Studies of viomycin, an anti-tuberculosis antibiotic: copper(ii) coordination, DNA degradation and the impact on delta ribozyme cleavage activity.

Viomycin is a basic peptide antibiotic, which is among the most effective agents against multidrug-resistant tuberculosis. In this paper we provide the characteristics of its acid base properties, coordination preferences towards the Cu(ii) ions, as well as the reactivity of the resulting complexes against plasmid DNA and HDV ribozyme. Careful coordination studies throughout the wide pH range allow for the characterisation of all the Cu(ii)-viomycin complex species. The assignment of proton chemical shifts was achieved by NMR experiments, while the DTF level of theory was applied to support molecular structures of the studied complexes. The experiments with the plasmid DNA reveal that at the physiological levels of hydrogen peroxide the Cu(ii)-viomycin complex is more aggressive against DNA than uncomplexed metal ions. Moreover, the degradation of DNA by viomycin can be carried out without the presence of transition metal ions. In the studies of antigenomic delta ribozyme catalytic activity, viomycin and its complex are shown to modulate the ribozyme functioning. The molecular modelling approach allows the indication of two different locations of viomycin binding sites to the ribozyme.

Following movement of domain IV of elongation factor G during ribosomal translocation.

Translocation of mRNA and tRNAs through the ribosome is catalyzed by a universally conserved elongation factor (EF-G in prokaryotes and EF-2 in eukaryotes). Previous studies have suggested that ribosome-bound EF-G undergoes significant structural rearrangements. Here, we follow the movement of domain IV of EF-G, which is critical for the catalysis of translocation, relative to protein S12 of the small ribosomal subunit using single-molecule FRET. We show that ribosome-bound EF-G adopts distinct conformations corresponding to the pre- and posttranslocation states of the ribosome. Our results suggest that, upon ribosomal translocation, domain IV of EF-G moves toward the A site of the small ribosomal subunit and facilitates the movement of peptidyl-tRNA from the A to the P site. We found no evidence of direct coupling between the observed movement of domain IV of EF-G and GTP hydrolysis. In addition, our results suggest that the pretranslocation conformation of the EF-G-ribosome complex is significantly less stable than the posttranslocation conformation. Hence, the structural rearrangement of EF-G makes a considerable energetic contribution to promoting tRNA translocation.

The structures of the anti-tuberculosis antibiotics viomycin and capreomycin bound to the 70S ribosome.

Viomycin and capreomycin belong to the tuberactinomycin family of antibiotics, which are among the most effective antibiotics against multidrug-resistant tuberculosis. Here we present two crystal structures of the 70S ribosome in complex with three tRNAs and bound to either viomycin or capreomycin at 3.3- and 3.5-A resolution, respectively. Both antibiotics bind to the same site on the ribosome, which lies at the interface between helix 44 of the small ribosomal subunit and helix 69 of the large ribosomal subunit. The structures of these complexes suggest that the tuberactinomycins inhibit translocation by stabilizing the tRNA in the A site in the pretranslocation state. In addition, these structures show that the tuberactinomycins bind adjacent to the binding sites for the paromomycin and hygromycin B antibiotics, which may enable the development of new derivatives of tuberactinomycins that are effective against drug-resistant strains.

Fluctuations of transfer RNAs between classical and hybrid states.

Adjacent transfer RNAs (tRNAs) in the A- and P-sites of the ribosome are in dynamic equilibrium between two different conformations called classical and hybrid states before translocation. Here, we have used single-molecule fluorescence resonance energy transfer to study the effect of Mg(2+) on tRNA dynamics with and without an acetyl group on the A-site tRNA. When the A-site tRNA is not acetylated, tRNA dynamics do not depend on [Mg(2+)], indicating that the relative positions of the substrates for peptide-bond formation are not affected by Mg(2+). In sharp contrast, when the A-site tRNA is acetylated, Mg(2+) lengthens the lifetime of the classical state but does not change the lifetime of the hybrid state. Based on these findings, the classical state resembles a state with direct stabilization of tertiary structure by Mg(2+) ions whereas the hybrid state resembles a state with little Mg(2+)-assisted stabilization. The antibiotic viomycin, a translocation inhibitor, suppresses tRNA dynamics, suggesting that the enhanced fluctuations of tRNAs after peptide-bond formation drive spontaneous attempts at translocation by the ribosome.

