Initial stages of the thermal unfolding of yeast phenylalanine transfer RNA as studied by chemical modification: the effect of magnesium

In-stem molecular beacon targeted to a 5'-region of tRNA inclusive of the D arm that detects mature tRNA with high sensitivity

Cellular functions are regulated by the up- and down-regulation and localization of RNA molecules. Therefore, many RNA detection methods have been developed to analyze RNA levels and localization. Molecular beacon (MB) is one of the major methods for quantitative RNA detection and analysis of RNA localization. Most oligonucleotide-based probes, including MB, are designed to target a long flexible region on the target RNA molecule, e.g., a single-stranded region. Recently, analyses of tRNA localization and levels became important, as it has been shown that environmental stresses and chemical reagents induce nuclear accumulation of tRNA and tRNA degradation in mammalian cells. However, tRNA is highly structured and does not harbor any long flexible regions. Hence, only a few methods are currently available for detecting tRNA. In the present study, we attempted to detect elongator tRNA^Met (eMet) and initiator tRNA^Met (iMet) by using an in-stem molecular beacon (ISMB), characterized by more effective quenching and significantly higher sensitivity than those of conventional MB. We found that ISMB1 targeted a 5′- region that includes the D arm of tRNA and that it detected eMet and iMet transcripts as well as mature eMet with high sensitivity. Moreover, the analysis revealed that the formation of the ISMB/tRNA transcript complex required more time than the formation of an ISMB/unstructured short RNA complex. These results suggest that ISMB-based tRNA detection can be a useful tool for various biological and medical studies.

The crystal structure of unmodified tRNAPhe from Escherichia coli

Post-transcriptional nucleoside modifications fine-tune the biophysical and biochemical properties of transfer RNA (tRNA) so that it is optimized for participation in cellular processes. Here we report the crystal structure of unmodified tRNA^Phe from Escherichia coli at a resolution of 3 Å. We show that in the absence of modifications the overall fold of the tRNA is essentially the same as that of mature tRNA. However, there are a number of significant structural differences, such as rearrangements in a triplet base pair and a widened angle between the acceptor and anticodon stems. Contrary to previous observations, the anticodon adopts the same conformation as seen in mature tRNA.

Structural changes of tRNA and 5S rRNA induced with magnesium and visualized with synchrotron mediated hydroxyl radical cleavage

The structure of native yeast tRNA(Phe) and wheat germ ribosomal 5S RNA induced by different magnesium ion concentrations was studied in solution with a synchrotron mediated hydroxyl radical RNA cleavage reaction. We showed that very small amounts of Mg+2 can induce significant changes in the hydroxyl radical cleavage pattern of tRNA(Phe). It also turned out that a reactivity of tRNAz(Phe) towards *OH coincides with the strong metal binding sites. Because of the Mg ions are heavily hydrated one can suggest the strong correlation of the observed nucleosides reactivity in vicinity of Mg2+ binding sites with availability of water molecules as a source of hydroxyl radical. On the other hand the structure of wheat germ 5S rRNA is less sensitive to the hydroxyl radical reaction than tRNA(Phe) although some changes are visible at 4 mM Mg ions. It is probably due to the lack of strong Mg+2 binding sites in that molecule. The reactivity of nucleotides in loops C and D of 5S rRNA is not effected, what suggests their flexibility or involvement in higher order structure formation. There is different effect of magnesium on tRNA and 5S rRNA folding. We found that nucleotides forming strong binding sites for magnesium are very sensitive to X-ray generated hydroxyl radical and can be mapped with *OH. The results show, that guanine nucleotides are preferentially hydrated. X-ray footprinting mediated hydroxyl radical RNA cleavage is a very powerful method and has been applied to studies of stable RNAs for the first time.

