1H NMR of valine tRNA modified bases. Evidence for multiple conformations.

Methyl and methylene protons of dihydrouridine 17 (hU), 6-methyladenosine 37 (M6A), 7-methylguanosine 46 (m7G), and ribothymidine 54 (rT) give clearly resolved peaks (220 MHz) for tRNA1val (coli solutions in D2O, 0.25 m NaCl, at 27 degrees C. Chemical shifts are generally consistent with a solution structure of tRNA1val similar to the crystal structure of tRNAphe (yeast). At least 3 separate transitions are observed as the temperature is raised. The earliest involves disruption of native tertiary structure and formation of intermediate structures in the m7G and rT regions. A second transition results in a change in structure of the anticodon loop, containing m6A. The final step involves unfolding of the m7G and rT intermediates and melting of the TpsiC helix. Low salt concentrations produce multiple, partially denatured conformations, rather than a unique form, for tRNA1val. Native structure is almost completely reformed by addition of Na+ but Mg2+ is required for correct conformation in the vicinity of m7G.     

Structure of transfer RNA by carbon NMR: resolution of single carbon resonances from 13C-enriched, purified species

Methyl carbon-13 NMR spectra of purified tRNA species are presented for the first time. In addition, these spectra of tRNA species specific for phenylalanine, tyrosine, and cysteine exhibited the first resolution of single methyl carbon resonances. Carbon-13 enriched methyl groups of ribothymidine (T) and 7-methylguanosine (m7G) and the methylthio group of 2-methylthio-N6-(delta2-isopentenyl) adenosine (ms2i6A) were resolved. The T methyl signal of tRNAPhe shifted from 12.3 ppm at 45 degrees in the absence of added Mg2+ to 11.1 ppm at 30 degrees in the presence of 10mM MgCl2. The same change in conditions led to a 0.4 ppm shift of the m7G methyl signal in the opposite direction. The relative ease in obtainment of single carbon resonances of purified tRNA species, and display of the sensitivity of their chemical shifts to changes in local structure, are requisite criteria for 13C-NMR to be a useful technique in probing tRNA conformation and its changes during interaction with proteins and other nucleic acids.     

Nucleotide sequence of a lysine tRNA from Bacillus subtilis.

A lysine tRNA (tRNA1Lys) was purified from Bacillus subtilis W168 by a consecutive use of several column chromatographic systems. The nucleotide sequence was determined to be pG-A-G-C-C-A-U-U-A-G-C-U-C-A-G-U-D-G-G-D-A-G-A-G-C-A-U-C-U-G-A-C-U-U(U*)-U-U-K-A-psi-C-A-G-A-G-G-m7G(G)-U-C-G-A-A-G-G-T-psi-C-G-A-G-U-C-C-U-U-C-A-U-G-G-C-U-C-A-C-C-AOH, where K and U* are unidentified nucleosides. The nucleosides of U34 and m7G46 were partially substituted with U* and G, respectively. The binding ability of lysyl-tRNA1Lys to Escherichia coli ribosomes was stimulated with ApApA as well as ApApG.     

Internal motions in yeast phenylalanine transfer RNA from 13C NMR relaxation rates of modified base methyl groups: a model-free approach

