The Mosaic Nature of Intergenic 16S-23S rRNA Spacer Regions Suggests rRNA Operon Copy Number Variation in Clostridium difficile Strains

Clostridium difficile is a major spore-forming environmental pathogen that causes serious health problems in patients undergoing antibiotic therapy. Consequently, reliable and sensitive methods for typing individual strains are required for epidemiological and environmental studies. Ribotyping is generally considered the best method, but it fails to account for sequence diversity which might exist in intergenic 16S-23S rRNA spacer regions (ISRs) within and among strains of this organism. Therefore, this study was undertaken to compare the sequence of each individual ISR in five strains of C. difficile to explore the extent of this diversity and see whether such information might provide the basis for more sensitive and discriminatory strain typing methods. After targeted PCR amplification, cloning, and sequencing, the diversity of the ISRs was used as a measure of rRNA operon copy number. In C. difficile strains 630, ATCC 43593, A, and B, 11, 11, 7, and 8 ISR length variants, respectively, were found (containing different combinations of sequence groups [i to xiii]), suggesting 11, 11, 7, and 8 rrn copies in the respective strains. Many ISRs of the same length differed markedly in their sequences, and some of these were restricted in occurrence to a single strain. Most of these ISRs did not contain any tRNA genes, and only single copies of the tRNA^Ala gene were found in those that did. The presence of ISR sequence groups (i to xiii) varied between strains, with some found in one, two, three, four, or all five strains. We conclude that the intergenic 16S-23S rRNA spacer regions showed a high degree of diversity, not only among the rrn operons in different strains and different rrn copies in a single strain but also among ISRs of the same length. It appears that C. difficile ISRs vary more at the inter- and intragenic levels than those of other species as determined by empirical comparison of sequences. The precise characterization of these sequences has demonstrated a high level of mosaic sequence block rearrangements that are present or absent in multiple strain-variable rrn copies within and between five different strains of C. difficile.     

Variation of 16S-23S rRNA intergenic spacer regions (ISRs) in Acinetobacter baylyi (strain B2) isolated from activated sludge

To determine the variability of the 16S-23S rRNA intergenic spacer region (ISR) of the newly described Acinetobacter baylyi, 88 clones containing ISR amplicons were screened and 14 chosen for further analysis. Two different sized 16S-23S rRNA ISRs were distinguished comprising five variable and four conserved nucleotide blocks. The major regions of heterogeneity between the different sized ISRs were due to blocks of substitutions with unique secondary structures interspersed with nucleotide substitutions, rather than differences caused by presence or absence of tRNA genes, which is often the case. Recombination events causing shuffling of nucleotide blocks are considered the most likely explanation for the mosaic structure observed between the different copies of the ISR. Single base differences present in the long ISR (LISR) were then exploited in attempts to detect possible heterogeneity between rrn copies in Acinetobacter baylyi but variability was not detected by RFLP analysis of LISR-specific PCR products. These primers were shown to be highly specific for 3 Acinetobacter baylyi strains based on LISR sequence homogeneity.     

Recombination Drives Evolution of the Clostridium difficile 16S-23S rRNA Intergenic Spacer Region

PCR-ribotyping, a typing method based on size variation in 16S-23S rRNA intergenic spacer region (ISR), has been used widely for molecular epidemiological investigations of C. difficile infections. In the present study, we describe the sequence diversity of ISRs from 43 C. difficile strains, representing different PCR-ribotypes and suggest homologous recombination as a possible mechanism driving the evolution of 16S-23S rRNA ISRs. ISRs of 45 different lengths (ranging from 185 bp to 564 bp) were found among 458 ISRs. All ISRs could be described with one of the 22 different structural groups defined by the presence or absence of different sequence modules; tRNA^Ala genes and different combinations of spacers of different lengths (33 bp, 53 bp or 20 bp) and 9 bp direct repeats separating the spacers. The ISR structural group, in most cases, coincided with the sequence length. ISRs that were of the same lengths had also very similar nucleotide sequence, suggesting that ISRs were not suitable for discriminating between different strains based only on the ISR sequence. Despite large variations in the length, the alignment of ISR sequences, based on the primary sequence and secondary structure information, revealed many conserved regions which were mainly involved in maturation of pre-rRNA. Phylogenetic analysis of the ISR alignment yielded strong evidence for intra- and inter-homologous recombination which could be one of the mechanisms driving the evolution of C. difficile 16S-23S ISRs. The modular structure of the ISR, the high sequence similarities of ISRs of the same sizes and the presence of homologous recombination also suggest that different copies of C. difficile 16S-23S rRNA ISR are evolving in concert.     

