Enhanced binding of aminoglycoside dimers to a "dimerized" A-site 16S rRNA construct

In this work, we investigated the binding of a series of dimeric aminoglycoside molecules to (i) a 27 nt A-site 16S rRNA construct, and (ii) an artificially grafted 46 nt 'dimerized' A-site 16S rRNA construct. It was observed that the dissociation constants of dimeric aminoglycosides to the dimerized A-site 16S rRNA construct can achieve up to approximately 19-fold enhancement compared to the monomeric aminoglycoside molecules.     

Which aminoglycoside ring is most important for binding? A hydropathic analysis of gentamicin, paromomycin, and analogues

The NMR structures of gentamicin and paromomycin in complex with the A-site of Escherichia coli 16S ribosomal RNA were modified with molecular modeling to 12 analogues. The intermolecular interactions between these molecules and RNA were examined using the HINT (Hydropathic INTeractions) computational model to obtain interaction scores that have been shown previously to be related to free energy. The calculations correlated well with experimental binding data, and the interaction scores were used to analyze the specific structural features of each aminoglycoside that contribute to the overall binding with the 16S rRNA. Our calculations indicate that, while ring I binds to the main binding pocket of the rRNA A-site, ring IV of paromomycin-based aminoglycosides contributes significantly to the overall binding.     

Interactions of elongation factor EF-P with the Escherichia coli ribosome

EF-P (eubacterial elongation factor P) is a highly conserved protein essential for protein synthesis. We report that EF-P protects 16S rRNA near the G526 streptomycin and the S12 and mRNA binding sites (30S T-site). EF-P also protects domain V of the 23S rRNA proximal to the A-site (50S T-site) and more strongly the A-site of 70S ribosomes. We suggest that EF-P: (a) may play a role in translational fidelity and (b) prevents entry of fMet-tRNA into the A-site enabling it to bind to the 50S P-site. We also report that EF-P promotes a ribosome-dependent accommodation of fMet-tRNA into the 70S P-site.     

RNA aptamers that specifically bind to a 16S ribosomal RNA decoding region construct

RNA–RNA recognition is a critical process in controlling many key biological events, such as translation and ribozyme functions. The recognition process governing RNA–RNA interactions can involve complementary Watson–Crick (WC) base pair binding, or can involve binding through tertiary structural interaction. Hence, it is of interest to determine which of the RNA–RNA binding events might emerge through an in vitro selection process. The A-site of the 16S rRNA decoding region was chosen as the target, both because it possesses several different RNA structural motifs, and because it is the rRNA site where codon/anticodon recognition occurs requiring recognition of both mRNA and tRNA. It is shown here that a single family of RNA molecules can be readily selected from two different sizes of RNA library. The tightest binding aptamer to the A-site 16S rRNA construct, 109.2-3, has its consensus sequences confined to a stem–loop region, which contains three nucleotides complementary to three of the four nucleotides in the stem–loop region of the A-site 16S rRNA. Point mutations on each of the three nucleotides on the stem–loop of the aptamer abolish its binding capacity. These studies suggest that the RNA aptamer 109.2-3 interacts with the simple 27 nt A-site decoding region of 16S rRNA through their respective stem–loops. The most probable mode of interaction is through complementary WC base pairing, commonly referred to as a loop–loop ‘kissing’ motif. High affinity binding to the other structural motifs in the decoding region were not observed.     

Mutation K42R in Ribosomal Protein S12 Does Not Affect Susceptibility of Mycobacterium smegmatis 16S rRNA A-Site Mutants to 2-Deoxystreptamines

Recent studies have suggested that ribosomal protein S12 modulates 16S rRNA function and susceptibility to 2-deoxystreptamine aminoglycosides. To study whether the non-restrictive K42R mutation in RpsL affects 2-deoxystreptamine susceptibility in Mycobacterium smegmatis, we studied the drug susceptibility pattern of various mutants with genetic alterations in the 16S rRNA decoding A-site in the context of wild-type and mutant protein S12. RpsL K42R substitution was found not to affect the drug resistance pattern associated with mutational alterations in 16S rRNA H44.     

Monitoring aminoglycoside-induced conformational changes in 16S rRNA through acrylamide quenching

Fluorescence of 2-aminopurine (2AP)-substituted A-site and acrylamide quenching were used to study the interactions of paromomycin and neamine with the decoding region of 16S rRNA. The results reveal that paromomycin binding to the A-site RNA leads to increased exposure of residue A1492. In contrast, neamine has little effect on the solvent accessibility of A1492. Electrospray ionization mass spectrometry was used to compare the affinity of paromomycin with the A-site and 2-AP-substituted A-site RNAs.     

