Loss of the spacer loop sequence from the rrnB operon in the Escherichia coli K-12 subline that bears the relA1 mutation.

A polymorphism affecting the spacer region of the rrnB rRNA operon is described. Strains from a major Escherichia coli K-12 subbranch are missing a 106-nucleotide portion of the rrnB 16S-to-23S spacer, and a 20-nucleotide sequence is found in its place. We have called this mutant operon rrnB2. The rrnB2 spacer was most probably derived from either rrnC or rrnE. This alteration of rrnB may have occurred by a recombinational exchange or by gene conversion. In the genealogy of E. coli K-12 strains, the appearance of rrnB2 is associated with the spontaneous occurrence of the first relaxed mutation, but attempts to show a selective relationship between the two mutational events have had negative results. The sequences of the rrnG and rrnC 16S-to-23S spacers have also been determined and their comparisons to the other rrn operons encoding tRNAGlu2 are presented.     

Molecular cloning and comparative sequence analyses of rRNA operons in Streptomyces nodosus ATCC 14899.

The genome of Streptomyces nodosus contains six ribosomal RNA (rRNA) operons. Four of the rRNA operons; rrnB, rrnD, rrnE and rrnF were cloned. We have completely sequenced all four operons, including a region 750 base pairs (bp) upstream of the 16S rRNA gene. The three rRNA genes present in each operon were closely linked in the order 16S-23S-5S. A sequence comparison of the four operons showed more than 99% sequence similarity between the corresponding 16S and 23S rRNA genes, and more than 97% similarity between 5S rRNA genes. The sequence differences observed between 23S rRNA genes appeared to be localized in two specific regions. Substantial sequence differences were found in the region upstream of the 16S rRNA gene as well as in the internal transcribed spacers. No tRNA gene was found in the 16S-23S spacer regions.     

Intraspecific diversity of the 23S rRNA gene and the spacer region downstream in Escherichia coli

The molecular microevolution of the 23S rRNA gene (rrl) plus the spacer downstream has been studied by sequencing of different operons from some representative strains of the Escherichia coli ECOR collection. The rrl gene was fully sequenced in six strains showing a total of 67 polymorphic sites, a level of variation per nucleotide similar to that found for the 16S rRNA gene (rrs) in a previous study. The size of the gene was highly conserved (2902 to 2905 nucleotides). Most polymorphic sites were clustered in five secondary-structure helices. Those regions in a large number of operons were sequenced, and several variations were found. Sequences of the same helix from two different strains were often widely divergent, and no intermediate forms existed. Intercistronic variability was detected, although it seemed to be lower than for the rrs gene. The presence of two characteristic sequences was determined by PCR analysis throughout all of the strains of the ECOR collection, and some correlations with the multilocus enzyme electrophoresis clusters were detected. The mode of variation of the rrl gene seems to be quite similar to that of the rrs gene. Homogenization of the gene families and transfer of sequences from different clonal lines could explain this pattern of variation detected; perhaps these factors are more relevant to evolution than single mutation. The spacer region between the 23S and 5S rRNA genes exhibited a highly polymorphic region, particularly at the 3' end.     

First complete nucleotide sequence and heterologous gene organization of the two rRNA operons in the phytoplasma genome

Phytoplasmas are cell-wallless Gram-positive low G + C bacteria belonging to the Mollicutes that inhabit the cytoplasm of plants and insects. Although phytoplasmas possess two ribosomal RNA (rrn) operons, only one has been fully sequenced. Here, we determined the complete nucleotide sequence of both rrn operons (designated rrnA and rrnB) of onion yellows (OY) phytoplasma. Both operons have rRNA genes organized as 5'-16S-23S-5S-3' with very highly conserved sequences; the 16S, 23S, and 5S rRNA genes are 99.9, 99.8, and 99.1% identical between the two operons. However, the organization of tRNA genes in the upstream region from 16S rRNA gene and in the downstream region from 5S rRNA gene differs markedly. Several promoter candidates were detected upstream from both operons, which suggests that both operons are functional. Interestingly, both have a tRNA(Ile) gene in the 16S-23S spacer region, while the reported rrnB operon of loofah witches' broom phytoplasma does not, indicating heterogenous gene organization of rrnB within phytoplasmas. The phytoplasma tRNA gene organization is similar to that of acholeplasmas, a closely related mollicute, and different from that of mycoplasmas, another mollicute. Moreover, the organization suggests that the rrn operons were derived from that of a related nonmollicute bacterium, Bacillus subtilis. This data should shed light on the evolutionary relationships and phylogeny of the mollicutes.     

