Methylation of 16S ribosomal RNA and resistance to aminoglycoside antibiotics in clones of Streptomyces lividans carrying DNA from Streptomyces tenjimariensis

Summary A single gene from Streptomyces tenjimariensis, conferring resistance to kanamycin, apramycin and sisomicin, has been cloned in Streptomyces lividans. The mechanism of resistance involves methylation of 16S RNA in the 30S ribosomal subunit.     

Interaction of proteins S16, S17 and S20 with 16 S ribosomal RNA

We have used rapid chemical probing methods to examine the effect of assembly of ribosomal proteins S16, S17 and S20 on the reactivity of individual residues of 16 S rRNA. Protein S17 strongly protects a compact region of the RNA between positions 245 and 281, a site previously assigned to binding of S20. Protein S20 also protects many of these same positions, albeit more weakly than S17. Strong S20-dependent protections are seen elsewhere in the 5' domain, most notably at positions 108, and in the 160-200 and 330 loop regions. Enenpectedly, S20 also causes protection of several bases in the 1430-1450 region, in the 3' minor domain. In the presence of the primary binding proteins S4, S8 and S20, we observe a variety of effects that result from assembly of the secondary binding protein S16. Most strongly protected are nucleotides around positions 50, 120, 300 to 330 and 360 in the 5' domain, and positions 606 to 630 in the central domain. In addition, numerous nucleotides in the 5' and central domains exhibit enhanced reactivity in response to S16. Interestingly, the strength of the S20-dependent effects in the 1430-1450 region is attenuated in the presence of S4 + S8 + S20, and restored in the presence of S4 + S8 + S20 + S16. Finally, the previously observed rearrangement of the 300 region stem-loop that occurs during assembly is shown to be an S16-dependent event. We discuss these findings with respect to assignment of RNA binding sites for these proteins, and in regard to the co-operativity of ribosome assembly.     

Inducible ribosomal RNA methylation in Streptomyces lividans, conferring resistance to lincomycin

Streptomyces lividans TK21 possesses inducible ribosomal RNA methylase activity that confers high-level resistance to lincomycin and lower levels of resistance to certain macrolides. The methylase gene (designated lrm) is inducible by erythromycin and other macrolides and also by celesticetin (a lincosamide) but not by lincomycin. The lrm enzyme monomethylates the N6-amino group of adenosine at position 2058 within 23S-like ribosomal RNA.     

Interaction of ribosomal proteins, S6, S8, S15 and S18 with the central domain of 16 S ribosomal RNA

We have constructed complexes of ribosomal proteins S8, S15, S8 + S15 and S8 + S15 + S6 + S18 with 16 S ribosomal RNA, and probed the RNA moiety with a set of structure-specific chemical and enzymatic probes. Our results show the following effects of assembly of proteins on the reactivity of specific nucleotides in 16 S rRNA. (1) In agreement with earlier work, S8 protects nucleotides in and around the 588-606/632-651 stem from attack by chemical probes; this is supported by protection in and around these same regions from nucleases. In addition, we observe protection of positions 573-575, 583, 812, 858-861 and 865. Several S8-dependent enhancements of reactivity are found, indicating that assembly of this protein is accompanied by conformational changes in 16 S rRNA. These results imply that protein S8 influences a much larger region of the central domain than was previously suspected. (2) Protein S15 protects nucleotides in the 655-672/734-751 stem, in agreement with previous findings. We also find S15-dependent protection of nucleotides in the 724-730 region. Assembly of S15 causes several enhancements of reactivity, the most striking of which are found at G664, A665, G674, and A718. (3) The effects of proteins S6 and S18 are dependent on the simultaneous presence of both proteins, and on the presence of protein S15. S6 + S18-dependent protections are located in the 673-730 and 777-803 regions. We observed some variability in our results with these proteins, depending on the ratio of protein to RNA used, and in different trials using enzymatic probes, possibly due to the limited solubility of protein S18. Consistently reproducible was protection of nucleotides in the 664-676 and 715-729 regions. Among the latter are three of the nucleotides (G664, G674 and A718) that are strongly enhanced by assembly of protein S15. This result suggests that an S15-induced conformational change involving these nucleotides may play a role in the co-operative assembly of proteins S6 and S18.     

