Identification of cold shock gene loci in Sinorhizobium meliloti by using a luxAB reporter transposon

Using a luxAB reporter transposon, seven mutants of Sinorhizobium meliloti were identified as containing insertions in four cold shock loci. LuxAB activity was strongly induced (25- to 160-fold) after a temperature shift from 30 to 15 degrees C. The transposon and flanking host DNA from each mutant was cloned, and the nucleic acid sequence of the insertion site was determined. Unexpectedly, five of the seven luxAB mutants contained transposon insertions in the 16S and 23S rRNA genes of two of the three rrn operons of S. meliloti. Directed insertion of luxAB genes into each of the three rrn operons revealed that all three operons were similarly affected by cold shock. Two other insertions were found to be located downstream of a homolog of the major Escherichia coli cold shock gene, cspA. Although the cold shock loci were highly induced in response to a shift to low temperature, none of the insertions resulted in a statistically significant decrease in growth rate at 15 degrees C.     

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.     

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.     

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.     

Structure, expression and products of the ribosomal RNA operons of Rhodopseudomonas palustris No. 7

Rhodopseudomonas palustris strains carry one or two ribosomal rRNA operons, and those with duplicated rrn operons grow faster. The two rrn operons in R. palustris No. 7 are virtually identical over a 54,70-bp stretch containing the genes for 16S rRNA, tRNAile, tRNAala, 23S rRNA and 5S rRNA, as well as the intergenic spacers and part of the extragenic spacer. In R. palustris, unlike most bacteria with multiple rrn operons, the putative promoter sequences of the two operons are highly diverged, suggesting possible functional differentiation. By simultaneous primer-extension analysis of both pre-rRNAs, we detected a two-fold higher level of expression from rrnA under photoautotrophic conditions. Alteration of the conditions of growth leads to changes in the relative levels of expression of the two operons. Within the 5,470-bp segment, only two sequence differences are found between the 23S rRNA genes; one is at the center of the 23S rRNA molecule and affects a site of unknown function, and the other is within or immediately adjacent to sequences involved in processing of the 5' 23S rRNA IVS. In vitro processing of 5' IVS-containing 23S rRNA precursors from each operon does not reveal any detectable difference between them. The 5' ends of the mature 16S, 23S, and 5S rRNAs were determined by primer-extension analysis, and the 3' end of 23S rRNA was determined by RNA linker ligation-mediated cDNA cloning. The 5' and 3' ends of the R. palustris 23S rRNA molecule are extensively processed, suggesting that, unlike the situation in the established eubacterial model, these ends cannot basepair.     

Comparative and functional analysis of the rRNA-operons and their tRNA gene complement in different lactic acid bacteria

The complete genome sequences of the lactic acid bacteria (LAB), Lactobacillus plantarum, Lactococcus lactis, and Lactobacillus johnsonii were used to compare location, sequence, organisation, and regulation of the ribosomal RNA (rrn) operons. All rrn operons of the examined LAB diverge from the origin of replication, which is compatible with their efficient expression. All operons show a common organisation of 5'-16S-23S-5S-3' structure, but differ in the number, location and specificity of the tRNA genes. In the 16S-23S intergenic spacer region, two of the five rrn operons of Lb. plantarum and three of the six of Lb. johnsonii contain tRNA-ala and tRNA-ile genes, while L. lactis has a tRNA-ala gene in all six operons. The number of tRNA genes following the 5S rRNA gene ranges up to 14, 16, and 21 for L. lactis, Lb. johnsonii and Lb. plantarum, respectively. The tRNA gene complements are similar to each other and to those of other bacteria. Micro-heterogeneity was found within the rRNA structural genes and spacer regions of each strain. In the rrn operon promoter regions of Lb. plantarum and L. lactis marked differences were found, while the promoter regions of Lb. johnsonii showed a similar tandem promoter structure in all operons. The rrn promoters of L. lactis show either a single or a tandem promoter structure. All promoters of Lb. plantarum contain two or three -10 and -35 regions, of which either zero to two were followed by an UP-element. The Lb. plantarum rrnA, rrnB, and rrnC promoter regions display similarity to the rrn promoter structure of Esherichia coli. Differences in regulation between the five Lb. plantarum promoters were studied using a low copy promoter-probe plasmid. Taking copy number and growth rate into account, a differential expression over time was shown. Although all five Lb. plantarum rrn promoters are significantly different, this study shows that their activity was very similar under the circumstances tested. An active promoter was also identified within the Lb. plantarum rrnC operon preceding a cluster of 17 tRNA genes.     

