Synthesis and Evaluation of Novel Neamine-Nucleoside Conjugates as Potential Antibiotic Targets for Escherichia coli 16S Ribosomal RNA.

Based on the nucleobase rich character of the binding pocket of A-site 16S ribosomal RNA of Escherichia coli, it was proposed that the neamine moiety of synthesized Neamine-nucleoside conjugates could bind to the groove of RNA while the nucleobase moiety would bind specifically to the sequence of the 16S rRNA A-site fragment. Thus the designed conjugate compound 5 was found to have the same dissociation constant as neamine for binding to 16S rRNA and the neamine-amino acid substituted nucleoside conjugate 8 and 9 showed 6.3 and 4.8 times greater RNA binding affinity, respectively, as compared with neamine. The results obtained successfully demonstrate the need for chemically modifying neamine and probe the changes induced using NMR protocols to assist in the discovery of new aminoglycoside antibiotics.

NMR elucidation of the role of Mg2+ in the structure and stability of the conserved RNA motifs of the EMCV IRES element.

The three dimensional solution structures of a highly conserved 16mer RNA, endowed with a classic 'GNRA' tetraloop motif, and a 17mer RNA containing a cytosine-rich heptaloop which is predicted to be a potential receptor for the former RNA, of the I-domain of Encephalomyocarditis virus IRES have been determined by NMR spectroscopy. As Mg(2+) plays an important role in the activity of the IRES, the corresponding NMR structures of the Mg(2+) bound RNA complexes have also been determined. These RNA NMR structures, 16mer (21 constraints per residue), 16mer RNA/Mg(2+) (21 constraints per residue), 17mer (17 constraints per residue) and 17mer RNA/Mg(2+) (16 constraints per residue), were calculated to a high degree of precision with low RMSDs and low clash scores represent, to the best our knowledge, the first structures of a type II picornavirus IRES. Conformational analysis of the average structure showed that the RNAs and their Mg(2+) complexes adopt characteristic A-form helical structures, stabilised by canonical and non-canonical interactions in both the stem and loop regions. The GCGA tetraloop of the 16mer folds into a standard GNRA conformation, with the structural role of A550 being in the form of a G547.A550 sheared base-pair made up of two hydrogen bonds. Further, the previously uncharacterised AACCCCA heptaloop present in the 17mer forms a compact tertiary loop motif, held together by strong π-π interactions. Analysis of the NMR structures demonstrates that the role of Mg(2+) is principally to confer enhanced stability to the RNAs whereby the tetra- and heptaloops can achieve optimum conformation for any RNA-RNA interactions which are crucial for understanding the structure-function relationship of the IRES.

NMR characterisation of a highly conserved secondary structural RNA motif of Halobacterium halobium 23S rRNA.

The highly conserved 29-mer RNA motif corresponding to the peptidyl transferase central circle region of the domain V of Halobacterium halobium 23S rRNA has been characterised by multidimensional NMR spectroscopy. The NMR structure has a good all atom average RMSD of 1.28 Å and a stable A-form helical conformation. The NMR structure differs from the X-ray crystal structure of an analogous motif, contained within the Escherichia coli ribosome, as none of the bases are flipped out and a number of non-canonical base pairs are formed in the solution structure. Thus in the observed NMR structure, the predicted A7 to U30 base pair is not seen and a non-canonical U6 to U30 base pair was formed in its place. Similarly the predicted A9 to U26 base pair was also not observed and another non-canonical A9 to A27 base pair was formed. It was also seen from the conformational analysis that the steps near the bulges had the greatest deviation from the canonical Watson-Crick base pair step parameters. Despite these differences, the 29-mer structure provides a working model of the RNA within the ribosome in a more natural solution state than that observed in the intact ribosome crystal structures, particularly around the A27 residue. The NMR structure determination of the 29-mer RNA motif provides a solid foundation for determining the NMR structure of the RNA-amicetin complex in the next step. To extend the above study, a fully (13)C and (15)N isotopically labelled 37-mer RNA version of the Halobacterium halobium RNA sample has been characterised using ultra high field 1 GHz spectroscopy. The results have been used to demonstrate the advantages conferred by the use of a 1 GHz spectrometer frequency over 800 MHz in terms of superior sensitivity and greater spectral dispersion achieved in the spectrum of the RNA.

Conserved RNA motifs of EMCV IRES as potential building blocks to design RNA nanostructures.

The highly conserved secondary structural RNA motifs endowed by the IRES element of EMCV picornavirus provide an excellent platform to design RNA nanostructures for application in medicine. We have identified a 44mer RNA, hosting distinct 15mer and 11mer RNA stem loop motifs, as potential building blocks for the design of RNA nanostructures.

Unambiguous structural elucidation of base-modified purine nucleosides using NMR.

A general and unambiguous approach has been developed for structural elucidation of modified purine nucleosides using NMR spectroscopy. Systematic assignment of proton and carbon signals of modified nucleosides was firmly established by COSY and the anomerism of the glycosidic linkage of synthetic nucleosides clearly elucidated by NOESY experiments. Characteristic properties of 15N-isotopic labelling at specific positions of nucleosides were also employed for structural studies. The reported approach is applicable to other modified nucleosides and nucleotides, as well as nucleobases.

