Structural domains of transfer RNA molecules

Genetic analysis of structure and function in phage T4 tRNASer

We have determined the nucleotide sequences of 55 spontaneous mutations that inactivate a suppressor gene of phage T4 tRNASer. Most of the mutations caused substitutions or deletions of single nucleotides at 18 different positions in the tRNA. Two of three mutations that allowed the synthesis of mature tRNA had nucleotide substitutions at the junction of the dihydrouridine and anticodon stems, suggesting that this region of tRNASer is important for aminoacylation. The third mutation that synthesized tRNA had a nucleotide deletion in the anticodon loop, which presumably affected the translational capacity of the tRNA. We also sequenced 58 spontaneous reversion mutations derived from strains with the inactive suppressor genes. Some of these regenerated the initial tRNA sequence, while other generated a second-site mutation in the tRNA. These second-site mutations restored helical base-pairings to the tRNA that had been eliminated by the initial mutations. The new base-pairings involved G.C and A.U, and the A.C wobble pair at certain positions in the tRNA. This finding establishes the existence of A.C wobble pair in tRNA helices.

Nucleotides that contribute to the identity of Escherichia coli tRNA(Phe)

A series of sequence variants of amber suppressor genes of tRNA(Phe) were synthesized in vitro and cloned in Escherichia coli to examine the contributions of individual nucleotides to identity for amino acid acceptance. Three different but complementary types of tRNA variants were constructed. The first involved the substitution of base-pairs on the cloverleaf stem regions of the E. coli tRNA(Phe). The second type of variant involved total gene synthesis based on wild-type tRNA(Phe) sequences found in Bacillus subtilis and in Halobacterium volcanii. In the third type of variant, the identity of E. coli tRNALys was changed to that of tRNA(Phe). The nucleotides which are important for tRNA(Phe) identity in E. coli are located on the corner of the L-shaped tRNA molecule, where the dihydrouridine loop interacts with the T loop, and extend to the interior opening of the anticodon stem and the adjoining variable loop. The nucleotide sequence on the dihydrouridine stem region, which joins the corner and stem regions, was not successfully studied though it may contribute to tRNA(Phe) identity. The fourth nucleotide from the 3' end of tRNA(Phe) has some importance for identity.

A simple structural feature is a major determinant of the identity of a transfer RNA

Analysis of a series of mutants of an Escherichia coli alanine transfer RNA shows that substitution of a single G-U base pair in the acceptor helix eliminates aminoacylation with alanine in vivo and in vitro. Introduction of that base pair into the analogous position of a cysteine and a phenylalanine transfer RNA confers upon each the ability to be aminoacylated with alanine. Thus, as little as a single base pair can direct an amino acid to a specific transfer RNA.

Changing the identity of a tRNA by introducing a G-U wobble pair near the 3' acceptor end

Although the genetic code for protein was established in the 1960's, the basis for amino acid identity of transfer RNA (tRNA) has remained unknown. To investigate the identity of a tRNA, the nucleotides at three computer-identified positions in tRNAPhe (phenylalanine tRNA) were replaced with the corresponding nucleotides from tRNAAla (alanine tRNA). The identity of the resulting tRNA, when examined as an amber suppressor in Escherichia coli, was that of tRNAAla.

Biochemical and physical characterization of an unmodified yeast phenylalanine transfer RNA transcribed in vitro

A recombinant plasmid was constructed with six synthetic DNA oligomers such that the DNA sequence corresponding to yeast tRNA(Phe) is flanked by a T7 promoter and a BstNI restriction site. Runoff transcription of the BstNI-digested plasmid with T7 RNA polymerase gives an unmodified tRNA of the expected sequence having correct 5' and 3' termini. This tRNA(Phe) transcript can be specifically aminoacylated by yeast phenylalanyl-tRNA synthetase and has a Km only 4-fold higher than that of the native yeast tRNA(Phe). The Km is independent of Mg2+ concentration, whereas the Vmax is very dependent on Mg2+ concentration. Comparison of the melting profiles of the native and the unmodified tRNA(Phe) at different Mg2+ concentrations suggests that the unmodified tRNA(Phe) has a less stable tertiary structure. Using one additional DNA oligomer, a mutant plasmid was constructed having a guanosine to thymidine change at position 20 in the tRNA gene. A decrease in Vmax/Km by a factor of 14 for aminoacylation of the mutant tRNA(Phe) transcript is observed.

