A chemical approach to studies of the three-dimensional structure of tRNA - alkylation with a reagent covalently bound to a "peculiar site''.

Yeast valine tRNA1 was chemically modified with chlorambucil N-hydroxysuccinimide ester. tthe reagent was attached covalently to the valine residue of valyl-tRNA1Val under the conditions which prevented tRNA from alkylation. Chlorambucilyl-valyl-tRNA1Val thus obtained was separated from excess reagent and incubated in an aqueous solution at neutral pH in the presence of Mg++ions. Highly efficient intramolecular self-alkylation of chlorambucilyl-valyl-tRNA1Val took place. The chlorambucil residue bound covalently to the amino group of the valine residue of tRNA1Val alkylates the 5'-terminal phosphate group of the molecule, and its 3'-terminal sequence -A-C-C-A.     

Nucleotide sequence of a spinach chloroplast valine tRNA.

The nucleotide sequence of a spinach chloroplast valine tRNA (sp. chl. tRNA Val) has been determined. This tRNA shows essentially equal homology to prokaryotic valine tRNAs (58-65% homology) and to the mitochondrial valine tRNAs of lower eukaryotes (yeast and N. crassa, 61-62% homology). Sp. chl. tRNA Val shows distinctly lower homology to mouse mitochondrial valine tRNA (53% homology) and to eukaryotic cytoplasmic valine tRNAs (47-53% homology). Sp. chl. tRNA Val, like all other chloroplast tRNAs sequenced, contains a methylated GG sequence in the dihydrouridine loop and lacks unusual structural features which have been found in several mitochondrial tRNAs.     

Specific and non-specific purine trap in the T-loop of normal and suppressor tRNAs

To elucidate the general constraints imposed on the structure of the D and T-loops in functional tRNAs, active suppressor tRNAs were selected in vivo from a combinatorial tRNA gene library in which several nucleotide positions in these loops were randomized. Analysis of the nucleotide sequences of the selected clones demonstrates that most of them contain combination U54-A58 allowing the formation of the standard reverse-Hoogsteen base-pair 54-58 in the T-loop. With only one exception, all these clones fall into two groups, each characterized by a distinct sequence pattern. Analysis of these two groups has allowed us to suggest two different types of nucleotide arrangement in the DT region. The first type, the so-called specific purine trap, is found in 12 individual tRNA clones and represents a generalized version of the standard D-T loop interaction. It consists of purine 18 sandwiched between the reverse-Hoogsteen base-pair U54-A58 and purine 57. The identity of purine 18 is restricted by the specific base-pairing with nucleotide 55. Depending on whether nucleotide 55 is U or G, purine 18 should be, respectively, G or A. The second structural type, the so-called non-specific purine trap, corresponds to the nucleotide sequence pattern found in 16 individual tRNA clones and is described here for the first time. It consists of purine 18 sandwiched between two reverse-Hoogsteen base-pairs U54-A58 and A55-C57 and, unlike the specific purine trap, requires the T-loop to contain an extra eighth nucleotide. Since purine 18 does not form a base-pair in the non-specific purine trap, both purines, G18 and A18, fit to the structure equally well. The important role of both the specific and non-specific purine traps in the formation of the tRNA L-shape is discussed.     

Alkylation of tRNAPhe with 4-(N-2-chloroethyl-N-methylamino) benzyl-5'-phosphamide of d(ATTTTCA)

Alkylation of E. coli tRNAPhe with 4-(N-2-chloroethyl-N-methylamino)benzyl-5'-phosphamide of oligonucleotide d(ATTTTCA) complementary to the sequence UGAAms2i6AA psi in the anticodon loop of tRNAPhe was studied. Three guanine residues--G28/29, G24 and G10 were found to be alkylated. Two binding sites for the reagent in the tRNA were assumed to be present. The efficiency of the alkylation of tRNA from these sites as well as an average association constant (Ka 3,8 X 10(3)M-1) for the reagent interaction with tRNA were evaluated.     