The telomeric dG(GT)4G sequence can adopt a parallel-stranded double helical conformation

Oligonucleotides 3'-d(GTGTGTGTGG)-L-d(GGTGTGTGTG)-3' (hp-GT) and 3'-d(G4STG4TG4STG4STGG)-L-d(GGTGTGTGTG)-3' (hp-SGT), (L=(CH2CH2O)3), were shown by use of several optical techniques to form a novel parallel-stranded (ps) intramolecular double helix with purine-purine and pyrimidine-pyrimidine base pairing. The rotational relaxation time of hp-GT was similar to that of a 10-bp reference duplex, and the fraction of unpaired bases was determined to be approximately 7%, testifying to the formation of an intramolecular double helical hairpin by the sequence under the given experimental conditions. A quasi-two-state mode of ps-double helix formation was validated, yielding a helix-coil transition enthalpy of -135 +/- 5 kJ/mol. The G x G and T x T (or 4ST x T) base pair configurations and conformational parameters of the double helix were derived with molecular modeling by force field techniques. Repetitive d(GT) sequences are abundant in telomers of different genomes and in the regulatory regions of genes. Thus, the observed conformational potential of the repetitive d(GT) sequence may be of importance in the regulation of cell processes.

Parallel-stranded DNA with mixed AT/GC composition: role of trans G.C base pairs in sequence dependent helical stability

Parallel-stranded (ps) DNAs with mixed AT/GC content comprising G.C pairs in a varying sequence context have been investigated. Oligonucleotides were devised consisting of two 10-nt strands complementary either in a parallel or in an antiparallel orientation and joined via nonnucleotide linkers so as to form 10-bp ps or aps hairpins. A predominance of intramolecular hairpins over intermolecular duplexes was achieved by choice of experimental conditions and verified by fluorescence determinations yielding estimations of rotational relaxation times and fractional base pairing. A multistate mode of ps hairpin melting was revealed by temperature gradient gel electrophoresis (TGGE). The thermal stability of the ps hairpins with mixed AT/GC content depends strongly on the specific sequence in a manner peculiar to the ps double helix. The thermodynamic effects of incorporating trans G.C base pairs into an AT sequence are context-dependent: an isolated G. C base pair destabilizes the duplex whereas a block of > or =2 consecutive G.C base pairs exerts a stabilizing effect. A multistate heterogeneous zipper model for the thermal denaturation of the hairpins was derived and used in a global minimization procedure to compute the thermodynamic parameters of the ps hairpins from experimental melting data. In 0.1 M LiCl at 3 degrees C, the formation of a trans G.C pair in a GG/CC sequence context is approximately 3 kJ mol(-)(1) more favorable than the formation of a trans A.T pair in an AT/TA sequence context. However, GC/AT contacts contribute a substantial unfavorable free energy difference of approximately 2 kJ mol(-)(1). As a consequence, the base composition and fractional distribution of isolated and clustered G.C base pairs determine the overall stability of ps-DNA with mixed AT/GC sequences. Thus, the stability of ps-DNA comprising successive > or =2 G.C base pairs is greater than that of ps-DNA with an alternating AT sequence, whereas increasing the number of AT/GC contacts by isolating G.C base pairs exerts a destabilizing effect on the ps duplex. Molecular modeling of the various helices by force field techniques provides insight into the structural basis for these distinctions.

The crystal structure of yeast phenylalanine tRNA at 2.0 A resolution: cleavage by Mg(2+) in 15-year old crystals

We have re-determined the crystal structure of yeast tRNA(Phe) to 2. 0 A resolution using 15 year old crystals. The accuracy of the new structure, due both to higher resolution data and formerly unavailable refinement methods, consolidates the previous structural information, but also reveals novel details. In particular, the water structure around the tightly bound Mg(2+) is now clearly resolved, and hence provides more accurate information on the geometry of the magnesium-binding sites and the role of water molecules in coordinating the metal ions to the tRNA. We have assigned a total of ten magnesium ions and identified a partly conserved geometry for high-affinity Mg(2+ )binding. In the electron density map there is also clear density for a spermine molecule binding in the major groove of the TPsiC arm and also contacting a symmetry-related tRNA molecule. Interestingly, we have also found that two specific regions of the tRNA in the crystals are partially cleaved. The sites of hydrolysis are within the D and anticodon loops in the vicinity of Mg(2+).