Reading frame selection and transfer RNA anticodon loop stacking

Messenger RNA's are translated in successive three-nucleotide steps (a reading frame), therefore decoding must proceed in only one of three possible frames. A molecular model for correct propagation of the frame is presented based on (i) the measured translational properties of transfer RNA's (tRNA's) that contain an extra nucleotide in the anticodon loop and (ii) a straightforward concept about anticodon loop structure. The model explains the high accuracy of reading frame maintenance by normal tRNA's, as well as activities of all characterized frameshift suppressor tRNA's that have altered anticodon loops.

The chemistry of self-splicing RNA and RNA enzymes

Proteins are not the only catalysts of cellular reactions; there is a growing list of RNA molecules that catalyze RNA cleavage and joining reactions. The chemical mechanisms of RNA-catalyzed reactions are discussed with emphasis on the self-splicing ribosomal RNA precursor of Tetrahymena and the enzymatic activities of its intervening sequence RNA. Wherever appropriate, catalysis by RNA is compared to catalysis by protein enzymes.

3-D graphics modelling of the tRNA-like 3'-end of turnip yellow mosaic virus RNA: structural and functional implications

The tRNA-like structure of the aminoacylatable 3'-end of turnip yellow mosaic virus (TYMV) RNA was submitted to 3-D graphics modelling. A model of this structure has been inferred previously from both biochemical results and sequence comparisons which presents a new RNA folding feature, the "pseudoknot". It has been verified that this structure can be constructed without compromising accepted RNA stereochemical rules, namely base stacking and preferential 3'-endo sugar pucker. The model has aided interpretation of previous structural mapping experiments using chemical and enzymatic probes, and new accessibilities of residues could be predicted and tested. Pseudoknots have been considered as potential splice sites because they form antiparallel helical segments in a single RNA molecule. We have examined this possibility with the constructed 3-D model and could verify the hypothesis on a structural basis. The model presents a striking similarity with canonical tRNA and allows a valuable comparison between the protection patterns of yeast tRNA(Val) and tRNA-like viral RNA by cognate yeast valyl-tRNA synthetase against structural probes.

Actions of the anticodon arm in translation on the phenotypes of RNA mutants

In previous publications, we have shown that it is practical to study the translational activity of tRNAs by replacement and alteration of the anticodon arm sequence of the genus on a plasmid clone. Experiments in which the anticodon arm sequence is transplanted between tRNA genes suggest that the translational activity is determined by these sequences. We have therefore made every variant of the anticodon loop and the three base-pairs of the stem proximal to the loop, in order to resolve the relation between the structure of Su7Am tRNATrp, and its function. All derivatives conserved the normal secondary structure of the molecule, which was known to be essential for translational activity. The probability of translation of the amber codon by these suppressors is measured in this work. This translational activity in vivo is rationalized in terms of data on the copy numbers of the plasmid clones, the nucleotide modifications of the tRNAs, the steady-state level of the mature tRNA, and the aminoacylation of these molecules. Nucleotide modification levels vary among these tRNAs, giving information about the specificities of modification systems that make O-methylribose, pseudouridine, and modified A in the anticodon arm. However, for this series of tRNAs, none of these modifications has a strong effect on translational efficiency of the tRNAs. A few of the substitutions reduce aminoacylation of the tRNAs with glutamine, as determined by comparison of suppression in normal strains and related strains, which have 25-fold elevated levels of the glutaminyl-tRNA synthetase (GlnRS). The substitutions that have the largest effect on GlnRS action are, unexpectedly, purines for conserved pyrimidines on the 5' side of the anticodon loop. Data on the concentrations of tRNA in vivo suggest that the anticodon loop and helix contribute similarly to the determination of the steady-state level of the tRNAs. This level varies sevenfold, though all tRNAs are processed from a homologous precursor made from the same transcription unit. Effects on levels appear to be mediated by changes in anticodon arm structure. A robust equation that relates aminoacyl-tRNA levels to suppressor efficiency is developed in order to resolve effects on tRNA levels and on ribosomal steps: E = A/(K + A), where E is efficiency, A is aminoacyl-tRNA concentration, and K is the effective concentration, or cellular tRNA content required for an individual tRNA to have an efficiency of 0.50. The tRNAs vary in their intrinsic ability to function on the ribosome (represented by K), after other influences have been normalized.(ABSTRACT TRUNCATED AT 400 WORDS)

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.

Refined crystal structure of an octanucleotide duplex with G . T mismatched base-pairs

Single crystal X-ray diffraction techniques have been used to determine the structure of the DNA octamer d(G-G-G-G-C-T-C-C) at a resolution of 2.25 A. The asymmetric unit consists of two strands coiled about each other to produce an A-type DNA helix. The double helix contains six G . C Watson-Crick base-pairs and two G . T mismatched base-pairs. The mismatches adopt a "wobble" type structure in which both bases retain their major tautomer forms. The double helix is able to accommodate this G . T pairing with little distortion of the overall helical conformation. Crystals of this octamer melt at a substantially lower temperature than do those of a related octamer also containing two G . T base-pairs. We attribute this destabilization to disruption of the hydration network around the mismatch site combined with changes in intermolecular packing. Full details are given of conformational parameters, base stacking, intermolecular contacts and hydration involving 52 solvent molecules.