16S-23S ribosomal DNA intergenic spacer regions in cellulolytic myxobacteria and differentiation of closely related strains

The diversity of 16S-23S rDNA intergenic spacer regions (ISR) among cellulolytic myxobacterial strains was assayed. Agarose gel electrophoresis of PCR amplification products from ten strains shows that there are at least four copies of rRNA operons in the genus Sorangium, based on their size and restriction enzymatic digest maps. There are two sequence organization patterns: tRNA(Ile)-tRNA(Ala)-containing ISR and tRNA-lacking ISR. The tRNA-containing ISRs are highly similar among strains and within a strain (more than 98% similarity) and contain the essential functional regions, such as a ribonuclease III recognition site and an antiterminator recognition site boxA. The tRNA-lacking ISR has no such functional sites that are important for yielding mature rRNA, which suggests that this type of rRNA operons might be degenerate. The tRNA-lacking ISR is divided into two types based on their sizes and sequences, which exhibits about 90% similarity within each type. Thus, the tRNA-lacking ISR polymorphisms can be used to discriminate among different strains of sorangial species.     

A rapid PCR procedure for the specific identification of Lactobacillus sanfranciscensis, based on the 16S-23S intergenic spacer regions

AIMS: The organization of ribosomal RNA (rrn) operons in Lactobacillus sanfranciscensis was studied in order to establish an easy-to-perform method for identification of L. sanfranciscensis strains, based on the length and sequence polymorphism of the 16S-23S rDNA intergenic spacer region (ISR). METHODS AND RESULTS: PCR amplification of the 16S-23S rDNA ISRs of L. sanfranciscensis gave three products distinguishing this micro-organism from the remaining Lactobacillus species. Sequence analysis revealed that two of the rrn operons were organized as in previously reported lactobacilli: large spacer (L-ISR), containing tRNA(Ile) and tRNA(Ala) genes; small spacer (S-ISR) without tRNA genes. The third described spacer (medium, M-ISR), original for L. sanfranciscensis, harboured a tRNA-like structure. An oligonucleotide sequence targeting the variable region between tDNA(Ile) and tDNA(Ala) of L. sanfranciscensis L-ISR was approved to be suitable in species-specific identification procedure. Analysis by pulse-field gel electrophoresis of the chromosomal digest with the enzyme I-CeuI showed the presence of seven rrn clusters. Lactobacillus sanfranciscensis genome size was estimated at c. 1.3 Mb. CONCLUSIONS: Direct amplification of 16S-23S ISRs or PCR with specific primer derived from L-ISR showed to be useful for specific typing of L. sanfranciscensis. This was due to the specific rrn operon organization of L. sanfranciscensis strains. SIGNIFICANCE AND IMPACT OF THE STUDY: In this paper, we have reported a rapid procedure for L. sanfranciscensis identification based on specific structures found in its rrn operon.     

Variation in the 16S-23S rRNA intergenic spacer regions in Vibrio parahaemolyticus strains are due to indels nearby their tRNAGlu

Vibrio parahaemolyticus contains 11 rRNA operons each including one of six 16S-23S rRNA gene intergenic spacer classes differing in size and nucleotide sequence. Some of the spacer classes may differ between isolates. We observed that the differences in the spacers between isolates are generally in two spacer classes present in single copies in the genome, one class containing tRNA(Ala) and tRNA(Glu) and the other tRNA(Glu) exclusively. Moreover, these differences are due to indels located nearby their tRNA(Glu). Comparison of the nucleotide sequence between spacer classes suggests that intragenomic nonreciprocal recombination causes the size variations observed in the spacer regions of V. parahaemolyticus strains.     