A model for the tertiary structure of mammalian mitochondrial transfer RNAs lacking the entire 'dihydrouridine' loop and stem

The mammalian mitochondrial tRNA(AGY)Ser is unique in lacking the entire dihydrouridine arm. This reduces its secondary structure to a 'truncated cloverleaf'. Experimental evidence on the tertiary structure has been obtained by chemically probing the conformation of both the bovine and human species in their native conformation and at various stages of denaturation. A structural model of the bovine tRNA is presented based on the results of this chemical probing, on a comparison between nine homologous 'truncated cloverleaf' secondary structures and on analogies with the crystal structure of yeast phenylalanine tRNA. The proposed structure is very similar in shape to that of yeast tRNA(Phe) but is slightly smaller in size. It is defined by a unique set of tertiary interactions. Structural considerations suggest that other mammalian mitochondrial tRNAs have smaller dimensions as well.

Conformational transitions of an unmodified tRNA: implications for RNA folding

Unmodified tRNAs are powerful systems to study the effects of posttranscriptional modifications and site-directed mutations on both the structure and function of these ribonucleic acids. To define the general limitations of synthetic constructs as models for native tRNAs, it is necessary to elucidate the conformational states of unmodified tRNAs as a function of solution conditions. Here we report the conformational properties of unmodified yeast tRNAPhe as a function of ionic strength, [Mg2+], and temperature using a combination of spectroscopic measurements along with chemical and enzymatic probes. We find that in low [Na+] buffer at low temperature, native yeast tRNAPhe adopts tertiary structure in the absence of Mg2+. By contrast, tertiary folding of unmodified yeast tRNAPhe has an absolute requirement for Mg2+. Below the melting temperature of the cloverleaf, unmodified yeast tRNAPhe exists in a Mg2+-dependent equilibrium between secondary and tertiary structure. Taken together, our findings suggest that although the tertiary structures of tRNAs are broadly comparable, the intrinsic stability of the tertiary fold, the conformational properties of intermediate states, and the stability of intermediate states can differ significantly between tRNA sequences. Thus, the use of unmodified tRNAs as models for native constructs can have significant limitations. Broad conclusions regarding "tRNA folding" as a whole must be viewed cautiously, particularly in cases where structural changes occur, such as during protein synthesis.

Sequences outside recognition sets are not neutral for tRNA aminoacylation. Evidence for nonpermissive combinations of nucleotides in the acceptor stem of yeast tRNAPhe

Phenylalanine identity of yeast tRNAPhe is governed by five nucleotides including residues A73, G20, and the three anticodon nucleotides (Sampson et al., 1989, Science 243, 1363-1366). Analysis of in vitro transcripts derived from yeast tRNAPhe and Escherichia coli tRNAAla bearing these recognition elements shows that phenylalanyl-tRNA synthetase is sensitive to additional nucleotides within the acceptor stem. Insertion of G2-C71 has dramatic negative effects in both tRNA frameworks. These effects become compensated by a second-site mutation, the insertion of the wobble G3-U70 pair, which by itself has no effect on phenylalanylation. From a mechanistic point of view, the G2-C71/G3-U70 combination is not a "classical" recognition element since its antideterminant effect is compensated for by a second-site mutation. This enlarges our understanding of tRNA identity that appears not only to be the outcome of a combination of positive and negative signals forming the so-called recognition/identity set but that is also based on the presence of nonrandom combinations of sequences elsewhere in tRNA. These sequences, we name "permissive elements," are retained by evolution so that they do not hinder aminoacylation. Likely, no nucleotide within a tRNA is of random nature but has been selected so that a tRNA can fulfill all its functions efficiently.

Hierarchy and dynamics of RNA folding

The evidence showing that the self-assembly of complex RNAs occurs in discrete transitions, each relating to the folding of sub-systems of increasing size and complexity starting from a state with most of the secondary structure, is reviewed. The reciprocal influence of the concentration of magnesium ions and nucleotide mutations on tertiary structure is analyzed. Several observations demonstrate that detrimental mutations can be rescued by high magnesium concentrations, while stabilizing mutations lead to a lesser dependence on magnesium ion concentration. Recent data point to the central controlling and monitoring roles of RNA-binding proteins that can bind to the different folding stages, either before full establishment of the secondary structure or at the molten globule state before the cooperative transition to the final three-dimensional structure.