Primordial reading of genetic information

From the consideration of general features of the anticodon loop and stem in tRNA and the properties of present-day translation, we put forward a plausible scenario to explain the evolution of the genetic code from a highly ambiguous triplet code to the present refined decoding system. Our model based on the reading of the code suggests that the anticodon of primordial tRNA could adopt either the 3' or the 5' stacked conformation permitting the formation of the "best two out of three" base pairs, either the first and second codon position or the second and third. Progressive acquisition of precise structural constraint and the modification of bases in the anticodon loop would give way eventually to the less ambiguous "two out of three" reading mechanism having only the 3' stacked conformation. Further adjustments of base composition and modification leads inevitably to the present generalized code. In this way the primordial code encoding 4-8 amino acids or related derivates evolves smoothly to the present code having 20 amino acids.

Proton exchange and base-pair kinetics of poly(rA).poly(rU) and poly(rI).poly(rC)

Proton exchange of poly(rA).poly(rU) and poly(rI).poly(rC) has been studied by nuclear magnetic resonance line broadening and saturation transfer from H2O. Five exchangeable peaks are observed. They are assigned to the imino, amino and 2'-OH ribose protons. The aromatic spectrum is also assigned. Contrary to previous observations, we find that the exchange of the imino proton is strongly buffer sensitive. This property is used to derive the base-pair lifetime, which is in the range of milliseconds at 27 degrees C, 100 times smaller than published values. The enthalpy for the base-opening reaction (-86 kJ/mol) and the insensitivity of the reaction to magnesium suggest that the open state involves a small number of base-pairs. The similarities in the exchange from the two duplexes indicate that the same open state is responsible for exchange of purine and pyrimidine imino protons. For the lifetime of the open state and for the base-pair dissociation constant, we obtain only lower limits. At 27 degrees C they are three microseconds and 10(-3), respectively. The analysis that yields the much larger values published previously is based on the assumption that amino protons exchange only from open base-pairs. But theory and preliminary experiments indicate that it may occur from the closed duplex. The exchange of amino protons is slower than that of the imino protons. Exchange of the 2'-OH protons from the duplexes is much slower than from single-stranded poly(rU), and it is accelerated by magnesium. This could indicate hydrogen-bonding to backbone phosphate. Discrepancies between our results and those of previous studies are discussed.

Crystallographic refinement of yeast aspartic acid transfer RNA

The structure of yeast transfer RNA aspartic acid has been refined in one crystal form to 3 A resolution using the restrained least-squares method of Hendrickson and Konnert and real-space fitting using the FRODO program of Jones. The final crystallographic discrepancy index R is 23.5% for 4585 reflections with magnitudes twice their standard deviations between 10 and 3 A. With lower occupancies for some residues of the D-loop, the phosphate U1, and the base U33, the R-factor is 22.3%. The adaptation of the restrained least-squares program for nucleic acids and the progress of the refinement are described. The conformations are analysed with respect to stereochemistry and folding of the backbone. The contacts and hydrogen bonds of the secondary structure are compared with those of yeast tRNAPhe. The presence of only four bases in the variable loop, instead of five as in yeast tRNAPhe, leads to a rotation of residue 48 and a lateral movement of residue 46. These two rearrangements induce different environments for [U8 . . . A14] . . . A21 as well as for A9 and G45. Otherwise, all tertiary contacts observed in yeast tRNAPhe are present in yeast tRNAAsp, except for the absence of hydrogen-bonding between G18 of the D-loop and C56 of the T-loop. The presence of anticodon triplet pairing leads to a distribution of temperature factors different from that observed in yeast tRNAPhe with a stabilization of the AC stem-and-loop and a destabilization of the T and D-loops. We are inclined to suggest that the labilization of the interactions between the T and D-loops is a consequence of the interaction of the anticodon triplets of symmetry-related molecules through hydrogen bonding, which mimics the interaction between the anticodon and its cognate codon on the messenger RNA.

