Imino proton NMR assignments and ion-binding studies on Escherichia coli tRNA3Gly

The imino region of the proton NMR spectrum of Escherichia coli tRNA3Gly has been assigned mainly by sequential nuclear Overhauser effects between neighbouring base pairs and by comparison of assignments of other tRNAs. The effects of magnesium, spermine and temperature on the 1H and 31P NMR spectra of this tRNA were studied. Both ions affect resonances close to the G15 . C48 tertiary base pair and in the ribosylthymine loop. The magnesium studies indicate the presence of an altered tRNA conformer at low magnesium concentrations in equilibrium with the high magnesium form. The temperature studies show that the A7 . U66 imino proton (from a secondary base pair) melts before some of the tertiary hydrogen bonds and that the anticodon stem does not melt sequentially from the ends. Correlation of the ion effects in the 1H and 31P NMR spectra has led to the tentative assignment of two 31P resonances not assigned in the comparable 31P NMR spectrum of yeast tRNAPhe. 31P NMR spectra of E. coli tRNA3Gly lack resolved peaks corresponding to peaks C and F in the spectra of E. coli tRNAPhe and yeast tRNAPhe. In the latter tRNAs these peaks have been assigned to phosphate groups in the anticodon loop. Ion binding E. coli tRNA3Gly and E. coli tRNAPhe had different effects on their 1H NMR spectra which may reflect further differences in their charge distribution and conformation.     

The wobble hypothesis revisited: uridine-5-oxyacetic acid is critical for reading of G-ending codons

According to Crick's wobble hypothesis, tRNAs with uridine at the wobble position (position 34) recognize A- and G-, but not U- or C-ending codons. However, U in the wobble position is almost always modified, and Salmonella enterica tRNAs containing the modified nucleoside uridine-5-oxyacetic acid (cmo⁵U34) at this position are predicted to recognize U- (but not C-) ending codons, in addition to A- and G-ending codons. We have constructed a set of S. enterica mutants with only the cmo⁵U-containing tRNA left to read all four codons in the proline, alanine, valine, and threonine family codon boxes. From the phenotypes of these mutants, we deduce that the proline, alanine, and valine tRNAs containing cmo⁵U read all four codons including the C-ending codons, while the corresponding threonine tRNA does not. A cmoB mutation, leading to cmo⁵U deficiency in tRNA, was introduced. Monitoring A-site selection rates in vivo revealed that the presence of cmo⁵U34 stimulated the reading of CCU and CCC (Pro), GCU (Ala), and GUC (Val) codons. Unexpectedly, cmo⁵U is critical for efficient decoding of G-ending Pro, Ala, and Val codons. Apparently, whereas G34 pairs with U in mRNA, the reverse pairing (U34-G) requires a modification of U34.     

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.     

Footprinting mRNA-ribosome complexes with chemical probes.

We footprinted the interaction of model mRNAs with 30S ribosomal subunits in the presence or absence of tRNA(fMet) or tRNA(Phe) using chemical probes directed at the sugar-phosphate backbone or bases of the mRNAs. When bound to the 30S subunits in the presence of tRNA(fMet), the sugar-phosphate backbones of gene 32 mRNA and 022 mRNA are protected from hydroxyl radical attack within a region of about 54 nucleotides bounded by positions -35 (+/- 2) and +19, extending to position +22 when tRNA(Phe) is used. In 70S ribosomes, protection is extended in the 5' direction to about position -39 (+/- 2). In the absence of tRNA, the 30S subunit protects only nucleotides -35 (+/- 2) to +5. Introduction of a stable tetraloop hairpin between positions +10 and +11 of gene 32 mRNA does not interfere with tRNA(fMet)-dependent binding of the mRNA to 30S subunits, but results in loss of protection of the sugar-phosphate backbone of the mRNA downstream of position +5. Using base-specific probes, we find that the Shine-Dalgarno sequence (A-12, A-11, G-10 and G-9) and the initiation codon (A+1, U+2 and G+3) of gene 32 mRNA are strongly protected by 30S subunits in the presence of initiator tRNA. In the presence of tRNA(Phe), the same Shine-Dalgarno bases are protected, as are U+4, U+5 and U+6 of the phenylalanine codon. Interestingly, A-1, immediately preceding the initiation codon, is protected in the complex with 30S subunits and initiator tRNA, while U+2 and G+3 are protected in the complex with tRNA(Phe) in the absence of initiator tRNA. Additionally, specific bases upstream from the Shine-Dalgarno region (U-33, G-32 and U-22) as well as 3' to the initiation codon (G+11) are protected by 30S subunits in the presence of either tRNA. These results imply that the mRNA binding site of the 30S subunit covers about 54-57 nucleotides and are consistent with the possibility that the ribosome interacts with mRNA along its sugar-phosphate backbone.     