Fluorine-19 NMR studies of the thermal unfolding of 5-fluorouracil-substituted Escherichia coli valine transfer RNA

19F NMR spectroscopy was used to monitor the thermal unfolding of E. coli tRNAVal labeled by incorporation of 5-fluorouracil (FUra). With rising temperatures, resonances in the 19F NMR spectrum of (FUra)tRNAVal gradually shift towards the central region of the spectrum and merge into a single broad peak above 85 degrees C. FU55 and FU12 are the first to shift, beginning at temperatures below 40 degrees C, which suggests that the initial steps of thermal denaturation of tRNAVal involve disruption of the tertiary interactions between the D- and T-arms. The acceptor stem and the FU64-G50 wobble base pair in the T-stem are particularly stable to thermal denaturation. A temperature-dependent splitting of the 19F resonance assigned to FU64, at temperatures above 40 degrees C, suggests that the T-arm of (FUra)tRNAVal exists in two conformations in slow exchange on the NMR time scale.

Association of transfer RNA acceptor identity with a helical irregularity

The aminoacylation specificity ("acceptor identity") of transfer RNAs (tRNAs) has previously been associated with the position of particular nucleotides, as opposed to distinctive elements of three-dimensional structure. The contribution of a G.U wobble pair in the acceptor helix of tRNA(Ala) to acceptor identity was examined with synthetic amber suppressor tRNAs in Escherichia coli. The acceptor identity was not affected by replacing the G.U wobble pair in tRNA(Ala) with a G.A, C.A, or U.U wobble pair. Furthermore, a tRNA(Ala) acceptor identity was conferred on tRNA(Lys) when the same site in the acceptor helix was replaced with any of several wobble pairs. Additional data with tRNA(Ala) show that a substantial acceptor identity was retained when the G.U wobble pair was translocated to another site in the acceptor helix. These results suggest that the G.U wobble pair induces an irregularity in the acceptor helix of tRNA(Ala) to match a complementary structure in the aminoacylating enzyme.

Restrained refinement of the monoclinic form of yeast phenylalanine transfer RNA. Temperature factors and dynamics, coordinated waters, and base-pair propeller twist angles

The structure of yeast phenylalanine transfer RNA in the monoclinic form has been further refined by using the restrained least-squares method of Hendrickson and Konnert. For the 4019 reflections between 10 and 3 A, with magnitudes at least 3 times their standard deviations, the R factor is 16.8%. The variation of the atomic temperature factors along the sequence indicates that the major flexibility regions are the amino acid and anticodon stems. The two strands of the amino acid helix exhibit large differential temperature factors, suggesting partial uncoiling or melting of the helix. In this work, the occupancy of all atoms was also varied. Residues D16 and D17 of the dihydrouridine loop as well as U33 and G37 of the anticodon loop have occupancies around 70%, indicating some local disorder or large-scale mobility at these positions. One hundred fifteen solvent molecules, including five magnesium ions, were found in difference maps. The role of several water molecules is clearly related to the stabilization of the secondary and tertiary interactions. The gold sites, which were not previously discussed, are described and show an energetically favored binding mode similar to that of cobalt and nickel complexes with nucleotides.

Study of the interaction between uncharged yeast tRNAPhe and elongation factor Tu from Bacillus stearothermophilis

Proton NMR studies are presented on the interaction of nonaminoacylated yeast tRNAPhe and elongation factor Tu X GTP from Bacillus stearothermophilis. From experiments in which transfer of magnetization is observed between proton spins of tRNA and the protein, it is concluded that complex formation takes place. Amino acid residues of the protein come into close contact with the base pair A5U68 and/or U52A62 of the acceptor T psi C limb of the tRNA molecule. From the line broadening of tRNA resonances, associated with complex formation, an association constant of 10(3)-10(4) M-1 is estimated. The NMR experiments do not monitor a significant conformational change of the tRNA molecule upon interaction with the protein. However, at times long after the onset of complex formation, spectral changes indicate that the upper part of the acceptor helix becomes distorted.

