized in vitro, is more resistant to heat denaturation than avian sarcoma and leukemia virus, murine leukemia virus, or human immunodeficiency virus type 1 dimeric RNA. The minimal domain required to form a stable REV RNA dimer in vitro was found to map between positions 268 and 452 (KpnI and SalI sites), thus corresponding to the E encapsidation sequence (J. E. Embretson and H. M. Temin, J. Virol. 61:2675-2683, 1987). In addition, both the 5' and 3' halves of E are necessary in cis for RNA dimerization and the extent of RNA dimerization is influenced by viral sequences flanking E. Rapid and efficient dimerization of REV RNA containing gag sequences in addition to the E sequences and annealing of replication primer tRNA(Pro) to the primer-binding site necessitate the nucleocapsid protein.

The anticodon triplet is not sufficient to confer methionine acceptance to a transfer RNA

Previous work suggested that the presence of the anticodon CAU alone was enough to confer methionine acceptance to a tRNA. Conversions of Escherichia coli nonmethionine tRNAs to a methionine-accepting species were obtained by substitutions reconstructing the whole methionine anticodon loop together with preservation (or introduction) of the acceptor stem base A73. We show here that the CAU triplet alone is unable to confer methionine acceptance when transplanted into a yeast aspartic tRNA. Both non-anticodon bases of the anticodon loop of yeast tRNA(Met) and A73 are required in addition to CAU for methionine acceptance. The importance of these non-anticodon bases in other CAU-containing tRNA frameworks was also established. These specific non-anticodon base interactions make a substantial thermodynamic contribution to the methionine acceptance of a transfer RNA.

The role of anticodon bases and the discriminator nucleotide in the recognition of some E. coli tRNAs by their aminoacyl-tRNA synthetases

The T7 polymerase transcription system was used for in vitro synthesis of unmodified versions of the E. coli tRNA mutants that insert asparagine, cysteine, glycine, histidine, and serine. These tRNAs were used to qualitatively explore the role of some anticodon bases and the discriminator nucleotide in the recognition of tRNA by aminoacyl-tRNA synthetases. Coupled with data from earlier studies, these new results essentially complete a survey of all E. coli tRNAs with respect to the involvement of anticodon bases and the discriminator nucleotide in tRNA recognition. It is found that in the vast majority of tRNAs both of these elements are significant components of tRNA identity. This is not universally true, however. Anticodon sequences are unimportant in tRNA(Ser), tRNA(Leu), and tRNA(Ala) while the discriminator base is inconsequential in tRNA(Ser) and tRNA(Thr). The significance of these results for origin-of-life studies is discussed.

Crucial role of pyrophosphate in the aminoacylation of E. coli tRNA(Phe) by yeast phenylalanyl-tRNA synthetase

Rapid inactivation of the yeast phenylalanyl-tRNA synthetase in the course of aminoacylation of the heterologous E. coli tRNA(Phe) is observed. This inactivation occurs due to the formation of the tight complex of the enzyme with the pyrophosphate formed during the aminoacylation reaction. This complex is shown to be the normal intermediate of the reaction. Possible inactivation mechanism and correlation between structural differences of yeast and E. coli tRNAs(Phe) with the changes in the enzymatic mechanism of aminoacylation are discussed.

Reverse transcriptase of human immunodeficiency virus can use either human tRNA(3Lys) or Escherichia coli tRNA(2Gln) as a primer in an in vitro primer-utilization assay

Although the reverse transcriptase (RT) of human immunodeficiency virus (HIV) uses human tRNA(3Lys) as a primer of viral genome DNA synthesis in vivo, HIV RT binds Escherichia coli glutamine tRNA and in vitro-made human lysine tRNA with nearly equivalent affinities. We show that HIV RT can use either tRNA(3Lys) or tRNA(2Gln) as a primer for DNA synthesis in vitro without the addition of any other host or viral proteins. E. coli tRNA(2Gln) can serve as a primer for HIV RT if a primer-binding site sequence complementary to the 3' end of tRNA(2Gln) is at the 3' end of the template. With this reduced template, the specificity of binding the proper tRNA is due to base-pairing between a bound tRNA to the primer-binding site of the viral RNA template rather than sequence-specific recognition of tRNA(3Lys) by RT. If an 8-nucleotide viral sequence 3' to the primer-binding site is included in the template, then addition of Zn2+ or Co2+ is required for tRNA(3Lys)-primed synthesis, and tRNA(2Gln) now fails to prime synthesis. The latter result implies that a template sequence adjacent to the primer-binding site and containing 6 nucleotides complementary to the anticodon loop of human tRNA(3Lys) plays an active role in tRNA discrimination.

Striking effects of coupling mutations in the acceptor stem on recognition of tRNAs by Escherichia coli Met-tRNA synthetase and Met-tRNA transformylase

We measured kinetic parameters in vitro and directly analyzed aminoacylation and formylation levels in vivo to study recognition of Escherichia coli initiator tRNA mutants by E. coli Met-tRNA synthetase and Met-tRNA transformylase. We show that, in addition to the anticodon sequence, mutations in the "discriminator" base A73 also affect aminoacylation. An A73----U change has a small effect, but a change to G73 or C73 significantly lowers Vmax/Kappm for in vitro aminoacylation and leads to appreciable accumulation of uncharged tRNA in vivo. Significantly, coupling of the G73 mutation with G72, a neighboring-base mutation, results in a tRNA essentially uncharged in vivo. Coupling of C73 and U73 mutations with G72 does not have such an effect. Elements crucial for Met-tRNA transformylase recognition of tRNAs are located at the end of the acceptor stem. These elements include a weak base pair or a mismatch between nucleotides (nt) 1 and 72 and base pairs 2.71 and 3.70. The natures of nt 1 and 72 are less important than the fact that they do not form a strong Watson-Crick base pair. Interestingly, the negative effect of a C.G base pair between nt 1 and 72 is suppressed by mutation of the neighboring nucleotide A73 to either C73 or U73. The presence of C73 or U73 could destabilize the C1.G72 base pair at the end of an RNA helix. Thus, in some tRNAs, the discriminator base could affect stability of the base pair between nt 1 and 72 and thereby the structure of tRNA at the end of the acceptor stem.

