Nucleotide sequence of a 'truncated rRNA operon' of the Euglena gracilis chloroplast genome.

An extra 16S rRNA gene (s-16S rDNA) from the Euglena gracilis chloroplast genome and several hundred positions of its flanking regions have been sequenced. The structural part has 1486 positions and is to 98% homologous in its sequence with the 16S rRNA gene in functional chloroplast rRNA operons. Sequences of about 200 positions upstream and 15 positions downstream of the structural part of the s-16S rRNA gene region are highly homologous with corresponding parts in the functional operon. Neither tRNA genes (A1a, I1e) nor parts of the 23S and 5S rRNA genes are found within 557 positions after the 3' end of the s-16S rRNA gene, i.e., the 330 bp homology, observed in electron microscopic studies of heteroduplexes (4), between the s-16S rDNA downstream region and the 6.2 kb repeated segment containing the functional rRNA operon, must be due to a DNA stretch in the interoperon spacer. A structural model of the "truncated rRNA operon" is presented. Results from S-1 endonuclease analysis suggest that the s-16S rDNA region is probably not transcribed into stable s-16S rRNA.     

Ribosomal and non-ribosomal resistance to oxazolidinones: species-specific idiosyncrasy of ribosomal alterations

A derivative of Mycobacterium smegmatis, which carries only one functional rRNA (rrn) operon, was used to isolate mutants resistant to the ribosome-targeted antibiotic linezolid. Isolation and characterization of linezolid-resistant clones revealed two classes of mutants. Ribosomes from class I mutants are resistant to oxazolidinones in an in vitro peptidyl transferase assay, indicating that resistance maps to the ribosome component. In contrast, ribosomes from class II mutants show wild-type susceptibility to a linezolid derivative in vitro, pointing to a non-ribosomal mechanism of resistance. Introduction of a wild-type ribosomal RNA operon into linezolid-resistant strains restored linezolid sensitivity in class I mutants, indicating that resistance (i) maps to the rRNA and (ii) is recessive. Sequencing of the entire rrn operon identified a single nucleotide alteration in 23S rRNA of class I mutant strains, 2447G --> T (Escherichia coli numbering). Introduction of mutant rrl2447T into M. smegmatis rrn- resulted in a linezolid-resistant phenotype, demonstrating a cause-effect relationship of the 2447G --> T alteration. The 2447G --> T mutation, which renders M. smegmatis linezolid resistant, confers lethality in E. coli. This finding is strong evidence of structural and pos-sibly functional differences between the ribosomes of Gram-positive and Gram-negative bacteria. In agreement with the results of the in vitro assay, class II mutants show a wild-type sequence of the complete rRNA operon. The lack of cross-resistance of the class II mutants to other antibiotics suggests a resistance mechanism other than activation of a broad-spectrum multidrug transporter.     

Streptomycin-resistance of Euglena gracilis chloroplasts: identification of a point mutation in the 16S rRNA gene in an invariant position.

We sequenced the chloroplast 16S rRNA gene of two Euglena gracilis mutants which contain streptomycin-resistant chloroplasts (Smr 139.12/4 and Smr 139.20/2). These mutants are known to contain a single intact rrn operon per circular chloroplast genome. Nucleotide sequence comparison between a 16S rRNA gene of wild type Euglena gracilis, strain Z, with streptomycin-sensitive chloroplasts, and the 16S rRNA gene of both Smr-strains reveals a single base change (C to T) at position 876. This position is equivalent to the invariant position 912 of the E. coli 16S rRNA gene. The analogous position is also conserved in all chloroplast small subunit RNA genes from lower and higher plants sequenced so far. Light dependent protein synthesis with purified chloroplasts from streptomycin-resistant cells is not inhibited by streptomycin. Based on the results reported here we postulate linkage between the observed point mutation on the 16S rRNA gene and streptomycin-resistance of chloroplast 70S ribosomes.     

Modulation of 16S rRNA function by ribosomal protein S12

Ribosomal protein S12 is a critical component of the decoding center of the 30S ribosomal subunit and is involved in both tRNA selection and the response to streptomycin. We have investigated the interplay between S12 and some of the surrounding 16S rRNA residues by examining the phenotypes of double-mutant ribosomes in strains of Escherichia coli carrying deletions in all chromosomal rrn operons and expressing total rRNA from a single plasmid-borne rrn operon. We show that the combination of S12 and otherwise benign mutations at positions C1409-G1491 in 16S rRNA severely compromises cell growth while the level and range of aminoglycoside resistances conferred by the G1491U/C substitutions is markedly increased by a mutant S12 protein. The G1491U/C mutations in addition confer resistance to the unrelated antibiotic, capreomycin. S12 also interacts with the 912 region of 16S rRNA. Genetic selection of suppressors of streptomycin dependence caused by mutations at proline 90 in S12 yielded a C912U substitution in 16S rRNA. The C912U mutation on its own confers resistance to streptomycin and restricts miscoding, properties that distinguish it from a majority of the previously described error-promoting ram mutants that also reverse streptomycin dependence.     

