Minimum sequence requirements for the binding of paromomycin to the rRNA decoding site A

We have recently introduced a computational methodology that combines molecular dynamics (MD) simulations, free-energy calculations, and in vitro binding assays to predict the minimum RNA structural requirements for selective, high-affinity RNA binding to small-molecule ligands. Here, we show that this methodology can be applied to the conformationally flexible aminoglycoside antibiotic paromomycin. A RNA consisting of an 11-mer:10-mer duplex that contains one 16S ribosome RNA decoding A-site bound to paromomycin was simulated for 4 ns. The methodology predicts that the 11-mer:10-mer duplex binds to paromomycin with high affinity, whereas smaller RNA duplexes lose complex stability and the ability to bind paromomycin. The predicted high-affinity binding to paromomycin of the 11-mer:10-mer duplex was confirmed experimentally (EC(50) = 0.28 microM), as well as the inability of smaller complexes to bind. Our simulations show good agreement with experiment for dynamic and structural properties of the isolated A-site, including hydrogen-bonding networks and RNA structural rearrangements upon ligand binding. The results suggest that MD simulations can supplement in vitro methods as a tool for predicting minimum RNA-binding motifs for both small, rigid ligands, and large, flexible ligands when structural information is available.     

Aminoglycoside binding to Oxytricha nova telomeric DNA

Telomeric DNA sequences have been at the center stage of drug design for cancer treatment in recent years. The ability of these DNA structures to form four-stranded nucleic acid structures, called G-quadruplexes, has been perceived as target for inhibiting telomerase activity vital for the longevity of cancer cells. Being highly diverse in structural forms, these G-quadruplexes are subjects of detailed studies of ligand-DNA interactions of different classes, which will pave the way for logical design of more potent ligands in future. The binding of aminoglycosides was investigated with Oxytricha nova quadruplex forming DNA sequence (GGGGTTTTGGGG)(2). Isothermal titration calorimetry (ITC) determined ligand to quadruplex binding ratio shows 1:1 neomycin:quadruplex binding with association constants (K(a)) ～ 10(5) M(-1) while paromomycin was found to have a 2-fold weaker affinity than neomycin. The CD titration experiments with neomycin resulted in minimal changes in the CD signal. FID assays, performed to determine the minimum concentration required to displace half of the fluorescent probe bound, showed neomycin as the best of the all aminoglycosides studied for quadruplex binding. Initial NMR footprint suggests that ligand-DNA interactions occur in the wide groove of the quadruplex. Computational docking studies also indicate that aminoglycosides bind in the wide groove of the quadruplex.     

RNA Sequence Determinants for Aminoglycoside Binding to an A-site rRNA Model Oligonucleotide

The codon-anticodon interaction on the ribosome occurs in the A site of the 30 S subunit. Aminoglycoside antibiotics, which bind to ribosomal RNA in the A site, cause misreading of the genetic code and inhibit translocation. Biochemical studies and nuclear magnetic resonance spectroscopy were used to characterize the interaction between the aminoglycoside antibiotic paromomycin and a small model oligonucle otide that mimics the A site ofEscherichia coli16 S ribosomal RNA. Upon chemical modification, the RNA oligonucleotide exhibits an accessibility pattern similar to that of 16 S rRNA in the 30 S subunit. In addition, the oligonucleotide binds specifically aminoglycoside antibiotics. The anti biotic binding site forms an asymmetric internal loop, caused by non-canonical base-pairs. Nucleotides that are important for binding of paromomycin were identified by performing quantitative footprinting on oligonucleotide sequence variants and include the C1407·G1494 base-pair, and A·U base-pair at positions 1410/1490, and nucleotides A1408, A1493 and U1495. The asymmetry of the internal loop, which requires the presence of a nucleotide in position 1492, is also crucial for antibiotic binding. Introduction into the oligonucleotide of base changes that are known to confer aminoglycoside resistance in 16 S rRNA result in weaker binding of paromomycin to the oligonucleotide. Oligonucleotides homologous to eukaryotic rRNA sequences show reduced binding of paromomycin, suggesting a physical origin for the species-specific action of aminoglycosides.     