An ultraviolet light-induced crosslink in yeast tRNA(Phe)

The irradiation of native or unmodified yeast tRNA(Phe) by short wavelength UV light (260 nM) results in an intramolecular crosslink that has been mapped to occur between C48 in the variable loop and U59 in the T loop. Photo-reversibility of the crosslink and the absence of fluorescent photo adducts suggest that the crosslink product is a cytidine-uridine cyclobutane dimer. This is consistent with the relative geometries of C48 and U59 in the crystal structure of yeast tRNA(Phe). Evaluation of the crosslinking efficiency of the mutants of tRNA(Phe) indicates that the reaction depends on the correct tertiary structure of the RNA.

A tyrosyl-tRNA synthetase binds specifically to the group I intron catalytic core

The Neurospora CYT-18 protein, the mitochondrial tyrosyl-tRNA synthetase, functions in splicing group I introns in mitochondria. Here, we show that CYT-18 binds strongly to diverse group I introns that have minimal sequence homology and recognizes highly conserved structural features of the catalytic core of these introns. Inhibition experiments indicate that the intron RNA and tRNA(Tyr) compete for the same or overlapping binding sites in the CYT-18 protein. Considered together with functional analysis, our results indicate that the CYT-18 protein promotes splicing by binding to the intron core and stabilizing it in a conformation required for catalytic activity. Furthermore, the specific binding of the synthetase suggests that the group I intron catalytic core has structural similarities to tRNAs, which could reflect either convergent evolution or an evolutionary relationship between group I introns and tRNAs.

Recognition of G-U mismatches by tris(4,7-diphenyl-1,10-phenanthroline)rhodium(III)

The coordination complex tris(4,7-diphenyl-1,10-phenanthroline)rhodium(III) [Rh(DIP)3(3+)], which promotes RNA cleavage upon photoactivation, has been shown to target specifically guanine-uracil (G-U) mismatches in double-helical regions of folded RNAs. Photoactivated cleavage by Rh(DIP)3(3+) has been examined on a series of RNAs that contain G-U mismatches, yeast tRNA(Phe) and yeast tRNA(Asp), as well as on 5S rRNAs from Xenopus oocytes and Escherichia coli. In addition, a "microhelix" was synthesized, which consists of seven base pairs of the acceptor stem of yeast tRNA(Phe) connected by a six-nucleotide loop and contains a mismatch involving residues G4 and U69. A U4.G69 variant of this sequence was also constructed, and cleavage by Rh(DIP)3(3+) was examined. In each of these cases, specific cleavage is observed at the residue which lies to the 3'-side of the wobble-paired U; some cleavage by the rhodium complex is also evident in several structured RNA loops. The remarkable site selectivity for G-U mismatches within double-helical regions is attributed to shape-selective binding by the rhodium complex. This binding furthermore depends upon the orientation of the G-U mismatch, which produces different stacking interactions between the G-U base pair with the Watson-Crick base pair following it on the 5'-side of U compared to the Watson-Crick pair preceding it on the 3'-side of U. Rh(DIP)3(3+) therefore serves as a unique probe of G-U mismatches and may be useful both as a model and in probing RNA-protein interactions as well as in identifying G-U mismatches within double-helical regions of folded RNAs.

Competition of aminoacyl-tRNA synthetases for tRNA ensures the accuracy of aminoacylation

The accuracy of protein biosynthesis rests on the high fidelity with which aminoacyl-tRNA synthetases discriminate between tRNAs. Correct aminoacylation depends not only on identity elements (nucleotides in certain positions) in tRNA (1), but also on competition between different synthetases for a given tRNA (2). Here we describe in vivo and in vitro experiments which demonstrate how variations in the levels of synthetases and tRNA affect the accuracy of aminoacylation. We show in vivo that concurrent overexpression of Escherichia coli tyrosyl-tRNA synthetase abolishes misacylation of supF tRNA(Tyr) with glutamine in vivo by overproduced glutaminyl-tRNA synthetase. In an in vitro competition assay, we have confirmed that the overproduction mischarging phenomenon observed in vivo is due to competition between the synthetases at the level of aminoacylation. Likewise, we have been able to examine the role competition plays in the identity of a non-suppressor tRNA of ambiguous identity, tRNA(Glu). Finally, with this assay, we show that the identity of a tRNA and the accuracy with which it is recognized depend on the relative affinities of the synthetases for the tRNA. The in vitro competition assay represents a general method of obtaining qualitative information on tRNA identity in a competitive environment (usually only found in vivo) during a defined step in protein biosynthesis, aminoacylation. In addition, we show that the discriminator base (position 73) and the first base of the anticodon are important for recognition by E. coli tyrosyl-tRNA synthetase.

The T-loop region of animal mitochondrial tRNA(Ser)(AGY) is a main recognition site for homologous seryl-tRNA synthetase

Recognition sites of bovine mitochondrial serine tRNA specific for condons AGY [tRNA(Ser) (AGY)] by the cognate mitochondrial seryl-tRNA synthetase were studied using a range of tRNA(Ser)(AGY) variants which were obtained by the in vitro transcription of synthetic tRNA genes with T7 RNA polymerase. Base replacements in the anticodon and discriminator sites did not affect serine acceptance. However, deletion and/or replacement in the T-loop region completely deprived the variants of their charging activities. Point mutation experiments in this region also showed that the adenosine residue in the middle of the T-loop (position 58), which is involved in tertiary interaction between the T-loop and the truncated D-arm [de Bruijn and Klug, 1983] played a significant role in the recognition process by the synthetase.