Inter- and intraspecific genomic variability of the 16S-23S intergenic spacer regions (ISR) in representatives of Acidithiobacillus thiooxidans and Acidithiobacillus ferrooxidans

The complete sequences of 32 intergenic spacer regions (ISR) from Acidithiobacillus strains, including 29 field strains isolated from coal, copper, molybdenum mine wastes or sediment of different geoclimatic regions in China, reference strain ATCC19859 and the type strains of the two species were determined. These data, together with other sequences available in the GenBank database, were used to carry out the first detailed assessment of the inter- and intraspecific genomic variability of the ISR sequences and to infer phylogenetic relationships within the genus. The total length of the 16S-23S rRNA intergenic spacer regions of the Acidithiobacillus thiooxidans and Acidithiobacillus ferrooxidans strains ranged from 451 to 490 bp, and from 434 to 456 bp, respectively. The degree of intrageneric ISR sequence similarity was higher than the degree of intergeneric similarity, and the overall similarity values of the ISRs varied from 60.49% to 84.71% between representatives of different species of the genus Acidithiobacillus. Sequences from the spacer of the A. thiooxidans and A. ferrooxidans strains ranged from 86.71% to 99.56% and 92.36% to 100% similarity, respectively. All Acidithiobacillus strains were separated into three phylogenetic major clusters and seven phylogenetic groups. ISR may be a potential target for the development of in situ hybridization probe aimed at accurately detecting acidithiobacilli in the various acidic environments.     

Analysis of 16S-23S intergenic spacer regions of the rRNA operons in Edwardsiella ictaluri and Edwardsiella tarda isolates from fish

AIMS: To analyse interspecies and intraspecies differences based on the 16S-23S rRNA intergenic spacer region (ISR) sequences of the fish pathogens Edwardsiella ictaluri and Edwardsiella tarda. METHODS AND RESULTS: The 16S-23S rRNA spacer regions of 19 Edw. ictaluri and four Edw. tarda isolates from four geographical regions were amplified by PCR with primers complementary to conserved sequences within the flanking 16S-23S rRNA coding sequences. Two products were generated from all isolates, without interspecies or intraspecific size polymorphisms. Sequence analysis of the amplified fragments revealed a smaller ISR of 350 bp, which contained a gene for tRNA(Glu), and a larger ISR of 441 bp, which contained genes for tRNA(Ile) and tRNA(Ala). The sequences of the smaller ISR of different Edw. ictaluri isolates were essentially identical to each other. Partial sequences of larger ISR from several Edw. ictaluri isolates also revealed no differences from the one complete Edw. ictaluri large ISR sequence obtained. The sequences of the smaller ISR of Edw. tarda were 97% identical to the Edw. ictaluri smaller ISR and the larger ISR were 96-98% identical to the Edw. ictaluri larger ISR sequence. The Edw. tarda isolates displayed limited ISR sequence heterogeneity, with > or =97% sequence identity among isolates for both small and large ISR. CONCLUSIONS: There is a high degree of size and sequence similarity of 16S-23S ISR both among isolates within Edw. ictaluri and Edw. tarda species and between the two species. SIGNIFICANCE AND IMPACT OF THE STUDY: Our results confirm a close genetic relationship between Edw. ictaluri and Edw. tarda and the relative homogeneity of Edw. ictaluri isolates compared with Edw. tarda isolates. Because no differences were found in ISR sequences among Edw. ictaluri isolates, sequence analysis of the ISR will not be useful to distinguish isolates of Edw. ictaluri. However, we identified restriction sites that differ between ISR sequences of Edw. ictaluri and Edw. tarda, which will be useful in distinguishing the two species.     

