Importance of conserved residues for the conformation of the T-loop in tRNAs

The conformation of the T-loop of yeast tRNA(Asp) was studied by structural mapping techniques using chemical and enzymatic probes and by three-dimensional graphics modeling with the known crystallographic structures of tRNAs as references. The structural importance of C61 (conserved in the T-stem of all tRNAs) for the loop conformation was directly checked by ethylnitrosourea phosphate alkylation, either on the 3'-half tRNAAsp molecule or on a variant in which C61 was replaced by U61. The reactivity of P60 against ethylnitrosourea alkylation in the variant emphasizes the role of the hydrogen bond between this phosphate and position N4 of C61 for stabilizing the conformation of the T-loop. Experiments on several tRNA variants, containing C61 but altered in the sequence or in the length of the T-loop, indicate that other structural features help to stabilize the hydrogen bond network around P60. Evidence is presented that the reverse Hoogsteen base pair T54-A58 contributes to this stabilization by maintaining the hydrogen bonding between the 2'OH of ribose 58 and P60. Using graphics modeling and based on the chemical data. T-loops of several variants were constructed. It appears that both the constant length of the T-loop and the presence of psi 55 are crucial for the correct interaction between the T- and D-loops. The conclusion of this study is that the T-loop in tRNA possesses an intrinsic conformation (mainly governed by the constant residues) existing primarily without the structural context of the entire tRNA molecule.     

Enzymatic conversion of adenosine to inosine in the wobble position of yeast tRNAAsp: the dependence on the anticodon sequence.

We have investigated the specificity of the tRNA modifying enzyme that transforms the adenosine at position 34 (wobble position) into inosine in the anticodon of several tRNAs. For this purpose, we have constructed sixteen recombinants of yeast tRNAAsp harboring an AXY anticodon (where X or Y was one of the four nucleotides A, G, C or U). This was done by enzymatic manipulations in vitro of the yeast tRNAAsp, involving specific hydrolysis with S1-nuclease and RNAase A, phosphorylation with T4-polynucleotide kinase and ligation with T4-RNA ligase: it allowed us to replace the normal anticodon GUC by trinucleotides AXY and to introduce simultaneously a 32P-labelled phosphate group between the uridine at position 33 and the newly inserted adenosine at position 34. Each of these 32P-labelled AXY "anticodon-substituted" yeast tRNAAsp were microinjected into the cytoplasm of Xenopus laevis oocytes and assayed for their capacity to act as substrates for the A34 to I34 transforming enzyme. Our results indicate that: 1/ A34 in yeast tRNAAsp harboring the arginine anticodon ACG or an AXY anticodon with a purine at position 35 but with A, G or C but not U at position 36 were efficiently modified into I34; 2/ all yeast tRNAAsp harboring an AXY anticodon with a pyrimidine at position 35 (except ACG) or uridine at position 36 were not modified at all. This demonstrates a strong dependence on the anticodon sequence for the A34 to I34 transformation in yeast tRNAAsp by the putative cytoplasmic adenosine deaminase of Xenopus laevis oocytes.     

Anticodon-anticodon interactions in solution. Studies of the self-association of yeast or Escherichia coli tRNAAsp and of their interactions with Escherichia coli tRNAVal