In vitro study of E.coli tRNA(Arg) and tRNA(Lys) identity elements

Various tRNA transcripts were constructed to study the identity elements of E.coli tRNA(Arg) and tRNA(Lys). Exchange of the anticodon of the major tRNA(Arg) from ACG to either CCG or CCU did not result in a significant loss of arginine acceptor activity, whereas not only that to UUU but also that to ACA or ACC decreased the activity. Base substitutions and deletion at A20 also impaired the arginine charging activity by over 50-fold. Arginine charging activity was introduced by either substitution of the anticodon from UAC to ACG in tRNA(Val) or from UUU to UCU in tRNA(Lys). Only a single base substitution at the third position of tRNA(Trp) anticodon (CCA) from A to G also gave rise to arginine charging activity, which was elevated to a comparable level to that of the tRNA(Arg) transcript by an additional A20 insertion. Base substitutions of the major tRNA(Arg) at the discriminator position into pyrimidines led to a decrease by factors of three to four. These data show that the third letter of the anticodon G36 or U36 besides the second letter C35 and the A20 in the variable pocket is responsible for the arginine acceptor identity, to which the discriminator base A73 or G73 contributes in an auxiliary fashion. In contrast to the arginine system, the transcript with the wild-type tRNA(Lys) sequence showed only 140-fold lower lysine charging activity than the native tRNA(Lys), suggesting the involvement of base modifications in recognition. Replacement of the anticodon UUU with not only UCU and UAC but also UUA and UUC seriously affected the lysine acceptor activity, and those with GUU and UUG also decreased by factors of 17 and 5, respectively. Introduction of UUU into the anticodons conferred lysine charging activity upon both tRNA(Val) and tRNA(Arg). Substitution of the discriminator base A73 by any of the other bases decreased the lysine acceptor activity by a factor of ten. These results indicate the involvements of all the three bases of the anticodon and A at the discriminator position in lysine specific aminoacylation.

Switching tRNA(Gln) identity from glutamine to tryptophan

The middle base (U35) of the anticodon of tRNA(Gln) is a major element ensuring the accuracy of aminoacylation by Escherichia coli glutaminyl-tRNA synthetase (GlnRS). An opal suppressor of tRNA(Gln) (su+2UGA) containing C35 (anticodon UCA) was isolated by genetic selection and mutagenesis. Suppression of a UGA mutation in the E. coli fol gene followed by N-terminal sequence analysis of purified dihydrofolate reductase showed that this tRNA was an efficient suppressor that inserted predominantly tryptophan. Mutations of the 3-70 base pair (U70 and A3U70) were made. These mutants of su+2UGA are less efficient suppressors and inserted predominantly tryptophan in vivo; alanine insertion was not observed. Mutations of the discriminator nucleotide (A73, U73, C73) result in very weak opal suppressors. Aminoacylation in vitro by E. coli TrpRS of tRNA(Gln) transcripts mutated in the anticodon demonstrate that TrpRS recognizes all three nucleotides of the anticodon. The results show the interchangeability of the glutamine and tryptophan identities by base substitutions in their respective tRNAs. The amber suppressor (anticodon CUA) tRNA(Trp) was known previously to insert predominantly glutamine. We show that the opal suppressor (anticodon UCA) tRNA(Gln) inserts mainly tryptophan. Discrimination by these synthetases for tRNA includes position 35, with recognition of C35 by TrpRS and U35 by GlnRS. As the use of the UGA codon as tryptophan in mycoplasma and in yeast mitochondria is conserved, recognition of the UCA anticodon by TrpRS may also be maintained in evolution.

Aminoacyl-tRNA synthetase-induced cleavage of tRNA

Aminoacyl-tRNA synthetases interact with their cognate tRNAs in a highly specific fashion. We have examined the phenomenon that upon complex formation E. coli glutaminyl-tRNA synthetase destabilizes tRNA(Gln) causing chain scissions in the presence of Mg2+ ions. The phosphodiester bond cleavage produces 3'-phosphate and 5'-hydroxyl ends. This kind of experiment is useful for detecting conformational changes in tRNA. Our results show that the cleavage is synthetase-specific, that mutant and wild-type tRNA(Gln) species can assume a different conformation, and that modified nucleosides in tRNA enhance the structural stability of the molecule.

Structural analysis of three prokaryotic 5S rRNA species and selected 5S rRNA--ribosomal-protein complexes by means of Pb(II)-induced hydrolysis

Lead ions have been applied to the structural analysis of 5S rRNA from Thermus thermophilus, Bacillus stearothermophilus and Escherichia coli. Based on the distribution of Pb(II)-induced cleavages, some minor modifications of the consensus secondary structure model of 5S rRNA are proposed. They include the possible base pairing between nucleotides at positions 11 and 109, as well as changes in secondary interactions within the helix B region. The 'prokaryotic arm' region is completely resistant to hydrolysis in the three RNA species, suggesting that it is a relatively stable, highly ordered structure. Hydrolysis of E. coli 5S rRNA complexed with ribosomal protein L18 shows, besides the shielding effect of the bound protein, a highly enhanced cleavage between A108 and A109. It supports the concept that the major L18-induced conformational change involves the junction of helices A, B and D.

Cleavage specificity of chloroplast and nuclear tRNA 3'-processing nucleases

tRNAs in eukaryotic nuclei and organelles are synthesized as precursors lacking the 3'-terminal CCA sequence and possessing 5' (leader) and 3' (trailer) extensions. Nucleolytic cleavage of the 3' trailer and addition of CCA are therefore required for formation of functional tRNA 3' termini. Many chloroplast tRNA genes encode a C at position 74 which is not removed during processing but which can be incorporated as the first base of the CCAOH terminus. Sequences downstream of nucleotide 74, however, are always removed. Synthetic yeast pre-tRNA(Phe) substrates containing the complete CCA74-76 sequence were processed with crude or partially purified chloroplast enzyme fractions. The 3'-extended substrates (tRNA-CCA-trailer) were cleaved exclusively between nucleotides 74 and 75 to give tRNA-COH, whereas a 3'-mature transcript (tRNA-CCAOH) was not cleaved at all. A 5'-, 3'-extended chloroplast tRNA-CAG-trailer was also processed entirely to tRNA-COH. Furthermore, a 5'-mature, 3'-extended yeast pre-tRNA(Phe) derivative, tRNA-ACA-trailer, in which C74 was replaced by A, was cleaved precisely after A74. In contrast, we found that a partially purified enzyme fraction (a nuclear/cytoplasmic activity) from wheat embryo cleaved the 3'-extended yeast tRNA(Phe) precursors between nucleotides 73 and 74 to give tRNA(OH). This specificity is consistent with that of all previously characterized nuclear enzyme preparations. We conclude that (i) chloroplast tRNA 3'-processing endonuclease cleaves after nucleotide 74 regardless of the nature of the surrounding sequences; (ii) this specificity differs from that of the plant nuclear/cytoplasmic processing nuclease, which cleaves after base 73; and (iii) since 3'-mature tRNA is not a substrate for either activity, these 3' nucleases must require substrates possessing a 3'-terminal extension that extends past nucleotide 76. This substrate specificity may prevent mature tRNA from counterproductive cleavage by the 3' processing system.