The role of 5-methylcytidine in the anticodon arm of yeast tRNA(Phe): site-specific Mg2+ binding and coupled conformational transition in DNA analogs.

The tDNA(Phe)AC, d(CCAGACTGAAGAU13m5C14U15GG), with a DNA sequence similar to that of the anticodon stem and loop of yeast tRNA(Phe), forms a stem and loop structure and has an Mg(2+)-induced structural transition that was not exhibited by an unmodified tDNA(Phe)AC d(T13C14T15) [Guenther, R. H., Hardin, C. C., Sierzputowska-Gracz, H., Dao, V., & Agris, P. F. (1992) Biochemistry (preceding paper in this issue)]. Three tDNA(Phe)AC molecules having m5C14, tDNA(Phe)AC d(U13m5C14U15), d(U13m5C14T15), and d(T13,5C14U15), also exhibited Mg(2+)-induced structural transitions and biphasic thermal transitions (Tm approximately 23.5 and 52 degrees C), as monitored by CD and UV spectroscopy. Three other tDNA(Phe)AC, d(T13C14T15), d(U13C14U15), and d(A7;U13m5C14U15) in which T7 was replaced with an A, thereby negating the T7.A10 base pair across the anticodon loop, had no Mg(2+)-induced structural transitions and only monophasic thermal transitions (Tm of approximately 52 degrees C). The tDNA(Phe)AC d(U13m5C14U15) had a single, strong Mg2+ binding site with a Kd of 1.09 x 10(-6) M and a delta G of -7.75 kcal/mol associated with the Mg(2+)-induced structural transition. In thermal denaturation of tDNA(Phe)AC d(U13m5C14U15), the 1H NMR signal assigned to the imino proton of the A5.dU13 base pair at the bottom of the anticodon stem could no longer be detected at a temperature corresponding to that of the loss of the Mg(2+)-induced conformation from the CD spectrum. Therefore, we place the magnesium in the upper part of the tDNA hairpin loop near the A5.dU13 base pair, a location similar to that in the X-ray crystal structure of native, yeast tRNA(Phe).(ABSTRACT TRUNCATED AT 250 WORDS)     

Influence of the polyamines spermine and spermidine on yeast tRNAPhe as revealed from its imino proton NMR spectrum.

A comparison of imino proton NMR spectra of yeast tRNAPhe recorded at various solution conditions indicates, that polyamines have a limited effect on the structure of this tRNA molecule. Polyamines are found to catalyse the solvent exchange of several imino protons in yeast tRNAPhe not only of non hydrogen bonded imino protons, but also of imino protons of the GU and of some AU and tertiary base pairs. It is concluded that at low levels of catalysing components the exchange rates of the latter protons are not determined by the base pair lifetime. In the presence of high levels of spermidine the solvent exchange rates of imino protons of several base pairs in the molecule were assessed as a function of the temperature. Apparent activation energies derived from these rates were found to be less than 80 kJ/mol, which is indicative for (transient) independent opening of the corresponding base pairs. In the acceptor helix the GU base pair acts as a dynamic dislocation. The AU base pairs at one side of the GU base pair exhibit faster transient opening than the GC base pairs on the other side of this wobble pair. The base pairs m2GC10 and GC11 from the D stem and GC28 from the anticodon stem show relatively slow opening up to high temperatures. Model studies suggest that 1-methyladenosine, an element of tRNA itself, catalyses imino proton solvent exchange in a way similar to polyamines.     