Structural analysis and genetic variation of the 16S-23S rDNA internal spacer region from Micrococcus luteus strains

AIMS: To clone and sequence the 16S-23S ribosomal DNA (rDNA) internal spacer region (ISR) from Micrococcus luteus. METHODS AND RESULTS: The primer pair for 16S-23S rDNA ISR amplified a fragment of about 850 bp in length for two strains, JCM3347 and JCM3348 and a fragment of about 790 bp for a strain, ATCC9341. After sequencing the ISRs were identified by the comparison of the ISRs and the flanking regions of ISR. CONCLUSIONS: Although the sequence difference of the ISR occurred at only one position between the two JCM strains, the highly variable length (440 and 370 bp) and sequence similarity (about 40%) were demonstrated between the ISRs of the two JCM strains and a ATCC strain. SIGNIFICANCE AND IMPACT OF THE STUDY: A CCTCCT sequence was first detected at the 3'-end of the 16S rDNA of the three strains. Moreover, highly similar sequence to the 21-bp region containing a putative rRNA processing site was observed in the ISR of the three strains. Interestingly, no intercistronic tRNAs were demonstrated in the ISRs from the three strains.     

Characterization of Paenibacillus popilliae rRNA operons

The terminal 39 nucleotides on the 3' end of the 16S rRNA gene, along with the complete DNA sequences of the 5S rRNA, 23S rRNA, tRNA(Ile), and tRNA(Ala) genes were determined for Paenibacillus popilliae using strains NRRL B-2309 and Dutky 1. Southern hybridization analysis with a 16S rDNA hybridization probe and restriction-digested genomic DNA demonstrated 8 copies of the 16S rRNA gene in P. popilliae strains KLN 3 and Dutky 1. Additionally, the 23S rRNA gene in P. popilliae strains NRRL B-2309, KLN 3, and Dutky 1 was shown by I-CeuI digestion and pulsed-field gel electrophoresis of genomic DNA to occur as 8 copies. It was concluded that these 3 P. popilliae strains contained 8 rrn operons. The 8 operon copies were preferentially located on approximately one-half of the chromosome and were organized into 3 different patterns of genes, as follows: 16S-23S-5S, 16S-ala-23S-5S, and 16S-5S-ile-ala-23S-5S. This is the first report to identify a 5S rRNA gene between the 16S and 23S rRNA genes of a bacterial rrn operon. Comparative analysis of the nucleotides on the 3' end of the 16S rRNA gene suggests that translation of P. popilliae mRNA may occur in Bacillus subtilis and Escherichia coli.     

Sequence heterogeneity of the ten rRNA operons in Clostridium perfringens

We have cloned and sequenced rRNA operons of Clostridium perfringens strain 13 and analyzed the sequence structure in view of the phylogenesis. The organism had ten copies of rRNA operons all of that comprised of 16S, 23S and 5S rDNAs except for one operon. The operons clustered around the origin of replication, ranging within one-third of the whole genome sequence as it is arranged in a circle. Seven operons were transcribed in clockwise direction, and the remaining three were transcribed in counter clockwise direction assuming that the gyrA was transcribed in clockwise direction. Two of the counter clockwise operons contained tRNA(Ile) genes between the 16S and 23S rDNAs, and the other had a tRNA(Ile) genes between the 16S and 23S rDNAs and a tRNA(Asn) gene in the place of the 5S rDNA. Microheterogeneity was found within the rRNA structural genes and spacer regions. The length of each 16S, 23S and 5S rDNA were almost identical among the ten operons, however, the intergenic spacer region of 16S-23S and 23S-5S were variable in the length depending on loci of the rRNA operons on the chromosome. Nucleotide sequences of the helix 19, helix 19a, helix 20 and helix 21 of 23S rDNA were divergent and the diversity appeared to be correlated with the loci of the rRNA operons on the chromosome.     