Suppression of a cold-sensitive mutant initiation factor 1 by alterations in the 23S rRNA maturation region

Genetic selection has been used to isolate second-site suppressors of a defective cold-sensitive initiation factor I (IF1) R69L mutant of Escherichia coli. The suppressor mutants specifically map to a single rRNA operon on a plasmid in a strain with all chromosomal rRNA operons deleted. Here, we describe a set of suppressor mutations that are located in the processing stem of precursor 23S rRNA. These mutations interfere with processing of the 23S rRNA termini. A lesion of RNase III also suppresses the cold sensitivity. Our results suggest that the mutant IF1 strain is perturbed at the level of ribosomal subunit association, and the suppressor mutations partially compensate for this defect by disrupting rRNA maturation. These results support the notion that IF1 is an RNA chaperone and that translation initiation is coupled to ribosomal maturation.     

Mutations in conserved helix 69 of 23S rRNA of Thermus thermophilus that affect capreomycin resistance but not posttranscriptional modifications

Translocation during the elongation phase of protein synthesis involves the relative movement of the 30S and 50S ribosomal subunits. This movement is the target of tuberactinomycin antibiotics. Here, we describe the isolation and characterization of mutants of Thermus thermophilus selected for resistance to the tuberactinomycin antibiotic capreomycin. Two base substitutions, A1913U and mU1915G, and a single base deletion, DeltamU1915, were identified in helix 69 of 23S rRNA, a structural element that forms part of an interribosomal subunit bridge with the decoding center of 16S rRNA, the site of previously reported capreomycin resistance base substitutions. Capreomycin resistance in other bacteria has been shown to result from inactivation of the TlyA methyltransferase which 2'-O methylates C1920 of 23S rRNA. Inactivation of the tlyA gene in T. thermophilus does not affect its sensitivity to capreomycin. Finally, none of the mutations in helix 69 interferes with methylation at C1920 or with pseudouridylation at positions 1911 and 1917. We conclude that the resistance phenotype is a consequence of structural changes introduced by the mutations.     

Chloramphenicol-erythromycin resistance mutations in a 23S rRNA gene of Escherichia coli.

Two chloramphenicol resistance mutations were isolated in an Escherichia coli rRNA operon (rrnH) located on a multicopy plasmid. Both mutations also confer resistance to 14-atom lactone ring macrolide antibiotics, but they do not confer resistance to 16-atom lactone ring macrolide antibiotics or other inhibitors of the large ribosomal subunit. Classic genetic and recombinant DNA methods were used to map the two mutations to 154-base-pair regions of the 23S RNA genes. DNA sequencing of these regions revealed that chloramphenicol-erythromycin resistance results from a guanine-to-adenine transition at position 2057 of the 23S RNA genes of both independently isolated mutants. These mutations affect a region of 23S RNA strongly implicated in peptidyl transfer and known to interact with a variety of peptidyl transferase inhibitors.     

Deletion analysis of the expression of rRNA genes and associated tRNA genes carried by a lambda transducing bacteriophage.

Transducing phage lambdailv5 carries genes for rRNA's, spacer tRNA's (tRNA1 Ile and tRNA1B Ala), and two other tRNA's (TRNA1 Asp and tRNA Trp). We have isolated a mutant of lambdailv5, lambdailv5su7, which carries an amber suppressor mutation in the tRNA Trp gene. A series of deletion mutants were isolated from the lambdailv5su7 phage. Genetic and biochemical analyses of these deletion mutants have confirmed our previous conclusion (E. A. Morgan, T. Ikemura, L. Lindahl, A. M. Fallon, and M. Nomura, Cell 13:335--344, 1978) that the genes for tRNA1 Asp and tRNA Trp located at the distal end of the rRNA operon (rrnC) are cotranscribed with other rRNA genes in that operon. In addition, these deletions were used to define roughly the physical location of the promoter(s) of the rRNA operon carried by the lambdailv5su7 transducing phage.     

