Loop stereochemistry and dynamics in transfer RNA

The stereochemistry and the dynamics of two loops of yeast tRNA-asp, the thymine loop and the anticodon loop, are compared in the hope of a better understanding of the relationships between loop sequence and loop topology. Both loops are seven residues long and both present sharp turns after the second residue, U33 and psi 55, stabilized by hydrogen bonds between N3-H of the pyrimidine and the phosphates of C36 and A58 and stacking interactions of the pyrimidine ring with the phosphates of U35 and A57, respectively. In the thymine loop, the two purines following C56, A57 and A58, open up to leave space for the intercalation of the first invariant guanine residue of the D-loop, while the two pyrimidine bases, which follow A58, turn away from the stacking pattern of the thymine arm and stack instead with the last base pair of the dihydrouridine arm A15-U48. In the anticodon loop, however, the bases G34 to C38 form an helical stack in continuity with the anticodon stem on the 3'-end. At the same time C36 forms Watson-Crick hydrogen bonds with G34 of a twofold symmetrically related molecule. The anticodon-anticodon base pairing interactions between symmetrically-related molecules are stabilized by stacking with the modified base G37 on both sides of the triplet. Some comparisons are made with the structure of yeast tRNA-phe and some implications about the structure of mitochondrial tRNAs are discussed.     

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

Chemical reactivities of the functional groups of yeast phenylalanine transfer RNA are compared with surface accessibilities of the groups calculated with various probe radii representing effective radii of the chemical reagents used. We observe 97% agreement with the hypothesis that the chemically modified bases are those with the greatest surface accessibility. This overall strong correlation supports the conclusion that base exposure in an important determinant of chemical modification in this polynucleotide.     

Loop Stereochemistry and Dynamics in Transfer RNA

Abstract

The stereochemistry and the dynamics of two loops of yeast tRNA-asp, the thymine loop and the anticodon loop, are compared in the hope of a better understanding of the relationships between loop sequence and loop topology. Both loops are seven residues long and both present sharp turns after the second residue, U33 and ψ55, stabilized by hydrogen bonds between N3-H of the pyrimidine and the phosphates of C36 and A58 and stacking interactions of the pyrimidine ring with the phosphates of U35 and A57, respectively. In the thymine loop, the two purines following C56, A57 and A58, open up to leave space for the intercalation of the first invariant guanine residue of the D-loop, while the two pyrimidine bases, which follow A58, turn away from the stacking pattern of the thymine arm and stack instead with the last base pair of the dihydrouridine arm A15-U48. In the anticodon loop, however, the bases G34 to C38 form an helical stack in continuity with the anticodon stem on the 3′-end. At the same time C36 forms Watson-Crick hydrogen bonds with G34 of a twofold symmetrically related molecule. The anticodon-anticodon base pairing interactions between symmetrically-related molecules are stabilized by stacking with the modified base G37 on both sides of the triplet. Some comparisons are made with the structure of yeast tRNA-phe and some implications about the structure of mitochondrial tRNAs are discussed.     

Coarse-Grained Prediction of RNA Loop Structures

One of the key issues in the theoretical prediction of RNA folding is the prediction of loop structure from the sequence. RNA loop free energies are dependent on the loop sequence content. However, most current models account only for the loop length-dependence. The previously developed “Vfold” model (a coarse-grained RNA folding model) provides an effective method to generate the complete ensemble of coarse-grained RNA loop and junction conformations. However, due to the lack of sequence-dependent scoring parameters, the method is unable to identify the native and near-native structures from the sequence. In this study, using a previously developed iterative method for extracting the knowledge-based potential parameters from the known structures, we derive a set of dinucleotide-based statistical potentials for RNA loops and junctions. A unique advantage of the approach is its ability to go beyond the the (known) native structures by accounting for the full free energy landscape, including all the nonnative folds. The benchmark tests indicate that for given loop/junction sequences, the statistical potentials enable successful predictions for the coarse-grained 3D structures from the complete conformational ensemble generated by the Vfold model. The predicted coarse-grained structures can provide useful initial folds for further detailed structural refinement.     

Brain transfer RNA

Transfer RNAs were isolated from rat and calf brains and their nucleosides were analysed by tritium derivative technique. Qualitative changes in the minor nucleoside components were compared on the fluorograms which showed differences in the intensities of spots. Cerebellar and cortical tRNAs were also compared, but revealed no significant quantitative differences in their methylated constituants despite 60% higher methyltransferase activity observed in cerebellum compared to cerebral cortex. An overall similarity was noticed between the relative proportions of the major and minor nucleosides of tRNAs derived from rat or calf brain, expressed as mol %. Brain tRNA was also analysed by two-dimensional polyacrylamide gel electrophoresis which showed qualitative and quantitative changes during postnatal development.     

Local RNA conformational dynamics revealed by 2-aminopurine solvent accessibility

Acrylamide quenching is widely used to monitor the solvent exposure of fluorescent probes in vitro. Here, we tested the utility of this technique to discriminate local RNA secondary structures using the fluorescent adenine analogue 2-aminopurine (2-AP). Under native conditions, the solvent accessibilities of most 2-AP-labeled RNA substrates were poorly resolved by classical single-population models; rather, a two-state quencher accessibility algorithm was required to model acrylamide-dependent changes in 2-AP fluorescence in structured RNA contexts. Comparing 2-AP quenching parameters between structured and unstructured RNA substrates permitted the effects of local RNA structure on 2-AP solvent exposure to be distinguished from nearest neighbor effects or environmental influences on intrinsic 2-AP photophysics. Using this strategy, the fractional accessibility of 2-AP for acrylamide ( f a) was found to be highly sensitive to local RNA structure. Base-paired 2-AP exhibited relatively poor accessibility, consistent with extensive shielding by adjacent bases. 2-AP in a single-base bulge was uniformly accessible to solvent, whereas the fractional accessibility of 2-AP in a hexanucleotide loop was indistinguishable from that of an unstructured RNA. However, these studies also provided evidence that the f a parameter reflects local conformational dynamics in base-paired RNA. Enhanced base pair dynamics at elevated temperatures were accompanied by increased f a values, while restricting local RNA breathing by adding a C-G base pair clamp or positioning 2-AP within extended RNA duplexes significantly decreased this parameter. Together, these studies show that 2-AP quenching studies can reveal local RNA structural and dynamic features beyond those that can be measured by conventional spectroscopic approaches.     