Rapid species identification and partial strain differentiation of Clostridium butyricum by PCR using 16S-23S rDNA intergenic spacer regions

Some Clostridium butyricum strains have been used as probiotics for both humans and animals. Strain-specific identification is necessary for the manufacturing process of probiotics. The aim of this study was to determine whether there are sufficient genetic variations in 16S-23S intergenic spacer regions (ISRs) to discriminate C. butyricum at the biovar level. We amplified ISRs from five reference strains, a probiotic strain (MIYAIRI 588) and 22 isolates, and we classified them into four groups on the basis of amplification patterns (type A through D). However, amplification of ISRs is not sufficient for discriminating strains. Moreover, we compared genetic structures of these ISRs. Sequence analysis revealed that the size variations of ISRs were generated by the insertion of tRNA genes and unique sequences into the internal portion, while the external portions were highly conserved. On the basis of the highly conserved nucleotide sequences within the ISRs, we developed a PCR primer set specific to C. butyricum. In addition, the PCR primer designed from the unique inserted sequence in type B strain was useful to differentiate probiotic strains at the biovar level.     

Restriction fragment length polymorphism of rRNA operons for discrimination and intergenic spacer sequences for cataloging of Bacillus subtilis sub-groups

Restriction fragment length polymorphism of rRNA operons (RFLP) and 16S-23S rRNA intergenic region (ISR) sequences of Bacillus subtilis subsp. subtilis, B. subtilis subsp. spizizenii, and B. atrophaeus were compared. ISR sequences of the B. subtilis subspecies were extremely similar (W23 versus 168 rrn H, J, G,W; 96.8%; rrn D, E; 98.4%; rrnB; 97.9%) and, therefore, not useful for their differentiation. However, RFLP of rRNA operons of the B. subtilis subspecies were distinct in terms of numbers and organization within the genome (e.g. the 168 sub-group generally contained 8.3- and 8.0-kb fragments absent in the W23 sub-group). The more distantly related B. atrophaeus was distinct from both B. subtilis subspecies in terms of ISR sequence and rRNA operon number and organization. RFLP of rRNA operons discriminates the two sub-groups of Bacillus subtilis that are indistinguishable by ISR sequence. However, ISR sequence defines the relatedness of B. subtilis to other species (e.g. B. atrophaeus) within the genus Bacillus.     

The role of recombination and mutation in 16S-23S rDNA spacer rearrangements

The intragenomic heterogeneity of the bacterial intergenic (16S-23S rDNA) spacer region (ISR) was analysed from the following species in which sequences for the complete rRNA operon (rrn) set have been determined (rrn number): Enterococcus faecalis (6) and E. faecium (6), Bacillus subtilis (10), Staphylococcus aureus (9), Vibrio cholerae (4), Haemophilus influenzae (6) and Escherichia coli (7). It was found that some spacer sequence blocks were highly conserved between operons of a genome, whereas the presence of others was variable. When these variations were analysed using the program PLATO and partial likelihood phylogenies determined by DNAml for each operon set, three regions showed significant (Z>3.3) spatial variation [Region I was 78-184 nt long (2.14.4) possibly due to recombination or selection. Within Region I, there was sequence block variation in all operon sets [some operons contained tRNA genes (tRNAala, tRNAile or tRNAglu), whereas others had sequence blocks such as VS2 (S. aureus) or rsl (E. coli)]. Q Analysis of the ISR sequence from E. faecalis and E. faecium showed that there was more interspecies than intraspecies variation (both in DNA sequence and in the presence or absence of blocks). Dot matrix analysis of the sequence blocks in the nine rrn ISRs from S. aureus showed that there was significant homology between VS2 and VS5/VS6. Furthermore, repeat motifs with only A or T were present in higher copy numbers in VS5/VS6 than in VS2. Since these sequence blocks (VS2 and VS5-VS6) are related, intragenic evolution resulting in AT expansion may have occurred between these two regions. A model is proposed that postulates a role for recombination and AT-expansion in intra-genomic ISR variations. This process may represent a general mechanism of concerted evolution for bacterial ISR rearrangements.     

