Correlation between chemical modification and surface accessibility in yeast phenylalanine transfer RNA

Fe.bleomycin as a probe of RNA conformation

Two crystallographically defined tRNAs, yeast tRNAAsp and tRNAPhe, were used as substrates for oxidative cleavage by Fe.bleomycin to facilitate definition at high resolution of the structural elements in RNAs conducive to bleomycin binding and cleavage. Yeast tRNAAsp underwent cleavage at G45 and U66; yeast tRNAPhe was cleaved at four sites, namely G19, A31, U52 and A66. Only two of these six sites involved oxidative cleavage of a 5'-G.Pyr-3' sequence, but three sites were at the junction between single- and double-stranded regions of the RNA, consistent with a binding model in which the bithiazole + C-terminal substituent of bleomycin bind to minor groove structures on the RNA. Also studied were four tRNA transcripts believed on the basis of biochemical and chemical mapping experiments to share structural elements in common with the mature tRNAs. Cleavage of these tRNAs by Fe.bleomycin gave patterns of cleavage very different from each other and than those of the mature tRNAs. This observation suggests strongly that Fe.bleomycin cannot be used for chemical mapping in the same fashion as more classical reagents, such as Pb2+ or dimethyl sulfate. However, the great sensitivity of Fe.bleomycin to changes in nucleic acid structure argues that those species which do show similar patterns of cleavage must be very close in structure.

Usefulness of functional and structural solution data for the modeling of tRNA-like structures

Structures of large RNAs are not easily solved by X-ray crystallography or by NMR spectroscopy. This paper reviews the alternate methodology based on enzymatic and chemical mapping data collected on RNAs combined with graphical modeling for the construction of three-dimensional models. The different steps that lead to the establishment of the models are critically discussed. It is shown how the correctness of an RNA model can be strengthened by establishing correlations between the structure and the functionality of the molecule and its variants. Finally, the predictive potential of a model is discussed The approach is illustrated by results obtained on plant viral tRNA-like structures, and particularly on that of brome mosaic virus (BMV) RNA.

Mapping tRNA and 5S RNA tertiary structures by charge dependent Fe(II)-catalyzed cleavage

Chemical and enzymatic footprinting experiments have made it possible to identify protein binding sites in DNA and RNA, and to localize structural differences within nucleic acids to a resolution of a single base pair. We show here that by combining three reagents, Fe(II).EDTA2-, Fe(II).EDDA and Fe2+, differential maps of sites in RNA that vary in their local conformation and/or charge can be constructed. Comparison of profiles with respect to controls in the absence of a counterion such as Mg2+ allows analysis of sites responsive to tertiary structure. A single site that is labile to metals such as Pb2+ exists in tRNA(Phe) and a number of other tRNA's; this site is hyper-reactive to Fe(II), but not to the other probes. Scission induced by the neutral complex, Fe(II).EDDA, offers the most general measure of surface accessibility, since its distribution about the target molecule is insensitive to charge. Enhanced cleavage by Fe(II) relative to the other agents is detected at several adjacent sites in 5S RNA, consistent with conformational mobility. Protection at a series of positions in the arm formed by loops E and D with helix IV suggests further that at low temperature this arm interacts with loop A and helix I.

An NMR study of the HIV-1 TAR element hairpin

The TAR hairpin is an important part of the 5' long terminal repeat of HIV-1 and appears to be recognized by a cellular protein. A 14-base model of the native TAR hairpin 5'-GAGC[CUGGGA]-GCUC-3' (loop bases in square brackets) has been studied by proton, phosphorus, and natural abundance carbon NMR; these results are compared to other published NMR studies of the TAR hairpin. Assignments of all nonexchangeable protons and of all the stem-exchangeable protons have been made, as well as all phosphorus and many carbon resonances. Large J1'2' and J3'4' proton-proton coupling in the C5, G8, and G9 sugars indicate an equilibrium between C2'- and C3'-endo forms; these data show a dynamic loop structure. We see three broad imino resonances that have not been reported before; these resonances are in the right region for unbonded loop imino protons. These peaks suggest the protons are protected from fast exchange with the solvent by the structure of the hairpin loop. Simulated annealing and molecular dynamics with 148 distance constraints, 11 hydrogen bonds, and 84 torsion angle constraints showed a wide variety of structures. Certain trends are evident, such as continuation of the A-form helix on the 3' side of the hairpin loop. The ensemble of calculated structures agree with most chemical modification data.