The temperature-jump method was used to measure the thermodynamic and kinetic parameters of the yeast tRNAAsp (anticodon GUC) duplex, which involves a U/U mismatch in the middle position of the quasi self-complementary anticodon, and of the yeast tRNAAsp (GUC)-Escherichia coli tRNAVal (GAC) complex, in which the tRNAs have complementary anticodons. The existence of the tRNAAsp duplex involving GUC-GUC interactions as evidenced in the crystal structure has now been demonstrated in solution. However, the value of its association constant (Kass = 10(4)M-1 at 0 degrees C) is characteristic of a rather weak complex, when compared with that between tRNAAsp and tRNAVal (Kass = 4 X 10(6) M-1 at 0 degrees C), the effect being essentially linked to differences in the rate constant for dissociation. tRNAAsp split in the anticodon by T1 ribonuclease gives no relaxation signal, indicating that the effects observed with intact tRNA were entirely due to anticodon interactions. No duplex formation was observed with other tRNAs having quasi self-complementary GNC anticodons (where N is C, A or G), such as E. coli tRNAGly (GCC), E. coli tRNAVal (GAC) or E. coli tRNAAla (GGC). This is compatible with the idea that, probably as in the crystal structure, a short double helix is formed in solution between the two GUC anticodons. Because of steric effects, such a complex formation would be hindered if a cytosine, adenine or guanine residue were located in the middle position of the anticodon. Escherichia coli tRNAAsp possessing a modified G residue, the Q base, at the first position of the anticodon, showed a weaker self-association than yeast tRNAAsp but its complex with E. coli tRNAVal was found to be only 1.5 times less stable than that between yeast tRNAAsp and E. coli tRNAVal. Temperature-jump experiments conducted under conditions mimicking those used for the crystallization of yeast tRNAAsp (in the presence of 1.6 M-ammonium sulphate and 3mM-spermine) revealed an important stabilization of the yeast and E. coli tRNAAsp duplexes or of their complexes with E. coli tRNAVal. The effect is due exclusively to ammonium sulphate; it is entropy driven and its influence is reflected on the association rate constant; no influence on the dissociation rate constant was observed. For all tRNA-tRNA complexes, the melting temperature upon addition of ammonium sulphate was considerably increased. This study permits the definition of solution conditions in which tRNAs with appropriate anticodons exist mainly as anticodon-anticodon dimers.     

Yeast tRNAAsp tertiary structure in solution and areas of interaction of the tRNA with aspartyl-tRNA synthetase. A comparative study of the yeast phenylalanine system by phosphate alkylation experiments with ethylnitrosourea

Ethylnitrosourea is an alkylating reagent preferentially modifying phosphate groups in nucleic acids. It was used to monitor the tertiary structure, in solution, of yeast tRNAAsp and to determine those phosphate groups in contact with the cognate aspartyl-tRNA synthetase. Experiments involve 3' or 5'-end-labelled tRNA molecules, low yield modification of the free or complexed nucleic acid and specific splitting at the modified phosphate groups. The resulting end-labelled oligonucleotides are resolved on polyacrylamide sequencing gels and data analysed by autoradiography and densitometry. Experiments were conducted in parallel on yeast tRNAAsp and on tRNAPhe. In that way it was possible to compare the solution structure of two elongator tRNAs and to interpret the modification data using the known crystal structures of both tRNAs. Mapping of the phosphates in free tRNAAsp and tRNAPhe allowed the detection of differential reactivities for phosphates 8, 18, 19, 20, 22, 23, 24 and 49: phosphates 18, 19, 23, 24 and 49 are more reactive in tRNAAsp, while phosphates 8, 20 and 22 are more reactive in tRNAPhe. All other phosphates display similar reactivities in both tRNAs, in particular phosphate 60 in the T-loop, which is strongly protected. Most of these data are explained by the crystal structures of the tRNAs. Thermal transitions in tRNAAsp could be followed by chemical modifications of phosphates. Results indicate that the D-arm is more flexible than the T-loop. The phosphates in yeast tRNAAsp in contact with aspartyl-tRNA synthetase are essentially contained in three continuous stretches, including those at the corner of the amino acid accepting and D-arm, at the 5' side of the acceptor stem and in the variable loop. When represented in the three-dimensional structure of the tRNAAsp, it clearly appears that one side of the L-shaped tRNA molecule, that comprising the variable loop, is in contact with aspartyl-tRNA synthetase. In yeast tRNAPhe interacting with phenylalanyl-tRNA synthetase, the distribution of protected phosphates is different, although phosphates in the anticodon stem and variable loop are involved in both systems. With tRNAPhe, the data cannot be accommodated by the interaction model found for tRNAAsp, but they are consistent with the diagonal side model proposed by Rich & Schimmel (1977). The existence of different interaction schemes between tRNAs and aminoacyl-tRNA synthetases, correlated with the oligomeric structure of the enzyme, is proposed.     