Genetic interaction between yeast Saccharomyces cerevisiae release factors and the decoding region of 18 S rRNA

Functional and structural similarities between tRNA and eukaryotic class 1 release factors (eRF1) described previously, provide evidence for the molecular mimicry concept. This concept is supported here by the demonstration of a genetic interaction between eRF1 and the decoding region of the ribosomal RNA, the site of tRNA-mRNA interaction. We show that the conditional lethality caused by a mutation in domain 1 of yeast eRF1 (P86A), that mimics the tRNA anticodon stem-loop, is rescued by compensatory mutations A1491G (rdn15) and U1495C (hyg1) in helix 44 of the decoding region and by U912C (rdn4) and G886A (rdn8) mutations in helix 27 of the 18 S rRNA. The rdn15 mutation creates a C1409-G1491 base-pair in yeast rRNA that is analogous to that in prokaryotic rRNA known to be important for high-affinity paromomycin binding to the ribosome. Indeed, rdn15 makes yeast cells extremely sensitive to paromomycin, indicating that the natural high resistance of the yeast ribosome to paromomycin is, in large part, due to the absence of the 1409-1491 base-pair. The rdn15 and hyg1 mutations also partially compensate for inactivation of the eukaryotic release factor 3 (eRF3) resulting from the formation of the [PSI+] prion, a self-reproducible termination-deficient conformation of eRF3. However, rdn15, but not hyg1, rescues the conditional cell lethality caused by a GTPase domain mutation (R419G) in eRF3. Other antisuppressor rRNA mutations, rdn2(G517A), rdn1T(C1054T) and rdn12A(C526A), strongly inhibit [PSI+]-mediated stop codon read-through but do not cure cells of the [PSI+] prion. Interestingly, cells bearing hyg1 seem to enable [PSI+] strains to accumulate larger Sup35p aggregates upon Sup35p overproduction, suggesting a lower toxicity of overproduced Sup35p when the termination defect, caused by [PSI+], is partly relieved.     

The region of human transferrin involved in binding to bacterial transferrin receptors is iocalized in the C-lobe

Iron-saturated human transferrin was digested with either chymotrypsin or trypsin to produce C-lobe and N-lobe protein fragments. Individual protein fragments were purified by a combination of gel filtration and Concanavalin A affinity chromatographic procedures. The C-lobe and N-lobe fragments of human transferrin were then used in binding assays to assess their ability in binding to the bacterial transferrin receptors. Competitive binding assays demonstrated that the C-lobe fragment of human transferrin binds as well as intact human transferrin to bacterial transterrin receptors from Neisseria meningitidis, Neisseria gonorrhoeae and Haemophlius influenzae. Using isogenic mutants of N. meningitidis deficient in either of the transferrin-binding proteins (Tbps), we demonstrated that both transferrin-binding proteins were able to bind to the C-lobe fragment of human transferrin.     

Conformational switch in the decoding region of 16S rRNA during aminoacyl-tRNA selection on the ribosome

Binding of aminoglycoside antibiotics to 16S ribosomal RNA induces a particular structure of the decoding center and increases the misincorporation of near-cognate amino acids. By kinetic analysis we show that this is due to stabilization of the near-cognate codon recognition complex and the acceleration of two rearrangements that limit the rate of amino acid incorporation. The same rearrangement steps are accelerated in the cognate coding situation. We suggest that cognate codon recognition, or near-cognate codon recognition augmented by aminoglycoside binding, promote the transition of 16S rRNA from a 'binding' to a 'productive' conformation that determines the fidelity of decoding.     

rRNA pseudouridylation defects affect ribosomal ligand binding and translational fidelity from yeast to human cells

How pseudouridylation (Ψ), the most common and evolutionarily conserved modification of rRNA, regulates ribosome activity is poorly understood. Medically, Ψ is important because the rRNA Ψ synthase, DKC1, is mutated in X-linked dyskeratosis congenita (X-DC) and Hoyeraal-Hreidarsson (HH) syndrome. Here, we characterize ribosomes isolated from?a yeast strain in which Cbf5p, the yeast homolog of DKC1, is catalytically impaired through a D95A mutation (cbf5-D95A). Ribosomes from cbf5-D95A cells display decreased affinities for tRNA binding to the A and P sites as well as the cricket paralysis virus internal ribosome entry site (IRES), which interacts with both the P and the E sites of the ribosome. This biochemical impairment in ribosome activity manifests as decreased translational fidelity and IRES-dependent translational initiation, which are also evident in mouse and human cells deficient for DKC1 activity. These findings uncover specific roles for Ψ modification in ribosome-ligand interactions that are conserved in yeast, mouse, and humans.     

Mutation proximal to the tRNA binding region of the Nicotiana plastid 16S rRNA confers resistance to spectinomycin.