Specific replacement of functional groups of uridine-33 in yeast phenylalanine transfer ribonucleic acid

Functional groups of the highly conserved uridine at position 33 in the anticodon loop of yeast tRNAPhe were altered by a synthetic protocol that replaces U-33 with any desired nucleotide and leaves all other nucleotides of the tRNA intact. The U-33-substituted tRNAs were prepared in an eight-step protocol that begins with partial cleavage of tRNAPhe at U-33 by ribonuclease A. By use of the combined half-molecules as substrate, U-33 was removed from the 5' half-molecule in three steps and then replaced by using RNA ligase to add the desired nucleoside 3',5'-bisphosphate. Each position 33 substituted 5' half-molecule was isolated and annealed to the original 3' half-molecule from the ribonuclease A digestion. The two halves were then rejoined in three steps to give a full-size tRNAPhe variant. This protocol should be applicable to other RNA molecules where a nucleotide substitution is desired at the 5' side of an available unique cleavage site. Seven substituted tRNAPheS containing uridine, pseudouridine, 3-methyluridine, 2'-O-methyluridine, cytidine, deoxycytidine, and purine riboside at position 33 were assayed for aminoacylation with yeast phenylalanyl-tRNA synthetase. Each of the seven tRNAs aminoacylated normally. Thus, unlike the adjacent guanine residue at position 34, U-33 is not involved in the interaction between yeast tRNAPhe and yeast phenylalanyl-tRNA synthetase.

A new principle of RNA folding based on pseudoknotting

Tertiary interactions involving hairpin or interior loops of RNA can lead to extended quasi-continuous double helical stem regions, consisting of coaxially stacked segments of duplex RNA, bridged by single-stranded connections. This type of compact folding plays a role in various strategic regions of RNA molecules. Their role in ribosome functioning, RNA splicing and recognition of tRNA-like structures is discussed.

Origins of life: conformational energy calculations on primitive tRNA nestling an amino acid

We report conformational energy calculations on our proposal of a molecular interaction theory for the origin of the nucleic acid-directed, adaptor-mediated synthesis of proteins that links the phenomena of chemical and biological evolution. A particular conformation of a pentanucleotide turns out to be a double-sided template for a primitive decoding system. It is able to neatly nestle an amino acid via hydrogen bonds, and this complex is found to be an energetically favourable conformation. The total potential energy of the complex is calculated using semi-empirical potential energy functions. A local-minimum conformation is obtained and its features are reported. The template conformation of the pentanucleotide is found to have an energy value far lower than a regular helical conformation. When the amino acid is nestled in the cleft of the template-conformation through specific hydrogen bonds, the energy is further lowered. A D-amino acid nestled into the PIT (Primitive tRNA) is found to be less stable than its L counterpart, as revealed by energy calculations.

Suppressor sufJ: a novel type of tRNA mutant that induces translational frameshifting

We describe the DNA sequence change responsible for the creation of a frameshift-suppressor gene in Salmonella typhimurium. The suppressor, sufJ, results from a base-pair insertion in the gene coding for a threonine transfer RNA (tRNA3Thr). Unlike previously studied frameshift suppressor mutations, the sufJ insertion does not fall within the sequence corresponding to the tRNA anticodon. The insertion (a G.C base pair) occurs within a run of three G.C base pairs in that region of the gene coding for one strand of the anticodon stem. In the secondary structure of the mature tRNA, the net result is that an extra, unpaired cytidine residue is pushed into the anticodon loop, thus increasing the size of the loop to eight nucleotides. These findings are discussed in connection with the peculiar "three-out-of-four" method of reading by the sufJ suppressor. A unifying model is presented accounting for the contrasting decoding behaviors of tRNAs with eight-nucleotide-long anticodon loops.

The solution structure of a RNA pentadecamer comprising the anticodon loop and stem of yeast tRNAPhe. A 500 MHz 1H-n.m.r. study

A 500 MHz 1H-n.m.r. study on the semi-synthetic RNA pentadecamer 5'-r(C-A-G-A-Cm-U-Gm-A-A-Y-A-psi-m5C-U-G) comprising the anticodon loop and stem (residues 28-42) of yeast tRNAPhe is presented. By using pre-steady-state nuclear-Overhauser-effect measurements all exchangeable and non-exchangeable base proton resonances, all H1' ribose resonances and all methyl proton resonances are assigned and over 70 intra- and inter-nucleotide interproton distances determined. From the distance data the solution structure of the pentadecamer is solved by model-building. It is shown that the pentadecamer adopts a hairpin-loop structure in solution with the loop in a 3'-stacked conformation. This structure is both qualitatively and quantitatively remarkably similar to that of the anticodon loop and stem found in the crystal structures of tRNAPhe with an overall root-mean-square difference of 0.12 nm between the interproton distances determined by n.m.r. and X-ray crystallography. The hairpin-loop solution structure of the pentadecamer is very stable with a 'melting' temperature of 53 degrees C in 500 mM-KCl, and the structural features responsible for this high stability are discussed. Interaction of the pentadecamer with the ribotrinucleoside diphosphate UpUpC, one of the codons for the amino acid phenylalanine, results only in minor perturbations in the structure of the pentadecamer, and the 3'-stacked conformation of the loop is preserved. The stability of the pentadecamer-UpUpC complex (K approximately 2.5 X 10(4) M-1 at 0 degrees C) is approximately an order of magnitude greater than that of the tRNAPhe-UpUpC complex.