Complementary addressed alkylation of Escherichia coli 16S rRNA with 2',3'-O-[4-2-chloroethyl)-N-methylamino]benzylidene derivatives of deoxyribooligonucleotides. II. The nature of rapid interaction at 0 degrees C

Fast non-covalent interactions of 16S rRNA Escherichia coli with 14C labeled 2',3'-O-[4-N-(2-chloroethyl)-N-methylamino]benzylidene derivatives of deoxyribooligonucleotides d(pACCTTGTT)rA, d[pTTACGATC)rU, d(pTTTGCTCCCC)rA (less than[14C]CHRCl-reagents) observed at 0 degrees C were investigated. It was shown, that 16S rRNA and [14C]CHRCl-reagents at 0 degrees C form stable complexes which can not be disrupted under mild acidic conditions (pH 4, 40 degrees C) and under denaturing conditions (7 M urea, 50 degrees C), but are completely disrupted in the course of centrifugation in sucrose density gradient in the presence of SDS. Formation of such complexes of 16S rRNA with greater than[14C]CHRCl-reagents at 0 degrees C was observed due to the presence in the reagent preparation of a number of unidentified products, formed in the course of the synthesis of benzylidene derivatives, and having a hydrophobicity larger, than those for greater than CHRCl-derivatives of deoxyribooligonucleotide. Preparation of [14C]CHRCl-reagents, subjected for purification by reverse-phase chromatography, were unable to form such a complex with 16S rRNA at 0 degrees C. Studies on the complementary addressed modification at 0 degrees C (or incubation at 0 degrees C) with the use of the oligonucleotide benzylidene derivatives not purified from hydrophobic contaminations may lead to alkylation within these complexes during subsequent treatments and in such a way give incorrect information about the level of alkylation within the complex under investigation.     

Recognition of the universally conserved 3'-CCA end of tRNA by elongation factor EF-Tu.

Escherichia coli tRNA(Val) with pyrimidine substitutions for the universally conserved 3'-terminal adenine can be readily aminoacylated. It cannot, however, transfer valine into polypeptides. Conversely, despite being a poor substrate for valyl-tRNA synthetase, tRNA(Val) with a 3'-terminal guanine is active in in vitro polypeptide synthesis. To better understand the function of the 3'-CCA sequence of tRNA in protein synthesis, the effects of systematically varying all three bases on formation of the Val-tRNA(Val):EF-Tu:GTP ternary complex were investigated. Substitutions at C74 and C75 have no significant effect, but replacing A76 with pyrimidines decreases the affinity of valyl-tRNA(Val) for EF-Tu:GTP, thus explaining the inability of these tRNA(Val) variants to function in polypeptide synthesis. Valyl-tRNA(Val) terminating in 3'-guanine is readily recognized by EF-TU:GTP. Dissociation constants of the EF-Tu:GTP ternary complexes with valine tRNAs having nucleotide substitutions at the 3' end increase in the order adenine < guanine < uracil; EF-Tu has very little affinity for tRNA terminating in 3' cytosine. Similar observations were made in studies of the interaction of 3' end mutants of E. coli tRNA(Ala) and tRNA(Phe) with EF-Tu:GTP. These results indicate that EF-Tu:GTP preferentially recognizes purines and discriminates against pyrimidines, especially cytosine, at the 3' end of aminoacyl-tRNAs.     

A 16S rRNA-tRNA product containing a nucleotide phototrimer and specific for tRNA in the P/E hybrid state in the Escherichia coli ribosome

Ribosome complexes containing deacyl-tRNA1(Val) or biotinylvalyl-tRNA1(Val) and an mRNA analog have been irradiated with wavelengths specific for activation of the cmo5U nucleoside at position 34 in the tRNA1(Val) anticodon loop. The major product for both types of tRNA is the cross-link between 16S rRNA (C1400) and the tRNA (cmo5U34) characterized already by Ofengand and his collaborators [Prince et al. (1982) Proc. Natl Acad. Sci. USA, 79, 5450-5454]. However, in complexes containing deacyl-tRNA1(Val), an additional product is separated by denaturing PAGE and this is shown to involve C1400 and m5C967 of 16S rRNA and cmo5U34 of the tRNA. Puromycin treatment of the biotinylvalyl-tRNA1(Val) -70S complex followed by irradiation, results in the appearance of the unusual photoproduct, which indicates an immediate change in the tRNA interaction with the ribosome after peptide transfer. These results indicate an altered interaction between the tRNA anticodon and the 30S subunit for the tRNA in the P/E hybrid state compared with its interaction in the classic P/P state.     