Mechanism of translation based on intersubunit complementarities of ribosomal RNAs and tRNAs

A universal rule is found about nucleotide sequence complementarities between the regions 2653-2666 in the GTPase-binding site of 23S rRNA and 1064-1077 of 16S rRNA as well as between the region 1103-1107 of 16S rRNA and GUUCG (or GUUCA) of tRNAs. This rule holds for all species in the living kingdoms except for two protista mitochondrial rRNAs of Trypanosoma brucei and Plasmodium falciparum. We found that quite similar relationships for the two species hold under the assumption presented in the present paper. The complementarity between T-loop of tRNA and the region 1103-1107 of 16S rRNA suggests that the first interaction of a ribosome with aminoacyl-tRNAEF-TuGTP ternary complex or EF-GGDP complex could occur at the region 1103-1107 of 16S rRNA with the T-loop-D-loop contact region of the ternary complex or the domain IV-V bridge region of the EF-GGDP complex. The second interaction should occur between the A-site codon and the anticodon loop or between the anticodon stem/loop of A-site tRNA and the tip of domain IV of EF-G. The above stepwise interactions would facilitate the collision of the region 1064-1077 of 16S rRNA with the region around A2660 at the alpha-sarcin/ricin loop of 23S rRNA. In this way, the universal rule is capable of explaining how spectinomycin-binding region of 16S rRNA takes part in translocation, how GTPases such as EF-Tu and EF-G can be introduced into their binding site on the large subunit ribosome in proper orientation efficiently and also how driving forces for tRNA movement are produced in translocation and codon recognition. The analysis of T-loops of all tRNAs also presents an evolutionary trend from a random and seemingly primitive sequence, as defined to be Y type, to the most developed structure, such as either 5G7 or 5A7 types in the present definition.     

A time-resolved investigation of ribosomal subunit association

The notion that the ribosome is dynamic has been supported by various biochemical techniques, as well as by differences observed in high-resolution structures of ribosomal complexes frozen in various functional states. Yet, the mechanisms and extent of rRNA dynamics are still largely unknown. We have used a novel, fast chemical-modification technique to provide time-resolved details of 16 S rRNA structural changes that occur as bridges are formed between the ribosomal subunits as they associate. Association of different 16 S rRNA regions was found to be a sequential, multi-step process involving conformational rearrangements within the 30 S subunit. Our results suggest that key regions of 16 S rRNA, necessary for decoding and tRNA A-site binding, are structurally altered in a time-dependent manner by association with the 50 S ribosomal subunits.     

The synthesis and 16S A-site rRNA recognition of carbohydrate-free aminoglycosides

The first carbohydrate-free aminoglycoside analogs bearing the 2-deoxystreptamine moiety were synthesized from asymmetrically protected 2-deoxystrepamine and subsequently demonstrated to have significant binding to the 16S A-site rRNA target and moderate functional activity.     

Ribosome interactions of aminoacyl-tRNA and elongation factor Tu in the codon-recognition complex

The mRNA codon in the ribosomal A-site is recognized by aminoacyl-tRNA (aa-tRNA) in a ternary complex with elongation factor Tu (EF-Tu) and GTP. Here we report the 13 A resolution three-dimensional reconstruction determined by cryo-electron microscopy of the kirromycin-stalled codon-recognition complex. The structure of the ternary complex is distorted by binding of the tRNA anticodon arm in the decoding center. The aa-tRNA interacts with 16S rRNA, helix 69 of 23S rRNA and proteins S12 and L11, while the sarcin-ricin loop of 23S rRNA contacts domain 1 of EF-Tu near the nucleotide-binding pocket. These results provide a detailed snapshot view of an important functional state of the ribosome and suggest mechanisms of decoding and GTPase activation.     

Aminoglycoside binding to human and bacterial A-Site rRNA decoding region constructs

The 16S bacterial ribosomal A-site decoding rRNA region is thought to be the pharmacological target for the aminoglycoside antibiotics. The clinical utility of aminoglycosides could possibly depend on the preferential binding of these drugs to the prokaryotic A-site versus the corresponding A-site from eukaryotes. However, quantitative aminoglycoside binding experiments reported here on prokaryotic and eukaryotic A-site RNA constructs show that there is little in the way of differential binding affinities of aminoglycosides for the two targets. The largest difference in affinity is 4-fold in the case of neomycin, with the prokaryotic A-site construct exhibiting the higher binding affinity. Mutational studies revealed that decoding region constructs retaining elements of non-Watson-Crick (WC) base pairing, specifically bound aminoglycosides with affinities in the muM range. These studies are consistent with the idea that aminoglycoside antibiotics can specifically bind to RNA molecules as long as the latter have non-A form structural elements allowing access of aminoglycosides to the narrow major groove.     