NMR structure of the peptidyl transferase RNA inhibitor antibiotic amicetin.

In this communication, we report the solution state NMR structure determination of the peptidyl transferase RNA inhibitor antibiotic amicetin. We have successfully characterised the NMR spectrum of amicetin using a range of homo- and heteronuclear NMR techniques. Using experimental ROE-based distance and 1H--1H scalar coupling derived dihedral angle geometrical constraints as input into the three-dimensional structure determination protocol, we have generated an energy-minimised average structure of the antibiotic. Amicetin adopts a stable well-folded conformation in solution, mediated by a network of hydrogen bonds caused by proton donor and acceptor groups at either end of the molecule. The NMR structure of amicetin shows that the cytosine moiety occupies the critical turn position within the fold, which may be structurally significant for interaction with peptidyl transferase ribosomal RNA. The structure is distinctly different from the published X-ray crystal structure of amicetin in which it adopts a linear, extended chain-like conformation with a number of intermolecular hydrogen bonds. In addition to structure, we have probed the dynamics of amicetin in solution and have observed retarded exchange of the amide proton involved in folding. We have also characterised the ionisation properties of amicetin by carrying out NMR pH titration and measuring the pKa of the primary and tertiary amino groups, 7.27 and 7.52, respectively, which are in agreement with the reported values in literature. Solving the NMR structure of amicetin provides a valuable opportunity to determine the structure of its complex with RNA in solution state.

NMR and molecular modelling studies of the binding of amicetin antibiotic to conserved secondary structural motifs of 23S ribosomal RNAs.

The interaction of a highly conserved secondary structural RNA motif of Halobacterium halobium and Escherichia coli 23S ribosomal RNAs with the peptidyl transferase inhibitor antibiotic amicetin has been investigated by proton NMR spectroscopy and molecular modelling. The NMR spectra of the synthetic 35mer RNA motifs revealed spectral features characteristic of a stable, well folded A-RNA type tertiary conformation, including resolved resonances assigned to unpaired bases located in the middle of the motif strongly implicated in amicetin binding. Addition of amicetin to the 35mer RNA samples was accompanied by significant and discrete changes to the spectra which can be qualitatively interpreted to the changes induced to the local conformation of the RNA motifs arising from the formation of a specific complex with amicetin. These results are also supported by the unconstrained molecular model of RNA-amicetin complex which highlights potential interactions between the two molecular components.

NMR studies of the structure and Mg2+ binding properties of a conserved RNA motif of EMCV picornavirus IRES element.

The structure and Mg(2+) binding properties of a conserved 75mer RNA motif of the internal ribosome entry site (IRES) element of encephalomyocarditis virus picornavirus have been investigated by (1)H-NMR and UV melting experiments. The assignment of the imino proton resonances with characteristic chemical shift dispersion for canonical and non-canonical base pairs confirmed the predicted secondary structure of the 75mer and its fragments. Addition of Mg(2+) resulted in a dramatic increase in apparent melting temperature, with the 75mer RNA registering the biggest increase, from 63 to 80 degrees C, thus providing evidence for enhanced stability arising from Mg(2+) binding. Similarly, addition of Mg(2+) induced selective changes to the chemical shifts of the imino protons of a GCGA tetraloop in the 75mer, that is essential for IRES activity, thereby highlighting a possible structural role for Mg(2+) in the folding of the 75mer. Significantly, the same protons show retarded exchange to water solvent, even at elevated temperature, which suggest that Mg(2+) induces a conformational rearrangement of the 75mer. Thus, we propose that Mg(2+) serves two important roles: (i) enhancing thermodynamic stability of the 75mer RNA (and its submotifs) via non-specific interactions with the phosphate backbone and (ii) promoting the folding of the 75mer RNA by binding to the GCGA tetraloop.

NMR structure determination and calcium binding effects of lipopeptide antibiotic daptomycin.

Daptomycin is an acidic lipopeptide antibiotic, whose three-dimensional structure and mechanism of action is currently unknown. Recently daptomycin, trade name Cubicin, was approved as a drug for the treatment of skin-related infections (M. Larkin Lancet, 2003, 3, 677) and became the first antibiotic of its class to be used in the clinic (A. Raja et al., Nature Rev. Drug Discov., 2003, 2, 943-944). We have carried out a systematic high field NMR study of daptomycin and its binding to calcium ions which is essential for antibiotic activity. In this first report, we demonstrate the sequence-specific resonance assignment of daptomycin under resolved NMR measurement conditions. In addition to this, we have determined the 3D structure of apo-daptomycin and demonstrated a 1 : 1 stoichiometry on the binding to calcium ions. We have also demonstrated that the binding of calcium ions does not result in major conformational changes, but does induce aggregation. This may be an important factor in the mode of action of daptomycin.