Nuclease S1 mapping of 16S ribosomal RNA in ribosomes

Escherichia coli 16S rRNA and 16S-like rRNAs from other species have several universally conserved sequences which are believed to be single-stranded in ribosomes. The quantitative disposition of these sequences within ribosomes is not known. Here we describe experiments designed to explore the availability of universal 16S rRNA sequences for hybridization with DNA probes in 30S particles and 70S ribosomes. Unlike previous investigations, quantitative data on the accessibility of DNA probes to the conserved portions of 16S rRNA within ribosomes was acquired. Uniquely, the experimental design also permitted investigation of cooperative interactions involving portions of conserved 16S rRNA. The basic strategy employed ribosomes, 30S subunits, and 16S rRNAs, which were quantitatively analyzed for hybridization efficiency with synthetic DNA in combination with nuclease S1. In deproteinated E. coli 16S rRNA and 30S subunits, the regions 520-530, 1396-1404, 1493-1504, and 1533-1542 are all single-stranded and unrestricted for hybridization to short synthetic DNAs. However, the quantitative disposition of the sequences in 70S ribosomes varies with each position. In 30S subunits there appear to be no cooperative interactions between the 16S rRNA universal sequences investigated.     

Fragmentation heterogeneity of 23S ribosomal RNA in Haemophilus species

The fragmentation of 23S rRNA of 22 Haemophilus influenzae strains and eight strains belonging to other Haemophilus species was investigated. Instead of intact molecules, the 23S rRNA molecules were found to be cleaved into two to five smaller conserved fragments in most strains examined, especially in H. influenzae type b (5/6) and nontypeable strains (5/5). One or two conserved potential cleavage sites were identified by PCR analysis of the strains showing a fragmented 23S rRNA pattern. The relevant nucleotide sequences were determined and compared to H. influenzae Rd, which contains intact 23S rRNA molecules. An identical 112 bp long intervening sequence (IVS) at position 542 and a conserved 121–123 bp IVS sequence at position 1171 were found in two H. influenzae type b strains and one nontypeable strain. Among the strains with fragmented 23S rRNA, nearly half showed a heterogeneous cleavage pattern due to the dispersion of IVSs among different 23S rRNA operons. The localization of the conserved H. influenzae IVSs coincided well with the extensively studied IVSs among other bacteria, but differed in nucleotide sequence from any other reported IVSs. Therefore, the IVSs of Haemophilus 23S rRNA may originate from a common source that is independent of other bacteria.     

Mutations in ribosomal proteins S4 and S12 influence the higher order structure of 16 S ribosomal RNA

We have studied the effects of protein mutations on the higher order structure of 16 S rRNA in Escherichia coli ribosomes, using a set of structure-sensitive chemical probes. Ten mutant strains were studied, which contained alterations in ribosomal proteins S4 and S12, including double mutants containing both altered S4 and S12. Two ribosomal ambiguity (ram) S4 mutant strains, four streptomycin resistant (SmR) S12 mutant strains, one streptomycin pseudodependent (SmP) S12 mutant strain, one streptomycin dependent (SmD) S12 mutant strain and two streptomycin independent (Sm1) double mutants (containing both-SmD and ram mutations) were probed and compared to an isogenic wild-type strain. In ribosomes from strains containing S4 ram mutations, nucleotides A8 and A26 become more reactive to dimethyl sulfate (DMS) at their N-1 positions. In ribosomes from strains bearing the SmD allele, A908, A909, A1413 and G1487 are significantly less reactive to chemical probes. These same effects are observed when the S4 and S12 mutations are present simultaneously in the double mutants. An interesting correlation is found between the reactivity of A908 and the miscoding potential of SmR, SmD, SmP and wild-type ribosomes; the reactivity of A908 increases as the translational error frequency of the ribosomes increases. In the case of ram ribosomes, the reactivity of A908 resembles that of wild-type, unless tRNA is bound, in which case it becomes hyper-reactive. Similarly, streptomycin has little effect on A908 in wild-type ribosomes unless tRNA is bound, in which case its reactivity increases to resemble that of ram ribosomes with bound tRNA. Finally, interaction of streptomycin with SmP and SmD ribosomes causes the reactivity of A908 to increase to near-wild-type levels. A simple model is proposed, in which the reactivity of A908 reflects the position of an equilibrium between two conformational states of the 30 S subunit, one of which is DMS-reactive, and the other DMS-unreactive. In this model, the balance between these two states would be influenced by proteins S4 and S12. Mutations in S12 generally cause a shift toward the unreactive conformer, and in the case of SmD and SmP ribosomes, this shift can be suppressed phenotypically by streptomycin, ram mutations in protein S4 cause a shift toward the reactive conformer, but only when tRNA is bound. This suggests that the opposing effects of these two classes of mutations influence the proof-reading process by somewhat different mechanisms.     