A small and compact genome in the marine cyanobacterium Prochlorococcus marinus CCMP 1375: lack of an intron in the gene for tRNA(Leu)(UAA) and a single copy of the rRNA operon

PCR-ribotying, a typing method based on polymorphism in the 16S-23S intergenic spacer region, has been recently used to investigate outbreaks due to Clostridium difficile. However, this method generates bands of high and close molecular masses which are difficult to separate on agarose gel electrophoresis. To improve reading of banding patterns of PCR-ribotyping applied to C. difficile, a partial sequencing of the rRNA genes (16S and 23S) and intergenic spacer region has been performed, then a new set of primers located closer to the intergenic spacer region has been defined. The new PCR gave reproducible patterns of bands easy to separate on agarose gel electrophoresis. Each of the 10 serogroups and 11 subgroups of serogroup A produced a different pattern. This typing method has evidenced major qualities such as easiness, rapidity and reproducibility. However, its discriminatory power has to be evaluated to validate its importance as a typing tool for C. difficile.     

Paenibacillus larvae 16S-23S rDNA intergenic transcribed spacer (ITS) regions: DNA fingerprinting and characterization

Paenibacillus larvae is the causative agent of American foulbrood in honey bee (Apis mellifera) larvae. PCR amplification of the 16S-23S ribosomal DNA (rDNA) intergenic transcribed spacer (ITS) regions, and agarose gel electrophoresis of the amplified DNA, was performed using genomic DNA collected from 134 P. larvae strains isolated in Connecticut, six Northern Regional Research Laboratory stock strains, four strains isolated in Argentina, and one strain isolated in Chile. Following electrophoresis of amplified DNA, all isolates exhibited a common migratory profile (i.e., ITS-PCR fingerprint pattern) of six DNA bands. This profile represented a unique ITS-PCR DNA fingerprint that was useful as a fast, simple, and accurate procedure for identification of P. larvae. Digestion of ITS-PCR amplified DNA, using mung bean nuclease prior to electrophoresis, characterized only three of the six electrophoresis bands as homoduplex DNA and indicating three true ITS regions. These three ITS regions, DNA migratory band sizes of 915, 1010, and 1474 bp, signify a minimum of three types of rrn operons within P. larvae. DNA sequence analysis of ITS region DNA, using P. larvae NRRL B-3553, identified the 3' terminal nucleotides of the 16S rRNA gene, 5' terminal nucleotides of the 23S rRNA gene, and the complete DNA sequences of the 5S rRNA, tRNA(ala), and tRNA(ile) genes. Gene organization within the three rrn operon types was 16S-23S, 16S-tRNA(ala)-23S, and l6S-5S-tRNA(ile)-tRNA(ala)-23S and these operons were named rrnA, rrnF, and rrnG, respectively. The 23S rRNA gene was shown by I-CeuI digestion and pulsed-field gel electrophoresis of genomic DNA to be present as seven copies. This was suggestive of seven rrn operon copies within the P. larvae genome. Investigation of the 16S-23S rDNA regions of this bacterium has aided the development of a diagnostic procedure and has helped genomic mapping investigations via characterization of the ITS regions.     