Recognition nucleotides for human phenylalanyl-tRNA synthetase

The specificity of the interaction between tRNAPhe and phenylalanyl-tRNA synthetase isolated from human placenta was investigated. Using yeast tRNAPhe transcripts with different point mutations it was shown that all the five recognition points for the yeast phenylalanyl-tRNA synthetase (G20, G34, A35, A36 and A73) are also important for the reaction catalyzed by the human enzyme. A set of mutations in nucleotides involved in tertiary interactions of tRNAPhe revealed that mutations which maintained the proper folding of the molecule had almost no influence on the efficiency of aminoacylation. The most striking difference between the yeast and human phenylalanyl-tRNA synthetases involved a mutation in the lower two base pairs of the anticodon stem. This mutation did not affect aminoacylation with the yeast enzyme, but greatly reduced activity with human phenylalanyl-tRNA synthetase.

Conformational rigidity of specific pyrimidine residues in tRNA arises from posttranscriptional modifications that enhance steric interaction between the base and the 2'-hydroxyl group

In order to elucidate roles of the 2'-O-methylation of pyrimidine nucleotide residues of tRNAs, conformations of 2'-O-methyluridylyl(3'----5')uridine (UmpU), 2'-O-methyluridine 3'-monophosphate (Ump), and 2'-O-methyluridine (Um) in 2H2O solution were analyzed by one- and two-dimensional proton NMR spectroscopy and compared with those of related nucleotides and nucleoside. As for UpU and UmpU, the 2'-O-methylation was found to stabilize the C3'-endo form of the 3'-nucleotidyl unit (Up-/Ump-moiety). This stabilization of the C3'-endo form is primarily due to an intraresidue effect, since the conformation of the 5'-nucleotidyl unit (-pU moiety) was only slightly affected by the 2'-O-methylation of the 3'-nucleotide unit. In fact even for Up and Ump, the 2'-O-methylation significantly stabilizes the C3'-endo form by 0.8 kcal/.mol-1. By contrast, for nucleosides (U and Um), the C3'-endo form is slightly stabilized by 0.1 kcal/.mol-1. Accordingly, the stabilization of the C3'-endo form by the 2'-O-methylation is primarily due to the steric repulsion among the 2-carbonyl group, the 2'-O-methyl group and the 3'-phosphate group in the C2'-endo form. For some tRNA species, 2-thiolation of pyrimidine residues is found in positions where the 2'-O-methylation is found for other tRNA species.(ABSTRACT TRUNCATED AT 250 WORDS)

Recognition of tertiary structure in tRNAs by Rh(phen)2phi3+, a new reagent for RNA structure-function mapping

With photoactivation Rh(phen)2phi3+ promotes strand cleavage at sites of tertiary interaction in tRNA. The rhodium complex, which binds double-helical DNA by intercalation in the major groove, yields no cleavage in double-helical regions of the RNA or in unstructured single-stranded regions. Instead, Rh(phen)2phi3+ appears to target regions which are structured so that the major groove is open and accessible for stacking with the complex, as occurs where bases are triply bonded. So as to examine the specificity of this novel reagent and to evaluate its use in probing structural changes in RNAs, cleavage studies have been conducted on two structurally characterized tRNAs, tRNA(Phe) and tRNA(Asp) from yeast, the unmodified yeast tRNA(Phe) transcript, and a chemically modified tRNA(Phe), as well as on a series of tRNA(Phe) mutants. On tRNA(Phe) strong cleavage is observed at residues G22, G45, U47, psi 55, and U59; weaker cleavage is observed at A44, m7G46, and C48. On tRNA(Asp) cleavage is found at residues A21 through G26, psi 32, and U48, with minor cleavage apparent at A44, G45, A46, psi 55, U59, and U60. There is a striking similarity in cleavage observed on these tRNAs, and the sites of cleavage mark regions of tertiary folding. Cleavage on the unmodified tRNA(Phe) transcript resembles closely that found on native yeast tRNA(Phe), but additional sites, primarily in the anticodon loop and stem, are evident. The results indicate that globally the structures containing or lacking the modified bases appear to be the same; the differences in cleavage observed may reflect a loosening or alteration in the structure due to the absence of the modified bases. Cleavage results on mutants of tRNA(Phe) illustrate Rh(phen)2phi3+ as a sensitive probe in characterizing tRNA tertiary structure. Results are consistent with other assays for structural or functional changes. Uniquely, Rh(phen)2phi3+ appears to target directly sites of tertiary interaction. Cleavage results on mutants which involve base changes within the triply bounded region of the molecule indicate that it is the structure of the triply bonded array rather than the individual nucleotides which are being targeted. Chemical modification to promote selective depurination of the third base (m7G46) involved in the triple in the folded, native tRNA leads to the reduction of cleavage by the metal complex; this result shows directly the importance of the stacked triple base structure for recognition by the metal complex.(ABSTRACT TRUNCATED AT 400 WORDS)