2'-O-methyl-1-methyl adenosine: a new modified nucleoside in ragi (Eleusine coracana) tRNA

A new modified nucleoside 2'-O-methyl-l-methyl adenosine has been found to be present in the tRNA of Eleusine coracana ( ragi ) seedlings. The sequence of the dinucleotide of which this modified nucleoside is a part suggests its presence in phenylalanine-tRNA. The structural implications of the presence of this new modification are discussed.

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.

Mapping of psoralen cross-linked nucleotides in RNA

A method is described for using the cross-linking reagent 4'-(hydroxy-methyl)-4,5',8-trimethylpsoralen (HMT) to map base paired regions and higher-order structure within RNA molecules. Applying this method to yeast tRNAPhe, we have specifically identified cross-links within the acceptor stem between U6 X U68, in the D-stem between C11 X C25, and in the T psi-stem between U50 X C63 and U52 X C63. We have also identified a unique cross-link between U8 X C48 which are trans pyrimidines in the core region due to tertiary interactions between U8:A14 and C48:G15. The precise point of cross-linking was deduced in every case by using purine-specific U2 ribonuclease along with cytidine-specific CL3 ribonuclease which will anomalously cleave after photoreversed pyrimidines. The ability to map the precise point of cross-linking should prove invaluable in identifying nucleotides in close proximity within the tertiary structure of other RNA molecules.

Interactions between avian myeloblastosis reverse transcriptase and tRNATrp. Mapping of complexed tRNA with chemicals and nucleases

The interactions between beef tRNATrp with avian myeloblastosis reverse transcriptase have been studied by statistical chemical modifications of phosphate (ethylnitrosourea) and cytidine (dimethyl sulfate) residues, as well as by digestion of complexed tRNA by Cobra venom nuclease and Neurospora crassa endonuclease. Results with nucleases and chemicals show that reverse transcriptase interacts preferentially with the D arm, the anticodon stem and the T psi stem. All these regions are located in the outside of the L-shaped structure of tRNA. This domain of interaction is different to that reported previously in the complex of beef tRNA with the cognate aminoacyl-tRNA synthetase (M. Garret et al.; Eur. J. Biochem. In press). Avian reverse transcriptase destabilizes the region of tRNA where most of the tertiary interactions maintaining the structure of tRNA are located.

Computer-aided nucleic acid secondary structure modeling incorporating enzymatic digestion data

We present a computer-aided method for determining nucleic acid secondary structure. The method utilizes a program which has the capability to filter matrix diagonal data on the basis of diagonal length, stabilization energy, and chemical and enzymatic data. The program also allows the user to assign selected regions of the structure as uniquely single-stranded or paired, and to filter out "trade-off" structures on the basis of such pairing. In order to demonstrate the utility of the program we present a preliminary secondary structure for the 3' end of alfalfa mosaic virus RNA 4 (AMV-4 RNA). This structure is based on an analysis which includes the use of in vitro partial enzymatic digestion of the RNA.

U1, U2 and U5 small nuclear RNAs are found in plants cells. Complete nucleotide sequence of the U5 RNA family from pea nuclei

U1, U2 and U5 RNAs were isolated from pea nuclei with antibody specific for 2,2,7-trimethylguanosine. The nucleotide sequence of the 3'-terminal halves of pea U1 and U2 snRNAs and the complete sequence of five out of the six U5 RNA variants isolated is given. The high number of U5 variants suggest they are encoded by a multigene family containing at least six different genes. Similar secondary structures could be derived for all of the pea U5 RNAs and although the degree of sequence conservation between plant and vertebrate U5 RNAs is as low as 35%, nearly identical secondary structures can be proposed for both RNA groups. All the snRNA species U1, U2 and U5 from pea share a structural domain, the so-called domain A, which is also common to all animal snRNA U1, U2, U4 and U5. Furthermore, a block of 22 consecutive nucleotides is conserved among pea and vertebrate U5 RNAs, from which 11 nucleotides constitute a hairpin-loop with a high number of posttranscriptional modifications. We propose that conservation of this hairpin-loop, together with domain A, is of prime importance for the functioning of U5 RNAs in plant and animal cells.