Internal motions at specific locations through yeast phenylalanine tRNA were measured by using nucleic acid biosynthetically enriched in 13C at modified base methyl groups. Carbon NMR spectra of isotopically enriched tRNA(Phe) reveal 12 individual peaks for 13 of the 14 methyl groups known to be present. The two methyls of N2,N2-dimethylguanosine (m22G-26) have indistinguishable resonances, whereas the fourteenth methyl bound to ring carbon-11 of the hypermodified nucleoside 3' adjacent to the anticodon, wyosine (Y-37), does not come from the [methyl-13C]methionine substrate. Assignments to individual nucleosides within the tRNA were made on the basis of chemical shifts of the mononucleosides [Agris, P. F., Kovacs, S. A. H., Smith, C., Kopper, R. A., & Schmidt, P. G. (1983) Biochemistry 22, 1402-1408; Smith, C., Schmidt, P. G., Petsch, J., & Agris, P. F. (1985) Biochemistry 24, 1434-1440] and correlation of 13C resonances with proton NMR chemical shifts via two-dimensional heteronuclear proton-carbon correlation spectroscopy [Agris, P. F., Sierzputowska-Gracz, H., & Smith, C. (1986) Biochemistry 25, 5126-5131]. Values of 13C longitudinal relaxation (T1) and the nuclear Overhauser enhancements (NOE) were determined at 22.5, 75.5, and 118 MHz for tRNA(Phe) in a physiological buffer solution with 10 mM MgCl2, at 22 degrees C. These data were used to extract two physical parameters that define the system with regard to fast internal motion: the generalized order parameters (S2) and effective correlation times (tau e) for internal motion of the C-H internuclear vectors.(ABSTRACT TRUNCATED AT 250 WORDS)     

Orientation of the tRNA anticodon in the ribosomal P-site: quantitative footprinting with U33-modified, anticodon stem and loop domains.

Binding of transfer RNA (tRNA) to the ribosome involves crucial tRNA-ribosomal RNA (rRNA) interactions. To better understand these interactions, U33-substituted yeast tRNA(Phe) anticodon stem and loop domains (ASLs) were used as probes of anticodon orientation on the ribosome. Orientation of the anticodon in the ribosomal P-site was assessed with a quantitative chemical footprinting method in which protection constants (Kp) quantify protection afforded to individual 16S rRNA P-site nucleosides by tRNA or synthetic ASLs. Chemical footprints of native yeast tRNA(Phe), ASL-U33, as well as ASLs containing 3-methyluridine, cytidine, or deoxyuridine at position 33 (ASL-m3U33, ASL-C33, and ASL-dU33, respectively) were compared. Yeast tRNAPhe and the ASL-U33 protected individual 16S rRNA P-site nucleosides differentially. Ribosomal binding of yeast tRNA(Phe) enhanced protection of C1400, but the ASL-U33 and U33-substituted ASLs did not. Two residues, G926 and G1338 with KpS approximately 50-60 nM, were afforded significantly greater protection by both yeast tRNA(Phe) and the ASL-U33 than other residues, such as A532, A794, C795, and A1339 (KpS approximately 100-200 nM). In contrast, protections of G926 and G1338 were greatly and differentially reduced in quantitative footprints of U33-substituted ASLs as compared with that of the ASL-U33. ASL-m3U33 and ASL-C33 protected G530, A532, A794, C795, and A1339 as well as the ASL-U33. However, protection of G926 and G1338 (KpS between 70 and 340 nM) was significantly reduced in comparison to that of the ASL-U33 (43 and 61 nM, respectively). Though protections of all P-site nucleosides by ASL-dU33 were reduced as compared to that of the ASL-U33, a proportionally greater reduction of G926 and G1338 protections was observed (KpS = 242 and 347 nM, respectively). Thus, G926 and G1338 are important to efficient P-site binding of tRNA. More importantly, when tRNA is bound in the ribosomal P-site, G926 and G1338 of 16S rRNA and the invariant U33 of tRNA are positioned close to each other.     

Composition and Characterization of tRNA from Methanococcus vannielii.

Purified bulk tRNA from Methanococcus vanielii (carbon source, formate) showed variation in the modified nucleoside pattern reported for Escherichia coli as analyzed by both ion-exchange and thin-layer chromatography. Ribothymidine and 7-methylguanosine were absent; 1-methyladenosine, 1-methylguanosine, N2-methylguanosine, N2,N2-dimethylguanosine, thiolated nucleosides, pseudouridine, dihydrouridine, and O2'-methylcytidine were quantitated. In vitro methylation by M. Vannielii extracts with S-adenosylmethionine and undermethylated E. coli tRNA revealed active tRNA methyltransferases for formation of methylated residues found in native M. vannielii tRNA, but none for the formation of 7-methylguanosine or ribothymidine. The native M. vannielii tRNA became methylated in the 7-methylguanosine position by E. Coli extracts, but ribothymidine was not formed. Both M. vannielii and E. coli tRNA methyltransferases produced unidentified methylated residues in tRNA's lacking or deficient in ribothymidine.     