Pulsed FT-NMR double resonance studies of yeast tRNAPhe: specific nuclear Overhauser effects and reinterpretation of low temperature relaxation data.

Cross-relaxation effects are demonstrated between the imino protons and other protons in yeast tRNAPhe and H2O. A detailed examination has been made of the observed relaxation rate of the proton resonance at 11.8 ppm from DSS as a function of the D2O content in the solvent. This result, as well as the size and number of observed nuclear Overhauser effects, suggests that dipolar magnetization transfer between solvent H2O, amino, imino, and other tRNA protons may dominate the relaxation processes of the imino protons at low temperature. At higher temperatures the observed relaxation rate is dominated by chemical exchange. The selective nuclear Overhauser effects are shown to be an important aid in resonance assignments. By these means we were able to identify tow protons from the wobble base pair GU4 at 11.8 ppm and 10.4 ppm.     

Characterization of the lead(II)-induced cleavages in tRNAs in solution and effect of the Y-base removal in yeast tRNAPhe

The specificity of lead(II)-induced hydrolysis of yeast tRNA(Phe) was studied as a function of concentration of Pb2+ ions. The major cut was localized in the D-loop and minor cleavages were detected in the anticodon and T-loops at high metal ion concentration. The effects of pH, temperature, and urea were also analyzed, revealing a basically unchanged specificity of hydrolysis. In the isolated 5'-half-molecule of yeast tRNAPhe not cut was found in the D-loop, indicating its stringent dependence on T-D-loop interaction. Comparison of hydrolysis patterns and efficiencies observed in yeast tRNA(Phe) with those found in other tRNAs suggests that the presence of a U59-C60 sequence in the T-loop is responsible for the highly efficient and specific hydrolysis in the spatially close region of the D-loop. The efficiencies of D-loop cleavage in intact yeast tRNA(Phe) and in tRNA(Phe) deprived of the Y base next to the anticodon were also compared at various Pb2+ ion concentrations. Kinetics of the D-loop hydrolysis analyzed at 0, 25, and 37 degrees C showed a 6 times higher susceptibility of tRNA(Phe) minus Y base (tRNA(Phe)-Y) to lead(II)-induced hydrolysis than in tRNA(Phe). The observed effect is discussed in terms of a long-distance conformational transition in the region of the interacting D- and T-loops triggered by the Y-base excision.     

Assignment of imino proton spectra of yeast phenylalanine transfer ribonucleic acid

Yeast tRNAPhe has been studied by using proton NMR and nuclear Overhauser effect (NOE) with deuterium substitution. Direct NOE evidence is presented for assignment of imino resonances of 23 of 27 base pairs in this tRNA. Other indirect evidence is presented for tentative assignment of four other base pairs. Almost total assignment also has been made of the important noninternally bonded imino protons and tertiary interactions (however, G18-psi 55 remains unassigned). The most surprising result has been identification of GC11 at -13.68 ppm; this is the first time a GC base pair has been identified so far downfield. This peak (GC11) is also identified as the resonance of the unique imino proton that exchanges in a time of more than 1 day, as previously described. These identifications of imino proton resonances made it possible to reinterpret the proton solvent exchange rate data previously published on this tRNA and understand them better. The assignments of resonances should pave the way for more detailed solution study of this tRNA and its interaction with biologically relevant molecules.     

19F NMR of 5-fluorouracil-substituted transfer RNA transcribed in vitro: resonance assignment of fluorouracil-guanine base pairs.