In vitro methylation of yeast tRNAAsp by rat brain cortical tRNA-(adenine-1) methyltransferase.

Rat brain cortices from young animals contain large amounts of tRNA (adenine-1)methyltransferase(s). The enzyme(s) can methylate E. coli tRNA and to a lower degree yeast tRNA. Among yeast tRNA species which can be methylated we have selected tRNAAsp as a substrate for the brain enzyme. The digestions of in vitro methylated [Me-3H]-tRNAAsp with pancreatic and/or T1 ribonucleases followed by chromatographies on DEAE-cellulose, 7 M urea, suggested that the methylation of tRNAAsp occurred at a single position within the D-loop. Further digestion of the radioactive oligonucleotide recovered after DEAE-cellulose chromatography by phosphomonoesterase and snake venom phosphodiesterase enzymes followed by bidimensional thin layer chromatography enabled us to determine the location of the adenine residue which becomes methylated by the brain enzyme. This one resulted to be the adenine 14 in the D-loop of yeast tRNAAsp.     

Enzymatic replacement in vitro of the first anticodon base of yeast tRNAAsp: application to the study of tRNA maturation in vivo, after microinjection into frog oocytes.

A combination of several enzymes, RNase-T1, nuclease S1, T4-polynucleotide kinase and T4-RNA ligase were used to prepare and modify different fragments of yeast tRNAAsp (normal anticodon G U C). This allowed us to reconstitute, in vitro, a chimeric tRNA that has any of the four bases G, A, U or C, as the first anticodon nucleotide, labelled with (32p) in its 3' position. Such reconstituted (32p) labelled yeast tRNAAsp were microinjected into the cytoplasm or the nucleus of the frog oocyte and checked for their stability as well as for their potential to work as a substrate for the maturation (modifying) enzymes under in vivo conditions. Our results indicate that the chimeric yeast tRNAsAsp were quite stable inside the frog oocyte. Also, the G34 was effectively transformed inside the cytoplasm of frog oocyte into Q34 and mannosyl-Q34; U34 into mcm5s2U and mcm5U. In contrast, C34 and A34 were not transformed at all neither in the cytoplasm nor in the nucleus of the frog oocyte. The above procedure constitutes a new approach in order to detect the presence of a given modifying enzyme inside the frog oocyte; also it provides informations about its cellular location and possibility about its specificity of interaction with foreign tRNA.     

Post-transcriptional modification of the wobble nucleotide in anticodon-substituted yeast tRNAArgII after microinjection into Xenopus laevis oocytes

An enzymatic procedure for the replacement of the ICG anticodon of yeast tRNAArgII by NCG trinucleotide (N = A, C, G or U) is described. Partial digestion with S1-nuclease and T1-RNAase provides fragments which, when annealed together, form an "anticodon-deprived" yeast tRNAArgII. A novel anticodon, phosphorylated with (32P) label on its 5' terminal residue, is then inserted using T4-RNA ligase. Such "anticodon-substituted" yeast tRNAArgII are microinjected into the cytoplasm of Xenopus laevis oocytes and shown to be able to interact with the anticodon maturation enzymes under in vivo conditions. Our results indicate that when adenosine occurs in the wobble position (A34) in yeast tRNAArgII it is efficiently modified into inosine (I34) while uridine (U34) is transformed into two uridine derivatives, one of which is probably mcm5U. In contrast, when a cytosine (C34) or guanosine (G34) occurs, they are not modified. These results are at variance with those obtained previously under similar conditions with anticodon derivatives of yeast tRNAAsp harbouring A, C, G or U as the first anticodon nucleotide. In this case, guanosine and uridine were modified while adenosine and cytosine were not.     