A cell-free plant extract for accurate pre-tRNA processing, splicing and modification.

An intron-containing tobacco tRNA(Tyr) precursor synthesized in a HeLa cell nuclear extract has been used to develop a cell-free processing and splicing system from wheat germ. Removal of 5' and 3' flanking sequences, accurate excision of the intervening sequence, ligation of the resulting tRNA halves, addition of the 3'-terminal CCA sequence and modification of seven nucleosides were achieved in appropriate wheat germ S23 and S100 extracts. The maturation of pre-tRNA(Tyr) in these extracts resembles the pathway observed in vivo for tRNA biosynthesis in Xenopus oocytes and yeast in that processing of the flanks precedes intron excision. Most of the modified nucleosides (m2(2) G, psi 35, psi 55, m7G and m1A) are introduced into the intron-containing pre-tRNA with mature ends, whereas two others (m1G and psi 39) are only found in the mature tRNA(Tyr). Processing and splicing proceed very efficiently in the wheat germ extracts, leading to complete maturation of 5' and 3' ends followed by about 65% conversion to mature tRNA(Tyr) under our standard conditions. The activity of the wheat germ endonuclease is stimulated 3-fold by the non-ionic detergent Triton X-100. All previous attempts to demonstrate the presence of a splicing endonuclease in wheat germ had failed (Gegenheimer et al., 1983). Hence, this is the first cell-free plant extract which supports pre-tRNA processing and splicing in vitro.     

Immunospecific retention of oligonucleotides possessing N6-methyladenosine and 7-methylguanosine.

Antibodies specific for N6-methyladenosine (m6A) and for 7-methylguanosine (m7G) were immobilized on Sepharose and the resulting immunoadsorbents tested for their ability to retain specific oligonucleotides possessing the corresponding antigenic haptens (i.e. m6A and m7G). Results obtained with oligonucleotides derived from ribonuclease T1 digests of Escherichia coli tRNA (previously labeled with [methyl-3H]methionine) indicated that each immunoadsorbent quantitatively and exclusively retained those methyl-3H-labeled oligonucleotides possessing [methyl-3H]m6A and [methyl-3H]m7G. Elution and subsequent characterization of the retained methyl-3H-labeled oligonucleotides via DEAE-cellulose chromatography revealed the presence of several small oligonucleotides containing m7G and a single, larger oligonucleotide containing m6A. These findings are in accord with previously sequenced structures which indicate that numerous bacterial tRNA species possess m7G while only tRNAVal contains m6A.     

Nuclear magnetic resonance signal assignments of purified [13C]methyl-enriched yeast phenylalanine transfer ribonucleic acid

Yeast tRNA Phe, enriched in carbon-13 specifically at the naturally occurring methyl groups, has been produced through biosynthesis, then purified, and analyzed. Transfer RNA Phe was purified from the [13C]methyl-enriched, unfractionated tRNA that had been extracted from a methionine auxotroph of Saccharomyces cerevisiae [Agris, P. F., Kovacs, S. A. H., Smith, C., Kopper, R. H., & Schmidt, P. G. (1983) Biochemistry 22, 1402-1408]. The yeast had been grown in minimal medium supplemented with [13C]methylmethionine. Transfer RNA Phe purity and the full extent of nucleoside modification were confirmed by high-performance liquid chromatography of constituent nucleosides with simultaneous UV spectral identification and quantitation. Mass spectometry of [13C]methyl-enriched nucleosides and NMR of the tRNA indicated an enrichment of at least 70 atom %. Twelve resolved and prominent carbon-13 NMR signals from the tRNA were seen between 10 and 60 ppm. These have been assigned to 13 of the 14 naturally occurring methyl groups. However, the partially resolved signals assigned to the two 5-methylcytidines could not be assigned to their specific nucleoside positions of either 40 or 49 in the molecule. In addition, the partially resolved signals of the two methyl esters of wybutosine could not be distinguished. The methyl group found not to be enriched with 13C is bound to the ring carbon in the hypermodified nucleoside wybutosine (Y). A 13th enriched signal downfield (120.9 ppm) has been assigned to one of the two carbons added to guanosine to form the third ring in the biosynthesis of Y. The 13C enrichment of this ring carbon demonstrates its origin from the methionine methyl group.(ABSTRACT TRUNCATED AT 250 WORDS)     