The organization of two rRNA (rrn) operons of the slow-growing pathogen Mycobacterium celatum provides key insights into mycobacterial evolution

The slow-growing Mycobacterium celatum is known to have two different 16S rRNA gene sequences. This study confirms the presence of two rrn operons and describes their organization. One operon (rrnA) was found to be located downstream from murA and the other (rrnB) was found downstream from tyrS. The promoter regions were sequenced, and also the intergenic transcribed spacer (ITS1 and ITS2) regions separating the 16S rRNA, 23S rRNA and 5S rRNA gene coding regions. Analysis of the RNA fraction revealed that rrnA is regulated by two (P1 and PCL1) promoters and rrnB is regulated by one (P1). These data show that the two rrn operons of M. celatum are organized in the same way as the two rrn operons of classical fast-growing mycobacteria. This information was incorporated into a phylogenetic analysis of the genus based on both 16S rRNA gene sequences and (where possible) the number of rrn operons per genome. The results suggest that the ancestral Mycobacterium possessed two (rrnA and rrnB) operons per genome and that subsequently, on two separate occasions, an operon (rrnB) was lost, leading to two clusters of species having a single operon (rrnA); one cluster includes the classical pathogens and the other includes Mycobacterium abscessus and Mycobacterium chelonae.     

Tn10-mediated inversions fuse uridine phosphorylase (udp) and rRNA genes of Escherichia coli.

Two strains carrying metE::Tn10 insertions (upstream of the udp gene) were used to isolate mutants of Escherichia coli overexpressing udp. These strains differ in their gene order; one contains an inversion between the rrnD and rrnE rRNA operons. Selection was based on the ability of overexpressed Udp to complement thymine auxotrophy. Chromosomal rearrangements that connect the udp gene and promoters of different rrn operons were obtained by this selection. Seven of 14 independent mutants selected in one of the initial strains contained similar inversions of the metE-rrnD segment of the chromosome (about 12% of its length). Another mutant contained traces of a more complicated event, inversion between rrnB and rrnG operons, which was followed by reinversion of the segment between metE and the hybrid rrnG/B operon. Similar inversions (udp-rrn) in a strain already carrying an rrnE-rrnD inversion flip the chromosomal segment between metE and rrnD/E in the opposite direction. In this case, inversions are also accompanied by duplications of the chromosomal region between the rrnA and hybrid udp-rrnD/E operons. PCR amplification with a set of oligonucleotides from the rrn, Tn5, and met genes was used for more detailed mapping. Amplified fragments of the rearranged chromosomes connecting rrnD sequences and insertion elements were sequenced, and inversion endpoints were established.     

Polymorphism and gene conversion of the 16S rRNA genes in the multiple rRNA operons of Vibrio parahaemolyticus

The genome sequence of a strain of Vibrio parahaemolyticus holds 11 copies of rRNA operons (rrn) with identical 16S rRNA genes (rrs). Conversely, the species type strain contains two rrs classes differing in 10 nucleotide sites within a short segment of 25 bp. Furthermore, we show here that the sequence of this particular segment largely differs between some strains of this species. We also show that of the eleven rrn operons in the species type strain, seven contain one rrs class and four the other, indicating gene conversion. Our results support the hypothesis that the rrs differences observed between strains of this species were caused by lateral transfer of an rrs segment and subsequent conversion.     