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.

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.

Nuclear magnetic resonance studies on yeast tRNAPhe. III. Assignments of the iminoproton resonances of the tertiary structure by means of nuclear Overhauser effect experiments at 500 MHz

Resonances of the water exchangeable iminoprotons of the tertiary structure of yeast tRNAPhe were studied by experiments involving Nuclear Overhauser Effects (NOE's). Direct NOE evidence is presented for the assignment of all resonances of iminoprotons participating in tertiary basepairing (except that of G19C56 which was assigned by an elimination procedure). The present results in conjunction with our previous assignment of secondary iminoprotons constitute for the first time a complete spectral assignment of all iminoprotons participating in basepairing in yeast tRNAPhe. In addition we have been able to assign the non(internally) hydrogen bonded N1 proton of psi 55 as well as the N3 proton of this residue, which is one of the two iminoprotons hydrogen bonded to a phosphate group according to X-ray results. No evidence could be obtained for the existence in solution of the other iminoproton-phosphate interaction: that between U33 N3H and P36 located in the anticodon loop. Remarkable is the assignment of a resonance at 12.4 - 12.5 ppm to the iminoproton of the tertiary basepair T54m1A58. The resonance positions obtained for the iminoprotons of G18 (9.8 ppm) and m2(2)G26 (10.4 ppm) are surprisingly far upfield considering that these protons are involved in hydrogen bonds according to X-ray diffraction results. As far as reported by changes in chemical shifts of iminoproton resonances the main structural event induced by Mg++ ions takes place near the tertiary interactions U8A14 and G22m7G46.

Carbodiimide modification analysis of aminoacylated yeast phenylalanine tRNA: evidence for change in the apex region

The G- and U-specific reagent, carbodiimide was used to probe the solution structure of aminoacylated yeast phenylalanine tRNA. Both quantitative and qualitative changes in modification were observed when the modification patterns of tRNA-CCA(3'OH), tRNA-CCA(3'NH2) and phe-tRNA-CCA(3'NH2) were compared. Five nucleotides were modified in all cases, D16 and G20 in the D-loop, U33 and Gm34 in the anticodon loop and U47, in the region of the extra arm. Small changes occurred in the D-loop with incorporation of the adenosine analogue manifest as new, low levels of modification of G22 (D-stem) and a loss of sensitivity to Mg+2 in modification of D16. Aminoacylation resulted in new modification of G19, modification of a residue in the T psi CG sequence, and a 2.5-fold increase in modification of G22. Taken together the results show that aminoacylation causes increased exposure of bases in the apex region of the L-shaped molecule where the D- and psi-loops are joined. The effects observed could occur as a consequence of stable or dynamic changes in conformation.

Study of transfer ribonucleic acid unfolding by dynamic nuclear magnetic resonance

Nuclear magnetic resonance (NMR) measurements of proton exchange were performed on yeast tRNAPhe, and in much less detail on Escherichia coli tRNAfMet, over a range of Mg2+ concentrations and temperatures, at neutral pH and 0.1 M NaCl. The resonances studied were those of ring nitrogen protons, resonating between 10 and 15 ppm downfield from sodium 3-(trimethylsilyl)-1-propanesulfonate, which partake in hydrogen bonding between bases of secondary and tertiary pairs. Methods include saturation--recovery, line width, and real-time observation after a change to deuterated solvent. The relevant theory is briefly reviewed. We believe that most of the higher temperature rates reflect major unfolding of the molecule. For E. coli tRNAfMet, the temperature dependence of the rate for the U8--A14 resonance maps well onto previous optical T-jump studies for a transition assigned to tertiary melting. For yeast tRNAPhe, exchange rates of several resolved protons could be studied from 30 to 45 degrees C in zero Mg2+ concentration and had activation energies on the order of 40 kcal/mol. Initially, the tertiary structure melts, followed shortly by the acceptor stem. At high Mg2+ concentration, relatively few exchange rates are measurable below the general cooperative melt at about 60 degrees C; these are attributed to tertiary changes. Real-time observations suggest a change in the exchange mechanism at room temperature with a lower activation energy. The results are compared with those obtained by other methods directed toward assaying ribonucleic acid dynamics.