Conformational analysis of m4(2)C-m4(2)C-m6(2)A: a chemically modified 3'-acceptor end of tRNA, studied by NMR and CD methods

A study on the conformation of the title compound, C-C-A, and on its constituent dinucleotides is presented. 1H-NMR spectra at 360 and 500 MHz were completely assigned by decoupling experiments. Computer simulation of the spectra yielded precise proton-proton and proton-phosphorus coupling constant values. The coupling constants are analyzed in terms of torsion angles and of N- and S-type sugar pucker. 31P-NMR spectra gave some information about P-O backbone torsion angles alpha and zeta. CD spectroscopy was used to obtain insight in the base-base interaction. The C(1) and C(2) unit in C-C-A show normal preference for N-type conformation of the sugar ring, whereas the A(3) residue appears rather biased towards the S-conformation. The zeta and alpha backbone torsion angles in the C-C phosphodiester linkage in C-C-A appear to assume normal g-, g- conformation, the zeta, alpha combination in the C-A linkage is proposed to have a g+, t conformation. In the C-C fragment in C-C-A a regular stack is indicated; it is suggested that the C-A part adopts an unusual antiparallel base stack.

Uridine-33 in yeast tRNA not essential for amber suppression

The nucleotide at position 33 on the 5' side of the anticodon of almost all tRNAs is a uridine. Crystallographic studies of different tRNAs reveal that although the precise orientation of uridine-33 is not always the same, it connects the anticodon stacked along the 3' side of the loop with the pyrimidine-32 stacked on the 5' side of the loop. The remarkably conserved nature of uridine-33 and its unique position in the anticodon loop structure has led to suggestions that this nucleotide has an essential role in the translational mechanism. We have developed a biochemical procedure to replace nucleotides 33-35 in yeast tRNATyr with any desired sequence and used it to construct amber suppressor tRNAs having different nucleotides at position 33. As all of these synthetic amber suppressor tRNAs functioned well in eukaryotic in vitro suppression assays, we conclude that uridine-33 does not have an obligatory role in the translation mechanism.

Base-base interactions in nucleic acids containing A-T base pairs. Structure of poly[d(A-T)]

The Watson-Crick type of base pairing is considered to be mandatory for the formation of duplex DNA. However, conformational calculations carried out in our laboratory, have shown that some combinations of backbone torsion angles and sugar pucker lead to duplexes with Hoogsteen type of base pairing also. Here we present the results of energy calculations performed on A-T containing doublet sequences in the D-form with both Hoogsteen and Watson-Crick type of base pairing and the 3 viable models for the A-T containing polynucleotide duplex poly[d(A-T)].

NMR study of slowly exchanging imino protons in yeast tRNAasp

We have monitored the exchange of imino and amino protons by NMR after quick transfer of yeast tRNAAsp in 2H2O solvent. When the concentration of exchange-catalyzing buffer is not too high, one imino proton exchanges considerably more slowly than any other (e.g., 100 hr versus 4 hr for the second-slowest imino proton at 18 degrees C in 15 mM Mg). This provides excellent conditions for identification, by the nuclear Overhauser effect, of the slowest exchanging proton, which we show to be the imino proton of the U-8 . A-14 reverse Hoogsteen tertiary-structure base pair; other slowly exchanging protons are identified as imino protons from A . U-11 and G . psi-13. In preliminary experiments, we find that the exchange of these protons is catalyzed by cacodylate or Tris buffer. The lifetimes of two other imino protons, ca. 10 min at 28 degrees C, are buffer independent. Slowly exchanging amino protons have also been observed. Correlation with the exchange of the uracil-8 imino proton suggests that they may be from adenine-14.

NMR analyses on the molecular mechanism of the conformational rigidity of 2-thioribothymidine, a modified nucleoside in extreme thermophile tRNAs

1H-NMR analyses have been made on the conformations of 2-thioribothymidine (s2T), 2-thiodeoxyribothymidine (s2dT), as well as ribothymidine (T) and deoxyribothymidine (dT). s2T and s2dT exclusively take the anti form rather than the syn form. The C3'-endo-gg form of the sugar moiety is remarkably stabilized on modification of T to s2T, but not on modification of dT to s2dT. The steric effects of the 2-thiocarbonyl group and the 2'-hydroxyl group cause the rigidity of the C3'-endo-gg form of s2T. Such rigidity of s2T probably contributes to the thermostability of 2-thiopyrimidine polyribonucleotides and extreme thermophile tRNAs.

