Enzymatic conversion of guanosine 3'' adjacent to the anticodon of yeast tRNAPhe to N1-methylguanosine and the wye nucleoside: dependence on the anticodon sequence.

N1-Methylguanosine (m1G) or wye nucleoside (Y) are found 3' adjacent to the anticodon (position 37) of eukaryotic tRNAPhe. The biosynthesis of these two modified nucleosides has been investigated. The importance of the type of nucleosides in the anticodon of yeast tRNAPhe on the potentiality of this tRNA to be a substrate for the corresponding maturation enzyme has also been studied. This involved microinjection into Xenopus laevis oocytes and incubation in a yeast extract of restructured yeast tRNAPhe in which the anticodon GmAA and the 3' adjacent Y nucleoside were substituted by various tetranucleotides ending with a guanosine. The results obtained by oocyte microinjection indicate: that all the restructured yeast tRNAsPhe are efficient substrates for the tRNA (guanosine-37 N1)methyltransferase. This means that the anticodon sequence is not critical for the tRNA recognition by this enzyme; in contrast, for Y nucleoside biosynthesis, the anticodon sequence GAA is an absolute requirement; the conversion of G-37 into Y-37 nucleoside is a multienzymatic process in which m1G-37 is the first obligatory intermediate; all the corresponding enzymes are cytoplasmic. In a crude yeast extract, restructured yeast tRNAPhe with G-37 is efficiently modified only into m1G-37; the corresponding enzyme is a S-adenosyl-L-methionine-dependent tRNA methyltransferase. The pure Escherichia coli tRNA (guanosine-37 N1) methyltransferase is unable to modify the guanosine-37 of yeast tRNAPhe.     

Yeast tRNAPhe conformation wheels: a novel probe of the monoclinic and orthorhombic models.

A series of conformation wheels is constructed from the recently refined X-ray crystallographic data of monoclinic and orthorhombic yeast tRNAPhe. These circular plots relate the primary chemical structure (i.e., base sequence) directly to the secondary and tertiary structure of the molecule. The circular sequence of backbone torsion angles displays a unique pattern that is useful both in distinguishing the ordered and disordered regions of the molecule and in comparing the three sets of experimental data. Composite conformation wheels describe the fluctuations in the "fixed" parameters (phi', phi, chi) and independent conformation wheels reveal the changes in the "variable" parameters (omega', omega, psi, psi') of the three different yeast tRNAPhe models. Additional plots of base-stacking parameters help to visualize the intimate interrelationship between chemical sequence and three-dimensional folding of yeast tRNAPhe. The composite data illustrate several conformational schemes that position the bases of adjacent nucleosides in a parallel stacked array and reveal an even larger number of conformations that introduce bends or turns in the polynucleotide chain.     

Nuclear magnetic resonance studies on yeast tRNAPhe. II. Assignment of the iminoproton resonances of the anticodon and T stem by means of nuclear Overhauser effect experiments at 500 MHz.

Resonances of the water exchangeable iminoprotons of the T and anticodon stem of yeast tRNAPhe were assigned by means of Nuclear Overhauser Effects (NOE's). Together with our previous assignments of iminoproton resonances from the acceptor and D stem (A. Heerschap, C.A.G. Haasnoot and C.W. Hilbers (1982) Nucleic Acids Res. 10, 6981-7000) the present results constitute a complete assignment of all resonances of iminoprotons involved in the secondary structure of yeast tRNAPhe with a reliability and spectral resolution not reached heretofore. Separate identification of the methylprotons in m5C40 and m5C49 was also possible due to specific NOE patterns in the lowfield part of the spectrum. Our experiments indicate that in solution the psi 39 residue in the anticodon stem is orientated in a syn conformation in contrast to the normally observed anti orientation of the uracil base in AU basepairs. Evidence is presented that in solution the acceptor stem is stacked upon the T stem. Furthermore, it turns out that in a similar way the anticodon stem forms a continuous stack with the D stem, but here the m2(2)G26 residue is located between the latter two stems (as is found in the X-ray crystal structure). The stacking of these stems is not strictly dependent on the presence of magnesium ions. NOE experiments show that these structural features are preserved when proceeding from a buffer with magnesium ions to a buffer without magnesium ions although differences in chemical shifts and NOE intensities indicate changes in the conformation of the tRNA.     

