Factors beyond Enolase 2 and Mitochondrial Lysyl-tRNA Synthetase Precursor Are Required for tRNA Import into Yeast Mitochondria.

In yeast, the import of tRNALys with CUU anticodon (tRK1) relies on a complex mechanism where interaction with enolase 2 (Eno2p) dictates a deep conformational change of the tRNA. This event is believed to mask the tRNA from the cytosolic translational machinery to re-direct it towards the mitochondria. Once near the mitochondrial outer membrane, the precursor of the mitochondrial lysyl-tRNA synthetase (preMsk1p) takes over enolase to carry the tRNA within the mitochondrial matrix, where it is supposed to participate in translation following correct refolding. Biochemical data presented in this report focus on the role of enolase. They show that despite the inability of Eno2p alone to form a complex with tRK1, mitochondrial import can be recapitulated in vitro using fractions of yeast extracts sharing either recombinant or endogenous yeast Eno2p as one of the main components. Taken together, our data suggest the existence of a protein complex containing Eno2p that is involved in RNA mitochondrial import.

The N-terminus of HIV-1 Tat protein is essential for Tat-TAR RNA interaction.

The human HIV transactivator protein Tat is essential for efficient viral transcription that occurs by a complex mechanism involving interaction of Tat with the TAR RNA element. This interaction appears to require the mediation of a cellular protein, cyclin T1. However, the possibility that Tat and TAR associate in a binary Tat-TAR complex has been little investigated. Using a chemically synthesized active Tat protein, the kinetic and equilibrium parameters of its interaction with TAR were determined by surface plasmon resonance technology. Independently of partner and method of immobilization onto the sensor chip, the association (k(a) = 5-9 x 10(5) M(-1) s(-1)) and dissociation rate constants (k(d) = 1.7-4.3 x 10(-3) s(-1)) yielded similar equilibrium dissociation constants (K(d) = 2-8 nM). A truncated peptide encompassing residues 30-86 of Tat did not bind to TAR at all. We conclude that Tat can form a high-affinity complex with TAR in the absence of cyclin T1 and that the N-terminal domain of Tat is essential for this interaction, suggesting a conformational link between this domain and the basic domain of Tat. These results are important in our quest for developing therapeutic compounds that impair viral replication.

A universal mode of helix packing in RNA.

RNA molecules fold into specific three-dimensional shapes to perform structural and catalytic functions. Large RNAs can form compact globular structures, but the chemical basis for close helical packing within these molecules has been unclear. Analysis of transfer, catalysis, in vitro-selected and ribosomal RNAs reveal that helical packing predominantly involves the interaction of single-stranded adenosines with a helix minor groove. Using the Tetrahymena thermophila group I ribozyme, we show here that the near-perfect shape complementarity between the adenine base and the minor groove allows for optimal van der Waals contacts, extensive hydrogen bonding and hydrophobic surface burial, creating a highly energetically favorable interaction. Adenosine is recognized in a chemically similar fashion by a combination of protein and RNA components in the ribonucleoprotein core of the signal recognition particle. These results provide a thermodynamic explanation for the noted abundance of conserved adenosines within the unpaired regions of RNA secondary structures.

On the wobble GoU and related pairs.

The wobble GoU pairs have been implicated in several biological processes where RNA molecules play a key role. We review the geometrical and conformational properties of wobble GoU pairs on the basis of available crystal structures of RNAs at high resolution. The similarities with the wobble A+oC pairs and UoU pairs are illustrated, while the differences with the recently discovered bifurcated G x U pairs are contrasted.

A sulfate pocket formed by three GoU pairs in the 0.97 A resolution X-ray structure of a nonameric RNA.

The crystal structure of the RNA duplex [r(CGUGAUCG)dC]2 has been solved at a resolution of 0.97 A. The model has been refined to R-work and R-free of 14.88% and 19.54% for 23,838 independent reflections. The base-pairing scheme forces the 5'-rC to be excluded from the helix and to be disordered. In the crystals, the sequence promotes the formation of two GoU wobble pairs that cluster around a crystallographic threefold axis in two different ways. In the first contact type, the GoU pairs are exclusively surrounded by water molecules, whereas in the other contact type, the three amino groups of the guanine residues of the symmetry-related GoU pairs trap a sulfate ion. This work provides the first example of the interaction of a GoU pair with a sulfate ion in a helical context. Despite the negative charge on the polynucleotide backbone, the guanine amino N2 is able to attract negatively charged groups that could, in the folding of complex RNA molecules, belong to a negative phosphodiester group from a neighboring strand and, in a RNA-protein complex, to a negative carboxyl group of an aspartate or glutamate side chain.