Expression of cspH, Encoding the Cold Shock Protein in Salmonella enterica Serovar Typhimurium UK-1

Both Salmonella enterica serovar Typhimurium and Escherichia coli contain the cspH gene encoding CspH, one of the cold shock proteins (CSPs). In this study, we investigated the expression of cspH in S. enterica serovar Typhimurium and found that it was induced in response to a temperature downshift during exponential phase. The cspH promoter was activated at 37 degrees C, and its mRNA was more stable than the other csp mRNAs at 37 degrees C. Moreover, lacZ expression of the translational cspH-lacZ fusion was induced at that temperature. Interestingly, the cspH mRNA had a much shorter 5'-untranslated region than those in the other cold-shock-inducible genes, and the promoter sequence, which was only 55 bp, was sufficient for cspH expression. The 14-base downstream box located 12 bases downstream of the initiation codon of cspH mRNA was essential for its cold shock activation.     

Ribosomal RNA and ribosomal proteins in corynebacteria

Ribosomal RNAs (rRNAs) (16S, 23S, 5S) encoded by the rrn operons and ribosomal proteins play a very important role in the formation of ribosomes and in the control of translation. Five copies of the rrn operon were reported by hybridization studies in Brevibacterium (Corynebacterium) lactofermentum but the genome sequence of Corynebacterium glutamicum provided evidence for six rrn copies. All six copies of the C. glutamicum 16S rRNA have a size of 1523 bp and each of the six copies of the 5S contain 120 bp whereas size differences are found between the six copies of the 23S rRNA. The anti-Shine-Dalgarno sequence at the 3'-end of the 16S rRNA was 5'-CCUCCUUUC-3'. Each rrn operon is transcribed as a large precursor rRNA (pre-rRNA) that is processed by RNaseIII and other RNases at specific cleavage boxes that have been identified in the C. glutamicum pre-rRNA. A secondary structure of the C. glutamicum 16S rRNA is proposed. The 16S rRNA sequence has been used as a molecular evolution clock allowing the deduction of a phylogenetic tree of all Corynebacterium species. In C. glutamicum, there are 11 ribosomal protein gene clusters encoding 42 ribosomal proteins. The organization of some of the ribosomal protein gene cluster is identical to that of Escherichia coli whereas in other clusters the organization of the genes is rather different. Some specific ribosomal protein genes are located in a different cluster in C. glutamicum when compared with E. coli, indicating that the control of expression of these genes is different in E. coli and C. glutamicum.     

Precise characterization of rDNA genes by intraspecies and inter-loci comparison of rDNA sequences and biochemical analysis of ribosomal RNA molecules in Agrobacterium tumefaciens

Annotation of rRNA genes has been incomplete in Agrobacterium species although a number of Agrobacterial rDNA fragments have been sequenced. In this study, precise characterization of rRNA operons (rrn) was carried out in two biovar 1 strains, C58 and MAFF301001. Complete DNA sequencing of four rrns in MAFF301001 indicated that each operon codes for 16S, 23S and 5S rRNA as well as three tRNAs, trn(Ile), trn(Ala) and trn(Met). The genes and 16S-23S ITS of a given locus were exactly identical with those in the other three loci, except for a T-base loss in the 23S rRNA gene of rrnA and in the 5S rRNA gene of rrnB. Comparison with the four C58 rDNAs available in the DNA database indicated extensive sequence and size variations in the 23S rRNA gene, suggesting the presence of an intervening sequence (IVS). Biochemical RNA analysis, including Northern hybridization and 5' end mapping, in MAFF301001 revealed 2886-base and 2571-base precursors, two 1.3-kb major fragments, a 150-base fragment and removal of an IVS for 23S rRNA. We confirmed similar biochemical characteristics in the C58 strain. The features of rDNA detected here enable correction of previously reported information about Agrobacterial rRNAs and rRNA genes and should be useful for phylogenetic considerations.