Genetic and physiological characterization of 23S rRNA and ftsJ mutants of Borrelia burgdorferi isolated by mariner transposition

Borrelia burgdorferi contains one 16S rRNA gene and two tandem sets of 23S and 5S rRNA genes located in a single chromosomal region. This unusual rRNA gene organization has been speculated to be involved in the slow growth of this organism. Because we were repeatedly unable to isolate a 23S ribosomal mutant in B. burgdorferi by allelic exchange, we developed a transposition mutagenesis system for this bacterium. To this end, Himar1 transposase is expressed in B. burgdorferi from a resident plasmid containing an erythromycin resistance marker, and this strain is then electroporated with suicide plasmids containing mariner transposons and kanamycin resistance genes expressible in B. burgdorferi. This system permitted us to generate hundreds of erythromycin/kanamycin-resistant B. burgdorferi clones with each of three suicide plasmids. DNA sequencing of several kanamycin-resistant clones generated with one of the suicide plasmids showed stable and random insertion of the transposon into the B. burgdorferi chromosomal and plasmid genome. One mutant was inactivated in rrlA (23S rRNA), another in ftsJ (rrmJ). rrlA disruption had no effect on growth rate under a wide range of culture conditions, but disruption of ftsJ interfered significantly with growth rate and bacterial morphology. These data show it is possible to isolate random and stable B. burgdorferi transposition mutants for physiological analysis of this pathogenic spirochete.     

Oxazolidinone resistance mutations in 23S rRNA of Escherichia coli reveal the central region of domain V as the primary site of drug action

Oxazolidinone antibiotics inhibit bacterial protein synthesis by interacting with the large ribosomal subunit. The structure and exact location of the oxazolidinone binding site remain obscure, as does the manner in which these drugs inhibit translation. To investigate the drug-ribosome interaction, we selected Escherichia coli oxazolidinone-resistant mutants, which contained a randomly mutagenized plasmid-borne rRNA operon. The same mutation, G2032 to A, was identified in the 23S rRNA genes of several independent resistant isolates. Engineering of this mutation by site-directed mutagenesis in the wild-type rRNA operon produced an oxazolidinone resistance phenotype, establishing that the G2032A substitution was the determinant of resistance. Engineered U and C substitutions at G2032, as well as a G2447-to-U mutation, also conferred resistance to oxazolidinone. All the characterized resistance mutations were clustered in the vicinity of the central loop of domain V of 23S rRNA, suggesting that this rRNA region plays a major role in the interaction of the drug with the ribosome. Although the central loop of domain V is an essential integral component of the ribosomal peptidyl transferase, oxazolidinones do not inhibit peptide bond formation, and thus these drugs presumably interfere with another activity associated with the peptidyl transferase center.     

A ketolide resistance mutation in domain II of 23S rRNA reveals the proximity of hairpin 35 to the peptidyl transferase centre

Ketolides represent a new generation of macrolide antibiotics. In order to identify the ketolide-binding site on the ribosome, a library of Escherichia coli clones, transformed with a plasmid carrying randomly mutagenized rRNA operon, was screened for mutants exhibiting resistance to the ketolide HMR3647. Sequencing of the plasmid isolated from one of the resistant clones and fragment exchange demonstrated that a single U754A mutation in hairpin 35 of domain II of the E. coli 23S rRNA was sufficient to confer resistance to low concentrations of the ketolide. The same mutation also conferred erythromycin resistance. Both the ketolide and erythromycin protected A2058 and A2059 in domain V of 23S rRNA from modification with dimethyl sulphate, whereas, in domain II, the ketolide protected, while erythromycin enhanced, modification of A752 in the loop of the hairpin 35. Thus, mutational and footprinting results strongly suggest that the hairpin 35 constitutes part of the macrolide binding site on the ribosome. Strong interaction of ketolides with the hairpin 35 in 23S rRNA may account for the high activity of ketolides against erythromycin-resistant strains containing rRNA methylated at A2058. The existence of macrolide resistance mutations in the central loop of domain V and in hairpin 35 in domain II together with antibiotic footprinting data suggest that these rRNA segments may be in close proximity in the ribosome and that hairpin 35 may be a constituent part of the ribosomal peptidyl transferase centre.     

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.     

Construction and Initial Characterization of Escherichia coli Strains with Few or No Intact Chromosomal rRNA Operons

The Escherichia coli genome carries seven rRNA (rrn) operons, each containing three rRNA genes. The presence of multiple operons has been an obstacle to many studies of rRNA because the effect of mutations in one operon is diluted by the six remaining wild-type copies. To create a tool useful for manipulating rRNA, we sequentially inactivated from one to all seven of these operons with deletions spanning the 16S and 23S rRNA genes. In the final strain, carrying no intact rRNA operon on the chromosome, rRNA molecules were expressed from a multicopy plasmid containing a single rRNA operon (prrn). Characterization of these rrn deletion strains revealed that deletion of two operons was required to observe a reduction in the growth rate and rRNA/protein ratio. When the number of deletions was extended from three to six, the decrease in the growth rate was slightly more than the decrease in the rRNA/protein ratio, suggesting that ribosome efficiency was reduced. This reduction was most pronounced in the Delta7 prrn strain, in which the growth rate, unlike the rRNA/protein ratio, was not completely restored to wild-type levels by a cloned rRNA operon. The decreases in growth rate and rRNA/protein ratio were surprisingly moderate in the rrn deletion strains; the presence of even a single operon on the chromosome was able to produce as much as 56% of wild-type levels of rRNA. We discuss possible applications of these strains in rRNA studies.     