Major groove accessibility of RNA

Chemical acylation experiments showed that the RNA major groove, often assumed to be too deep and narrow to permit recognition interactions, is accessible at duplex termini. Reactivity extended further into the helix in the 5' than in the 3' direction. Asymmetric and large loops between helices uncoupled them, which yielded both enhanced reactivity at terminal base pairs and weaker stabilization enthalpy compared to that in small loops or symmetric loops of the same size. Uncoupled helices have effective helix ends with accessible major grooves; such motifs are attractive contributors to protein recognition, tertiary folding, and catalysis.

A highly sensitive probe for guanine N7 in folded structures of RNA: application to tRNA(Phe) and Tetrahymena group I intron

A nickel complex has been shown to promote conformation-specific oxidation of guanosine in polynucleotide RNA. In all cases, reaction was strictly dependent on the solvent exposure and surface properties of guanine N7. Modification of native tRNA(Phe) (yeast) was detected at G18, G19, G20, and Gm34 and concurred with predictions based on its crystal structure. Additional guanine derivatives became exposed to oxidation only after the tRNA unfolded in the absence of Mg2+. Reaction of the Tetrahymena group I intron RNA (L-21 ScaI) also compared favorably to its three-dimensional model by appropriately identifying guanosine residues in hairpin loops, duplex termini, and the essential cofactor binding site. These results complemented prior data generated by hydroxyl radical, and in combination they served to distinguish the solvent accessibility of sugar backbone and base positions in guanosine residues. Most importantly, this nickel complex exhibited greater selectivity than either dimethyl sulfate or RNase T1 for characterizing tRNA(Phe) and intron RNA.

Effect of conformational features on the aminoacylation of tRNAs and consequences on the permutation of tRNA specificities

The structure and function of in vitro transcribed tRNA(Asp) variants with inserted conformational features characteristic of yeast tRNA(Phe), such as the length of the variable region or the arrangement of the conserved residues in the D-loop, have been investigated. Although they exhibit significant conformational alterations as revealed by Pb2+ treatment, these variants are still efficiently aspartylated by yeast aspartyl-tRNA synthetase. Thus, this synthetase can accommodate a variety of tRNA conformers. In a second series of variants, the identity determinants of yeast tRNA(Phe) were transplanted into the previous structural variants of tRNA(Asp). The phenylalanine acceptance of these variants improves with increasing the number of structural characteristics of tRNA(Phe), suggesting that phenylalanyl-tRNA synthetase is sensitive to the conformational frame embedding the cognate identity nucleotides. These results contrast with the efficient transplantation of tRNA(Asp) identity elements into yeast tRNA(Phe). This indicates that synthetases respond differently to the detailed conformation of their tRNA substrates. Efficient aminoacylation is not only dependent on the presence of the set of identity nucleotides, but also on a precise conformation of the tRNA.

RNA recognition by Tat-derived peptides: interaction in the major groove?

Replication of human immunodeficiency virus requires binding of the viral Tat protein to its RNA target sequence TAR; peptides derived from Tat bind to a TAR "contact site" spanning 5 bp and a trinucleotide pyrimidine bulge. We find that high affinity binding requires a U residue in the bulge loop and 2 specific adjacent base pairs. Other bulged RNAs bind in a lower affinity nonspecific manner; sequence-specific binding requires a bulge loop of more than 1 nucleotide. Reaction with diethyl pyrocarbonate indicates that one effect of the bulge is to make the otherwise deep and narrow RNA major groove accessible. A model consistent with these data involves local distortion of A-form geometry at the bulge, which bends the helix and permits protein binding and interactive access in the RNA major groove.