A conformational rationale for the wobble behaviour of the first base of the anticodon triplet in tRNA

We present a conformational rationale for wobble behaviour of the first base in the anticodon triplet of tRNA and hence for the well-known degeneracy of the genetic code. The U-turn hydrogen bond plays an important role in the structure of the anticodon arm and particularly for the anticodon triplet to be in a geometry suitable for the process of recognition in the adaptor-mediated synthesis of proteins. This hydrogen bond in turn precludes a hydrogen bond between the first two sugars of the anticodon triplet, allowing the first base to wobble, while it facilitates one between the second and third sugars of the triplet, positioning these bases for the standard base-pairing with the codon. This neatly explains why there is a degeneracy in the code and why a RNA happens to be the adaptor for protein synthesis. Relevent conformational calculations are presented in support of the theory.

Isolation and characterization of a tRNA(guanine-7-)-methyltransferase from Salmonella typhimurium

The tRNA modifying enzyme, S-adenosylmethionine:tRNA(guanine-7-)-methyltransferase, has been extensively purified from Salmonella typhimurium. A rapid and efficient purification method using phosphocellulose chromatography followed by ammonium sulfate precipitation and Sephadex G-100 gel filtration is described. The enzyme appears to be a single polypeptide chain with a molecular weight of approximately 25 000--30 000 daltons. The Km for S-adenosylmethionine and for undermethylated tRNA is 53 microM and 3.4 microM, respectively. The methylation reaction is dependent on added monovalent or divalent cations; 5 mM spermidine, 3 mM MgCl2 and 1 mM spermine are the most effective. The enzyme, though not homogeneous, is free from contaminating ribonucleases and other tRNA methyltransferases.

The primary structures of three yeast mitochondrial serine tRNA isoacceptors

Yeast mitochondria contain several isoaccepting species of serine-tRNA. The relative amount of these isoacceptors varies according to the conditions used to grow the yeast cells. In order to gain insight into the structural differences among these isoacceptors, the three mitochondrial tRNAsSer, which are present in derepressed yeast cells, have been sequenced. The primary structure of tRNASer1 differs considerably from that of tRNASer2; these two isoacceptors have only 39 nucleotides in common. In contrast, tRNASer3 differs from tRNASer2 by only one post-transcriptional modification: the psi residue in position 28 of tRNASer2 is replaced by a normal U in tRNASer3. Unlike tRNASer2 and tRNASer3, the primary sequence of tRNASer1 shows two unusual structural features: it has a D in position 14 instead of the "universal" A14 of the standard tRNA cloverleaf and it contains two G residues between the D-stem and the anticodon-stem. Considering their respective anticodons, tRNASer1 should recognize the two serine codons A-G-C and A-G-U, whereas both tRNASer2 and tRNASer3 should recognize all four serine codons of the U-C-N series.

Theoretical mechanisms for synthesis of carcinogen-induced embryonic proteins: XI. A theoretical interpretation of the sequential methylation of yeast phenylalanine tRNA

Theoretical studies on the mechanisms of methylation of tRNA was reported in a previous paper dealing with the induction of genic activity of proposed "embryonic" tRNA methylases. The mechanism described only the first methylation of a tRNA that had a known structure, namely yeast phenylalanine tRNA. In this paper, a complete scheme of methylation for the molecule is reported in detail using molecular model building. The mechanism uses only one specific uridine residue with which S-adenosyl-L-methionine complexes for all required methylation sites.

Role of the constant uridine in binding of yeast tRNAPhe anticodon arm to 30S ribosomes

Twenty-two anticodon arm analogues were prepared by joining different tetra, penta, and hexaribonucleotides to a nine nucleotide fragment of yeast tRNAPhe with T4 RNA ligase. The oligomer with the same sequence as the anticodon arm of tRNAPhe bind poly U programmed 30S ribosomes with affinity similar to intact tRNAPhe. Analogues with an additional nucleotide in the loop bind ribosomes with a weaker affinity whereas analogues with one less nucleotide in the loop do not bind ribosomes at all. Reasonably tight binding of anticodon arms with different nucleotides on the 5' side of the anticodon suggest that positions 32 and 33 in the tRNAPhe sequence are not essential for ribosome binding. However, differences in the binding constants for anticodon arms containing modified uridine residues in the "constant uridine" position suggest that both of the internal "U turn" hydrogen bonds predicted by the X-ray crystal structure are necessary for maximal ribosome binding.