Comparison of the tertiary structure of yeast tRNA(Asp) and tRNA(Phe) in solution. Chemical modification study of the bases

A comparative study of the solution structures of yeast tRNA(Asp) and tRNA(Phe) was undertaken with chemical reagents as structural probes. The reactivity of N-7 positions in guanine and adenine residues was assayed with dimethylsulphate and diethyl-pyrocarbonate, respectively, and that of the N-3 position in cytosine residues with dimethylsulphate. Experiments involved statistical modifications of end-labelled tRNAs, followed by splitting at modified positions. The resulting end-labelled oligonucleotides were resolved on polyacrylamide sequencing gels and analysed by autoradiography. Three different experimental conditions were used to follow the progressive denaturation of the two tRNAs. Experiments were done in parallel on tRNA(Asp) and tRNA(Phe) to enable comparison between the two solution structures and to correlate the results with the crystalline conformations of both molecules. Structural differences were detected for G4, G45, G71 and A21: G4 and A21 are reactive in tRNA(Asp) and protected in tRNA(Phe), while G45 and G71 are protected in tRNA(Asp) and reactive in tRNA(Phe). For the N-7 atom of A21, the different reactivity is correlated with the variable variable loop structures in the two tRNAs; in the case of G45 the results are explained by a different stacking of A9 between G45 and residue 46. For G4 and G71, the differential reactivities are linked to a different stacking in both tRNAs. This observation is of general significance for helical stems. If the previous results could be fully explained by the crystal structures, unexpected similarities in solution were found for N-3 alkylation of C56 in the T-loop, which according to crystallography should be reactive in tRNA(Asp). The apparent discrepancy is due to conformational differences between crystalline and solution tRNA(Asp) at the level of the D and T-loop contacts, linked to long-distance effects induced by the quasi-self-complementary anticodon GUC, which favour duplex formation within the crystal, contrarily to solution conditions where the tRNA is essentially in its free state.     

Thermospray liquid chromatography-mass spectrometry of nucleosides and of enzymatic hydrolysates of nucleic acids.

Nucleosides dissolved in aqueous buffered solutions undergo ionization during direct introduction of the solution into a mass spectrometer using a thermospray interface. The principal ions formed represent the protonated molecule, the corresponding protonated free base, and sugar. In addition to potential utility for characterization of new nucleosides, the technique can be used to monitor nucleosides separated from enzymatic hydrolysates by liquid chromatography. The selectivity of chromatographic detection is significantly greater than with UV absorbance alone so that independent detection of components of unresolved chromatographic peaks is usually possible. Detection limits, with signal/noise greater than 10 for most nucleosides, are approximately 0.1-1 ng per component for selected ion monitoring and 10-50 ng for full-scan mass spectra. Examples are given from the detection of modified nucleosides in enzymatic hydrolysates of 0.05 A260 units (2.5 micrograms) of rabbit liver tRNAVal and of unfractionated H. volcanii tRNA.     

Suppression of the serT42 mutation with modified tRNA(1Ser) and tRNA(5Ser) genes.