Cleavage specificity of chloroplast and nuclear tRNA 3'-processing nucleases

tRNAs in eukaryotic nuclei and organelles are synthesized as precursors lacking the 3'-terminal CCA sequence and possessing 5' (leader) and 3' (trailer) extensions. Nucleolytic cleavage of the 3' trailer and addition of CCA are therefore required for formation of functional tRNA 3' termini. Many chloroplast tRNA genes encode a C at position 74 which is not removed during processing but which can be incorporated as the first base of the CCAOH terminus. Sequences downstream of nucleotide 74, however, are always removed. Synthetic yeast pre-tRNA(Phe) substrates containing the complete CCA74-76 sequence were processed with crude or partially purified chloroplast enzyme fractions. The 3'-extended substrates (tRNA-CCA-trailer) were cleaved exclusively between nucleotides 74 and 75 to give tRNA-COH, whereas a 3'-mature transcript (tRNA-CCAOH) was not cleaved at all. A 5'-, 3'-extended chloroplast tRNA-CAG-trailer was also processed entirely to tRNA-COH. Furthermore, a 5'-mature, 3'-extended yeast pre-tRNA(Phe) derivative, tRNA-ACA-trailer, in which C74 was replaced by A, was cleaved precisely after A74. In contrast, we found that a partially purified enzyme fraction (a nuclear/cytoplasmic activity) from wheat embryo cleaved the 3'-extended yeast tRNA(Phe) precursors between nucleotides 73 and 74 to give tRNA(OH). This specificity is consistent with that of all previously characterized nuclear enzyme preparations. We conclude that (i) chloroplast tRNA 3'-processing endonuclease cleaves after nucleotide 74 regardless of the nature of the surrounding sequences; (ii) this specificity differs from that of the plant nuclear/cytoplasmic processing nuclease, which cleaves after base 73; and (iii) since 3'-mature tRNA is not a substrate for either activity, these 3' nucleases must require substrates possessing a 3'-terminal extension that extends past nucleotide 76. This substrate specificity may prevent mature tRNA from counterproductive cleavage by the 3' processing system.

Identity determinants of E. coli tryptophan tRNA

The first base pair of the acceptor stem A1-U72 and the discriminator base G73, as well as the anticodon nucleotides, characterize the tryptophan tRNA in E. coli. To determine the contribution of these nucleotides to the tryptophan acceptor activity, various transcripts of E. coli tryptophan tRNA mutants were constructed. Substitutions of the discriminator base G73, which is conserved within prokaryotic tryptophan tRNAs, impaired aminoacylation with tryptophan. Substitutions of other purine-pyrimidine pairs for A1-U72 revealed that only U72 weakly contributed to recognition by tryptophanyl-tRNA synthetase. The E. coli aspartic acid tRNA transcript introducing the tryptophan anticodon CCA showed almost the same tryptophan charging activity as the tryptophan tRNA transcript possessing a G1-C72 base pair. Only a low activity was detected in the mutant tryptophan tRNA transcript possessing a set of G1-C72 and A73, which is observed in eukaryotic tryptophan tRNAs. These results indicate that the anticodon and G73 are major identity determinants of tryptophan tRNA in E. coli, whereas the A1-U72 base pair is only a weak recognition element.

Folding of circularly permuted transfer RNAs

All of the ribose-phosphate linkages in yeast tRNA(Phe) that could be cleaved without affecting the folding of the molecule have been determined in a single experiment. Circular permutation analysis subjects circular tRNA molecules to limited alkaline hydrolysis in order to generate one random break per molecule. Correctly folded tRNAs were identified by lead cleavage at neutral pH, a well-characterized reaction that requires proper folding of tRNA(Phe). Surprisingly, most of the circularly permuted tRNA molecules folded correctly. This result suggests that the tRNA folding motif could occur internally within other RNA sequences, and a computer search of Genbank entries has identified many examples of such motifs.

Interactions of transfer RNA pseudouridine synthases with RNAs substituted with fluorouracil

We have previously purified and characterized two different S. cerevisiae enzymes that produce pseudouridine specifically in nucleotide positions 13 and 55, respectively, in their tRNA substrates. The interactions of these enzymes with fluorinated tRNAs have now been studied. Such RNAs were produced by in vitro transcription using as templates synthetic genes that encode variants of a yeast glycine tRNA. RNAs substituted with fluorouracil were found to markedly inhibit pseudouridine synthase activity and the inhibitory effect of a tRNA was to a large extent dependent on the presence of fluorouracil in the nucleotide position where normally pseudouridylation occurs. Pseudouridine synthases were shown to form highly stable, non-covalent complexes with fluorinated tRNAs and we demonstrate that this interaction may be used to further characterize and purify these enzymes. The use of 5-fluorouracil as a cancer therapeutic agent is discussed in relation to our results.

A synthetic alanyl-initiator tRNA with initiator tRNA properties as determined by fluorescence measurements: comparison to a synthetic alanyl-elongator tRNA

Two synthetic tRNAs have been generated that can be enzymatically aminoacylated with alanine and have AAA anticodons to recognize a poly(U) template. One of the tRNAs (tRNA(eAla/AAA)) is nearly identical to Escherichia coli elongator tRNA(Ala). The other has a sequence similar to Escherichia coli initiator tRNA(Met) (tRNA(iAla/AAA)). Although both tRNAs can be used in poly(U)-directed nonenzymatic initiation at 15 mM Mg2+, only the elongator tRNA can serve for peptide elongation and polyalanine synthesis. Only the initiator tRNA can be bound to 30S ribosomal subunits or 70S ribosomes in the presence of initiation factor 2 (IF-2) and low Mg2+ suggesting that it can function in enzymatic peptide initiation. A derivative of coumarin was covalently attached to the alpha amino group of alanine of these two Ala-tRNA species. The fluorescence spectra, quantum yield and anisotropy for the two Ala-tRNA derivatives are different when they are bound to 70S ribosomes (nonenzymatically in the presence of 15 mM Mg2+) indicating that the local environment of the probe is different. Also, the effect of erythromycin on their fluorescence is quite different, suggesting that the probes and presumably the alanine moiety to which they are covalently linked are in different positions on the ribosomes.

