A functional pseudoknot in 16S ribosomal RNA.

Several lines of evidence indicate that the universally conserved 530 loop of 16S ribosomal RNA plays a crucial role in translation, related to the binding of tRNA to the ribosomal A site. Based upon limited phylogenetic sequence variation, Woese and Gutell (1989) have proposed that residues 524-526 in the 530 hairpin loop are base paired with residues 505-507 in an adjoining bulge loop, suggesting that this region of 16S rRNA folds into a pseudoknot structure. Here, we demonstrate that Watson-Crick interactions between these nucleotides are essential for ribosomal function. Moreover, we find that certain mild perturbations of the structure, for example, creation of G-U wobble pairs, generate resistance to streptomycin, an antibiotic known to interfere with the decoding process. Chemical probing of mutant ribosomes from streptomycin-resistant cells shows that the mutant ribosomes have a reduced affinity for streptomycin, even though streptomycin is thought to interact with a site on the 30S subunit that is distinct from the 530 region. Data from earlier in vitro assembly studies suggest that the pseudoknot structure is stabilized by ribosomal protein S12, mutations in which have long been known to confer streptomycin resistance and dependence.     

Interconversion of active and inactive 30 S ribosomal subunits is accompanied by a conformational change in the decoding region of 16 S rRNA

Zamir, Elson and their co-workers have shown that 30 S ribosomal subunits are reversibly inactivated by depletion of monovalent or divalent cations. We have re-investigated the conformation of 16 S rRNA in the active and inactive forms of the 30 S subunit, using a strategy that is designed to eliminate reversible ion-dependent conformational effects that are unrelated to the heat-dependent Zamir-Elson transition. A combination of structure-specific chemical probes enables us to monitor the accessibility of pyrimidines at N-3 and purines at N-1 and N-7. Chemically modified bases are identified by end-labeling followed by analine-induced strand scission (in some cases preceded by hybrid selection), or by primer extension using synthetic DNA oligomers. These studies show the following: The transition from the active to the inactive state cannot be described as a simple loosening or unfolding of native structure, such as that which is observed under conditions of more severe ion depletion. Instead, it has the appearance of a reciprocal interconversion between two differently structured states; some bases become more reactive toward the probes, whilst others become less reactive as a result of inactivation. Changes in reactivity are almost exclusively confined to the "decoding site" centered at positions 1400 and 1500, but significant differences are also detected at U723 and G791 in the central domain. This may reflect possible structural and functional interactions between the central and 3' regions of 16 S rRNA. The inactive form also shows significantly decreased reactivity at positions 1533 to 1538 (the Shine-Dalgarno region), in agreement with earlier findings. The principal changes in reactivity involve the universally conserved nucleotides G926, C1395, A1398 and G1401. The three purines show reciprocal behavior at their N-1 versus N-7 positions. G926 loses its reactivity at N-1, but becomes highly reactive at N-7 as a result of the transition of the inactive state. In contrast, A1398 and G1401 become reactive at N-1, but lose their hyper-reactivity at N-7. The possible structural and functional implications of these findings are discussed.     

The conserved 5 S rRNA complement to tRNA is not required for translation of natural mRNA

We have tested a putative base-paired interaction between the conserved GT psi C sequence of tRNA and the conserved GAAC47 sequence of 5 S ribosomal RNA by in vitro protein synthesis using ribosomes containing deletions in this region of 5 S rRNA. Ribosomes reconstituted with 5 S rRNA possessing a single break between residues 41 and 42, deletion of residues 42-46, or deletion of residues 42-52 were tested for their ability to translate phage MS2 RNA. Initiator tRNA binding, aminoacyl-tRNA binding, ppGpp synthesis, and miscoding were also tested. All of the measured functions could be carried out by ribosomes carrying the deleted 5 S rRNAs. The sizes and relative amounts of the polypeptides synthesized by MS2 RNA-programmed ribosomes were identical whether or not the 5 S RNA contained deletions. Aminoacyl-tRNA binding and miscoding were essentially unaffected. Significant reduction in ApUpG (but not poly(A,U,G) or MS2 RNA)-directed fMet-tRNA binding and ppGpp synthesis were observed, particularly in the case of the larger (residues 42-52) deletion. We conclude that if tRNA and 5 S rRNA interact in this fashion, it is not an obligatory step in protein synthesis.     