Solution structure of human U1 snRNA. Derivation of a possible three-dimensional model

The solution structure of human U1 snRNA was investigated by using base-specific chemical probes (dimethylsulfate, carbodiimide, diethylpyrocarbonate) and RNase V1. Chemical reagents were employed under various conditions of salt and temperature and allowed information at the Watson-Crick base-pairing positions to be obtained for 66% of the U1 snRNA bases. Double-stranded or stacked regions were examined with RNase V1. The dat gained from these experiments extend and support the previous 2D model for U1snRNA. However, to elucidate some aspects of the solution data that could not be accounted for by the secondary structure model, the information gathered from structure probing was used to provide the experimental basis required to construct and to test a tertiary structure model by computer graphics modeling. As a result, U1 snRNA is shown to adopt an asymmetrical X-shape that is formed by two helical domains, each one being generated by coaxial stacking of helices at the U1 snRNA cruciform. Chemical reactivities and model building show that a few nucleotides, previously proposed to be unpaired, can form A.G and U.U non Watson-Crick base-pairs, notably in stem-loop B. The structural model we propose for regions G12 to A124 integrates stereochemical constraints and is based both on solution structure data and sequence comparisons between U1 snRNAs.

Defining the inside and outside of a catalytic RNA molecule

Ribozymes are RNA molecules that catalyze biochemical reactions. Fe(II)-EDTA, a solvent-based reagent which cleaves both double- and single-stranded RNA, was used to investigate the structure of the Tetrahymena ribozyme. Regions of cleavage alternate with regions of substantial protection along the entire RNA molecule. In particular, most of the catalytic core shows greatly reduced cleavage. These data constitute experimental evidence that an RNA enzyme, like a protein enzyme, has an interior and an exterior. Determination of positions where the phosphodiester backbone of the RNA is on the inside or on the outside of the molecule provides major constraints for modeling the three-dimensional structure of the Tetrahymena ribozyme. This approach should be generally informative for structured RNA molecules.

Computer modeling from solution data of spinach chloroplast and of Xenopus laevis somatic and oocyte 5 S rRNAs

Detailed atomic models of a eubacterial 5 S rRNA (spinach chloroplast 5 S rRNA) and of a eukaryotic 5 S rRNA (somatic and oocyte 5 S rRNA from Xenopus laevis) were built using computer graphic. Both models integrate stereochemical constraints and experimental data on the accessibility of bases and phosphates towards several structure-specific probes. The base sequence was first inserted on to three-dimensional structural fragments picked up in a specially devised databank. The fragments were modified and assembled interactively on an Evans & Sutherland PS330. Modeling was finalized by stereochemical and energy refinement. In spite of some uncertainty in the relative spatial orientation of the substructures, the broad features of the models can be generalized and several conclusions can be reached: (1) both models adopt a distorted Y-shape structure, with helices B and D not far from colinearity; (2) no tertiary interactions exist between loop c and region d or loop e; (3) the internal loops, in particular region d, contain several non-canonical base-pairs of A.A, U.U and A.G types; (4) invariant residues appear to be more important for protein or RNA binding than for maintaining the tertiary structure. The models are corroborated by footprinting experiments with ribosomal proteins and by the analysis of various mutants. Such models help to clarify the structure-function relationship of 5 S rRNA and are useful for designing site-directed mutagenesis experiments.

