G1401: a keystone nucleotide at the decoding site of Escherichia coli 30S ribosomes

The role of the mitochondrial ribosome in human disease: searching for mutations in 12S mitochondrial rRNA with high disruptive potential

Mutations of mitochondrial DNA are linked to many human diseases. Despite the identification of a large number of variants in the mitochondrially encoded rRNA (mt-rRNA) genes, the evidence supporting their pathogenicity is, at best, circumstantial. Establishing the pathogenicity of these variations is of major diagnostic importance. Here, we aim to estimate the disruptive effect of mt-rRNA variations on the function of the mitochondrial ribosome. In the absence of direct biochemical methods to study the effect of mt-rRNA variations, we relied on the universal conservation of the rRNA fold to infer their disruptive potential. Our method, named heterologous inferential analysis or HIA, combines conservational information with functional and structural data obtained from heterologous ribosomal sources. Thus, HIA's predictive power is superior to the traditional reliance on simple conservation indexes. By using HIA, we have been able to evaluate the disruptive potential for a subset of uncharacterized 12S mt-rRNA variations. Our analysis revealed the existence of variations in the rRNA component of the human mitoribosome with different degrees of disruptive power. In cases where sufficient information regarding the genetic and pathological manifestation of the mitochondrial phenotype is available, HIA data can be used to predict the pathogenicity of mt-rRNA mutations. In other cases, HIA analysis will allow the prioritization of variants for additional investigation. Eventually, HIA-inspired analysis of potentially pathogenic mt-rRNA variations, in the context of a scoring system specifically designed for these variants, could lead to a powerful diagnostic tool.

Impact of methylations of m2G966/m5C967 in 16S rRNA on bacterial fitness and translation initiation

The functional centers of the ribosome in all organisms contain ribosomal RNA (rRNA) modifications, which are introduced by specialized enzymes and come at an energy cost for the cell. Surprisingly, none of the modifications tested so far was essential for growth and hence the functional role of modifications is largely unknown. Here, we show that the methyl groups of nucleosides m²G966 and m⁵C967 of 16S rRNA in Escherichia coli are important for bacterial fitness. In vitro analysis of all phases of translation suggests that the m²G966/m⁵C967 modifications are dispensable for elongation, termination and ribosome recycling. Rather, the modifications modulate the early stages of initiation by stabilizing the binding of fMet-tRNA^fMet to the 30S pre-initiation complex prior to start-codon recognition. We propose that the m²G966 and m⁵C967 modifications help shaping the bacterial proteome, most likely by fine-tuning the rates that determine the fate of a given messenger RNA (mRNA) at early checkpoints of mRNA selection.

Effect of mutations in the A site of 16 S rRNA on aminoglycoside antibiotic-ribosome interaction

Decoding of genetic information occurs upon interaction of an mRNA codon-tRNA anticodon complex with the small subunit of the ribosome. The ribosomal decoding region is associated with highly conserved sequences near the 3' end of 16 S rRNA. The decoding process is perturbed by the aminoglycoside antibiotics, which also interact with this region of rRNA. Mutations of certain nucleotides in rRNA reduce aminoglycoside binding affinity, as previously demonstrated using a model RNA oligonucleotide system. Here, predictions from the oligonucleotide system were tested in the ribosome by mutation of universally conserved nucleotides at 1406 to 1408 and 1494 to 1495 in the decoding region of plasmid-encoded bacterial 16 S rRNA. Phenotypic changes range from the benign effect of U1406-->A or A1408-->G substitutions, to the highly deleterious 1406G and 1495 mutations that assemble into 30 S subunits but are defective in forming functional ribosomes. Changes in the local conformation of the decoding region caused by these mutations were identified by chemical probing of isolated 30 S subunits. Ribosomes containing 16 S rRNA with mutations at positions 1408, 1407+1494, or 1495 had reduced affinity for the aminoglycoside paromomycin, whereas no discernible reduction in affinity was observed with 1406 mutant ribosomes. These data are consistent with prior NMR structural determination of aminoglycoside interaction with the decoding region, and further our understanding of how aminoglycoside resistance can be conferred.