The tylosin resistance gene tlrB of Streptomyces fradiae encodes a methyltransferase that targets G748 in 23S rRNA

tlrB is one of four resistance genes encoded in the operon for biosynthesis of the macrolide tylosin in antibiotic-producing strains of Streptomyces fradiae. Introduction of tlrB into Streptomyces lividans similarly confers tylosin resistance. Biochemical analysis of the rRNA from the two Streptomyces species indicates that in vivo TlrB modifies nucleotide G748 within helix 35 of 23S rRNA. Purified recombinant TlrB retains its activity and specificity in vitro and modifies G748 in 23S rRNA as well as in a 74 nucleotide RNA containing helix 35 and surrounding structures. Modification is dependent on the presence of the methyl group donor, S-adenosyl methionine. Analysis of the 74-mer RNA substrate by biochemical and mass spectrometric methods shows that TlrB adds a single methyl group to the base of G748. Homologues of TlrB in other bacteria have been revealed through database searches, indicating that TlrB is the first member to be described in a new subclass of rRNA methyltransferases that are implicated in macrolide drug resistance.     

A genetic model to investigate drug-target interactions at the ribosomal decoding site

Recent advances in X-ray crystallography have greatly contributed to the understanding of the structural interactions between aminoglycosides and the ribosomal decoding site. Efforts to genetically probe the functional relevance of proposed drug-nucleotide contacts have in part been hampered by the presence of multiple rRNA operons in most bacteria. A derivative of the Gram-positive Mycobacterium smegmatis was rendered single rRNA operon allelic by means of gene inactivation techniques. In this system, genetic manipulation of the single chromosomal rRNA operon results in cells carrying homogeneous populations of mutant ribosomes. An exhaustive mutagenesis study of the ribosomal A site has been performed to define the importance of individual drug-nucleotide contacts. Mutational alterations in the M. smegmatis decoding site are discussed here, comparing the results with those obtained in other organisms. Implications for the selectivity of antimicrobial agents and for the fitness cost of resistance mutations are addressed.     

Efficient and simple generation of unmarked gene deletions in Mycobacterium smegmatis

Genetic research in molecular laboratories relies heavily on directed mutagenesis and gene deletion techniques. In mycobacteria, however, genetic analysis is often hindered by difficulties in the preparation of deletion mutants. Indeed, in comparison to the allelic exchange systems available for the study of other common model organisms, such as Saccharomyces cerevisiae and Escherichia coli, mycobacterial gene disruption systems suffer from low mutant isolation success rates, mostly due to inefficient homologous recombination and a high degree of non-specific recombination. Here, we present a gene deletion system that combines efficient homologous recombination with advanced screening of mutants. This novel methodology allows for gene disruption in three consecutive steps. The first step relies on the use of phage Che9c recombineering proteins for directed insertion into the chromosome of a linear DNA fragment that encodes GFP and confers hygromycin resistance. In the second step, GFP positive and hygromycin resistant colonies are selected, and in the last step, the gfp-hyg cassette is excised from the chromosome, thus resulting in the formation of an unmarked deletion. We provide a detailed gene deletion methodology and demonstrate the use of this genetic system by deleting the prcSBA operon of Mycobacterium smegmatis.     

The cloned rRNA genes of P. lophurae: a novel rDNA structure.

The detailed structure of two ribosomal DNA (rDNA) clones CL-1 and HA-2, from the avian malaria parasite Plasmodium lophurae has been examined using hybridization and electron microscopy. The results demonstrate that the clone CL-1 contains two regions homologous to 25s rRNA of approximately 2200 base pairs (bp) and 450 bp in length, separated by a non homologous region of 240 bp. CL-1 also contains two regions of approximately 1100 bp and 550 bp homologous to 17s rRNA, separated by a non homologous region of 230 bp. The clone HA-2 contains a single region of 670 bp, which is homologous to 25s rRNA. This region is flanked by non homologous stretches of DNA 940 bp and 110 bp in length. As HA-2 is known to be adjacent to CL-1 in the genome (1), these results suggest that the 25s rDNA is interrupted twice, and the 17s rDNA once, by stretches of DNA not found in mature rRNA.