Solution structure of a tRNA with a large variable region: yeast tRNASer

Different chemical reagents were used to study the tertiary structure of yeast tRNASer, a tRNA with a large variable region: ethylnitrosourea, which alkylates the phosphate groups; dimethylsulphate, which methylates N-7 of guanosine and N-3 of cytosine; and diethylpyrocarbonate, which modifies N-7 of adenine. The non-reactivity of N-3 of cytidine 47:1, 47:6, 47:7 and 47:8 and the reactivity of cytidine 47:3 confirms the existence of a variable stem of four base-pairs and a short variable loop of three residues. For the N-7 positions in purines, accessible residues are G1, G10, Gm18, G19, G30, I34, G35, A36, i6A37, G45, G47, G47:5, G47:9 and G73. The protection of N-7 atoms of residues G9, G15, A21, A22 and G47:9 reflects the tertiary folding. Strong phosphate protection was observed for P8 to P11, P20:1 to P22, P48 to P50 and for P59 and P60. A model was built on a PS300 graphic system on the basis of these data and its stereochemistry refined. While trying to keep most tertiary interactions, we adapted the tertiary folding of the known structures of tRNAAsp and tRNAPhe to the present sequence and solution data. The resulting model has the variable arm not far from the plane of the common L-shaped structure. A generalization of this model to other tRNAs with large variable regions is discussed.

Reaction of nucleic acid bases with alpha-acetylenic esters. Part IV. Preparation of an alkylating derivative of tRNA(Phe) by conformation-specific chemical modification

The reaction of yeast tRNA(Phe) with methyl chlorotetrolate, ClCH2-C identical to C-COOCH3, was studied. This reagent converts adenine and cytosine rings into derivatives in which an additional heterocycle bearing the alkylating chloromethyl group is fused to the original base; these derivatives can exist in two isomeric forms. Modified nucleosides of this type can be easily identified by reverse-phase HPLC. It was found that under native conditions, the modification of tRNA involves the anticodon loop and the 3'-end. The isomers of adenine derivatives formed in the anticodon loop were different from those formed in the 3'-end. It is suggested that the isomeric structure of the derivatives is related to the fine conformational differences between these two regions of tRNA(Phe). Methyl chlorotetrolate could thus be used as a conformational probe of single-stranded nucleic acids. Preliminary assays showed that modified tRNA(Phe) binds irreversibly to yeast phenylalanyl-tRNA synthetase.

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.

Iodo-Gen-mediated radioiodination of nucleic acids

Iodo-Gen (1,3,4,6-tetrachloro-3a,6a-diphenylglycoluril), widely used as an oxidizing agent for iodination of proteins, can also be used for iodination of nucleic acids. Optimal conditions were determined for efficient labeling of RNA and DNA with 125I. The proposed procedure for radioiodination of nucleic acids is more beneficial than the methods utilizing TlCl3 because of the milder reaction conditions, the simplicity and completeness of separation of reaction products from the oxidizing agents, and the absence of a toxic catalyst. Using the standard procedure for Iodo-Gen-mediated iodination a specific radioactivity of up to 1.3 X 10(9) dpm/micrograms RNA can be achieved. The proposed procedure is also suitable for radioiodination of DNA.

Three-dimensional model of the active site of the self-splicing rRNA precursor of Tetrahymena

The rRNA intervening sequence of Tetrahymena is a catalytic RNA molecule, or "ribozyme." A tertiary-structure model of the active site of this ribozyme has been constructed based on comparative sequence analysis of related group I intervening sequences, data on the accessibility of each nucleotide to chemical and enzymatic probes, and principles of RNA folding derived from a consideration of the structure of tRNA determined by x-ray crystallography. In the model, the catalytic center has a two-helix structural framework composed of the base-paired segments of the group I conserved sequence elements. The structural framework supports and orients the conserved nucleotides that are adjacent to the base-paired sequence elements; these conserved nucleotides are proposed to form the active site and to bind the 5' splice-site duplex and the guanine nucleotide substrate. Tests of the model are proposed.

Reactions of nucleic acid bases with alpha-acetylenic esters. Chemical modification of poly(A) and poly(C)

The reaction of chlorotetrolic (4-chloro-2-butynoic) esters with adenine and cytosine derivatives, in which a new heterocycle bearing an alkylating chloromethyl side chain is fused to the purine or pyrimidine ring, was extended to poly(A) and poly(C) used as models of nucleic acids. The derivatization proceeds under mild conditions and its extent can be controlled by the reaction time. The additional rings can exist in two isomeric forms and the nature of the isomer formed depends on steric factors in the vicinity of the reacting base. The reaction with chlorotetrolic esters discriminates between the single-stranded (reactive) and double-stranded (unreactive) forms, between the exposed an hidden adenine and cytosine bases and even between the exposed and sterically hindered fragments of the base moiety and thus allows structural investigations of these nucleic acids. The chloromethyl group of the derivatized nucleobases can be used to bind the modified polymers to other molecules.