Conformational changes of yeast tRNAphe as monitored by 31P NMR

The 31P NMR spectra of tRNAs contain approximately 17 resonances resolved from the main resonance which consists of about 80% of the total resonance intensity arising from the sugar phosphate backbone. In the present paper we study the behavior of the 31P resonances of yeast tRNAPhe as a function of temperature and of solution conditions. By comparison with other melting experiments we show that three resonances (called c, e and j2) belong to phosphates in the anticodon loop, while the remaining resolved 31P resonances come from phosphates in specific conformations in the central part of the molecule imposed by the tertiary structure. These conformations are different from the normal g-,g- conformation found in A-RNA double helices. The assignments are in good agreement with those previously made on the basis of chemical and enzymatic modification experiments [P. J. M. Salemink, T. Swarthof & C. W. Hilbers (1979) Biochemistry, 18, 3477-3485]. AT high Mg2+ concentrations the anticodon loop is found to be present in two different conformations. For all solution conditions studied loss of the anticodon loop structure takes place before the tertiary structure is melted out. The melting of the tertiary structure is not strictly an all- or-none process. The lifetimes of phosphate conformations involved in the tertiary structure may differ by at least a factor of two. It can also be concluded that the range of chemical shifts observed for phosphodiesters cannot at the moment be accounted for by theoretical calculations.

Chemical probes for higher-order structure in RNA

Three chemical reactions can probe the secondary and tertiary interactions of RNA molecules in solution. Dimethyl sulfate monitors the N-7 of guanosines and senses tertiary interactions there, diethyl pyrocarbonate detects stacking of adenosines, and an alternate dimethyl sulfate reaction examines the N-3 of cytidines and thus probes base pairing. The reactions work between 0 degrees C and 90 degrees C and at pH 4.5--8.5 in a variety of buffers. As an example we follow the progressive denaturation of yeast tRNAPhe terminally labeled with 32P as the tertiary and secondary structures sequentially melt out. A single autoradiograph of a terminally labeled molecule locates regions of higher-order structure and identifies the bases involved.

Chemical evidence for a codon-induced allosteric change in tRNALys involving the 7-methylguanosine residue 46

[32P]TRNALys, from Escherichia coli, was modified with kethoxal, in the presence and absence of the oligonucleotide codon (A)4. The presence of the codon resulted in a faster modification rate of the tRNA at three guanine sites which were identified by a diagonal fingerprint method. A large increase in the modification rate occurred at the 7-methylguanosine residue 46 (m7G-46) in the presence of the codon: weakly enhanced modification was observed at G-15 and G-57. It is concluded that the formation of a codon-anticodon complex induces, primarily, a conformational change involving disruption of the m7G-46 from the m7G-46 . G-22 . C-13 base triple. Subsequently, the guanines of G-15 and G-57, in the D and T loops, respectively, become slightly more reactive, suggesting a weak tendency for these two interacting arms to unfold. The results are interpreted in terms of an equilibrium between two main conformers, and a third minor one; the possible significance of these conformers in protein biosynthesis, is considered.

A study of the thermal unfolding of Escherichia coli phenylalanine transfer RNA by chemical modification at elevated temperatures

Escherichia coli tRNAPhe was modified by 3 M sodium bisulphite pH 6.0 for 24 h in the temperature range 25 degrees C (x 5 degrees C) to 55 degrees C and in the absence of added magnesium ions. The sites and extents of conversion of cytidines to uridine occurring at each temperature were determined by fingerprinting. The new sites of cytidine modification found at higher reaction temperatures were assumed to arise from breakage of secondary and tertiary structure hydrogen bonds involving cytidine residues. From these data, we conclude that hydrogen bonds within the 'complex core' of the tRNA (including the base pairs G-10 . C-25, C-11 . G-24 and C-13 . G-21 within the dihydrouridine stem and the tertiary structure base pair G-15 . C-48 melt at a lower temperature than the tertiary structure hydrogen bonds between G-19 in the dihydrouridine loop and C-56 in the TpsiC loop.