In vivo determination of RNA structure-function relationships: analysis of the 790 loop in ribosomal RNA

The 790 loop is a conserved hairpin located between positions 786 and 796 of Escherichia coli 16 S rRNA that is required for ribosome function. Using a novel genetic approach, all positions in the loop were simultaneously mutated and functional mutant sequences were selected in vivo. This "instant evolution" experiment revealed that approximately 190 of the 262,144 possible mutant sequences were functional. Analysis of functional mutant sequences allowed discrimination between nucleotides directly involved in protein synthesis and those involved primarily in loop structure. Among the functional mutant sequences, positions 789 and 791 were invariant and extensive covariation was observed among the nucleotides at the base of the loop at positions 787, 788, 794 and 795. NMR and thermodynamic analyses of model 790 hairpins in vitro revealed weak pairing interactions between positions 787 and 795 and between positions 788 and 794 consistent with the in vivo mutational analysis. Functional analysis of site-directed mutants containing all possible nucleotide combinations at positions 787 and 795 in vivo showed that stable base-pairs at these positions prevent subunit association.

Modeling the structure of the ribosome

Considering the size and complexity of the ribosome and the growing body of data from a wide range of experiments on ribosomal structure, it is becoming increasingly important to develop tools that facilitate the development of reliable models for the ribosome. We use a combination of manual and computer-based approaches for building and refining models of the ribosome and other RNA-protein complexes. Our methods are aimed at determining the range of models compatible with the data, making quantitative statements about the positional uncertainties (resolution) of different regions, identifying conflicts in the data, establishing which regions of the ribosome need further experimental exploration, and, where possible, predicting the outcome of future experiments. Our previous low-resolution model for the small subunit of the Escherichia coli ribosome is briefly reviewed, along with progress on atomic resolution modeling of the mRNA-tRNA complex and its interaction with the decoding site of the 16S RNA.

Identification of bases in 16S rRNA essential for tRNA binding at the 30S ribosomal P site

Previous studies suggest that the mechanism of action of the ribosome in translation involves crucial transfer RNA (tRNA)-ribosomal RNA (rRNA) interactions. Here, a selection scheme was developed to identify bases in 16S rRNA that are essential for tRNA binding to the P site of the small (30S) ribosomal subunit. Modification of the N-1 and N-2 positions of 2-methylguanine 966 and of the N-7 position of guanine 1401 interfered with messenger RNA (mRNA)-dependent binding of tRNA to the P site. Modification of the same positions as well as of the N-1 and N-2 positions of guanine 926 interfered with mRNA-independent binding of tRNA at high magnesium ion concentration. These results suggest that these three bases are involved in intermolecular contacts between ribosomes and tRNA.

Arrangement of mRNA at the decoding site of human ribosomes. 18S rRNA nucleotides and ribosomal proteins cross-linked to oligouridylate derivatives with alkylating groups at either the 3' or the 5' termini

Affinity labeling of human placental 80S ribosomes with mRNA analogs of up to 12 uridyl residues, i.e. alkylating derivatives of oligouridylates bearing either 4-(N-2-chloroethyl-N-methylamino)benzylmethylphosphamide group at the 5'-termini or 2',3'-O-[4-(N-2-chloroethyl-N-methylamino)]benzylidene residue attached to the 3'-termini, in the presence of cognate Phe-tRNA(Phe) has been investigated. All the mRNA analogs modified only the 40S subunit. The fraction of 18S rRNA modified by the mRNA analogs with the alkylating group at the 5'-end decreased dramatically with extension of the reagent oligouridylate moiety. Nucleotides of 18S rRNA alkylated with the mRNA analogs were determined using a reverse transcription technique. For the mRNA analogs with the alkylating groups at the 3'-termini, G1702 and G1763/G1764 were identified as the cross-linking sites. The intensities of the bands corresponding to reverse transcriptase stops depended on the length of the reagent oligouridylate moieties. Cross-linking sites of the mRNA analogs with the alkylating group at the 5'-termini on 18S rRNA were A1023, C1026, C1057 and A1058 for the (pU)3 and (pU)4 derivatives and a single nucleotide C1057 for the (pU)6 one. Ribosomal protein S26 was found as the main target of modification with the same derivatives of (pU)6 and (pU)12.