RNA structure analysis using T2 ribonuclease: detection of pH and metal ion induced conformational changes in yeast tRNAPhe.

We describe the use of an enzymic probe of RNA structure, T2 ribonuclease, to detect alterations of RNA conformation induced by changes in Mg2+ ion concentration and pH. T2 RNase is shown to possess single-strand specificity similar to S1 nuclease. In contrast to S1 nuclease, T2 RNase does not require divalent cations for activity. We have used this enzyme to investigate the role of Mg2+ ions in the stabilization of RNA conformation. We find that, at neutral pH, drastic reduction of the available divalent metal ions results in a decrease in the ability of T2 RNase to cleave the anticodon loop of tRNAPhe. This change accompanies an increase in the cleavage of the molecule in the T psi C and in the dihydrouracil loops. Similar treatment of Tetrahymena thermophila 5S ribosomal RNA shows that changes in magnesium ion concentration does not have a pronounced effect on the cleavage pattern produced by T2 RNase. T2 RNase activity has a broader pH range than S1 nuclease and can be used to study pH induced conformational shifts in RNA structure. We find that upon lowering the pH from 7.0 to 4.5, nucleotide D16 in the dihydrouracil loop of tRNAPhe becomes highly sensitive to T2 RNase hydrolysis. This change accompanies a decrease in the relative sensitivity of the anticodon loop to the enzyme. The role of metal ion and proton concentrations in maintenance of the functional conformation of tRNAPhe is discussed.     

Unusual structures in single-stranded ribonucleic acid: proton nuclear magnetic resonance of AUCCA in deuterium oxide

Conformational features of the oligoribonucleic acid (oligo-RNA) A1-U2-C3-C4-A5 are explored by proton nuclear magnetic resonance (NMR). The sequence is a molecular cognate of a portion of the T psi C loop and stem regions of yeast tRNAPhe. The molecule forms at least two classes of flexible yet ordered structures. Class I states are similar in spectral properties to the component oligomers, AU, AUC, and AUCC, and are likely to be standard right-helical structures. Class II states are characterized by a 2'-endo pucker at A1 and unusually large shielding of several C3 and U2 protons. Most of these features are consistent with identifying the class II solution structures with the "arch" conformation for the T psi C region determined by X-ray crystallography of yeast tRNAPhe.     

Studies of yeast phenylalanine-accepting transfer ribonucleic acid backbone structure in solution by phosphorus-31 nuclear magnetic resonance spectroscopy.

Approximately 17 diester phosphates from the backbone structure of yeast tRNAPhe give rise to phosphorus resonances, which are resolved in its 31P NMR spectrum. To localize these diester phosphates within the tRNA structure, 31P NMR spectra of several chemically or enzymatically modified yeast tRNAPhe species were recorded. To this end selective modifications were performed in the anticodon, the DHU, and the T psi C loop. Modifications, performed in different loop regions, give rise to perturbation of different characteristic 31P resonances. The 31P spectra were correlated with the corresponding 1H NMR spectra of the ring N hydrogen-bonded protons and interpreted in view of the X-ray results obtained on yeast tRNAPhe. It is concluded that the diester phosphate groups, which experience an unusual shift, can be accounted for in the X-ray structure in terms of hydrogen-bonded phosphates groups and diester phosphates with a diester geometry, deviating from the normal double-helical conformation.     

The solution structure of a RNA pentadecamer comprising the anticodon loop and stem of yeast tRNAPhe. A 500 MHz 1H-n.m.r. study.