Distinct Types of rRNA Operons Exist in the Genome of the Actinomycete Thermomonospora chromogena and Evidence for Horizontal Transfer of an Entire rRNA Operon

We describe here the presence of two distinct types of rRNA operons in the genome of a thermophilic actinomycete Thermomonospora chromogena. The genome of T. chromogena contains six rRNA operons (rrn), of which four complete and two incomplete ones were cloned and sequenced. Comparative analysis revealed that the operon rrnB exhibits high levels of sequence variations to the other five nearly identical ones throughout the entire length of the operon. The coding sequences for the 16S and 23S rRNA genes differ by approximately 6 and 10%, respectively, between the two types of operons. Normal functionality of rrnB is concluded on the basis of the nonrandom distribution of nucleotide substitutions, the presence of compensating nucleotide covariations, the preservation of secondary and tertiary rRNA structures, and the detection of correctly processed rRNAs in the cell. Comparative sequence analysis also revealed a close evolutionary relationship between rrnB operon of T. chromogena and rrnA operon of another thermophilic actinomycete Thermobispora bispora. We propose that T. chromogena acquired rrnB operon from T. bispora or a related organism via horizontal gene transfer.     

Mapping and spacer identification of rRNA operons of Salmonella typhimurium.

The rRNA operons of Salmonella typhimurium have been characterized with respect to their map position, orientation, and type of tRNA spacer. One of the seven rrn operons was found to be linked to pheA and another was found to be linked to aroE. This information, together with published information about the other five rrn operons, shows that S. typhimurium and Escherichia coli are essentially identical in terms of the number, the map position, and the orientation of all seven operons. S. typhimurium and E. coli were also similar in that four of the rrn spacer regions code for tRNAGlu2 and three code for tRNAAla1B. However, the two species differed in that rrnD coded for tRNAGlu2 and rrnB coded for tRNAAla1B in S. typhimurium. This is the opposite of the arrangement in E. coli. We have tabulated the coordinates of the BamHI and PstI sites flanking six of the S. typhimurium rrn genes and present revisions for the coordinates of some of the E. coli sites.     

Physical mapping of the ribosomal RNA genes of Mycoplasma capricolum.

Physical mapping of the rRNA genes of Mycoplasma capricolum was done by digestion of the mycoplasmal DNA with EcoRI, PstI and BglII and hybridization with nick-translated probes consisting of defined portions of the rrnB ribosomal RNA operon of Escherichia coli. The results indicate that the rRNA genes in the chromosome of M. capricolum are arranged in two clusters, each organized in the order 5'-16S-23S-5S-3', resembling the order of the genes in the rrnB operon, with no large spacer regions separating the genes in each cluster.     

Exchange of Spacer Regions between Rrna Operons in Escherichia Coli

The Escherichia coli rRNA operons each have one of two types of spacer separating the 16S and 23S coding regions. The spacers of four operons encode tRNA(Glu2) and the other three encode both tRNA(Ile) and tRNA(Ala1B). We have prepared a series of mutants in which the spacer region of a particular rrn operon has been replaced by the opposite type. Included among these were a mutant retaining only a single copy of the tRNA(Glu2) spacer (at rrnG) and another retaining only a single copy of the tRNA(Ile)-tRNA(Ala1B) spacer (at rrnA). While both mutants grew more slowly than controls, the mutant deficient in tRNA(Glu2) spacers was more severely affected. At a frequency of 6 X 10(-5), these mutants phenotypically reverted to faster growing types by increasing the copy number of the deficient spacer. In most of these phenotypic revertants, the deficient spacer type appeared in a rrn operon which previously contained the surplus type, bringing the ratio of spacer types closer to normal. In a few cases, these spacer changes were accompanied by an inversion of the chromosomal material between the donor and recipient rrn operons. Two examples of inversion of one-half of the E. coli chromosome between rrnG and rrnH were observed. The correlation of spacer change with inversion indicated that, in these particular cases, the change was due to an intrachromatid gene conversion event accompanied by a reciprocal crossover rather than reciprocal exchange between sister chromatids.     