Enzymatic formation of queuosine and of glycosyl queuosine in yeast tRNAs microinjected into Xenopus laevis oocytes. The effect of the anticodon loop sequence

The eukaryotic tRNA-guanine transglycosylases (queuine insertases) catalyse an exchange of guanine for queuine in position 34, the wobble nucleoside, of tRNAs having a GUN anticodon where N (position 36) stands for A, U, C or G. In tRNAAsp (anticodon QUC) and tRNATyr (anticodon Q psi A) from certain eukaryotic cells, the nucleoside Q-34 is further hypermodified into a glycosylated derivative by tRNA-queuine glycosyltransferase. In order to gain insight into the influence of the nucleosides in position 36, 37 and 38 of an anticodon loop on the potential of a tRNA to become a substrate for the two modifying enzymes, we have constructed several variants of yeast tRNAs in which the normal anticodon has been replaced by one of the synthetic anticodons GUA, GUC, GUG or GUU. In yeast tRNAAsp, the nucleosides 37 (m1G) and 38(C) have also been replaced by an adenosine. These reconstructed chimerical tRNAs were microinjected into the cytoplasm of Xenopus laevis oocytes and tested for their ability to react with the oocyte maturation enzymes. Our results indicate that the nucleosides in positions 36, 37 and 38 influence the efficiencies of conversion of G-34 to Q-34 and of Q-34 to glycosyl Q-34; the importance of their effects are much more pronounced on the glycosylation of Q-34 than on the insertion of queuine. The effect of the nucleoside in position 37 is of particular importance in the case of yeast tRNAAsp: the replacement of the naturally occurring m1G-37 by an unmodified adenosine (as it is in X. laevis tRNAAsp), considerably increases the yield of the glycosylation reaction catalysed by the X. laevis tRNA-queuine glycosyltransferase.     

Nuclear Overhauser effect study and assignment of D stem and reverse-Hoogsteen base pair proton resonances in yeast tRNAAsp

Nuclear Overhauser effects (NOEs) in yeast tRNAAsp were found for all four GU and G psi base pairs. NOEs of both reverse-Hoogsteen pairs were identified by comparison with a purine C8 deuterated sample. Several NOEs involving these resonances were also found which are clearly between single protons on adjacent base pairs. These interbase NOEs, combined with the assumption of reasonable similarity between the structure of yeast tRNAAsp and that of yeast tRNAPhe, lead to unambiguous assignment of many resonances including all the ring NH and C2 protons in the D stem. The stability of the stem at 28 degrees C, as recently deduced by Moras et al (Nature 288 669-674), from x-ray diffraction is confirmed. Assignments of the ring NH resonances of T54-A58 and of a G psi pair are made for the first time.     

A theoretical study of the effect of structural variations on the biochemical reactivity of yeast tRNAPhe and yeast tRNAAsp

The ASIF index which combines both steric and electronic factors is applied to the comparative study of the reactivity of yeast tRNAAsp and yeast tRNAPhe using the coordinates deduced from their crystal structures. The results compared with the known experimental reactivities in solution are somewhat less perfect for tRNAAsp than for tRNAPhe. The reasons for this situation are probably related to the differences existing between the structures of tRNAAsp in the crystal and in solution.     

A primordial RNA modification enzyme: the case of tRNA (m1A) methyltransferase

The modified nucleoside 1-methyladenosine (m¹A) is found in the T-loop of many tRNAs from organisms belonging to the three domains of life (Eukaryota, Bacteria, Archaea). In the T-loop of eukaryotic and bacterial tRNAs, m¹A is present at position 58, whereas in archaeal tRNAs it is present at position(s) 58 and/or 57, m¹A57 being the obligatory intermediate in the biosynthesis of 1-methylinosine (m¹I57). In yeast, the formation of m¹A58 is catalysed by the essential tRNA (m¹A58) methyltransferase (MTase), a tetrameric enzyme that is composed of two types of subunits (Gcd14p and Gcd10p), whereas in the bacterium Thermus thermophilus the enzyme is a homotetramer of the TrmI polypeptide. Here, we report that the TrmI enzyme from the archaeon Pyrococcus abyssi is also a homotetramer. However, unlike the bacterial site-specific TrmI MTase, the P.abyssi enzyme is region-specific and catalyses the formation of m¹A at two adjacent positions (57 and 58) in the T-loop of certain tRNAs. The stabilisation of P.abyssi TrmI at extreme temperatures involves intersubunit disulphide bridges that reinforce the tetrameric oligomerisation, as revealed by biochemical and crystallographic evidences. The origin and evolution of m¹A MTases is discussed in the context of different hypotheses of the tree of life.     