Summary Nicotiana tabacum lines carrying maternally inherited resistance to spectinomycin were obtained by selection for green callus in cultures bleached by spectinomycin. Two levels of resistance was found. SPC1 and SPC2 seedlings are resistant to high levels (500 g/ml), SPC23 seedlings are resistant to low levels (50 g/ml) of spectinomycin. Lines SPC2 and SPC23 are derivatives of the SR1 streptomycin-resistant plastome mutant. Spectinomycin resistance is due to mutations in the plastid 16S ribosomal RNA: SPC1, an A to C change at position 1138; SPC2, a C to U change at position 1139; SPC23, a G to A change at position 1333. Mutations similar to those in the SPC1 and SPC2 lines have been previously described, and disrupt a conserved 16S ribosomal RNA stem structure. The mutation in the SPC23 line is the first reported case of a mutation close to the region of the 16S rRNA involved in the formation of the initiation complex. The new mutants provide markers for selecting plastid transformants.     

Proflavine binding to yeast rRNA and ribosomes as related to structure

Proflavine binding experiments were carried out with yeast rRNA, native and “unfolded” ribosomes; the binding constants and the number of binding sites were calculated by a spectroscopic method. The study of the intercalation complexes by fluorescence and electric dichroism shows the intercalation binding sites to involve two subtypes of sites, which could be related to different nucleotide composition and secondary structure of the rRNA regions, i.e., binding sites located in the (A + U)-rich single strands and binding sites located in the (G + C)-rich double-helical strands (fluorescence quenching sites). Electric dichroism of complexed proflavine is interpreted in terms of rRNA conformation within the ribosomes. The conclusions are in agreement with the ribosomal model of Cox and Bonanou and show that, according to this model, the base planes of the nucleotides are not all parallel in the native ribsome, but rather radiate around the folding axis of the ribonucleoprotein sheet.     

Aminoglycoside Stress Together with the 12S rRNA 1494C>T Mutation Leads to Mitophagy

Aminoglycosides as modifying factors modulated the phenotypic manifestation of mitochondrial rRNA mutations and the incomplete penetrance of hearing loss. In this report, using cybrids harboring the m.1494C>T mutation, we showed that gentamycin aggravated mitochondrial dysfunction in a combination of the m.1494C>T mutation. The m.1494C>T mutation was responsible for the dramatic reduction in three mtDNA-encoded proteins of H-strand, with the average of 39% reduction, except of the MT-ND6 protein, accompanied with 21% reduction of ATP production and increase in mitochondrial reactive oxygen species, compared with those of control cybrids. After exposure to gentamycin, 35% reduction of mitochondrial ATP production was observed in mutant cybrids with a marked decrease of the mitochondrial membrane potential. More excessive cellular reactive oxygen species was detected with stimulus of gentamycin than those in mutant cells. Under gentamycin and m.1494C>T stress together, more dysfunctional mitochondria were forced to fuse and exhibited mitophagy via up-regulated LC3-B, as a compensatory protective response to try to optimize mitochondrial function, rather than undergo apoptosis. These findings may provide valuable information to further understand of mechanistic link between mitochondrial rRNA mutation, toxicity of AGs and hearing loss.     

Identification of a site on 18 S rRNA of human placenta ribosomes in the region of the mRNA binding center

The affinity labeling of human placenta 80 S ribosomes by 4-(N-2-chloroethyl-N-methylamino)benzyl-5'-phosphamide of hexauridylate was studied. This mRNA analog has normal coding properties because its binding to placenta ribosomes significantly increases in the presence of cognate tRNAPhe. Incubation of the mRNA analog in the complex with the ribosomes and Phe-tRNAPhe leads to its covalent attachment exclusively to the small subunit (mainly to 18 S rRNA). The site of the reaction has been identified by hybridization experiments to be located within positions 975 to 1055 of 18 S rRNA. The identified fragment is located in a highly conserved part of the small subunit rRNA domain II.     

Sequence-specific bacterial growth inhibition by peptide nucleic acid targeted to the mRNA binding site of 16S rRNA

To compare oxidative dissolution rates of chalcopyrite by different consortia of moderately thermophilic acidophiles, various defined mixed cultures of three bacteria Acidithiobacillus caldus s2, Leptospirillum ferriphilum YSK, and Sulfobacillus sp. LN and one archaeon Ferroplasma thermophilum L1 were studied in batch shake flask cultures incubated at 45 °C. Chalcopyrite dissolution was determined by measuring variations of soluble copper, ferric iron, and pH. Microbial population dynamics involved in bioleaching process were monitored using real-time quantitative polymerase chain reaction (PCR) technology. The complex consortia containing both chemoautotrophic (L. ferriphilum and At. caldus) and chemomixotrophic (Sulfobacillus LN and F. thermophilum) moderate thermophiles were found to be the most efficient in all of those tested. Mutualistic interactions between physiologically distinct moderately thermophilic acidophiles, involving transformations of iron and sulfur and transfer of organic compound, were considered to play a critical role in promoting chalcopyrite dissolution. The real-time PCR assay was reliable to analyze population dynamics of moderate thermophiles in bioleaching systems, and the analysis results were consistent with physiological characteristics of these strains.     