DNA sequence of the 16S rRNA/23S rRNA intercistronic spacer of two rDNA operons of the archaebacterium Methanococcus vannielii

The DNA sequence of the spacer (plus flanking) regions separating the 16S rRNA and 23S rRNA genes of two presumptive rDNA operons of the archaebacterium Methanococcus vannielii was determined. The spacers are 156 and 242 base pairs in size and they share a sequence homology of 49 base pairs following the 3' terminus of the 16S rRNA gene and of about 60 base pairs preceding the 5' end of the 23S rRNA gene. The 242 base pair spacer, in addition contains a sequence which can be transcribed into tRNAAla, whereas no tRNA-like secondary structure can be delineated from the 156 base pair spacer region. Almost complete sequence homology was detected between the end of the 16S rRNA gene and the 3' termini of either Escherichia coli or Halobacterium halobium 16S rRNA, whereas the putative 5' terminal 23S rRNA sequence shared partial homology with E. coli 23S rRNA and eukaryotic 5.8S rRNA.     

Characterization of an rRNA operon (rrnB) of Mycobacterium fortuitum and other mycobacterial species: implications for the classification of mycobacteria.

Mycobacteria are thought to have either one or two rRNA operons per genome. All mycobacteria investigated to date have an operon, designated rrnA, located downstream from the murA gene. We report that Mycobacteriun fortuitum has a second rrn operon, designated rrnB, which is located downstream from the tyrS gene; tyrS is very close to the 3' end of a gene (3-mag) coding for 3-methylpurine-DNA-glycosylase. The second rrn operon of Mycobacterium smegmatis was shown to have a similar organization, namely, 5' 3-mag-tyrS-rrnB 3'. The rrnB operon of M. fortuitum was found to have a single dedicated promoter. During exponential growth in a rich medium, the rrnB and rrnA operons were the major and minor contributors, respectively, to pre-rRNA synthesis. Genomic DNA was isolated from eight other fast-growing mycobacterial species. Samples were investigated by Southern blot analysis using probes for murA, tyrS, and 16S rRNA sequences. The results revealed that both rrnA and rrnB operons were present in each species. The results form the basis for a proposed new scheme for the classification of mycobacteria. The approach, which is phylogenetic in concept, is based on particular properties of the rrn operons of a cell, namely, the number per genome and a feature of 16S rRNA gene sequences.     

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.     

Physical mapping of stable RNA genes in Bacillus subtilis using polymerase chain reaction amplification from a yeast artificial chromosome library.

A new approach for mapping genes which utilizes yeast artificial chromosome clones carrying parts of the Bacillus subtilis genome and the polymerase chain reaction technique is described. This approach was used to physically map stable RNA genes of B. subtilis. Results from over 400 polymerase chain reactions carried out with the yeast artificial chromosome clone library, using primers specific for the genes of interest and designed from published sequences, were collected. The locations of 10 known rRNA gene regions (rrnO, rrnA, rrnE, rrnD, rrnB, rrnJ-rrnW, and rrnI-rrnH-rrnG) have been determined by this method, and these results correlate with those observed by standard genetic mapping. All rRNA operons, except rrnB, are found between 0 and 90 degrees, while rrnB has been placed in the area of 270 degrees on the chromosome map. Also localized were the tRNA gene clusters associated with the following ribosomal operons: rrnB (21 tRNAs), rrnJ (9 tRNAs), rrnD (16 tRNAs), and rrnO and rrnA (2 internal tRNAs). A previously unmapped four-tRNA gene cluster, trnY, a tRNA gene region that is not associated with a ribosomal operon, was found near the origin of replication. The P-RNA gene, important for processing of tRNAs, was found between map locations 197 and 204 degrees.