Four sites in the acceptor helix and one site in the variable pocket of tRNA(Ala) determine the molecule's acceptor identity

The structural features that determine tRNA(Ala) acceptor identity have been studied with amber-suppressor tRNAs in Escherichia coli cells. Previous work established that a wobble pair composed of guanosine at position 3 and uridine at position 70 (G3-U70) in the acceptor helix of tRNA(Ala) is a determinant of the molecule's acceptor identity. We show that additional determinants are located at three other sites in the acceptor helix and at one site in the variable pocket of tRNA(Ala). These latter determinants are less important than G3.U70 since their individual alterations in mutants of tRNA(Ala) have smaller degrading effects on the functions of the molecules, and subsets of the determinants, when combined with G3.U70, are sufficient to switch the identities of several other tRNAs to that of tRNA(Ala). Other workers are using fragments of the tRNA(Ala) acceptor helix to study the molecule's acceptor identity. Our demonstration that the variable pocket contributes to tRNA(Ala) acceptor identity means that such fragments do not faithfully replicate the structure-function relationship of the cellular process.

Identification of the catalytic nucleophile of tRNA (m5U54)methyltransferase

A covalent complex between tRNA (m5U54)methyltransferase, 5-fluorouridine tRNA(Phe), and S-adenosyl-L-[methyl-3H]methionine was formed in vitro and purified. Previously, it was shown that in this complex the 6-position of fluorouridine-54 is covalently linked to a catalytic nucleophile and the 5-position is bound to the transferred methyl group of AdoMet [Santi, D. V., & Hardy, L. W. (1987) Biochemistry 26, 8599-8606]. Proteolysis of the complex generated a [3H]methyl-FUtRNA-bound peptide, which was purified by 7 M urea-15% polyacrylamide gel electrophoresis. The peptide component of the complex was sequenced by gas-phase Edman degradation and found to contain two cysteines. The tritium was shown to be associated with Cys 324 of the methyltransferase, which unequivocally identifies this residue as the catalytic nucleophile.

The 5' untranslated regions of acetyl-coenzyme A carboxylase mRNA provide specific translational control in vitro

Acetyl-coenzyme A carboxylase (ACC) catalyzes the rate-limiting step in the biosynthesis of long-chain fatty acids. Transcription of the single-copy ACC gene from two independent promoters, together with the differential splicing of the transcripts, gives rise to mature ACC mRNA having the same open reading frame (ORF), but exhibiting heterogeneity in their 5' untranslated region (5'-UTR). Class 1 ACC mRNA are transcribed from the inducible promoter 1 and their 5'-end leading sequences are provided by exon 1. Class 2 ACC mRNA are transcribed from the constitutively expressing promoter 2 and their leading sequences are derived from exon 2. In order to understand the role of different 5' UTR of ACC mRNA we have synthesized in vitro transcripts with defined ACC mRNA 5' UTR and examined their relative translational efficiencies in rabbit reticulocyte lysates. The major translation product of both forms of ACC mRNA was initiated at the first AUG of the ORF. Class 1 transcripts had a 6-9-fold better translational efficiency than class 2 transcripts, based on the quantity of major peptide produced by a given amount of transcript. The poor translational efficiency of class 2 transcripts can be improved by the removal of sequences contributed by exon 2, suggesting that they play an inhibitory role in the translation of class 2 types of ACC mRNA. In addition to their higher translational efficiency, the class 1 transcripts can also initiate translation at in-frame non-AUG codons, located in exon 1, i.e. upstream to the starting AUG of the common ACC mRNA ORF. This results in novel ACC peptides with extended N termini. These observations are consistent with the hypothesis that the 5' UTR heterogeneity in the ACC mRNA may be involved in post-transcriptional control, at the level of translation, of the ACC gene expression.

Characterization of elongating T7 and SP6 RNA polymerases and their response to a roadblock generated by a site-specific DNA binding protein

As a means of generating homogeneous populations of elongation complexes with the RNA polymerases encoded by phages T7 and SP6, transcription has been carried out in vitro on templates associated with the Gln-111 mutant of EcoRI endonuclease. The Gln-111 protein, as a result of a single amino acid substitution at position 111, lacks cleavage function yet shows higher than wild-type affinity for the EcoRI recognition sequence GAATTC. On a series of linear and circular templates associated with Gln-111 protein, blockage of the phage RNA polymerase elongation complex is observed. The 3' endpoint of the major blocked-length RNA species, just 3 bp upstream from the GAATTC, reveals an extremely close approach of polymerase's leading edge to essential contacts between Gln-111 protein and its binding site. In contrast to E. coli RNA polymerase, which is blocked stably and quantitatively by Gln-111 protein (Pavco, P.A. and Steege, D. A. (1990) J. Biol. Chem. 265, 9960-9969), the phage polymerases show substantial levels of readthrough transcription beyond the protein block.

SP6 RNA polymerase stutters when initiating from an AAA... sequence

The 16S ribosomal RNA gene of Escherichia coli was placed under the transcriptional control of consensus and modified T7 promoters and a modified SP6 promoter. Both T7 and SP6 polymerases faithfully transcribed the coding sequence (beginning at the +1 position) of each construct, although SP6 polymerase was five-fold more effective than T7 polymerase in initiating with the AAAUUG... sequence. An appreciable fraction of the SP6 transcript molecules contained additional adenosines in the -1, -2, -3, -4, and -5 positions. The transcripts containing additional residues constituted approximately 40-50% of the total SP6 transcription products. Neither the nature nor extent of the additional residues was affected by replacing the pppA 5'-end by pA. Since the identity of the inserted residues does not correspond to the sequence of the template, these additional nucleosides must result from 'stuttering' of the SP6 enzyme at the -1 to +3 positions during initiation of transcription.