A 500 MHz 1H-n.m.r. study on the semi-synthetic RNA pentadecamer 5'-r(C-A-G-A-Cm-U-Gm-A-A-Y-A-psi-m5C-U-G) comprising the anticodon loop and stem (residues 28-42) of yeast tRNAPhe is presented. By using pre-steady-state nuclear-Overhauser-effect measurements all exchangeable and non-exchangeable base proton resonances, all H1' ribose resonances and all methyl proton resonances are assigned and over 70 intra- and inter-nucleotide interproton distances determined. From the distance data the solution structure of the pentadecamer is solved by model-building. It is shown that the pentadecamer adopts a hairpin-loop structure in solution with the loop in a 3'-stacked conformation. This structure is both qualitatively and quantitatively remarkably similar to that of the anticodon loop and stem found in the crystal structures of tRNAPhe with an overall root-mean-square difference of 0.12 nm between the interproton distances determined by n.m.r. and X-ray crystallography. The hairpin-loop solution structure of the pentadecamer is very stable with a 'melting' temperature of 53 degrees C in 500 mM-KCl, and the structural features responsible for this high stability are discussed. Interaction of the pentadecamer with the ribotrinucleoside diphosphate UpUpC, one of the codons for the amino acid phenylalanine, results only in minor perturbations in the structure of the pentadecamer, and the 3'-stacked conformation of the loop is preserved. The stability of the pentadecamer-UpUpC complex (K approximately 2.5 X 10(4) M-1 at 0 degrees C) is approximately an order of magnitude greater than that of the tRNAPhe-UpUpC complex.     

Probing structural elements in RNA using engineered disulfide cross-links.

Three analogs of unmodified yeast tRNAPhe, each possessing a single disulfide cross-link, have been designed and synthesized. One cross-link is between G1 and C72 in the amino acid acceptor stem, a second cross-link is in the central D region of yeast tRNAPhe between C11 and C25 and the third cross-link bridges U16 and C60 at the D loop/T loop interface. Air oxidation to form the cross-links is quantitative and analysis of the cross-linked products by native and denaturing PAGE, RNase T1 mapping, Pb(II) cleavage, UV cross-linking and thermal denaturation demonstrates that the disulfide bridges do not alter folding of the modified tRNAs relative to the parent sequence. The finding that cross-link formation between thiol-derivatized residues correlates with the position of these groups in the crystal structure of native yeast tRNAPhe and that the modifications do not significantly perturb native structure suggests that this methodology should be applicable to the study of RNA structure, conformational dynamics and folding pathways.     

Enzymatic 2''-O-methylation of the wobble nucleoside of eukaryotic tRNAPhe: specificity depends on structural elements outside the anticodon loop.

We have investigated the specificity of the enzyme tRNA (wobble guanosine 2'-O-)methyltransferase which catalyses the maturation of guanosine-34 of eukaryotic tRNAPhe to the 2'-O-methyl derivative Gm-34. This study was done by micro-injection into Xenopus laevis oocytes of restructured yeast tRNAPhe in which the anticodon GmAA and the 3' adjacent nucleotide 'Y' were substituted by various tetranucleotides. The results indicate that the enzyme is cytoplasmic; the chemical nature of the bases of the anticodon and its 3' adjacent nucleotide is not critical for the methylation of G-34; the size of the anticodon loop is however important; structural features beyond the anticodon loop are involved in the specific recognition of the tRNA by the enzyme since Escherichia coli tRNAPhe and four chimeric yeast tRNAs carrying the GAA anticodon are not substrates; unexpectedly, the 2'-O-methylation is not restricted to G-34 since C-34, U-34 and A-34 in restructured yeast tRNAPhe also became methylated. It seems probable that the tRNA (wobble guanosine 2'-O-)methyltransferase is not specific for the type of nucleotide-34 in eukaryotic tRNAPhe; however the existence in the oocyte of several methylation enzymes specific for each nucleotide-34 has not yet been ruled out.     

Fluorescent derivatives of yeast tRNAPhe.