Mapping of the second tetracycline binding site on the ribosomal small subunit of E.coli

Tetracycline blocks stable binding of aminoacyl-tRNA to the bacterial ribosomal A-site. Various tetracycline binding sites have been identified in crystals of the 30S ribosomal small subunit of Thermus thermophilus. Here we describe a direct photo- affinity modification of the ribosomal small subunits of Escherichia coli with 7-[³H]-tetracycline. To select for specific interactions, an excess of the 30S subunits over tetracycline has been used. Primer extension analysis of the 16S rRNA revealed two sites of the modifications: C936 and C948. Considering available data on tetracycline interactions with the prokaryotic 30S subunits, including the presented data (E.coli), X-ray data (T.thermophilus) and genetic data (Helicobacter pylori, E.coli), a second high affinity tetracycline binding site is proposed within the 3′-major domain of the 16S rRNA, in addition to the A-site related tetracycline binding site.     

Arrangement of the Template 3′ of the A-Site Codon on the Human 80S Ribosome

The arrangement of the template sequence 3′ of the A-site codon on the 80S ribosome was studied using mRNA analogs containing Phe codon UUU at the 5′ end and a photoreactive perfluoroarylazido group linked to C5 of U or N7 of G. The analogs were positioned on the ribosome with the use of tRNA^Phe, which directed the UUU codon to the P site, bringing a modified nucleotide to position +9 or +12 relative to the first nucleotide of the P-site codon. Upon mild UV irradiation of ribosome complexes, the analogs of both types crosslinked to the 18S rRNA and proteins of the 40S subunit. Comparisons were made with the crosslinking patterns of complexes in which an mRNA analog contained a modified nucleotide in position +7 (the crosslinking to 18S rRNA in such complexes has been studied previously). The efficiency of crosslinking to ribosomal components depended on the nature of the modified nucleotide of an mRNA analog and its position on the ribosome. The extent of crosslinking to the 18S rRNA drastically decreased as the modified nucleotide was transferred from position +7 to position +12. The 18S rRNA nucleotides involved in crosslinking were identified. A modified nucleotide in position +9 crosslinked to the invariant dinucleotide A1824/A1825 and variable A1823 in the 3′ minidomain of the 18S rRNA and to S15. The same ribosomal components have earlier been shown to crosslink to modified nucleotides in positions +4 to +7. In addition, all mRNA analogs crosslinked to invariant C1698 in the 3′ minidomain and to conserved region 605–620, which closes helix 18 in the 5′ domain.     

利用糖芯片技术检测氨基糖苷类抗生素与RNAs和蛋白质之间的相互作用

氨基糖苷类抗生素是一类广谱型抗细菌感染药物,其不断增加的细菌耐药性很大程度上限制了它的临床应用,研究和开发新型氨基糖苷类抗生素具有重要意义。将氨基糖苷类抗生素固定到玻璃片基上,制成糖芯片,再分别与荧光标记的RNAs和蛋白质杂交,通过分析杂交后的荧光信号强度检测它们之间的相互作用。结果显示,氨基糖苷类抗生素芯片可以特异性地与r RNA的A位点模拟物、I型核酶和蛋白酶结合。因此糖芯片技术不仅可以检测氨基糖苷类抗生素与r RNAs的特异性结合,而且可以应用于寻找新型RNA结合配体的研究,为快速鉴定和筛选可紧密结合RNA靶标且毒性较低的新型氨基糖苷类抗生素奠定了一定的基础。     

The sarcin-ricin loop of 23S rRNA is essential for assembly of the functional core of the 50S ribosomal subunit

The sarcin–ricin loop (SRL) of 23S rRNA in the large ribosomal subunit is a factor-binding site that is essential for GTP-catalyzed steps in translation, but its precise functional role is thus far unknown. Here, we replaced the 15-nucleotide SRL with a GAAA tetraloop and affinity purified the mutant 50S subunits for functional and structural analysis in vitro. The SRL deletion caused defects in elongation-factor-dependent steps of translation and, unexpectedly, loss of EF-Tu-independent A-site tRNA binding. Detailed chemical probing analysis showed disruption of a network of rRNA tertiary interactions that hold together the 23S rRNA elements of the functional core of the 50S subunit, accompanied by loss of ribosomal protein L16. Our results reveal an influence of the SRL on the higher-order structure of the 50S subunit, with implications for its role in translation.     