5-Fluorouracil is readily incorporated into active tRNA(Val) transcribed in vitro from a recombinant phagemid containing a synthetic E. coli tRNA(Val) gene. This tRNA has the expected sequence and a secondary and tertiary structure resembling that of native 5-fluorouracil-substituted tRNA(Val), as judged by 19F NMR spectroscopy. To assign resonances in the 19F spectrum, mutant phagemids were constructed having base changes in the tRNA gene. Replacement of fluorouracil in the T-stem with cytosine, converting a FU-G to a C-G base pair, results in the loss of one downfield peak in the 19F NMR spectrum of the mutant tRNA(Val). The spectra of other mutant tRNAs having guanine for adenine substitutions that convert FU-A to FU-G base pairs all have one resonance shifted 4.5 to 5 ppm downfield. These results allow assignment of several 19F resonances and demonstrate that the chemical shift of the 19F signal from base-paired 5-fluorouracil differs considerably between Watson-Crick and wobble geometry.     

Study of the structure of the duplex (Phn-NH(CH2)2NH)pd(CCAAACA) .pd(TGTTTGGC) with covalently bound 10-(2-hydroxyethyl)phenazine in an aqueous solution by 2D-1H-NMR spectroscopy]

The spatial structure of duplex (Phn-NH(CH2)2NH)pd(CCAAACA).pd(TGTTTGGC) having a N-(2-oxyethyl)-phenazinium residue covalently linked with the 5'-terminal phosphate of the heptanucleotide was studied by means of one- and two-dimensional 1H-NMR spectroscopy. The resonances of phenazinium protons, ethylenediamine linker protons, as well as, oligonucleotide H5/H6/H8/CH3 base protons and H1',H2'a, H2'b, H3', H4' deoxyribose protons have been assigned by means of 1H-COSY, 1H-NOESY and 1H-13C-COSY. The presence of the phenazine residue in duplex causes an additional imino proton signal of the terminal (G-7).(C-1) base pair, suggesting a higher stability of the duplex (Phn-NH(CH2)2NH)pd(CCAAACA).pd(TGTTTGGC) as compared to the unmodified duplex pd(CCAAACA).pd(TGTTTGGC). Analysis of NOE interactions between protons of the dye and the oligonucleotides show the phenazinium polycyclic system to intercalate between G-7 and C-8 residues of the octanucleotide.     

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).     

Structural studies on tRNA acceptor stem microhelices: exchange of the discriminator base A73 for G in human tRNALeu switches the acceptor specificity from leucine to serine possibly by decreasing the stability of the terminal G1-C72 base pair.

Correct recognition of transfer RNAs (tRNAs) by aminoacyl-tRNA synthetases (aaRS) is crucial to the maintenance of translational fidelity. The discriminator base A73 in human tRNALeuis critical for its specific recognition by the aaRS. Exchanging A73 for G abolishes leucine acceptance and converts it into a serine acceptor in vitro . Two RNA microhelices of 24 nt length that correspond to the tRNALeuacceptor stem and differ only in the discriminator base were synthesized: a wild-type tRNALeumicrohelix, where nt 21 corresponds to the discriminator base position 73, and an A21G mutant microhelix. To investigate whether different identities of both tRNAs are caused by conformational differences, NMR and UV melting experiments were performed on both microhelices. Two-dimentional NOESY spectra showed both microhelices to exhibit the same overall conformation at their 3'-CCA ends. Thermodynamic analysis and melting behaviour of the base-paired imino protons observed by NMR spectroscopy suggest that the A21G (A73G in tRNA) exchange results in a decrease of melting transition cooperativity and a destabilization of the terminal G1-C20 (G1-C72 in tRNA) base pair. Furthermore, the fact that this 3'-terminal imino proton is more solvent-exposed at physiological temperature might be another indication for the importance of the stability of the terminal base pair for specific tRNA recognition.     

2'-O-methylation and inosine formation in the wobble position of anticodon-substituted tRNA-Phe in a homologous yeast in vitro system.