The preparation of four fluorescent derivatives of tRNAPhe (yeast) and their characterization by chemical, spectroscopic, and biochemical methods is described. The derivatives are prepared by replacing wybutine (position 37 in the anticodon loop) or NaBH4-reduced dihydrouracil (positions 16/17 in the hU loop) with ethidium or proflavine; they are isolated by reversed-phase chromatography (RPC-5). All tRNAPhe-dye derivatives are aminoacylated by yeast phenylalanyl-tRNA synthetase to at least 80% of the charging capacity of the unmodified tRNAPhe with an unchanged Km (0.2 mucroM) and a V lowered by 30--50%. They exhibit good to excellent activity in the aminoacylation assay from synthetase from Escherichia coli. It is concluded that the insertion of the dyes does not seriously disturb essential elements of the native tRNAPhe structure. The dyes are bound via N-ribosylic linkages. The appearance of isomeric tRNAPhe-ethidium derivatives is attributed to the involvement of the different amino groups of ethidium in the condensation. In addition, there are indications for the existence of alpha and beta anomers of the tRNA-dye compounds. The dyes are rigidly fixed to their position in the tRNA molecule by stacking interactions with the neighboring bases. The ethidium probes show Mg2+-induced changes of the tRNA conformation which are paralleled by changes of the rate of aminoacylation. On the basis of this observation it is hypothesized that conformational flexibility of the tRNA molecule is a functionally important feature of the tRNA structure.     

Specificity of the photoreaction of 4'-(hydroxymethyl)-4,5',8-trimethylpsoralen with ribonucleic acid. Identification of reactive sites in Escherichia coli phenylalanine-accepting transfer ribonucleic acid

In order to test the potential of psoralen photoaddition for the probing of RNA conformation at sequence resolution, we have analyzed the specificity of the reaction of 4'-(hydroxymethyl)-4,5',8-trimethylpsoralen (HMT) with Escherichia coli tRNAPhe. The sites of HMT covalent addition have been identified by a combination of analytical techniques involving chemical cleavage of the tRNAPhe molecule at the m7G site and gel electrophoresis of RNase T1 digests together with paper electrophoretic characterization of HMT-modified nucleotides and oligonucleotides. In addition, we have taken advantage of the alteration of the cleavage rate of pancreatic RNase adjacent to a photoadduct. HMT photoaddition shows a very high preference for uracil residues. However, important differences in HMT photoreactivity are observed for various U sites of the tRNAPhe molecule. Reactivity of specific bases has been correlated with partial melting of the molecule. Data available so far indicate a strong preference of the photoreactive probe for a "loose" helical conformation as compared with a tight helix, whereas a random coil appears poorly reactive.     

Transfer RNA shields specific nucleotides in 16S ribosomal RNA from attack by chemical probes

Binding of tRNAPhe to ribosomes shields a set of highly conserved nucleotides in 16S rRNA from attack by a combination of structure-specific chemical probes. The bases can be classified according to whether or not their protection is strictly poly(U)-dependent (G529, G530, U531, A1408, A1492, and A1493) or poly(U)-independent (A532, G693, A794, C795, G926, 2mG966, G1338, A1339, U1381, C1399, C1400, and G1401). A third class (A790, G791, and A909) is shielded by both tRNA and 50S ribosomal subunits. Similar results are obtained when the protecting ligand is tRNAPhe E. Coli, tRNAPhe yeast, tRNAPhe E. Coli lacking its 3' terminal CA, or the 15 nucleotide anticodon stem-loop fragment of tRNAPhe yeast. Implications for structural correlates of the classic ribosomal A- and P-sites and for the possible involvement of 16S rRNA in translational proofreading are discussed.     