Structure and conformation of pseudouridine analogues

The structural and conformational features of the "anomeric" DL-trans- and DL-cis-5-(3-hydroxytetrahydrofuran-2-yl)uracils (3a, 4a) and five similar analogues were studied in order to determine their applicability as models of beta- and alpha-pseudouridine. The 270-MHz proton NMR spectra were measured for all analogues to define their ring geometries in solution and to estimate the solution population of model N, S conformers in a two-state dynamic equilibrium treatment. Two sets of calculations were employed to evaluate the relative contributions of these states to the observed vicinal coupling constants related to the C(3')-C(4') fragment. In the first, similar geometries were assumed for each pair of conformers, while in the second, limited to 3, the geometries were those derived from X-ray crystallographic data; both gave comparable results. The cis analogues 4a and 4b are excellent conformational models for alpha-pseudouridine. In the trans series (3a-c), the equilibrium is weighted toward the N conformer (approximately 80%), differing from that found in beta-pseudouridine for which each model conformer is equally populated. Possible implications of the conformational effects upon the pairing properties of pseudouridine in tRNA are discussed.

Molecular structure of a double helix that has non-Watson-Crick type base pairing formed by 2-substituted poly(A) and poly(U)

X-ray fiber diffraction studies of duplexes formed by 2-substituted poly(A) and poly(U) provide evidence for the existence of a double helical structure of poly(A).poly(U) held together by Hoogsteen-type base pairing with parallel chain polarity.

Mapping tRNA structure in solution using double-strand-specific ribonuclease V1 from cobra venom

A method for mapping all base-paired stems in both elongation and initiator tRNAs is described using double-stranded-specific ribonuclease V1 from the venom of the cobra Naja naja oxiana. 32p-end-labeled RNA is first partially digested with double-strand-specific V1 nuclease under near physiological conditions, and the resultant fragments are than electrophoretically fractionated by size in adjacent lanes of a polyacrylamide gel run in 90% formamide. After autoradiography, the base-paired nucleotides are definitively located by comparing V1 generated bands with fragments of known length produced by both Neurospora endonuclease and base-specific ribonucleases. Using the substrates yeast tRNAPhe an E, coli tRNAfMet of known three-dimensional structure, we find V1 nuclease to cleave entirely within every base-paired stem. Our studies also reveal that nuclease V1 will digest paired nucleotides not hydrogen-bonded by standard Watson-Crick base-pairing. In yeast tRNAPhe cleavage of both wobble base-pairs and nucleotides involved in tertiary base-base hydrogen bonding is demonstrated.

Conformational flexibility in single-stranded oligonucleotides: crystal structure of a hydrated calcium salt of adenylyl-(3'--5')-adenosine

The crystal and molecular structure of a hydrated calcium salt of adenylyl-(3'--5')-adenosine(ApA) was determined from X-ray diffraction data collected on an automated diffractometer. Crystals of the salt are orthorhombic, space group P21212, with a = 30.614 (3), b = 17.894 (2), and c = 5.373 (1) A. The structure was solved by a combination of Patterson and direct methods and refined by least squares. The final value of the R index is 0.08. The 5'-terminal adenosine residue has a C(2')-endo ribose and assumes a syn conformation, which is stabilized by an O(5')-H...N(3) hydrogen bond within the nucleoside. The 3'-terminal nucleoside has a C(3')-endo ribose and is in the anti conformation. Both omega and omega', the torsion angles within the phosphodiester group, are approximately 60 degrees. Adenine bases from adjacent anions are joined by pairs of N(6)-H...N(1) hydrogen bonds and are stacked with symmetry-related bases. The calcium ion is bound to the dinucleoside phosphate by a direct interaction with the phosphate group and by outer-sphere, ligand-mediated interactions with O(2') of the 5'-terminal nucleoside and N(7) of the 3'-terminal nucleoside. This tridentate interaction of the ApA anion with the calcium coordination sphere probably enhances the stability of the observed ApA conformation. When combined with other crystallographic studies of ApA conformations, the crystal structure of this calcium salt provides additional evidence that dinucleoside phosphates have considerable conformational flexibility.

Unusual structures in single-stranded ribonucleic acid: proton nuclear magnetic resonance of AUCCA in deuterium oxide

Conformational features of the oligoribonucleic acid (oligo-RNA) A1-U2-C3-C4-A5 are explored by proton nuclear magnetic resonance (NMR). The sequence is a molecular cognate of a portion of the T psi C loop and stem regions of yeast tRNAPhe. The molecule forms at least two classes of flexible yet ordered structures. Class I states are similar in spectral properties to the component oligomers, AU, AUC, and AUCC, and are likely to be standard right-helical structures. Class II states are characterized by a 2'-endo pucker at A1 and unusually large shielding of several C3 and U2 protons. Most of these features are consistent with identifying the class II solution structures with the "arch" conformation for the T psi C region determined by X-ray crystallography of yeast tRNAPhe.