Context dependent RNA-RNA recognition in a three-dimensional model of the 16S rRNA core.

A 3-D model of the core of the 16S rRNA of Escherichia coli containing 328 residues has been built in the protein map derived from neutron scattering data with the help of all the available phylogenetic, biochemical, and cross-linking data. The three pseudoknots of the 16S-core cluster, through the arrangement of complex three-, four- and five-way junctions, around the neck and at the subunit interface. The roles in assembly, initiation or elongation of the three pseudoknots in ribosomal dynamics are emphasized. The 530-loop, localized on the periphery of the 30S particle, could be built with and without a pseudoknot independently of the state of the particle. The pseudoknot of the central domain controls the dynamics of an helix connected to the subunit interface which could trigger some mechanism during translation. The process of the model construction is compatible with a folding scenario in which the 5'-terminal pseudoknot controls the assembly of the central junction and the subsequent folding of the 3'-major domain. The modelling, together with the phylogenetic analysis and the experimental data, point to several potential RNA-RNA contacts which depend on the structural and sequence context in which they occur.

Inter-domain cross-linking and molecular modelling of the hairpin ribozyme.

The hairpin ribozyme is a small catalytic RNA composed of two helical domains containing a small and a large internal loop and, thus, constitutes a valuable paradigm for the study of RNA structure and catalysis. We have carried out molecular modelling of the hairpin ribozyme to learn how the two domains (A and B) might fold and approach each other. To help distinguish alternative inter-domain orientations, we have chemically synthesized hairpin ribozymes containing 2'-2' disulphide linkages of known spacing (12 or 16 A) between defined ribose residues in the internal loop regions of each domain. The abilities of cross-linked ribozymes to carry out RNA cleavage under single turnover conditions were compared to the corresponding disulphide-reduced, untethered ribozymes. Ribozymes were classed in three categories according to whether their cleavage rates were marginally, moderately, or strongly affected by cross-linking. This rank order of activity guided the docking of the two domains in the molecular modelling process. The proposed three-dimensional model of the hairpin ribozyme incorporates three different crystallographically determined structural motifs: in domain A, the 5'-GAR-3'-motif of the hammerhead ribozyme, in domain B, the J4/5 motif of group I ribozymes, and connecting the two domains, a "ribose zipper", another group I ribozyme feature, formed between the hydroxyl groups of residues A10, G11 of domain A and C25, A24 of domain B. This latter feature might be key to the selection and precise orientation of the inter-domain docking necessary for the specific phosphodiester cleavage. The model provides an important basis for further studies of hairpin ribozyme structure and function.

The 16S rRNA binding site of Thermus thermophilus ribosomal protein S15: comparison with Escherichia coli S15, minimum site and structure.

Binding of Escherichia coli and Thermus thermophilus ribosomal proteins S15 to a 16S ribosomal RNA fragment from T. thermophilus (nt 559-753) has been investigated in detail by extensive deletion analysis, filter-binding assays, gel mobility shift, structure probing, footprinting with chemical, enzymatic, and hydroxyl radical probes. Both S15 proteins recognize two distinct sites. The first one maps in the bottom of helix 638-655/717-734 (H22) and in the three-way junction between helix 560-570/737-747 (H20), helix 571-600/606-634 (H21), and H22. The second is located in a conserved purine-rich region in the center of H22. The first site provides a higher contribution to the free energy of binding than the second one, and both are required for efficient binding. A short RNA fragment of 56 nt containing these elements binds S15 with high affinity. The structure of the rRNA is constrained by the three-way junction and requires both magnesium and S15 to be stabilized. A 3D model, derived by computer modeling with the use of experimental data, suggests that the bound form adopts a Y-shaped conformation, with a quasi-coaxial stacking of H22 on H20, and H21 forming an acute angle with H22. In this model, S15 binds to the shallow groove of the RNA on the exterior side of the Y-shaped structure, making contact with the two sites, which are separated by one helix turn.

RNA tectonics: towards RNA design.

Our understanding of the structural, folding and catalytic properties of RNA molecules has increased enormously in recent years. The discovery of catalytic RNA molecules by Sidney Altman and Tom Cech, the development of in vitro selection procedures, and the recent crystallizations of hammerhead ribozymes and of a large domain of an autocatalytic group 1 intron are some of the milestones that have contributed to the explosion of the RNA field. The availability of a three-dimensional model for the catalytic core of group 1 introns contributed also a heuristic drive toward the development of new techniques and approaches for unravelling RNA architecture, folding and stability. Here, we emphasize the mosaic structure of RNA and review some of the recent literature pertinent to this working framework. In the long run, RNA tectonics aims at constructing combinatorial libraries, using RNA mosaic units for creating molecules with dedicated shapes and properties.