Mutagenesis of 16S rRNA C1409-G1491 base-pair differentiates between 6'OH and 6'NH3+ aminoglycosides

Using a single rRNA allelic Gram-positive model system, we systematically mutagenized 16S rRNA positions 1409 and 1491 to probe the functional relevance of structural interactions between aminoglycoside antibiotics and the A-site rRNA that were suggested by X-ray crystallography. At the structural level, the interaction of the 2-deoxystreptamine aminoglycosides with the rRNA base-pair C1409-G1491 has been suggested to involve the following features: (i) ring I of the disubstituted 2-deoxystreptamines stacks upon G1491 and H-bonds to the Watson-Crick edge of A1408; (ii) ring III of the 4,5-disubstituted aminoglycosides shows hydrogen bonding to G1491. However, we found that mutants with altered 16S rRNA bases 1409 and 1491 discriminated poorly between 4,5-disubstituted and 4,6-disubstituted 2-deoxystreptamines, but differentially affected aminoglycosides with a hydroxyl group versus an ammonium group at position 6' of ring I, e.g. G1491U conferred high-level drug resistance to paromomycin and geneticin, but not to neomycin, tobramycin or gentamicin.     

Mutations in helix 27 of the yeast Saccharomyces cerevisiae 18S rRNA affect the function of the decoding center of the ribosome

A dynamic structural rearrangement in the phylogenetically conserved helix 27 of Escherichia coli 16S rRNA has been proposed to directly affect the accuracy of translational decoding by switching between "accurate" and "error-prone" conformations. To examine the function of helix 27 in eukaryotes, random and site-specific mutations in helix 27 of the yeast Saccharomyces cerevisiae 18S rRNA have been characterized. Mutations at positions of yeast 18S rRNA corresponding to E. coli 886 (rdn8), 888 (rdn6), and 912 (rdn4) increased translational accuracy in vivo and in vitro, and caused a reduction in tRNA binding to the A-site of mutant ribosomes. The double rdn4rdn6 mutation separated the killing and stop-codon readthrough effects of the aminoglycoside antibiotic, paromomycin, implicating a direct involvement of yeast helix 27 in accurate recognition of codons by tRNA or release factor eRF1. Although our data in yeast does not support a conformational switch model analogous to that proposed for helix 27 of E. coli 16S rRNA, it strongly suggests a functional conservation of this region in tRNA selection.     

Conserved loop sequence of helix 69 in Escherichia coli 23 S rRNA is involved in A-site tRNA binding and translational fidelity

Ribosomal (r) RNAs play a crucial role in the fundamental structure and function of the ribosome. Helix 69 (H69) (position 1906-1924), a highly conserved stem-loop in domain IV of the 23 S rRNA of bacterial 50 S subunits, is located on the surface for intersubunit association with the 30 S subunit by connecting with helix 44 of 16 S rRNA with the bridge B2a. H69 directly interacts with A/T-, A-, and P-site tRNAs during each translation step. To investigate the functional importance of the highly conserved loop sequence (1912-1918) of H69, we employed a genetic method that we named SSER (systematic selection of functional sequences by enforced replacement). This method allowed us to identify and select from the randomized loop sequences of H69 in Escherichia coli 23 S rRNA functional sequences that are absolutely required for ribosomal function. From a library consisting of 16,384 sequence variations, 13 functional variants were obtained. A1912 and U(Psi)1917 were selected as essential residues in all variants. An E. coli strain having 23 S rRNA with a U to A mutation at position 1915 showed a severe growth phenotype and low translational fidelity. The result could be explained by the fact that the A1915-ribosome variant has weak subunit association, weak A-site tRNA binding, and decreased translational activity. This study proposes that H69 plays an important role in the control of translational fidelity by modulating A-site tRNA binding during the decoding process.     

The three transfer RNAs occupying the A, P and E sites on the ribosome are involved in viral programmed -1 ribosomal frameshift

The -1 programmed ribosomal frameshifts (PRF), which are used by many viruses, occur at a heptanucleotide slippery sequence and are currently thought to involve the tRNAs interacting with the ribosomal P- and A-site codons. We investigated here whether the tRNA occupying the ribosomal E site that precedes a slippery site influences -1 PRF. Using the human immunodeficiency virus type 1 (HIV-1) frameshift region, we found that mutating the E-site codon altered the -1 PRF efficiency. When the HIV-1 slippery sequence was replaced with other viral slippery sequences, mutating the E-site codon also altered the -1 PRF efficiency. Because HIV-1 -1 PRF can be recapitulated in bacteria, we used a bacterial ribosome system to select, by random mutagenesis, 16S ribosomal RNA (rRNA) mutations that modify the expression of a reporter requiring HIV-1 -1 PRF. Three mutants were isolated, which are located in helices 21 and 22 of 16S rRNA, a region involved in translocation and E-site tRNA binding. We propose a novel model where -1 PRF is triggered by an incomplete translocation and depends not only on the tRNAs interacting with the P- and A-site codons, but also on the tRNA occupying the E site.