Site-directed in vitro replacement of nucleosides in the anticodon loop of tRNA: application to the study of structural requirements for queuine insertase activity.

We have investigated the specificity of the enzymes Q-insertase and mannosyl-Q transferase that replace the guanosine at position 34 (wobble base) in the anticodon of several tRNAs by Q or mannosyl-Q derivatives. We have restructured in vitro the normal anticodon of yeast tRNA-Asp-GUC, yeast tRNAArgICG and yeast tRNALeuUAG. With yeast tRNA-Asp-GUC, we have replaced one or several nucleotides in the vicinity of G34 by one of the four canonical nucleotides or by pseudouridylic acid; we have also constructed a tRNAAsp with eight bases instead of seven in the anticodon loop. With yeast tRNAArgICG and yeast tRNALeuUAG, we have replaced their anticodon by the trinucleotide GUC, coding for aspartic acid. The chimerical tRNAs were microinjected into the cytoplasm of Xenopus laevis oocytes and after 72 h the amount of Q34 and mannosyl-Q34 incorporated was measured. Our results show that the U33G34U35 sequence, within an anticodon loop of seven bases in chimerical yeast tRNA-Asp-GUC, tRNAArgGUC or tRNALeuGUC, is the main determinant for Q-insertase activity at position 34; the rest of the tRNA sequence has only a slight influence. For mannosyl-Q transferase, however, a much broader structural feature of the tRNA than just the U33G34U35 sequence is important for the efficiency of Q34 transformation into mannosyl-Q34.     

Influence of tRNA tertiary structure and stability on aminoacylation by yeast aspartyl-tRNA synthetase.

Mutations have been designed that disrupt the tertiary structure of yeast tRNA(Asp). The effects of these mutations on both tRNA structure and specific aspartylation by yeast aspartyl-tRNA synthetase were assayed. Mutations that disrupt tertiary interactions involving the D-stem or D-loop result in destabilization of the base-pairing in the D-stem, as monitored by nuclease digestion and chemical modification studies. These mutations also decrease the specificity constant (kcat/Km) for aspartylation by aspartyl-tRNA synthetase up to 10(3)-10(4) fold. The size of the T-loop also influences tRNA(Asp) structure and function; change of its T-loop to a tetraloop (-UUCG-) sequence results in a denatured D-stem and an almost 10(4) fold decrease of kcat/Km for aspartylation. The negative effects of these mutations on aspartylation activity are significantly alleviated by additional mutations that stabilize the D-stem. These results indicate that a critical role of tertiary structure in tRNA(Asp) for aspartylation is the maintenance of a base-paired D-stem.     

Nucleotides in precursor tRNAs that are required intact for catalysis by RNase P RNAs.

Precursor tRNAAsp molecules, containing a 26-base 5' leader, were treated with diethylpyrocarbonate, 50% hydrazine or anhydrous hydrazine/3M NaCl and then subjected to processing by RNase P RNAs from Escherichia coli or Bacillus subtilis. Fully processed tRNAs and material not successfully cleaved by the catalytic RNAs were analyzed for their content of chemically altered nucleotides. Several bases were identified as being required intact for optimal activity as substrate as judged by exclusion of chemically modified residues from processed molecules, and simultaneous enhancement in material that was not recognized as substrate. Such nucleotides cluster near the site of cleavage at the mature 5' end and in the T stem and loop. Purines at residues 1 and 2 adjacent to the site of cleavage, position 57 in the T loop, and site 64 in the T stem exhibited the most pronounced effects. These results suggest a model of recognition of substrate by RNase P RNAs in which the ribozyme interacts with the corner of the precursor tRNA's three dimensional structure, where the T- and D-loops are juxtaposed, and extends along the top of the molecule back towards the site of catalysis.