The mRNA codon environment at the P and E sites of human ribosomes deduced from photo crosslinking with pUUUGUU

Three mRNA analogs--derivatives of hexaribonucleotide pUUUGUU comprising phenylalanine and valine codons with a perfluoroarylazido group attached to the C5 atom of the uridine residue at the first, second, or third position--were used for photocrosslinking with 80S ribosomes from human placenta. The mRNA analogs were positioned on the ribosome with tRNA recognizing these codons: UUU was at the P site if tRNA(Phe) was used, while tRNA(Val) was used to put there the GUU codon (UUU at the E site). Thus, the crosslinking group of mRNA analog might occupy positions -3 to +3 with respect to the first nucleotide of the codon at the P site. Irradiation of the complexes with soft UV light (lambda > 280 nm) resulted in the crosslinking of pUUUGUU derivatives with 18S RNA and proteins in the ribosome small subunit. The crosslinking with rRNA was observed only in the presence of tRNA. The photoactivatable group in positions -1 to +3 binds to G1207, while that in positions -2 or -3 binds to G961 of 18S RNA. In all cases, we observed crosslinking with S2 and S3 proteins irrespective of the presence of tRNA in the complex. Crosslinking with S23 and S26 proteins was observed mainly in the presence of tRNA when modified nucleotide occupied the +1 position (for both proteins) or the -3 position (for S26 protein). The crosslinking with S5/S7 proteins was substantial when modified nucleotide was in the -3 position, this crosslinking was not observed in the absence of tRNA.     

Protein environment of the sense codon of the template in the A site of the human ribosome as inferred from crosslinking to oligoribonucleotide derivatives

The protein environment of each nucleotide of the template codon located in the A site of the human ribosome was studied with UUCUCAA and UUUGUU derivatives containing a Phe codon (UUC and UUU, respectively) and a perfluoroarylazido group at U4, U5, or U6. The analogs were positioned in the ribosome with the use of tRNA(Phe), which is cognate to the UUC or UUU codon and directs it to the P site, bringing a modified codon in the A site with a modified nucleotide occupying position +4, +5, or +6 relative to the first nucleotide of the P-site codon. On irradiation of ribosome complexes with tRNA(Phe) and mRNA analogs with mild UV light, the analogs crosslinked predominantly to the 40S subunit, modifying the proteins to a greater extent than the rRNA. The 18S rRNA nucleotides crosslinking to the analogs were identified previously. Of the small-subunit proteins, S3 and S15 were the major targets of modification in all cases. The former was modified both in ternary complexes and in the absence of tRNA, and the latter, only in ternary complexes. The extent of crosslinking of mRNA analogs to S15 decreased when the modified nucleotide was shifted from position +4 to position +6. The results were collated with the data on ribosomal proteins located at the decoding site of the 70S ribosome, and conclusion was made that the protein environment of the A-site codon strikingly differs between bacterial and eukaryotic ribosomes.     

Rabbit liver tRNA1Val:II. unusual secondary structure of T psi C stem and loop due to a U54:A60 base pair.

In contrast to all other known tRNAs, mammalian tRNA1Val contains two adenosines A59 and A60, opposite to U54 and psi 55 in the U psi CG sequence of the T psi C loop, which could form unusual A:U (or A: psi pairs in addition to the five "normal" G:C pairs. In order to measure the number of G:C and A:U (A: psi) pairs in the T psi C stem, we prepared the 30 nucleotide long 3'-terminal fragment of this tRNA by "m7G-cleavage". From differentiated melting curves and temperature jump experiments it was concluded that the T psi C stem in this fragment is in fact extended by an additional A60:U54 pair. A dimer of this fragment with 14 base pairs was characterized by gel electrophoresis and by the same physical methods. An additional A:U pair in the tRNA1Val fragment does not necessarily mean that this is also true for intact tRNA. However, we showed that U54 is far less available for enzymatic methylation in mammalian tRNA1Val compared to tRNA from T-E. coli. This clear difference in U54 reactivity, together with the identification of an extra A60:U54 pair in the U psi CG containing fragment suggests the presence of a 6 base pair T psi C stem and a 5 nucleotide T psi C loop in this tRNA.     

Nuclear magnetic resonance studies on transfer ribonucleic acid: assignment of AU tertiary resonances.