Refolded HIV-1 tat protein protects both bulge and loop nucleotides in TAR RNA from ribonucleolytic cleavage

Substantial evidence indicates that HIV-1 trans-activation by tat protein is mediated through the TAR RNA element. This RNA forms a stem-loop structure containing a three-nucleotide bulge and a six-nucleotide loop. Previous mutagenic analysis of TAR indicates that the bulge residues and a 4 bp segment of the stem constitute, in part, the tat binding site. However, there appears to be no sequence-specific contribution of the six-base loop. We have employed a ribonuclease protection technique to explore the interaction of tat with single-stranded regions of TAR. The results indicate that tat interacts with both the bulge and loop regions of TAR. Treatment of TAR RNA with RNase A results in cleavage at U23 and U31, located in the bulge and loop regions, respectively. High concentrations (approximately 2 microM) of Escherichia coli derived tat protein, prepared by standard procedures, gave complete protection of TAR RNA from RNase A cleavage. However, under these conditions, truncated TAR derivatives in which no stem-loop structure is expected to form were also protected, indicating nonspecific binding. In order to obtain a tat preparation with enhanced specificity toward TAR RNA, methods were developed for refolding the recombinant protein. This treatment enhanced the affinity of tat for TAR by approximately 30-fold [Kd(apparent) less than 25 nM] and markedly increased its specificity for the TAR. Again, tat protected TAR RNA from RNase A cleavage at both U23 and U31. Protection was also observed with RNase T1 which cleaves TAR RNA at three G residues in the six-base loop.(ABSTRACT TRUNCATED AT 250 WORDS)

Anticodon and acceptor stem nucleotides in tRNA(Gln) are major recognition elements for E. coli glutaminyl-tRNA synthetase

The correct attachment of amino acids to their corresponding (cognate) transfer RNA catalysed by aminoacyl-tRNA synthetases is a key factor in ensuring the fidelity of protein biosynthesis. Previous studies have demonstrated that the interaction of Escherichia coli tRNA(Gln) with glutaminyl-tRNA synthetase (GlnRS) provides an excellent system to study this highly specific recognition process, also referred to as 'tRNA identity'. Accurate acylation of tRNA depends mainly on two principles: a set of nucleotides in the tRNA molecule (identity elements) responsible for proper discrimination by aminoacyl-tRNA synthetases and competition between different synthetases for tRNAs. Elements of glutamine identity are located in the anticodon and in the acceptor stem region, including the discriminator base. We report here the production of more than 20 tRNA(2Gln) mutants at positions likely to be involved in tRNA discrimination by the enzyme. Unmodified tRNA, containing the wild-type anticodon and U or G at its 5'-terminus, can be aminocylated by GlnRS with similar kinetic parameters to native tRNA(2Gln). By in vitro aminoacylation the mutant tRNAs showed decreases of up to 3 x 10(5)-fold in the specificity constant (kcat/KM)14 with the major contribution of kcat. Despite these large changes, some of these mutant tRNAs are efficient amber suppressors in vivo. Our results show that strong elements for glutamine identity reside in the anticodon region and in positions 2 and 3 of the acceptor stem, and that the contribution of different identity elements to the overall discrimination varies significantly. We discuss our data in the light of the crystal structure of the GlnRS:tRNA(Gln) complex.

Interaction of Escherichia coli tRNA(Ser) with its cognate aminoacyl-tRNA synthetase as determined by footprinting with phosphorothioate-containing tRNA transcripts

A footprinting technique using phosphorothioate-containing RNA transcripts has been developed and applied to identify contacts between Escherichia coli tRNA(Ser) and its cognate aminoacyl-tRNA synthetase. The cloned gene for the tRNA was transcribed in four reactions in which a different NTP was complemented by 5% of the corresponding nucleoside 5'-O-(1-thiotriphosphate). The phosphorothioate groups of such transcripts are cleaved by reaction with iodine to permit sequencing of the transcripts. Footprinting was achieved by performing the same reaction with the phosphorothioate-tRNA-enzyme complex. At 1 mM iodine, selective protection of the tRNA transcripts in the cognate system was observed, with strong protection at positions 52 and 68 and weak protection at positions 46, 53, 67, 69, and 70. It is suggested that these regions of the tRNA interact with the helical arm of the synthetase.

Identity elements of Escherichia coli tRNA(Ala)

Studies using the T7 transcription system revealed that the discriminator base A73 and the G20 in the variable pocket play important roles in the Escherichia coli alanine tRNA identity. The C60 in the T-loop, which is unique to alanine tRNA, was not found to be crucial for alanine identity. Anticodon replacement into the valine anticodon UAC did not decrease alanine charging activity, and no alanine charging activity was detected in the mutant valine tRNA possessing the alanine anticodon UGC.

Identity elements for specific aminoacylation of yeast tRNA(Asp) by cognate aspartyl-tRNA synthetase

The nucleotides crucial for the specific aminoacylation of yeast tRNA(Asp) by its cognate synthetase have been identified. Steady-state aminoacylation kinetics of unmodified tRNA transcripts indicate that G34, U35, C36, and G73 are important determinants of tRNA(Asp) identity. Mutations at these positions result in a large decrease (19- to 530-fold) of the kinetic specificity constant (ratio of the catalytic rate constant kcat and the Michaelis constant Km) for aspartylation relative to wild-type tRNA(Asp). Mutation to G10-C25 within the D-stem reduced kcat/Km eightfold. This fifth mutation probably indirectly affects the presentation of the highly conserved G10 nucleotide to the synthetase. A yeast tRNA(Phe) was converted into an efficient substrate for aspartyl-tRNA synthetase through introduction of the five identity elements. The identity nucleotides are located in regions of tight interaction between tRNA and synthetase as shown in the crystal structure of the complex and suggest sites of base-specific contacts.

A comparison of optimal and suboptimal RNA secondary structures predicted by free energy minimization with structures determined by phylogenetic comparison

This article describes the latest version of an RNA folding algorithm that predicts both optimal and suboptimal solutions based on free energy minimization. A number of RNA's with known structures deduced from comparative sequence analysis are folded to test program performance. The group of solutions obtained for each molecule is analysed to determine how many of the known helixes occur in the optimal solution and in the best suboptimal solution. In most cases, a structure about 80% correct is found with a free energy within 2% of the predicted lowest free energy structure.