The 3''-terminal region of bacterial 23S ribosomal RNA: structure and homology with the 3''-terminal region of eukaryotic 28S rRNA and with chloroplast 4.5s rRNA.

The sequence of the 110 nucleotide fragment located at the 3'-end of E.coli, P.vulgaris and A.punctata 23S rRNAs has been determined. The homology between the E.coli and P.vulgaris fragments is 90%, whereas that between the E.coli and A.punctate fragments is only 60%. The three rRNA fragments have sequences compatible with a secondary structure consisting of two hairpins. Using chemical and enzymatic methods recently developed for the study of the secondary structure of RNA, we demonstrated that one of these hairpins and part of the other are actually present in the three 3'-terminal fragments in solution. This supports the existence of these two hairpins in the intact molecule. Indeed, results obtained upon limited digestion of intact 23S RNA with T1 RNase were in good agreement with the existence of these two hairpins. We observed that the primary structures of the 3'-terminal regions of yeast 26S rRNA and X.laevis 28S rRNA are both compatible with a secondary structure similar to that found at the 3'-end of bacterial 23S rRNAs. Furthermore, both tobacco and wheat chloroplast 4.5S rRNAs can also be folded in a similar way as the 3'-terminal region of bacterial 23S rRNA, the 3'-end of chloroplast 4.5S rRNAs being complementary to the 5'-end of chloroplast 23S rRNA. This strongly reinforces the hypothesis that chloroplast 4.5S rRNA originates from the 3'-end of bacterial 23S rRNA and suggests that this rRNA may be base-paired with the 5'-end of chloroplast 23S rRNA. Invariant oligonucleotides are present at identical positions in the homologous secondary structures of E.coli 23S, yeast 26S, X.laevis 28S and wheat and tobacco 4.5S rRNAs. Surprisingly, the sequences of these oligonucleotides are not all conserved in the 3'-terminal regions of A.punctata or even P.vulgaris 23S rRNAs. Results obtained upon mild methylation of E.coli 50S subunits with dimethylsulfate strongly suggest that these invariant oligonucleotides are involved in RNA tertiary structure or in RNA-protein interactions.     

Probing the stabilizing effects of modified nucleotides in the bacterial decoding region of 16S ribosomal RNA

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Polynucleotide probes that target a hypervariable region of 16S rRNA genes to identify bacterial isolates corresponding to bands of community fingerprints

Temperature gradient gel electrophoresis (TGGE) is well suited for fingerprinting bacterial communities by separating PCR-amplified fragments of 16S rRNA genes (16S ribosomal DNA [rDNA]). A strategy was developed and was generally applicable for linking 16S rDNA from community fingerprints to pure culture isolates from the same habitat. For this, digoxigenin-labeled polynucleotide probes were generated by PCR, using bands excised from TGGE community fingerprints as a template, and applied in hybridizations with dot blotted 16S rDNA amplified from bacterial isolates. Within 16S rDNA, the hypervariable V6 region, corresponding to positions 984 to 1047 (Escherichia coli 16S rDNA sequence), which is a subset of the region used for TGGE (positions 968 to 1401), best met the criteria of high phylogenetic variability, required for sufficient probe specificity, and closely flanking conserved priming sites for amplification. Removal of flanking conserved bases was necessary to enable the differentiation of closely related species. This was achieved by 5' exonuclease digestion, terminated by phosphorothioate bonds which were synthesized into the primers. The remaining complementary strand was removed by single-strand-specific digestion. Standard hybridization with truncated probes allowed differentiation of bacteria which differed by only two bases within the probe target site and 1.2% within the complete 16S rDNA. However, a truncated probe, derived from an excised TGGE band of a rhizosphere community, hybridized with three phylogenetically related isolates with identical V6 sequences. Only one of the isolates comigrated with the excised band in TGGE, which was shown to be due to identical sequences, demonstrating the utility of a combined TGGE and V6 probe approach.     

Polymerase chain reaction detection of bacterial 16S rRNA gene in human blood

Bacterial 16S ribosomal RNA genes (rDNA) were detected in blood samples from two healthy individuals by PCR under conditions involving 30 cycles that did not produce any visible products from negative control saline. Even from control samples, PCR involving 35-40 cycles yielded visible bands. Major clones detected in the blood samples, but not in control, were the Aquabacterium subgroup, Stenotrophomonas subgroup, Budvicia subgroup, Serratia subgroup, Bacillus subgroup and Flavobacteria subgroup. No clone was located within the bacteroides-clostridium-lactobacillus cluster, which is indigenous to gastrointestinal flora.