The hydrogen-bonded ring NH nuclear magnetic resonance (NMR) spectra of several transfer ribonucleic acid (RNA) species have been examined with particular emphasis on the extreme low-field portion. Betwen --13.8 and --15 ppm there are two extra resonances which are not derived from cloverleaf base pairs. A combined approach involving undermodified tRNAs, chemical modification, and hairpin fragment studies has assigned the T54--A58 resonance at --14.3 ppm in yeast tRNAPhe and Escherichia coli tRNA1 Val., the U8--A14 resonance has been assigned at --14.3 ppm, and the s4U8--A14 resonance in bacterial tRNAs has been assigned at --14.9 ppm. The T54--A58 resonance shifts between --14.3. and --13.8 ppm depending on the surrounding nucleotide sequence in the ribothymidine loop.     

Similar binding of the carcinostatic drugs cis-[Pt(NH3)2Cl2] and [Ru(NH3)5Cl] Cl2 to tRNAphe and a comparison with the binding of the inactive trans-[Pt(NH3)2Cl2] complex - reluctance in binding to Watson-Crick base pairs within double helix.

A comparative study of the binding of square planar cis- and trans-[Pt(NH3)2Cl2] complexes and the octahedral [Ru(NH3)5(H2O)]3+ complex to tRNAphe from yeast was carried out by X-ray crystallography. Both of the carcinostatic compounds, cis-[Pt(NH3)2Cl2] and [Ru(NH3)5(H2O)]3+ show similarities in their mode of binding to tRNA. These complexes bind specifically to the N(7) positions of guanines G15 and G18 in the dihydrouridine loop. [Ru(NH3)5(H2O)]3+ has an additional binding site at N(7) of residue G1 after extensive soaking times (58 days). A noncovalent binding site for ruthenium is also observed in the deep groove of the acceptor stem helix with shorter (25 days) soaking time. The major binding site for the inactive trans-[Pt(NH3)Cl2] complex is at the N(1) position of residue A73, with minor trans-Pt binding sites at the N(7) positions of residues Gm34, G18 and G43. The similarities in the binding modes of cis-[Pt(NH3)2Cl2] and [Ru(NH3)5(H2O)]3+ are expected to be related to their carcinostatic properties.     

The T-arm of tRNA is a substrate for tRNA (m5U54)-methyltransferase

Fragments of Escherichia coli FUra-tRNA(1Val) as small as 15 nucleotides form covalent complexes with tRNA (m5U54)-methyltransferase (RUMT). The sequence essential for binding includes position 52 of the T-stem and the T-loop and extends toward the 3' acceptor end of FUra-tRNA. The in vitro synthesized 17mer T-arm of E. coli tRNA(1Val), composed of the seven-base T-loop and 5-base-pair stem, is a good substrate for RUMT. The Km is decreased 5-fold and kcat is decreased 2-fold compared to the entire tRNA. The T-arm structure could be further reduced to an 11mer containing the loop and two base pairs and still retain activity; the Km was similar to that of the 17mer T-arm, whereas kcat was decreased an additional 20-fold. The data indicate that the primary specificity determinants for the RUMT-tRNA interaction are contained within the primary and secondary structure of the T-arm of tRNA.     

Temperature-dependent structural changes in complexes of tRNA(adenine-1)-methyltransferase from Thermus thermophilus HB8 and tRNA studied by optical and electron microscope methods

The complexation of tRNA (adenine-1-)-methyltransferase from Thermus thermophilus HB8 (E.C.2.1.1.36) with Escherichia coli tRNA(Phe) and yeast tRNA1(Val) was investigated in a temperature range from 20 to 90 degrees C. The quantity of methylase subunits bounded with tRNA and the association constant (Ka) were determined by means of fluorescence quenching of the enzyme tryptophane residues by tRNA molecules. The number of enzyme subunits bounded with one tRNA molecule at temperatures 20-70 degrees C is equal to 8 +/- 2. The Ka values increase from (2 divided by 3).10(7) at 20 degrees C up to 8.5.10(7) M-1 at 70 degrees C. The temperature increase from 70 to 90 degrees C causes a decrease in the enzyme specific activity and in Ka values. In the temperature range from 75 to 90 degrees C a cooperative transition of methylase macromolecules into associates was observed. This association is accompanied by an increase of UV-light scattering and of fluorescence polarization coefficient of methylase tryptophane residues. In the absence of tRNA the size of enzyme associates (d) is evaluated to be more than 320 nm (d greater than or equal to lambda-320 nm), in the presence of tRNA-less than 320 nm (d much less than lambda-320 nm). An electron microscopic investigation of methylase and its complexes with tRNA at 20 degrees C revealed disk-like particles with a diameter and height of 8-11 nm and 4-5 nm, respectively. These disk-like methylase preparations dialized against distilled water form flexible polymeric rods with a diameter of 10-12 nm and the length of about several hundreds nm. During complexation of methylase with tRNA, in the same conditions as the dializes was carried out, large associates were not revealed.     