Mono Q chromatography permits recycling of DNA template and purification of RNA transcripts after T7 RNA polymerase reaction

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Rapid and simple purification of T7 RNA polymerase

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A conserved sequence element in ribonuclease III processing signals is not required for accurate in vitro enzymatic cleavage

Ribonuclease III of Escherichia coli is prominently involved in the endoribonucleolytic processing of cell and viral-encoded RNAs. Towards the goal of defining the RNA sequence and structural elements that establish specific catalytic cleavage of RNase III processing signals, this report demonstrates that a 60 nucleotide RNA (R1.1 RNA) containing the bacteriophage T7 R1.1 RNase III processing signal, can be generated by in vitro enzymatic transcription of a synthetic deoxyoligonucleotide and accurately cleaved in vitro by RNase III. Several R1.1 RNA sequence variants were prepared to contain point mutations in the internal loop which, on the basis of a hypothetical 'dsRNA mimicry' structural model of RNase III processing signals, would be predicted to inhibit cleavage by disrupting essential tertiary RNA-RNA interactions. These R1.1 sequence variants are accurately and efficiently cleaved in vitro by RNase III, indicating that the dsRNA mimicry structure, if it does exist, is not important for substrate reactivity. Also, we tested the functional importance of the strongly conserved CUU/GAA base-pair sequence by constructing R1.1 sequence variants containing base-pair changes within this element. These R1.1 variants are accurately cleaved at rates comparable to wild-type R1.1 RNA, indicating the nonessentiality of this conserved sequence element in establishing in vitro processing reactivity and selectivity.

Interaction of HIV-1 reverse transcriptase with a synthetic form of its replication primer, tRNA(Lys,3)

Using synthetic oligonucleotides, a gene encoding the HIV-1 replication primer, tRNA(Lys,3), was constructed and placed downstream from a bacteriophage T7 promoter. In vitro transcription of this gene yielded a form of tRNA(Lys,3) which lacks the modified bases characteristic of the natural species and the 3' -C-A-dinucleotide. Synthetic tRNA(Lys,3) annealed to a pbs-HIV1 RNA template can prime cDNA synthesis catalysed by recombinant HIV-1 reverse transcriptase. Trans-DDP crosslinking indicates that this synthetic tRNA is still capable of interacting with HIV-1 RT via a 12-nucleotide portion encompassing the anticodon domain. Gel-mobility shift and competition analyses imply that the affinity of synthetic tRNA for RT is reduced. In contrast to earlier observations, synthetic tRNA is readily competed from RT by natural tRNA(Pro). The reduced affinity of synthetic tRNA(Lys,3) for RT is not appreciably affected by mutations in positions within the loop of the anticodon domain. These results would imply that the overall structure of the anticodon domain of tRNA(Lys,3) is an important factor in its recognition by HIV-1 RT. In addition, modified bases within this, although not absolutely required, would appear to make a significant contribution to the enhanced stability of the ribonucleoprotein complex.

Phosphorothioate-containing RNAs show mRNA activity in the prokaryotic translation systems in vitro

Phosphorothioate-containing RNAs were generated by transcription of coliphage T7 DNA using the Sp diastereomers of ribonucleoside 5'-O-(1-thiotriphosphates) and T7 RNA polymerase. RNAs in which a single nucleotide was substituted by the corresponding nucleoside phosphorothioate functioned as mRNA in the cell-free translation systems prepared from Escherichia coli and from an extreme thermophilic bacterium, Thermus thermophilus. This substitution increased the efficiency of protein synthesis by stabilizing the mRNAs in these systems. As the proportion of substituted nucleotides was increased, their mRNA activity was decreased accordingly. As judged from the analysis by SDS-polyacrylamide gel-electrophoresis, the proteins synthesized using phosphorothioate-containing mRNAs as template were identical to those obtained with unsubstituted mRNAs. However, larger proteins which were barely detectable when unsubstituted mRNA was used were well represented when phosphorothioate-RNA was used instead. The advantages in using the phosphorothioate-mRNAs in the in vitro translation systems are discussed.

Specific valylation identity of turnip yellow mosaic virus RNA by yeast valyl-tRNA synthetase is directed by the anticodon in a kinetic rather than affinity-based discrimination

Variants with mutations in three parts of the tRNA-like structure of turnip yellow mosaic virus RNA (the anticodon, the discriminator position in the amino acid acceptor stem, and in the variable loop) were created via site-directed mutagenesis of a cDNA clone and transcription with T7 RNA polymerase. The valylation properties of transcripts were studied in the presence of pure yeast valyl-tRNA synthetase. Mutation of the central position of the anticodon triplet resulted in a quasi-total loss of valylation activity, indicating that the anticodon is a principal determinant for valylation of the turnip yellow mosaic virus tRNA-like structure. These anticodon mutants interacted with yeast valyl-tRNA synthetase with affinities comparable to those of the wild-type RNA and behaved as competitive inhibitors in the valylation reaction of yeast tRNAVal. The defective aminoacylation of these mutants therefore results from kinetic rather than affinity effects. Minor negative effects on valylation efficiency were observed for mutants with substitutions at the two other sites studied, suggesting a structural role or a limited contribution to the valine identity of the tRNA-like molecule.

Conversion of aminoacylation specificity from tRNA(Tyr) to tRNA(Ser) in vitro

The discrimination mechanism between tRNA(Ser) and tRNA(Tyr) was studied using various in vitro transcripts of E. coli tRNATyr variants. The insertion of only two nucleotides into the variable stem of tRNA(Tyr) generates serine charging activity. The acceptor activities of some of the tRNA(Tyr) mutants with insertions in the long variable arm were enhanced by changes in nucleotides at positions 9 and/or 20B, which are possible elements for dictating the orientation of the long variable arm. These findings suggest that the long variable arm is involved in recognition by seryl-tRNA synthetase in spite of sequence and length variations shown within tRNA(Ser) isoacceptors, and eventually serves as a determinant for selection from other tRNA species. Changing the anticodon from GUA to the serine anticodon GGA resulted in a marked decrease in tyrosine charging activity, but this mutant did not show any serine charging activity. The discriminator base, the fourth base from the 3' end of tRNA, was also important for aminoacylation with tyrosine. Complete specificity change in vitro was facilitated by insertion of three nucleotides into the variable arm plus two nucleotide changes at positions 9 and 73.