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.

In vitro construction of yeast tRNAAsp variants: nucleotide substitutions and additions in T-stem and T-loop

A procedure for the construction of 3'-end labelled yeast tRNAAsp harboring substitutions or additions of any desired nucleotide in T-stem and T-loop (position 57 to 61) has been developed. This was done by in vitro enzymatic manipulations of the yeast tRNAAsp involving specific hydrolysis with RNases, phosphorylation and dephosphorylation with T4 polynucleotide kinase and ligation with T4 RNA ligase. Using this procedure we have replaced conserved or semi-conserved nucleotides located in position 57 to 61 of yeast tRNAAsp. We have also constructed different yeast tRNAAsp with eight bases instead of seven in T-loop. Further use of these tRNAAsp variants will be discussed with the help of the crystallographic three-dimensional structure.

Local mobility of nucleic acids as determined from crystallographic data. II. Z-form DNA

Directions and magnitudes of the local mobility of the Z-DNA hexamer duplex CpGpCpGpCpG have been determined by crystallographic refinement of anisotropic displacement parameters using the observed X-ray diffraction data. The cytidine and guanosine residues demonstrate different modes of mobility, implying that a dinucleotide is the smallest repeating unit in terms of flexibility as well as structure. Directions of librational and translational mobility of the cytidine and guanosine residues of Z-DNA are similar to those observed for the same nucleotides in B-DNA. This suggests that the local mobility of DNA is primarily determined by the individual nucleotide type and by the constraints of Watson-Crick base-pairing, rather than by helical form. Differences in the magnitudes of mobility may be responsible for some of the different physical properties of B-DNA and Z-DNA. The B to Z transition is discussed in terms of the observed flexibilities of these two helical forms.

Yeast tRNAAsp tertiary structure in solution and areas of interaction of the tRNA with aspartyl-tRNA synthetase. A comparative study of the yeast phenylalanine system by phosphate alkylation experiments with ethylnitrosourea

Ethylnitrosourea is an alkylating reagent preferentially modifying phosphate groups in nucleic acids. It was used to monitor the tertiary structure, in solution, of yeast tRNAAsp and to determine those phosphate groups in contact with the cognate aspartyl-tRNA synthetase. Experiments involve 3' or 5'-end-labelled tRNA molecules, low yield modification of the free or complexed nucleic acid and specific splitting at the modified phosphate groups. The resulting end-labelled oligonucleotides are resolved on polyacrylamide sequencing gels and data analysed by autoradiography and densitometry. Experiments were conducted in parallel on yeast tRNAAsp and on tRNAPhe. In that way it was possible to compare the solution structure of two elongator tRNAs and to interpret the modification data using the known crystal structures of both tRNAs. Mapping of the phosphates in free tRNAAsp and tRNAPhe allowed the detection of differential reactivities for phosphates 8, 18, 19, 20, 22, 23, 24 and 49: phosphates 18, 19, 23, 24 and 49 are more reactive in tRNAAsp, while phosphates 8, 20 and 22 are more reactive in tRNAPhe. All other phosphates display similar reactivities in both tRNAs, in particular phosphate 60 in the T-loop, which is strongly protected. Most of these data are explained by the crystal structures of the tRNAs. Thermal transitions in tRNAAsp could be followed by chemical modifications of phosphates. Results indicate that the D-arm is more flexible than the T-loop. The phosphates in yeast tRNAAsp in contact with aspartyl-tRNA synthetase are essentially contained in three continuous stretches, including those at the corner of the amino acid accepting and D-arm, at the 5' side of the acceptor stem and in the variable loop. When represented in the three-dimensional structure of the tRNAAsp, it clearly appears that one side of the L-shaped tRNA molecule, that comprising the variable loop, is in contact with aspartyl-tRNA synthetase. In yeast tRNAPhe interacting with phenylalanyl-tRNA synthetase, the distribution of protected phosphates is different, although phosphates in the anticodon stem and variable loop are involved in both systems. With tRNAPhe, the data cannot be accommodated by the interaction model found for tRNAAsp, but they are consistent with the diagonal side model proposed by Rich & Schimmel (1977). The existence of different interaction schemes between tRNAs and aminoacyl-tRNA synthetases, correlated with the oligomeric structure of the enzyme, is proposed.

