Cloning of a gene involved in rRNA precursor processing and 23S rRNA cleavage in Rhodobacter capsulatus

Kordes, Elisabeth; Jock, S.; Fritsch, Jürgen; Bosch, Francesc; Klug, Gabriele

doi:10.1128/jb.176.4.1121-1127.1994

Cited by 51 publications

(36 citation statements)

References 45 publications

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“…The primers 450 and 1440 (66) were used to amplify the ITS region (66) and are located in conserved regions of the 3Ј end of the 16S rRNA gene and the 5Ј end of the 23S rRNA gene. The PCR products generated with this primer pair also contained the intervening region (16,27,34,36,38,53,54,71) of the 23S rRNA gene and permitted sequencing analysis of the 5Ј ends of the 23S rRNA genes by using primers 1431, 1432, 1439, and 1440 (66). The primer pair 1432 and 23S lowerB were used to amplify most of the 23S rRNA genes.…”

Section: Methodsmentioning

confidence: 99%

Discordant Phylogenies within the rrn Loci of Rhizobia

et al. 2003

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It is evident from complete genome sequencing results that lateral gene transfer and recombination are essential components in the evolutionary process of bacterial genomes. Since this has important implications for bacterial systematics, the primary objective of this study was to compare estimated evolutionary relationships among a representative set of ␣-Proteobacteria by sequencing analysis of three loci within their rrn operons. Tree topologies generated with 16S rRNA gene sequences were significantly different from corresponding trees assembled with 23S rRNA gene and internally transcribed space region sequences. Besides the incongruence in tree topologies, evidence that distinct segments along the 16S rRNA gene sequences of bacteria currently classified within the genera Bradyrhizobium, Mesorhizobium and Sinorhizobium have a reticulate evolutionary history was also obtained. Our data have important implications for bacterial taxonomy, because currently most taxonomic decisions are based on comparative 16S rRNA gene sequence analysis. Since phylogenetic placement based on 16S rRNA gene sequence divergence perhaps is questionable, we suggest that the proposals of bacterial nomenclature or changes in their taxonomy that have been made may not necessarily be warranted. Accordingly, a more conservative approach should be taken in the future, in which taxonomic decisions are based on the analysis of a wider variety of loci and comparative analytical methods are used to estimate phylogenetic relationships among the genomes under consideration.Rhizobia are nitrogen-fixing bacterial symbionts of legumes that are of economic importance in low-input sustainable agriculture, agroforestry, and land reclamation. Descriptions of phenotypic and genetic variation among rhizobia have been extensive. Currently there are six genera of rhizobia, Allorhizobium, Azorhizobium, Bradyrhizobium, Rhizobium, Mesorhizobium, and Sinorhizobium, that have been proposed (65), and there is a report of a single species of Methylobacterium (of the family Methylobacteriaceae), Methylobacterium nodulans, which forms a symbiosis with specific species of Crotolaria (59). The primary criterion by which these genera are defined is analysis of 16S rRNA gene sequence (65).Sequencing the 16S rRNA gene has profoundly affected how relationships among the bacteria are portrayed (45). The 16S rRNA gene sequence is useful for this purpose because it is slowly evolving and the gene product is both universally essential and functionally conserved. However, basing bacterial phylogeny on 16S rRNA gene sequence variation not only presupposes that evolution throughout the genome progresses at a constant rate by mutation and Darwinian selection but also assumes that the evolution of the genome and of the 16S rRNA gene is strictly hierarchical. From a practical point of view this approach also requires each genome to harbor a single copy of the 16S rRNA gene or that multiple alleles within single genomes have identical sequences.Although seemingly convenient for c...

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Section: Methodsmentioning

confidence: 99%

Discordant Phylogenies within the rrn Loci of Rhizobia

et al. 2003

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“…In alpha-Proteobacteria additional fragmentation sites were found. In Rhodobacter capsulatus and Rhodobacter sphaeroides, the 23S rRNA is fragmented at position 1200 (helix 46; E. coli numbering) due to IVS processing (16,27). In domain III of 23S rRNA of some Rhizobium and Agrobacterium strains sporadic fragmentation without the involvement of IVSs has been described (28,30).…”

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confidence: 99%

RNase III Processing of Intervening Sequences Found in Helix 9 of 23S rRNA in the Alpha Subclass of Proteobacteria