Transfer RNA shields specific nucleotides in 16S ribosomal RNA from attack by chemical probes

Binding of tRNAPhe to ribosomes shields a set of highly conserved nucleotides in 16S rRNA from attack by a combination of structure-specific chemical probes. The bases can be classified according to whether or not their protection is strictly poly(U)-dependent (G529, G530, U531, A1408, A1492, and A1493) or poly(U)-independent (A532, G693, A794, C795, G926, 2mG966, G1338, A1339, U1381, C1399, C1400, and G1401). A third class (A790, G791, and A909) is shielded by both tRNA and 50S ribosomal subunits. Similar results are obtained when the protecting ligand is tRNAPhe E. Coli, tRNAPhe yeast, tRNAPhe E. Coli lacking its 3' terminal CA, or the 15 nucleotide anticodon stem-loop fragment of tRNAPhe yeast. Implications for structural correlates of the classic ribosomal A- and P-sites and for the possible involvement of 16S rRNA in translational proofreading are discussed.     

Protection of ribosomal RNA from kethoxal in polyribosomes: Implication of specific sites in ribosome function

In an attempt to probe the topography of 5 S, 16 S and 23 S RNAs in a functionally engaged ribosome, polysomes were probed using the structure-sensitive, guanine-specifie reagent kethoxal. Reactivities of guanine residues at 38 specific ribosomal RNA sites in polysomes were compared with their corresponding reactivities in vacant 70 S ribosomes. No polysome-specific protection was seen for 5 S RNA. In 16 S RNA, positions 530, 693 or 1079, 966, 1338 and 1517 showed protection in polysomes; all of these sites have highly conserved primary and secondary structures, and include several methylated nucleotides. In 23 S RNA, polysome protection is seen at positions 277, 1071, 1475 or 2112, 2116 and 2751. We attribute polysome-specific protection either to direct contact of transfer RNA and/or messenger RNA with the protected sites or to tRNA and/or mRNA-induced changes in ribosome conformation involving the protected sites.     

Identification of sites of 4'-(hydroxymethyl)-4,5',8-trimethylpsoralen cross-linking in Escherichia coli 23S ribosomal ribonucleic acid

The reagent 4'-(hydroxymethyl)-4,5',8-trimethylpsoralen (HMT) was used to cross-link 23S rRNA from Escherichia coli under 50S ribosomal subunit reconstitution conditions. Following partial digestion of the RNA with ribonuclease T1, two-dimensional diagonal electrophoresis in denaturing polyacrylamide gels was used to isolate fragments derived from the cross-linked sites. These fragments were analyzed by digestion with ribonucleases T1 and A and their positions in the 23S RNA sequence identified. Fragment a1 (positions 1325-1426) is cross-linked to a2 (positions 1574-1623); fragment b1 (positions 1700-1731) is cross-linked to b2 (positions 1732-1753); and a cross-link is formed within fragment c (or c') (positions 863-916). In the latter case, the cross-link was located precisely, linking residues C867 and U913. All three HMT-mediated cross-links are consistent with a proposed secondary structure model for 23S RNA [Noller, H. F., Kop, J., Wheaton, V., Brosius, J., Gutell, R. R., Kopylov, A. M., Dohme, F., Herr, W., Stahl, D. A., Gupta, R., & Woese, C. R. (1981) Nucleic Acids Res. 9, 6167-6189].     

Binding of tRNA to the ribosomal A and P sites protects two distinct sets of nucleotides in 16 S rRNA

Transfer RNA protects a characteristic set of bases in 16 S rRNA from chemical probes when it binds to ribosomes. We used several criteria, based on construction of well-characterized in vitro ribosome-tRNA complexes, to assign these proteins to A or P-site binding. All of these approaches lead to similar conclusions. In the A site, tRNA caused protection of G529, G530, A1492 and A1493 (strongly), and A1408 and G1494 (weakly). In the P site, the protected bases are G693, A794, C795, G926 and G1401 (strong), and A532, G966, G1338 and G1339 (weak). In contrast to what is observed for 23 S rRNA, blocking the release of EF-Tu.GDP from the ribosome by kirromycin has no detectable effect on the protection of bases in 16 S rRNA.     

Interactions ofCandida albicans with bacteria and salivary molecules in oral biofilms

The yeastCandida albicans coaggregates with a variety of streptococcal species, an interaction that may promote oral colonization by yeast cells.C. albicans andCandida tropicalis are the yeasts most frequently isolated from the human oral cavity and our data demonstrate that both these species bind toStreptococcus gordonii NCTC 7869 while two otherCandida species (Candida krusei andCandida kefyr) do not. Adherence ofC. albicans was greatest when the yeast had been grown at 30° C to mid-exponential growth phase. For 21 strains ofC. albicans there was a positive correlation between the ability to adhere toS. gordonii and adherence to experimental salivary pellicle. Whole saliva either stimulated or slightly inhibited adherence ofC. albicans toS. gordonii depending on the streptococcal growth conditions. The results suggest that the major salivary adhesins and coaggregation adhesins ofC. albicans are co-expressed.