Evidence for the existence of an expressed minor variant tRNAPhe in yeast

Two expressed brewer's yeast tRNAsPhe, a major and a minor one, have been purified and sequenced. The major tRNAPhe corresponds to the already known tRNAPhe, whereas the minor one differs from the former in the substitution of T6-A67 by C6-G67 base pair in the "acceptor stem". The minor tRNAPhe contaminates all preparations of yeast tRNAPhe except those prepared by polyacrylamide gel electrophoresis.     

Chemical modification study of aminoacyl-tRNA conformation.

Chemical reactivity of cytosines in 32P-labeled E. coli tRNA1Leu, E. coli tRNAPhe and yeast tRNAPhe before and after aminoacylation was examined by use of a cytosine-specific reagent, semicarbazide-bisulfite mixture. In all the three tRNA species examined, the cytosine residues that were susceptible to the modification were the same in the aminoacylated tRNA and the unacylated tRNA. Only a limited number of the cytosine residues were modifiable: those that occur in the anticodon, the 3'-CCA terminus, the D-loop, and the extra loop. The sites accessible by the reagent are in good agreement with the general three-dimensional structure of tRNA proposed in literature. These results indicate that the gross conformation of these tRNAs does not change on aminoacylation, and consequently favor the view that the T psi C(G) sequence could become exposed in later steps of protein synthesis in order to achieve the binding of aminoacyl tRNA to ribosomes.     

Demonstration of a tertiary interaction in solution between the extra arm and the D-stem in two different transfer RNA''s by NMR.

According to the X-ray structure of yeast tRNAPhe at 2.5 A resolution, a hydrogen bond is formed between m7G46 and G22. By removal of this m7G46-residue we demonstrate that this interaction is present in solution as well. Comparison of the 1H 360 MHz NMR spectra of intact yeast tRNAPhe and its m7G-excised derivative locates the position of this tertiary H-bond at 12.5 ppm downfield from DSS. Additional evidence for the presence of this interaction in solution comes from a comparison of 1H NMR spectra of E. coli tRNAf1Met and E. coli tRNAf3Met, which differ only in a single position in the extra arm. In tRNAf3Met residue 47 is a m7G-residue, whereas in tRNAf3Met it is A, resulting in the absence of the m7G47 - G23 - C13 triple interaction, characteristic of tRNAf1Met. The resonance position of this tertiary interaction in tRNAf1Met is located around -13.6 ppm, a chemical shift difference of 1.1 ppm with respect to the position observed for tRNAPhe. The origin of this chemical shift difference is discussed in relation to the structure of their respective augmented D-helices.     

Proton nuclear magnetic resonance of minor nucleosides in yeast phenylalanine transfer ribonucleic acid. Conformational changes as a consequence of aminoacylation, removal of the Y base, and codon--anticodon interaction.

The assignments of the resonances of the methyl and methylene groups belonging to the residues dihydro-uridine-16 and -17 (C5 and C6), dimethylguanosine-26, N-2-methylguanosine-10, and 7-methylguanosine-46 of yeast tRNAPhe at low temperature are reported. Observing the high-field proton NMR spectral region at different temperatures, the effects of aminoacylation, removal of the Y base, and codon-anticodon interaction on the tertiary structure of yeast tRNAPhe were investigated. The following are the results of this study. (1) The two dihydrouridine residues of tRNAPhe have different environments in aqueous solution: dihydro-uridine-16 is more shielded than dihydrouridine-17. (2) The ribothymidine residue from the fragment (47--76) of yeast tRNAPhe and from a tRNA with a partially disrupted structure exhibits multiple conformations arising from different stacking modes between the ribothymidine-54 and the guanosine-53 residue. (3) Upon aminoacylation the type of guanosine-53 interaction with ribothymidine-54 in the tRNAPhe changes. (4) Removal of the Y base from the anticodon loop of yeast tRNAPhe weakens the thermal stability of the tertiary interactions. (5) The interaction of two complementary anticodons in the absence of proteins and of ribosomes results in stabilization of the tertiary structure. Codon-anticodon interaction dependent rearrangement of the tertiary structure of yeast tRNAPhe was not observed. The spin-lattice relaxation times of the methyl and methylene groups of the minor nucleosides in yeast tRNAPhe demonstrate that the minor nucleosides undergo rotational reorientation (tau c) in the nano-second range. The observed differences in these tau c values indicate a similarity of structure of tRNAPhe in solution and in crystalline form.     