Evguenieva‐Hackenberg

Klug

2000

J Bacteriol

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We provide experimental evidence for RNase III-dependent processing in helix 9 of the 23S rRNA as a general feature of many species in the alpha subclass of Proteobacteria (alpha-Proteobacteria). We investigated 12 Rhodobacter, Rhizobium, Sinorhizobium, Rhodopseudomonas, and Bartonella strains. The processed region is characterized by the presence of intervening sequences (IVSs). The 23S rDNA sequences between positions 109 and 205 (Escherichia coli numbering) were determined, and potential secondary structures are proposed. Comparison of the IVSs indicates very different evolutionary rates in some phylogenetic branches, lateral genetic transfer, and evolution by insertion and/or deletion. We show that the IVS processing in Rhodobacter capsulatus in vivo is RNase III-dependent and that RNase III cleaves additional sites in vitro. While all IVS-containing transcripts tested are processed in vitro by RNase III from R. capsulatus, E. coli RNase III recognizes only some of them as substrates and in these substrates frequently cleaves at different scissile bonds. These results demonstrate the different substrate specificities of the two enzymes. Although RNase III plays an important role in the rRNA, mRNA, and bacteriophage RNA maturation, its substrate specificity is still not well understood. Comparison of the IVSs of helix 9 does not hint at sequence motives involved in recognition but reveals that the "antideterminant" model, which represents the most recent attempt to explain the E. coli RNase III specificity in vitro, cannot be applied to substrates derived from alpha-Proteobacteria.rRNA and ribosomal DNA (rDNA) sequences are widely used for bacterial classification, phylogenetic studies, and identification purposes. Therefore, it is important to know which sequences are removed from the primary rRNA transcript during rRNA maturation. Ten years ago, it was believed that fragmented 23S rRNAs in bacteria are an exception. Now it is known that this phenomenon is widespread. Fragmented 23S rRNAs are found in representatives of many species of the alpha, gamma, and epsilon subclasses of Proteobacteria (alpha-, gamma-, and epsilon-Proteobacteria, respectively) (4, 9, 12, 13, 16, 19, 21, 23, 28-31, 33, 35, 37) and in Spirochaeta (26). In most cases, the processing sites are characterized by the presence of internal transcribed spacers, or so-called intervening sequences (IVSs), which are removed without splicing. Instead, the resulting fragments are held together by the compact structure of the ribosomes which remain functional.In all bacteria with fragmented 23S rRNA investigated thus far, with the exception of those belonging to alpha-Proteobacteria, two possible processing sites were found: at positions 540 (helix 25) and 1120 (helix 45) (Escherichia coli numbering). The occurrence of IVSs at these positions is sporadic: only some strains of a bacterial species possess fragmented 23S rRNA, and often even in a given bacterial strain not all rrn operons contain IVSs (4, 12, 21, 23). In alpha-Proteobacteria addition...

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“…The primers (450 and 1440) used to amplify the ITS region (Table 2) are located in conserved regions of the 3h end of the 16S rRNA gene and the 5h end of the 23S rRNA gene. The PCR products generated with this primer pair also contained the intervening region Kordes et al, 1994 ;Lessie, 1965 ;Mackay et al, 1979 ;Marrs & Kaplan, 1970 ;Schuch & Loening, 1975 were used for sequencing the purified PCR products as described previously (van Berkum et al, 1996). The primer sequences used to sequence the ITS region are listed in Table 2.…”

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Evolutionary relationships among the soybean bradyrhizobia reconstructed from 16S rRNA gene and internally transcribed spacer region sequence divergence.

Berkum¹,

Fuhrmann²

2000

International Journal of Systematic and Evolutionary Microbiology

168

124

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From sequence divergence of 16S rRNA genes and the internally transcribed spacer (ITS) region it is reported that variation in phylogenetic placement exists among the 17 different serotype strains of Bradyrhizobium that have been isolated from nodules of soybean. Evolutionary relationships among the bradyrhizobia were more resolved using reconstructions derived from ITS than from 16S rRNA gene sequence divergence. Strain USDA 129 was placed together with USDA 62, 110, 122 and 126, but did not cluster with USDA 123 and 127, with which it shares antigenic determinants. The results from the phylogenetic analysis were supported with data from determinations of genetic diversity among additional strains within each of these serogroups using amplified fragment length polymorphism analysis. From these results it was concluded that strains of serogroup 129 were more similar to strains of serogroups 62, 110 and 122 than they were to strains of serogroups 123 and 127. The serotype strain of Bradyrhizobium japonicum USDA 135 and the type strain for Bradyrhizobium liaoningense possessed identical 16S rRNA gene and ITS region sequences. Also, the type strain for B. liaoningense cross-reacted with antisera prepared against somatic antigens of USDA 135. Therefore, it was not possible to distinguish B. liaoningense from serogroup 135 in our analysis of B. japonicum and Bradyrhizobium elkanii.Keywords : Bradyrhizobium, phylogeny, soybean, Glycine max, serology INTRODUCTIONTraditional classification schemes of living organisms rely upon variation in morphological characters and a fossil record. Since there are only few useful morphological characters for rhizobia, classification schemes based on variation in genetic characters are often more informative than schemes based on phenotypic variation. An advantage of this approach is that DNA sequences and gene products can be compared The GenBank accession numbers for the ITS region sequences of strains USDA 122, 123, 124, 125, 126, 127, 129, 130, 135, 31, 3622 T (Bradyrhizobium liaoningense), 38, 4, 46, 62 and 94 are AF208503-AF208518, respectively. The GenBank accession numbers U35000 and U69638 were modified to reflect the sequencing results obtained with strains USDA 76 T and 6 T , respectively.in an evolutionary context (molecular systematics). Usually evolutionary history (or phylogeny) is then represented as a bifurcating hierarchical tree. It has become acceptable to reconstruct such evolutionary relationships among bacteria from data of sequence divergence among their 16S rRNA genes (Maidak et al., 1994).Published investigations of evolutionary relationships and genetic diversity in rhizobia has been focused more on the genera Rhizobium, Sinorhizobium and Mesorhizobium rather than Bradyrhizobium. Most reported data of diversity in Bradyrhizobium are centred on the symbionts of soybean. Initially, Bradyrhizobium (Rhizobium) japonicum was the only recognized species (Fred et al., 1932 ; Jordan, 1982). Later, Hollis et al. (1981) separated B. japonicum into three DNA homolog...

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Cloning of a gene involved in rRNA precursor processing and 23S rRNA cleavage in Rhodobacter capsulatus

Cited by 51 publications

References 45 publications

Discordant Phylogenies within the rrn Loci of Rhizobia

Discordant Phylogenies within the rrn Loci of Rhizobia

RNase III Processing of Intervening Sequences Found in Helix 9 of 23S rRNA in the Alpha Subclass of Proteobacteria

Evolutionary relationships among the soybean bradyrhizobia reconstructed from 16S rRNA gene and internally transcribed spacer region sequence divergence.

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