Novel techniques in nuclear magnetic resonance for nucleic acids

Naturally-occurring modification restricts the anticodon domain conformational space of tRNA(Phe)

Post-transcriptional modifications contribute chemistry and structure to RNAs. Modifications of tRNA at nucleoside 37, 3'-adjacent to the anticodon, are particularly interesting because they facilitate codon recognition and negate translational frame-shifting. To assess if the functional contribution of a position 37-modified nucleoside defines a specific structure or restricts conformational flexibility, structures of the yeast tRNA(Phe) anticodon stem and loop (ASL(Phe)) with naturally occurring modified nucleosides differing only at position 37, ASL(Phe)-(Cm(32),Gm(34),m(5)C(40)), and ASL(Phe)-(Cm(32),Gm(34),m(1)G(37),m(5)C(40)), were determined by NMR spectroscopy and restrained molecular dynamics. The ASL structures had similarly resolved stems (RMSD approximately 0.6A) of five canonical base-pairs in standard A-form RNA. The "NOE walk" was evident on the 5' and 3' sides of the stems of both RNAs, and extended to the adjacent loop nucleosides. The NOESY cross-peaks involving U(33) H2' and characteristic of tRNA's anticodon domain U-turn were present but weak, whereas those involving the U(33) H1' proton were absent from the spectra of both ASLs. However, ASL(Phe)-(Cm(32),Gm(34),m(1)G(37),m(5)C(40)) exhibited the downfield shifted 31P resonance of U(33)pGm(34) indicative of U-turns; ASL(Phe)-(Cm(32),Gm(34),m(5)C(40)) did not. An unusual "backwards" NOE between Gm(34) and A(35) (Gm(34)/H8 to A(35)/H1') was observed in both molecules. The RNAs exhibited a protonated A(+)(38) resulting in the final structures having C(32).A(+)(38) intra-loop base-pairs, with that of ASL(Phe)-(Cm(32),Gm(34),m(1)G(37),m(5)C(40)) being especially well defined. A single family of low-energy structures of ASL(Phe)-(Cm(32),Gm(34), m(1)G(37),m(5)C(40)) (loop RMSD 0.98A) exhibited a significantly restricted conformational space for the anticodon loop in comparison to that of ASL(Phe)-(Cm(32),Gm(34),m(5)C(40)) (loop RMSD 2.58A). In addition, the ASL(Phe)-(Cm(32),Gm(34),m(1)G(37),m(5)C(40)) average structure had a greater degree of similarity to that of the yeast tRNA(Phe) crystal structure. A comparison of the resulting structures indicates that modification of position 37 affects the accuracy of decoding and the maintenance of the mRNA reading frame by restricting anticodon loop conformational space.

The synthesis of deuterionucleosides

The synthesis of deuterionucleosides for site-specific incorporation into oligo-DNA or -RAA is herein reviewed for NMR or biological studies. The review covers the following aspects: (i) deuteration of the aglycone; (ii) single-site chemical deuteration of the sugar residues; (iii) multiple-site chemical deuteration of the sugar residues; (iv) enzymatic synthesis of deuterated nucleosides or nucleotides; and (v) synthesis of labelled nucleosides with multiple isotopes

Recent solution structures of RNA and its complexes with drugs, peptides and proteins

The past two years have seen remarkable progress in the study of RNA structure: the predicted era of RNA structural biology has arrived. Crystallographic structures of the hammerhead ribozyme and of a large subunit of a group I self-splicing intron have begun to reveal the structural basis of RNA enzymatic activity. A remarkable number of structures of small RNAs and of complexes with drugs, peptides and one protein domain have been determined by NMR.

Initial analysis of 750 MHz NMR spectra of selective 15N-G,U labelled E. coli 5S rRNA

The overall folding of an RNA molecule is reflected in its base pairing pattern. The identification of that pattern provides a first step towards the determination of the structure of an RNA molecule. We show that the application of heteronuclear NMR methods at 750 MHz to E. coli 5S rRNA (120 nucleotides) selectively labelled with 15N in guanine and uridine allows observation of base pairing patterns for a larger RNA molecule. We also present evidence that the fold of the E-domain of the 5S rRNA (nt 79-97) as a contiguous part of the 5S rRNA and as an isolated molecule is virtually the same.

The use of non-uniform deuterium labelling ['NMR-window'] to study the NMR structure of a 21mer RNA hairpin

The first synthesis of a non-uniformly deuterium labelled 21mer RNA is reported using our 'NMR-window' concept, showing its unique application in the unambiguous NMR assignment of the non-exchangeable aromatic and sugar protons.