Scanning tunnelling microscopy of 16S ribosomal RNA in water

The scanning tunnelling microscope has been used to image 16S ribosomal RNA molecules in water electrophoretically deposited on graphite surface. Two kinds of images have been obtained: images showing aggregates of 16S ribosomal RNA molecules similar to those obtained from DNA solutions and others showing individual 16S ribosomal RNA molecules. An interesting characteristic of these images, recorded in constant current mode, is that the 16S ribosomal RNA molecules appear to be located below the graphite surface. The morphology and several structural parameters of the molecules were consistent with the data obtained from electron microscopy.     

Interaction of ribosomal proteins S6, S8, S15 and S18 with the central domain of 16 S ribosomal RNA from Escherichia coli

The co-operative interaction of 30 S ribosomal subunit proteins S6, S8, S15 and S18 with 16 S ribosomal RNA from Escherichia coli was studied by (1) determining how the binding of each protein is influenced by the others and (2) characterizing a series of protein-rRNA fragment complexes. Whereas S8 and S15 are known to associate independently with the 16 S rRNA, binding of S18 depended upon S8 and S15, and binding of S6 was found to require S8, S15 and S18. Ribonucleoprotein (RNP) fragments were derived from the S8-, S8/S15- and S6/S8/S15/S18-16 S rRNA complexes by partial RNase hydrolysis and isolated by electrophoresis through Mg2+-containing polyacrylamide gels or by centrifugation through sucrose gradients. Identification of the proteins associated with each RNP by gel electrophoresis in the presence of sodium dodecyl sulfate demonstrated the presence of S8, S8 + S15 and S6 + S8 + S15 + S18 in the corresponding fragment complexes. Analysis of the rRNA components of the RNP particles confirmed that S8 was bound to nucleotides 583 to 605 and 624 to 653, and that S8 and S15 were associated with nucleotides 583 to 605, 624 to 672 and 733 to 757. Proteins S6, S8, S15 and S18 were shown to protect nucleotides 563 to 605, 624 to 680, 702 to 770, 818 to 839 and 844 to 891, which span the entire central domain of the 16 S rRNA molecule (nucleotides 560 to 890). The binding site for each protein contains helical elements as well as single-stranded internal loops ranging in size from a single bulged nucleotide to 20 bases. Three terminal loops and one stem-loop structure within the central domain of the 16 S rRNA were not protected in the four-protein complex. Interestingly, bases within or very close to these unprotected regions have been shown to be accessible to chemical and enzymatic probes in 30 S subunits but not in 70 S ribosomes. Furthermore, nucleotides adjacent to one of the unprotected loops have been cross-linked to a region near the 3' end of 16 S rRNA. Our observations and those of others suggest that the bases in this domain that are not sequestered by interactions with S6, S8, S15 or S18 play a role involved in subunit association or in tertiary interactions between portions of the rRNA chain that are distant from one-another in the primary structure.(ABSTRACT TRUNCATED AT 400 WORDS)     

Chromosomal loci for 16S ribosomal RNA in Escherichia coli

Summary Genetic loci for 16S ribosomal RNA (rRNA) on the Escherichia coli chromosome were determined using the K-sequence, a characteristic oligonucleotide of strain K12, as a genetic marker. Oligonucleotide analyses of 16S rRNA from various recombinants between strain K12 and strain B(H) showed that the loci for 16S rRNA containing the K-sequence were near the metB locus which was at 77 min. on the chromosome map.     

Mutations in 16S ribosomal RNA disrupt antibiotic--RNA interactions.

Two of six mutations at a base-paired site in Escherichia coli 16S rRNA confer resistance to nine different aminoglycoside antibiotics in vivo. Chemical probing of mutant and wild-type ribosomes in the presence of paromomycin indicates that interactions between the antibiotic and 16S rRNA in mutant ribosomes are disrupted. The altered interactions measured in vitro correlate precisely with resistance seen in vivo and may be attributable to specific structural changes observed in the mutant rRNA.