19F nuclear magnetic resonance as a probe of anticodon structure in 5-fluorouracil-substituted Escherichia coli transfer RNA

The use of 19F nuclear magnetic resonance (n.m.r.) spectroscopy as a probe of anticodon structure has been extended by investigating the effects of tetranucleotide binding to 5-fluorouracil-substituted Escherichia coli tRNA(Val)1 (anticodon FAC). 19F n.m.r. spectra were obtained in the absence and presence of different concentrations of oligonucleotides having the sequence GpUpApX (X = A,G,C,U), which contain the valine codon GpUpA. Structural changes in the tRNA were monitored via the 5-fluorouracil residues located at positions 33 and 34 in the anticodon loop, as well as in all other loops and stems of the molecule. Binding of GpUpApA, which is complementary to the anticodon and the 5'-adjacent FUra 33, shifts two resonances in the 19F spectrum. One, peak H (3.90 p.p.m.), is also shifted by GpUpA and was previously assigned to FUra 34 at the wobble position of the anticodon. The effects of GpUpApA differ from those of GpUpA in that the tetranucleotide induces the downfield shift of a second resonance, peak F (4.5 p.p.m.), in the 19F spectrum of 19F-labeled tRNA(Val)1. Evidence that the codon-containing oligonucleotides bind to the anticodon was obtained from shifts in the methyl proton spectrum of the 6-methyladenosine residue adjacent to the anticodon and from cleavage of the tRNA at the anticodon by RNase H after binding dGpTpApA, a deoxy analog of the ribonucleotide codon. The association constant for the binding of GpUpApA to fluorinated tRNA(Val)1, obtained by Scatchard analysis of the n.m.r. results, is in good agreement with values obtained by other methods. On the basis of these results, we assign peak F in the 19F n.m.r. spectrum of 19F-labeled tRNA(Val)1 to FUra 33. This assignment and the previous assignment of peak H to FUra 34 are supported by the observation that the intensities of peaks F and H in the 19F spectrum of fluorinated tRNA(Val)1 are specifically decreased after partial hydrolysis with nucleass S1 under conditions leading to cleavage in the anticodon loop. The downfield shift of peak F occurs only with adenosine in the 3'-position of the tetranucleotide; binding of GpUpApG, GpUpApC, or GpUpApU results only in the upfield shift of peak H. The possibility is discussed that this base-specific interaction between the 3'-terminal adenosine and the 5-fluorouracil residue at position 33 involves a 5'-stacked conformation of the anticodon loop. Evidence also is presented for a temperature-dependent conformational change in the anticodon loop below the melting temperature of the tRNA.     

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

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

Mapping of the active site of Escherichia coli methionyl-tRNA synthetase: identification of amino acid residues labeled by periodate-oxidized tRNA(fMet) molecules having modified lengths at the 3'-acceptor end.

Initiator tRNA molecules modified at the 3'-end and lacking either the A76 (tRNA-C75), the C75-A76 (tRNA-C74), the C74-C75-A76 (tRNA-A73), or the A73-C74-C75-A76 (tRNA-A72) nucleotides were prepared stepwise by repeated periodate, lysine, and alkaline phosphatase treatments. When incubated with trypsin-modified methionyl-tRNA synthetase (MTST), excess amounts of the dialdehyde derivative of each of these shortened tRNAs (tRNA-C75ox, tRNA-C74ox, tRNA-A73ox, and tRNA-A72ox) abolished both the isotopic [32P]PPi-ATP exchange and the tRNA aminoacylation activities of the enzyme. In the presence of limiting concentrations of the various tRNAox species, the relative extents of inactivation of the enzyme were consistent with the formation of 1:1 complexes of the reacting tRNAs with the monomeric modified synthetase. Specificity of the labeling was further established by demonstrating that tRNA-C75ox binds the enzyme with an equilibrium constant and stoichiometry values in good agreement with those for the binding of nonoxidized tRNA-C75. The peptides of MTST labeled with either tRNA-C75ox or tRNA-C74ox were identified. The chymotryptic digestion of the covalent MTST.[14C]tRNA-C75ox complex yielded four peptides (A-D). In the case of tRNA-C74ox, only two of the above peptides (C and D) were identified. Peptides A, B, C, and D corresponded to fragments Ser334-Phe340, Lys61-Leu65, Val141-Tyr165, and Glu433-Phe437, respectively, in the MTST primary structure.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cross-linking of the anticodon of P and A site bound tRNAs to the ribosome via aromatic azides of variable length: involvement of 16S rRNA at the A site