Photoreaction of 8-methoxypsoralen with yeast-tRNAPhe. Identification of the major reaction sites

Yeast tRNAPhe was photoreacted with [3H]8-methoxypsoralen and the product was digested with ribonuclease T1, ribonuclease A or a combination of the two or cleaved with sodium borohydride/aniline. The oligonucleotides from these digestions were analyzed by polyacrylamide gel electrophoresis or high-pressure liquid chromatography and the psoralen-containing fragments were identified. The results indicate that one major and two minor photoreaction sites for 8-methoxypsoralen exist in yeast tRNAPhe. The major site (containing about 55% of the label) was determined as U50 in the T psi arm of the tRNA molecule while the minor sites were assigned to U59 (30% of the label) and C70 (15%) respectively. Our results suggest that psoralens may be used as photoprobes for studying conformational changes in tRNA molecules.     

On the conformation of serine-specific transfer RNA. Studies by small-angle X-ray scattering and ultraviolet absorption of the molecule in solution.

The scattered X-ray intensities from dilute solutions of tRNASer (yeast) in 0.1 M Soerensen buffer at pH 7.0 were measured at 25 degrees C. The radius of gyration, molecular weight and volume were determined. A model equivalent in scattering is given. The change of the conformation of tRNASer by heating was followed by small-angle X-ray measurements and ultraviolet absorption in a temperature range 20-70 degrees C. The molecule begins to unfold at about 40 degrees C and 70 degrees C has a random coil conformation. Addition of magnesium stabilizes the tRNASer molecule. The reversibility of the melting process was also studied by both methods. An interesting effect was found by ultraviolet absorption: by heating the tRNASer solutions to 55 degrees C and 60 degrees C and subsequently slowly cooling, the melting curves lie at higher absorption values than the corresponding cooling curves. The small-angle data and optical properties of tRNASer are compared with those of tRNAPhe which has already been thoroughly investigated.     

Structural and functional roles of the N1- and N3-protons of psi at tRNA's position 39.

Pseudouridine at position 39 (Psi(39)) of tRNA's anticodon stem and loop domain (ASL) is highly conserved. To determine the physicochemical contributions of Psi(39)to the ASL and to relate these properties to tRNA function in translation, we synthesized the unmodified yeast tRNA(Phe)ASL and ASLs with various derivatives of U(39)and Psi(39). Psi(39)increased the thermal stability of the ASL (Delta T (m)= 1.3 +/- 0.5 degrees C), but did not significantly affect ribosomal binding ( K (d)= 229 +/- 29 nM) compared to that of the unmodified ASL (K (d)= 197 +/- 58 nM). The ASL-Psi(39)P-site fingerprint on the 30S ribosomal subunit was similar to that of the unmodified ASL. The stability, ribosome binding and fingerprint of the ASL with m(1)Psi(39)were comparable to that of the ASL with Psi(39). Thus, the contribution of Psi(39)to ASL stability is not related to N1-H hydrogen bonding, but probably is due to the nucleoside's ability to improve base stacking compared to U. In contrast, substitutions of m(3)Psi(39), the isosteric m(3)U(39)and m(1)m(3)Psi(39)destabilized the ASL by disrupting the A(31)-U(39)base pair in the stem, as confirmed by NMR. N3-methylations of both U and Psi dramatically decreased ribosomal binding ( K (d)= 1060 +/- 189 to 1283 +/- 258 nM). Thus, canonical base pairing of Psi(39)to A(31)through N3-H is important to structure, stability and ribosome binding, whereas the increased stability and the N1-proton afforded by modification of U(39)to Psi(39)may have biological roles other than tRNA's binding to the ribosomal P-site.