Chemical accessibility of the 4.5S RNA in spinach chloroplast ribosomes.

We have examined the accessibility to diethylpyrocarbonate of spinach chloroplast 4.5S ribosomal RNA when free and when it is part of the ribosomal structure. The modifications in free 4.5S RNA were found mostly in single-stranded regions of the secondary structure model proposed in our previous paper (Kumagai, I. et al. (1982) J.B.C. 257, 12924-28): adenines at positions 17, 19, 33, 36, 54, 55, 60, 64, 68, 72, 77, 86 and 87 were identified as the reactive residues. On the other hand, in 4.5S RNA in 70S ribosomes or 50S subunits, adenine 33 was exclusively modified, and its reactivity was much higher than in free 4.5S RNA. This highly accessible A33 of spinach 4.5S RNA is located within a characteristic seven nucleotide sequence, which is found in the 4.5S rRNAs from spinach, tobacco and a fern but deleted in 4.5S RNAs from maize and wheat.     

Evolution of transfer RNA

Evolution by gene duplication and subsequent divergence is indicated by similarities common to 43 different transfer RNAs. Pairwise comparisons of these tRNAs reveal additional similarity, greatest for certain pairs of tRNAs for the same amino acid in the same organism, and also occurring in certain pairs of tRNAs for different amino acids in the same organism. Although tRNAs functionally interact with several other molecules, there have been surprisingly few restrictions on the divergence of their primary structures. This divergence has proceeded so far that clear phylogenetic separations are absent in most cases: it it impossible to construct a coherent phylogeny for most of the 43. Selection and stochastic processes have both been active in the evolution of tRNA. Selection has favored moderate change more than expected and has reduced radical change below that expected from stochastic processes alone. Two obvious effects of selection are nine invariant loci, another five that are always purines and five others that are always pyrimidines, in the tRNAs involved in protein synthesis. In addition to these constraints in the primary nucleotide sequence, the method of “identical site equivalents”, introduced here, demonstrates that further constraints exist equivalent to about 12 additional invariant loci. These “invisible” restraints reflect disperse chemical forces maintaining the tertiary structure and reducing evolutionary divergence to an extent quantitatively comparable to that of the nine observable invariant loci. The average divergence (49·4%) for pairs of tRNAs for different amino acids involved in protein synthesis represents an equilibrium between natural selection and stochastic processes. These tRNAs have had time to diverge nearly to the 75% maximum expected from stochastic process alone; this is shown by comparing the two glycine tRNAs involved in peptidoglycan synthesis with tRNAs for different amino acids participating in polypeptide synthesis. The rates of nucleotide replacements in genes coding for the tRNAs and the cytochromes c are about the same: 2 × 10 ^?10 replacements per nucleotide site per year.     

Phylogeny of transfer RNA

Phylogenetic trees of transfer RNA specific for phenylalanine, methionine initiator glycine and valine are constructed. Although the exact relationships between taxa cannot be obtained from the mere analysis of the sequences some conclusions can be drawn about the evolution of this molecule.This research was supported by DAAD (Germany) and Comité de Investigaciones de la Universidad de los Andes Bogotá, Columbia. Dedicated to my Son Andres Felipe.     

Phylogeny of transfer RNA

Phylogenetic trees of transfer RNA specific for phenylalanine, methionine initiator glycine and valine are constructed. Although the exact relationships between taxa cannot be obtained from the mere analysis of the sequences some conclusions can be drawn about the evolution of this molecule.     

Secondary structure in transfer RNA genes

The bacterial strand of the heteroduplex of λh80 dglyTsu⁺₃₆tyrTthrT with λh80 carries a cluster of three transfer RNA genes. The bacterial strands of the heteroduplexes of φ80hpsu^+,?_III and φ80hpsu^?_III with φ80h carry two and one genes for tyrosine tRNA, respectively. When these heteroduplexes are spread under weakly denaturing conditions (low formamide), secondary structure features consisting of one or several closely clustered, short duplex regions (folds) are observed. The features map at the positions of the tRNA gene clusters. They are not seen if the DNA is hybridized to Escherichia coli tRNA. It is concluded that the secondary structure features are due to self-complementary sequences in the tRNA genes. In some cases, the duplex folds appear to involve base pairing between sequences on different tRNA genes of a cluster and may also involve the spacer sequences between the tRNA sequences.     

Thiolated nucleotides in yeast transfer RNA

By culturing Saccharomyces cerevisiae in growth medium containing Mg³⁵SO₄, we have determined the extent and variation of tRNA thiolation in this yeast. We find that 5-methoxycarbonylmethyl-2-thiouridine (mcm⁵s²U)¹ is the major, if not only, thiolated derivative in S. cerevisiae tRNA. In addition, a comparison of the chromatographic mobility of mcm⁵s²Up on cellulose thin layers with those reported for unknown uridine derivatives found in purified yeast tRNA digests, leads to the conclusion that at least two of these tRNAs contain this modification.