Serine tRNA gene derivatives with altered anticodons were introduced to the temperature-sensitive serT42 mutant, whose tRNA(1Ser) shows a base substitution of A10 for wild type G10. When a low copy number vector-system was used, the growth and beta-galactosidase synthetic activity of the serT42 mutant were restored by complementation with the tRNA(5Ser) (T34) gene or the tRNA(1Ser) (G34) gene as well as the tRNA(1Ser) (wt) gene, but not with tRNA(5Ser) (wt), tRNA(1Ser) (A34) or tRNA(1Ser) (C34) genes at 42 degrees C. When multicopy vectors were used, the transformation even with tRNA(1Ser) (A10) gene restored the growth and beta-galactosidase synthetic activity at 42 degrees C. The tRNA(1Ser) (A10) showed no thermosensitivity in serine acceptor activity by in vitro assay. At 42 degrees C, the amount of tRNA(1Ser) (A10) in the serT42 mutant was almost the same as those in the wild type. The nucleotides in the tRNA(1Ser) (A10) were found to be fully modified like those in the wild type tRNA(1Ser). Both of the tRNAs transcribed from tRNA(5Ser) (T34) and tRNA(1Ser) (G34) genes showed serine acceptor activity. Modified nucleosides of these tRNAs were also analyzed.     

Determination of the DNA sugar pucker using 13C NMR spectroscopy

Solid-state 13C NMR spectroscopy of a series of crystalline nucleosides and nucleotides allows direct measurement of the effect of the deoxyribose ring conformation on the carbon chemical shift. It is found that 3'-endo conformers have 3' and 5' chemical shifts significantly (5-10 ppm) upfield of comparable 3'-exo and 2'-endo conformers. The latter two conformers may be distinguished by smaller but still significant differences in the carbon chemical shifts at the C-2' and C-4' positions. High-resolution solid-state NMR of three modifications of fibrous calf thymus DNA shows that these trends are maintained in high-molecular-weight DNA and confirms that the major ring pucker in A-DNA is 3'-endo, while both B-DNA and C-DNA are largely 2'-endo. The data show that 13C NMR spectroscopy is a straightforward and useful probe of DNA ring pucker in both solution and the solid state.     

Chemical and physical properties of mammalian mitochondrial aminoacyl-transfer RNAs. II. Analysis of 7-methylguanosine in mitochondrial and cytosolic aminoacyl-transfer RNAs.

The 7-methylguanosine (m7G) content of two individual mitochondrial tRNAs, labelled in the aminoacyl moiety was assayed by the specific cleavage of the tRNA at this nucleotide followed by electrophoretic analysis to identify the 3'-terminal fragment of the tRNA. Neither Syriam hamster mitochondrial tRNALeu nor tRNAMet were found to contain m7G. In contrast, cytosolic tRNAMetS were cleaved indicating the presence of m7G, apparently 27--28 and 29 nucleotides from their 3' terminus. Cystolic tRNALeu was not cleaved. These results are discussed in relationship to the reported low content of methylated nucleosides in mitochondrial 4 S RNA.     

1H n.m.r. parameters of the N-terminal 19-residue S-peptide of ribonuclease in aqueous solution

The 1H n.m.r. chemical shifts and the spin-spin coupling constants of the N-terminal 19-residue S-peptide of ribonuclease A have been measured in a 10 mM solution in D2O, pD 3.0, 27 degrees, at 300 MHz. The titration parameters for end groups Lys-1 and Ala-19 and side chains Lys-1, Glu-2, Lys-7, Glu-9, Arg-10, His-12 and Asp-14 have been determined at 90 MHz. An assignment of observed signals to individual residue protons based upon characteristic shifts, spectral analysis, double resonance, titration shifts and comparison with the spectrum of C-peptide (N-terminal 13-residue) is proposed. Differences in the observed chemical shifts, pKa's and titration shifts with reference to those proposed as "random coil" parameters are not large enough to assume the existence of a significant population of secondary structure in the conditions studied. The H alpha chemical shifts differences can be accounted for by the Phe-8 phenyl ring current for an extended peptide backbone conformation and appropriate values for the torsion angles chi 1 Phe-8 and chi 2 Phe-8.