Roles of VioG and VioQ in the incorporation and modification of the Capreomycidine residue in the peptide antibiotic viomycin.

The nonproteinogenic amino acid capreomycidine is the signature residue found in the tuberactinomycin family of antitubercular peptide antibiotics and an important element of the pharmacophore. Recombinant VioG, a single-module peptide synthetase from the viomycin gene cluster cloned from Streptomyces vinaceus (ATCC11861), specifically activates capreomycidine for incorporation into viomycin (tuberactinomycin B). Insertional disruption of the putative hydroxylase gene vioQ resulted in a mutant that accumulated tuberactinomycin O, suggesting that hydroxylation at C-5 of the capreomycidine residue is a post-assembly event. The inactivated chromosomal copy of vioQ could be complemented with a wild-type copy of the gene to restore viomycin production.

Effect of magnesium ions on the tertiary structure of the hepatitis C virus IRES and its affinity for the cyclic peptide antibiotic viomycin.

A key ion-dependent folding unit within the hepatitis C IRES comprises the IIIef junction and pseudoknot. This region is also important in recruitment of the 40S ribosomal subunit. Here, circular dichroism is used to study the influence of metal ions on the structure and stability of this region. Comparison of the thermal stability of an IRES fragment encompassing subdomains IIIe/f and IV (named 3EF4) with that of a larger fragment also possessing subdomain IIId (3DEF4) indicates an additional stabilizing effect of Mg(2+) ions on the latter fragment. Magnesium and potassium ions stabilize both fragments through nonspecific counterion effects. The additional effect of magnesium on 3DEF4, observed in the absence or presence of 100 mM KCl, is attributed to a nonspecific but high-affinity site for metal ions created by a region of unusual high charge density. Subdomain IIId presumably participates in tertiary packing interactions that provide such a site. Viomycin binds to the full-length IRES and RNA fragments with K(d) values of 25-55 microM. Interestingly, viomycin binding to the two fragments is affected differently by Mg(2+); noncompetitive inhibition of binding to 3DEF4 is observed, whereas binding to 3EF4 is not impaired. Formation of a Mg(2+)-stabilized tertiary fold, involving subdomain IIId, may thereby hinder viomycin binding to 3DEF4 indirectly. Mutational and deletion studies locate viomycin binding within subdomains IIIe/f rather than within the pseudoknot. In pseudoknot mutants, Mg(2+) ions have different effects on viomycin binding and thermal stability, suggesting altered tertiary interactions involving subdomain IIId.

The antibiotic viomycin as a model peptide for the origin of the co-evolution of RNA and proteins.

Viomycin is an RNA-binding peptide antibiotic which inhibits prokaryotic protein synthesis and group I intron self-splicing. This antibiotic enhances the activity of the ribozyme derived from the Neurospora crassa VS RNA, and at sub-inhibitory concentrations it induces the formation of group I intron oligomers. Here, we address the question whether viomycin exerts specificity in the promotion of RNA-RNA interactions. In an in vitro selection experiment we tested the ability of viomycin to specifically select molecules out of an RNA pool. Group I intron RNA was incubated with a pool of random sequence RNA, or with a pool of RNA molecules which had previously been enriched for viomycin-binding RNAs. Viomycin was added in order to select viomycin-binding RNAs and to guide their interaction with the intron RNA resulting in recombinant molecules. Viomycin was indeed capable of specifically selecting RNA molecules which contain viomycin-binding sites promoting recombination. These results suggest that small peptides are able to play the role of selector molecules in a putative 'RNA World' launching the co-evolution of RNA and proteins into an 'RNA-protein World'.