Four variants of yeast tRNA-Phe in which the anticodon and 3'-adjacent nucleotide (GmAAY) have been replaced by synthetic tetranucleotides NAAG (where N is each of the four canonical nucleosides G, C, U or A) are substrates for a yeast tRNA modification enzyme which catalyses the S-adenosyl-L-methionine dependent formations of Gm-34, Cm-34, Um-34, Am-34 and Im-34 (where Nm represents a 2'-O-methylnucleoside and I inosine). The kinetics of these nucleosides-34 2'-O-methylations reveal that yeast tRNA-Phe with G-34 (the natural substrate) is less efficiently modified than variants of the same tRNA containing U-34 and C-34. The formation of Am-34 in the tRNA containing A-34 was found to be particularly inefficient. However, in this tRNA, we observed the formation of I-34 followed by a 2'-O-methylation (giving rise to Im-34). In the yeast in vitro system described here, inosine formation is not dependent on the addition of any cofactor including hypoxanthine; the mechanism of inosine formation in yeast tRNA might therefore be distinct from that found in higher eukaryotes.     

tRNA Binding to Antitumor Drug Doxorubicin and Its Analogue

The binding sites of antitumor drug doxorubicin (DOX) and its analogue N-(trifluoroacetyl) doxorubicin (FDOX) with tRNA were located, using FTIR, CD, fluorescence spectroscopic methods and molecular modeling. Different binding sites are involved in drug-tRNA adducts with DOX located in the vicinity of A-29, A-31, A-38, C-25, C-27, C-28, G-30 and U-41, while FDOX bindings involved A-23, A-44, C-25, C-27, G-24, G-42, G-53, G-45 and U-41 with similar free binding energy (-4.44 for DOX and -4.41 kcal/mol for FDOX adducts). Spectroscopic results showed that both hydrophilic and hydrophobic contacts are involved in drug-tRNA complexation and FDOX forms more stable complexes than DOX with K _DOX-tRNA = 4.7 (±0.5)×10⁴ M⁻¹ and K _FDOX-tRNA = 6.3 (±0.7)×10⁴ M⁻¹. The number of drug molecules bound per tRNA (n) was 0.6 for DOX and 0.4 for FDOX. No major alterations of tRNA structure were observed and tRNA remained in A-family conformation, while biopolymer aggregation and particle formation occurred at high drug concentrations.     

Nuclear magnetic resonance studies on the tertiary folding of transfer ribonucleic acid: assignment of the 7-methylguanosine resonance.

Analysis of the low-field nuclear magnetic resonance (NMR) spectra of several class 1 D4V5 transfer ribonucleic acid (tRNA) species containing 7-methylguanosine in their variable loops reveals a set of six to seven tertiary base pair resonances, one of which is always located at ca. --13.4 ppm. Other tRNA species which do not contain 7-methyl-guanosine do not contain the tertiary resonance at --13.4 ppm. Chemical removal of 7-methylguanosine from several tRNAs containing the same dihydrouridine (DHU) helix sequence as yeast tRNAPhe results in the loss of the --13.4-ppm tertiary resonance. In the initiator methionine tRNA, which contains a different DHU helix sequence, the 7-methylguanosine hydrogen bond has been assigned at --14.55 ppm by chemical removal of this residue. In these experiments the aromatic C8H proton of 7-methylguanosine was also assigned (--9.1 ppm). The unexpectedly low-field position of the 7-methylguanosine resonance is explained by the deshielding effect of the delocalized positive charge in this nucleoside.     

Study of yeast mitochondrial tRNAs by two-dimensional polyacrylamide gel electrophoresis: characterization of isoaccepting species and search for imported cytoplasmic tRNAs.

By two-dimensional polyacrylamide gel electrophoresis, yeast mitochondrial tRNA is fractionated into 27 major species. All but 6 of them migrate distinctly from cytoplasmic tRNAs. Migration of mitochondrial DNA-coded mitochondrial tRNAs shows the occurence of only one cytoplasmic tRNA in mitochondria. Several mitochondrial tRNA spots are identified on the electrophoregrams, some of them show isoaccepting species (Val, Ser, Met, Leu). It is suggested that there are sufficient mitochondrial tRNA genes on yeast mitochondrial DNA to allow mitochondrial protein biosynthesis by the mitochondrial tRNAs alone. Guanosine + Cytidine content and rate base composition are reported for some individual species. Mitochondrial tRNAPhe lacks Ribothymidine.