Methylation of the conserved A1518-A1519 in Escherichia coli 16S ribosomal RNA by the ksgA methyltransferase is influenced by methylations around the similarly conserved U1512.G1523 base pair in the 3' terminal hairpin

An in vitro system developed for the site-specific mutagenesis of 16S rRNA of Escherichia coli ribosomes was used to make five mutations around the highly conserved U1512.G1523 base pair in the 3' terminal hairpin. Each of the mutant RNAs was reconstituted with a complete mixture of 30S proteins to yield 30S ribosomal particles, which were tested for the ability of the ksgA methylase to form m6(2)A1518 and m6(2)A1519. Dimethylation of A1518 and A1519 in the hairpin loop was inhibited 20-80% by the mutations. The results indicate that G1523 and C1524 in the stem are important determinants for the dimethylation of A1518 and A1519 in the loop. Either the enzyme recognition region extends that far or the effect of mutations in the stem are propagated in some manner to the loop. The conserved U.G base pair does not of itself appear to play a major role in ksgA methylase recognition.

Separation of mutant and wild-type ribosomes based on differences in their anti Shine-Dalgarno sequence

We describe a system to isolate 30S ribosomal subunits which contain targeted mutations in their 16S rRNA. The mutations of interest should be present in so-called specialized 30S subunits which have an anti-Shine-Dalgarno sequence that is altered from 5' ACCUCC to 5' ACACAC. These plasmid-encoded specialized 30S subunits are separated from their chromosomally encoded wild-type counterparts by affinity chromatography that exploits the different Shine-Dalgarno complementarity. An oligonucleotide complementary to the 3' end of wild-type 16S rRNA and attached to a solid phase matrix retains the wild-type 30S subunits. The flow-through of the column contains close to 100% mutant 30S subunits. Toeprinting assays demonstrate that affinity column treatment does not cause significant loss of activity of the specialized particles in initiation complex formation, whereas elongation capacity as determined by poly(Phe) synthesis is only slightly decreased. The method described offers an advantage over total reconstitution from in vitro transcribed mutant 16S rRNA since our 30S subunits contain the naturally occurring base modifications in their 16S rRNA.

Interaction between the two conserved single-stranded regions at the decoding site of small subunit ribosomal RNA is essential for ribosome function

Formation of the tertiary base pair G1401:C1501, which brings together two universally present and highly sequence-conserved single-stranded segments of small subunit ribosomal RNA, is essential for ribosome function. It was previously reported that mutation of G1401 inactivated all in vitro functions of the ribosome [Cunningham et al. (1992) Biochemistry 31, 7629-7637]. Here we show that mutation of C1501 to G was equally inactivating but that the double mutant C1401:G1501 with the base pair reversed had virtually full activity for tRNA binding to the P, A, and I sites and for peptide bond formation. Initiation-dependent formation of the first peptide bond remained 70-85% inhibited, despite full 70S initiation complex formation ability as evidenced by the ability to form fMET-puromycin. These results suggest that the defect in formation of the first peptide bond lies in filling the initial A site, Ai, rather than the subsequent elongation A sites, Ae. An increased mobility around the anticodon was detected by UV cross-linking of the anticodon of P-site-bound tRNA to C1399 as well as to the expected C1400. These findings provide the first experimental evidence for the existence of the G1401:C1501 base pair and show that this base pair, located at the decoding site, is essential for function. The structural implications of tertiary base pair formation are discussed.