16S～23S RDNA间区在链球菌和流感嗜血杆菌分类中的应用

利用16S~23S rDNA间区（intergenic spacer regions,ISR）在不同细菌中拷贝数、碱基排列、序列长度及所含tRNA基因种类和数目的差异,对15株链球菌和流感嗜血杆菌进行属、种、型和株系的分类鉴定。在16S rDNA的3′端和23S rDNA的5′端的保守区中合成引物,PCR扩增16S~23S rDNA ISR序列,对多态片段切胶纯化直接测序。在GenBank上查找对应细菌的ISR序列。用DNAMAN软件进行系统进化分析。链球菌属为单拷贝16S~23Sr RNA ISR、有一个tRNAAla基因编码区、分子大小在269~446bp之间,序列分成4个保守区和4个可变区,可变区碱基排列方式和数目的不同是种分类的依据。7株链球菌的同源率在78%~88%。同种异株的差异反映在碱基的插入和缺失上。流感嗜血杆菌各生物型均为2个拷贝的ISR,小片段为514~519bp,编码1个tRNAGlu基因,有3个狭窄可变区。大片段富含A T碱基,在I、II和IV型中分别是868、848和856bp,编码一个tRNAIle基因和一个tRNAAla基因。不同生物型小分子ISR与标准菌株比较,同源性在97.3%~99.6 %之间。 ISR作为细菌分类的目的基因具有属、种、型和株特异性与灵敏性。简单的基因分离分析技术为认识病原微生物提供了更多的机会。 Abstract:To facilitate species level identification of bacteria without the requirement of presumptive identification,the paper describes a rapid identification method of bacteria by amplification and direct sequencing 16S~23S rDNA intergenic spacer regions (ISR) of the pathogens which cause the upper respiratory tract infective disease by Streptococcus and Haemophilus.Three pairs of primer targeting conserved sequences flanking the 3′ end of 16S and the 5′end of 23S rRNA were used to amplify 16S~23S rRNA ISR of 7 streptococcus strains and 8 Haemophilus strains.The PCR products were separated by 1% agarose gel electrophoresis and the polymorphisms fragments were purified with the Wizard PCR Min-Prep Kit (Promega) and Protocol-SK131(Sangon).The nucleotide sequences of ISR inserts were determined by using the XEQTM DTCS Kit——Terminator Cycle Sequencing and a CEQTM 2000XL DNA Analysis system (Backman Coulter) automatic DAN sequencer.Then those sequences were compared with known seqnences on the GenBank.The alignment of nucleotide sequence,evolutionary distances and phylogenetic tress were analyzed by software DANMAN version 4.0.The PCR products were showed polymorphism patterns with agarose gel.One band was contained in streptococcus genus.The significant variation was found among the spacer sequences of different species in Streptococcus with the lengths of the spacer varying from 269 to 446bp.All the ISR of the streptococcal species had a tRNA Ala gene in the spacer and the sequence identities varied from 78 to 88% within genera.It was found that some spacer sequence blocks were highly conserved between operons of a genome,whereas the presence of others was variable,three regions showed significant spatial variation.Most of the differences between the sequences came from several bases insertions/deletions and substitutions.There are two major bands in the Haemophilus biotypes(515 and 884bp),the small ISR amplicon contained one tDNA coding for tRNAGlu.In contrast to the large one contained two tRNA genes coding for tRANAla and tRNAIle.Two regions of repeating motifs with only A or T were present in higher copy numbers between tRANAla and tRNAIle.The phylogenetic trees varied from 97.5 to 98.8%.The PCR and direct sequencing of 16S~23S rRAN ISR were successful in the pathogen species identification.     

Acholeplasma laidlawii has tRNA genes in the 16S-23S spacer of the rRNA operon.

We amplified the 16S-23S rRNA intergenic spacer region of Acholeplasma laidlawii PG8 by polymerase chain reaction (PCR) and obtained two specific PCR products in different sizes. We have sequenced both PCR products and found that one of them has sequence homologous to the spacer tRNA genes in Bacillus subtilis. This is the first evidence of tRNA genes between the 16S-23S rRNA intergenic spacer regions in members of the class Mollicutes.     

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.     

Variations in the 16S-23S rRNA internal transcribed spacer of fibrolytic Butyrivibrio isolates from the reindeer rumen

Strains of Butyrivibrio are principal cellulytic bacteria in the rumen of the High Arctic Svalbard reindeer ( Rangifer tarandus platyrhynchus ). According to phylogenetic analysis based on 16S rRNA gene sequencing, Butyrivibrio can be divided into three subgroups within the Clostridia class of the phylum Firmicutes, but the current phenotypic and genotypic differentiation within the family Lachnospiraceae is insufficient. This current study describes the sequence diversity of the 16S-23S rRNA intergenic transcribed spacer (ITS) region of Butyrivibrio isolates from reindeer. A total of 17 different ITS sequences with sizes between 449 and 784 nt were obtained. Genes encoding tRNA(Ile) and tRNA(Ala) were identified in four of the sequences. Phylogenetic neighbor-joining trees were constructed based on the ITS sequence and compared with a phylogenetic neighbor-joining tree based on 16S rRNA gene sequences previously obtained for the same isolates. These comparisons indicated a better differentiation between strains in the ITS sequence than the 16S rRNA gene based tree. Through this study, a better means for identifying and tracking fibrolytic and potentially probiotic Butyrivibrio strains in reindeer and other ruminants has been provided.