Molecular models for DNA damaged by photoreaction

Structural models of a DNA molecule containing a radiation-induced psoralen cross-link and of a DNA containing a thymine photodimer were constructed by applying energy-minimization techniques and model-building procedures to data from x-ray crystallographic studies. The helical axes of the models show substantial kinking and unwinding at the sites of the damage, which may have long-range as well as local effects arising from the concomitant changes in the supercoiling and overall structure of the DNA. The damaged areas may also serve as recognition sites for repair enzymes. These results should help in understanding the biologic effects of radiation-induced damage on cells.

Chemical conversion of cytidine residues into 4-thiouridines in yeast tRNAPhe. Determination of the modified cytidines

Treatment of yeast phenylalanine tRNA with pressurized hydrogen sulfide results in conversion of cytidine residues into 4-thiouridine residues. Under conditions leading to an average modification of one cytidine per tRNA molecule 9 positions are thiolated. The 4-thiouridine residues are distributed along the tRNA molecule. Four of the reactive cytidines are located in single-stranded regions: Cm32 , C60 , C74 and C75 . The five others are located in base pairs: C2, C27, C56 , C61 and C63 . Importance of replacement of an amino group by a thiol group on hydrogen bonding and on biological activity of the modified tRNA is discussed.

A new theoretical index of biochemical reactivity combining steric and electrostatic factors. An application to yeast tRNAPhe

A new theoretical index of the chemical reactivity of sites within macromolecules is developed, which combines both steric and electrostatic factors. It is applied to the study of yeast tRNAPhe and the results obtained are compared with known experimental reactivities. A comparison indicates the superiority of the new index over the sole use of the surface accessibility.

Tertiary structure of animal tRNATrp in solution and interaction of tRNATrp with tryptophanyl-tRNA synthetase

Alkylation in beef tRNATrp of phosphodiester bonds by ethylnitrosourea and of N-7 in guanosines and N-3 in cytidines by dimethyl sulfate and carbethoxylation of N-7 in adenosines by diethyl pyrocarbonate were investigated under various conditions. This enabled us to probe the accessibility of tRNA functional groups and to investigate the structure of tRNATrp in solution as well as its interactions with tryptophanyl-tRNA synthetase. The phosphate reactivity towards ethylnitrosourea of unfolded tRNA was compared to that of native tRNA. The pattern of phosphate alkylation of tRNATrp is very similar to that found with other tRNAs studied before using the same approach with protected phosphates mainly located in the D and T psi arms. Base modification experiments showed a striking similarity in the reactivity of conserved bases known to be involved in secondary and tertiary interactions. Differences are found with yeast tRNAPhe since beef tRNATrp showed a more stable D stem and a less stable T psi stem. When alkylation by ethylnitrosourea was studied with the tRNATrp X tryptophanyl-tRNA synthetase complex we found that phosphates located at the 5' side of the anticodon stem and in the anticodon loop were strongly protected against the reagent. The alkylation at the N-3 position of the two cytidines in the CCA anticodon was clearly diminished in the synthetase X tRNA complex as compared with the modification in free tRNATrp; in contrast the two cytidines of the terminal CCA in the acceptor stem are not protected by the synthetase. The involvement of the anticodon region of tRNATrp in the recognition process with tryptophanyl-tRNA synthetase was confirmed in nuclease S1 mapping experiments.