The topography of the ribosomal decoding site was explored by affinity labeling from the 5'-anticodon base, 5-(carboxymethoxy)uridine-34, of P or A site bound tRNA1Val. A nitrophenyl azide was attached to the carboxyl group of this nucleotide via side chains varying in length from 18 to 24 A. Binding of acetylvalyl-tRNA to the P site was codon dependent and that of valyl-tRNA to the A site was both codon and elongation factor Tu (EFTu) dependent. Cross-linking to both A and P sites was irradiation, probe, codon, and, in the case of the A site, EFTu dependent. Putative P-site cross-linked aminoacyl-tRNA was reactive with puromycin. The yield of cross-linking was little affected by placement of the tRNA at the A or P site but varied considerably with the length and structure of the probe side chain. When the distance from the pyrimidine C-5 atom to the azide group was 23 A, 42-45% cross-linking was obtained at each site, but when the distance was decreased to 18 A, only 7-12% was found. Placing an S-S bond in the center of the 23-A leash decreased the A-site yield to about half, while insertion of a CONH group decreased A-site cross-linking about 8-fold. P-site cross-linking was more sensitive to mercaptan quenching (50% at 0.5 mM) than was that at the A site (50% at greater than 2.0 mM) but both were partially shielded from solvent.(ABSTRACT TRUNCATED AT 250 WORDS)     

Tertiary structure of Escherichia coli tRNA(3Thr) in solution and interaction of this tRNA with the cognate threonyl-tRNA synthetase

The solution structure of Escherichia coli tRNA(3Thr) (anticodon GGU) and the residues of this tRNA in contact with the alpha 2 dimeric threonyl-tRNA synthetase were studied by chemical and enzymatic footprinting experiments. Alkylation of phosphodiester bonds by ethylnitrosourea and of N-7 positions in guanosines and N-3 positions in cytidines by dimethyl sulphate as well as carbethoxylation of N-7 positions in adenosines by diethyl pyrocarbonate were conducted on different conformers of tRNA(3Thr). The enzymatic structural probes were nuclease S1 and the cobra venom ribonuclease. Results will be compared to those of three other tRNAs, tRNA(Asp), tRNA(Phe) and tRNA(Trp), already mapped with these probes. The reactivity of phosphates towards ethylnitrosourea of the unfolded tRNA was compared to that of the native molecule. The alkylation pattern of tRNA(3Thr) shows some similarities to that of yeast tRNA(Phe) and mammalian tRNA(Trp), especially in the D-arm (positions 19 and 24) and with tRNA(Trp), at position 50, the junction between the variable region and the T-stem. In the T-loop, tRNA(3Thr), similarly to the three other tRNAs, shows protections against alkylation at phosphates 59 and 60. However, tRNA(3Thr) is unique as far as very strong protections are also found for phosphates 55 to 58 in the T-loop. Compared with yeast tRNA(Asp), the main differences in reactivity concern phosphates 19, 24 and 50. Mapping of bases with dimethyl sulphate and diethyl pyrocarbonate reveal conformational similarities with yeast tRNA(Phe). A striking conformational feature of tRNA(3Thr) is found in the 3'-side of its anticodon stem, where G40, surrounded by two G residues, is alkylated under native conditions, in contrast to other G residues in stem regions of tRNAs which are unreactive when sandwiched between two purines. This data is indicative of a perturbed helical conformation in the anticodon stem at the level of the 30-40 base pairs. Footprinting experiments, with chemical and enzymatic probes, on the tRNA complexed with its cognate threonyl-tRNA synthetase indicate significant protections in the anticodon stem and loop region, in the extra-loop, and in the amino acid accepting region. The involvement of the anticodon of tRNA(3Thr) in the recognition process with threonyl-tRNA synthetase was demonstrated by nuclease S1 mapping and by the protection of G34 and G35 against alkylation by dimethyl sulphate. These data are discussed in the light of the tRNA/synthetase recognition problem and of the structural and functional properties of the tRNA-like structure present in the operator region of the thrS mRNA.