Analysis of conserved non-rRNA genes of Tropheryma whipplei

The causative agent of Whipple's disease, Tropheryma whipplei, is a slow-growing bacterium that remains poorly-understood. Genetic characterization of this organism has relied heavily upon rRNA sequence analysis. Pending completion of a complete genome sequencing effort, we have characterized several conserved non-rRNA genes from T. whipplei directly from infected tissue using broad-range PCR and a genome-walking strategy. Our goals were to evaluate its phylogenetic relationships, and to find ways to expand the strain typing scheme, based on rDNA sequence comparisons. The genes coding for the ATP synthase beta subunit (atpD), elongation factor Tu (tuf), heat shock protein GroEL (groEL), beta subunit of DNA-dependent RNA polymerase (rpoB), and RNase P RNA (rnpB) were analyzed, as well as the regions upstream and downstream of the rRNA operon. Phylogenetic analyses with all non-rRNA marker molecules consistently placed T. whipplei within the class, Actinobacteria. The arrangement of genes in the atpD and rpoB chromosomal regions was also consistent with other actinomycete genomes. Tandem sequence repeats were found upstream and downstream of the rRNA operon, and downstream of the groEL gene. These chromosomal sites and the 16S-23S rRNA intergenic spacer regions were examined in the specimens of 11 patients, and a unique combination of tandem repeat numbers and spacer polymorphisms was found in each patient. These data provide the basis for a more discriminatory typing method for T. whipplei.     

Ecotypes of planktonic actinobacteria with identical 16S rRNA genes adapted to thermal niches in temperate, subtropical, and tropical freshwater habitats

Seven strains with identical 16S rRNA genes affiliated with the Luna2 cluster (Actinobacteria) were isolated from six freshwater habitats located in temperate (Austria and Australia), subtropical (People's Republic of China), and tropical (Uganda) climatic zones. The isolates had sequence differences at zero to five positions in a 2,310-nucleotide fragment of the ribosomal operon, including part of the intergenic spacer upstream of the 16S rRNA gene, the complete 16S rRNA gene, the complete 16S-23S internal transcribed spacer (ITS1), and a short part of the 23S rRNA gene. Most of the few sequence differences found were located in the internal transcribed spacer sequences. Two isolates obtained from habitats in Asia and Europe, as well as two isolates obtained from different habitats in the People's Republic of China, had identical sequences for the entire fragment sequenced. In spite of minimal sequence differences in the part of the ribosomal operon investigated, the strains exhibited significant differences in their temperature response curves (with one exception), as well as pronounced differences in their temperature optima (25.0 to 35.6 degrees C). The observed differences in temperature adaptation were generally in accordance with the thermal conditions in the habitats where the strains were isolated. Strains obtained from temperate zone habitats had the lowest temperature optima, strains from subtropical habitats had intermediate temperature optima, and a strain from a tropical habitat had the highest temperature optimum. Based on the observed temperature responses, we concluded that the strains investigated are well adapted to the thermal conditions in their home habitats. Consequently, these closely related strains represent different ecotypes adapted to different thermal niches.     

Ecotypes of Planktonic Actinobacteria with Identical 16S rRNA Genes Adapted to Thermal Niches in Temperate, Subtropical, and Tropical Freshwater Habitats

Seven strains with identical 16S rRNA genes affiliated with the Luna2 cluster (Actinobacteria) were isolated from six freshwater habitats located in temperate (Austria and Australia), subtropical (People's Republic of China), and tropical (Uganda) climatic zones. The isolates had sequence differences at zero to five positions in a 2,310-nucleotide fragment of the ribosomal operon, including part of the intergenic spacer upstream of the 16S rRNA gene, the complete 16S rRNA gene, the complete 16S-23S internal transcribed spacer (ITS1), and a short part of the 23S rRNA gene. Most of the few sequence differences found were located in the internal transcribed spacer sequences. Two isolates obtained from habitats in Asia and Europe, as well as two isolates obtained from different habitats in the People's Republic of China, had identical sequences for the entire fragment sequenced. In spite of minimal sequence differences in the part of the ribosomal operon investigated, the strains exhibited significant differences in their temperature response curves (with one exception), as well as pronounced differences in their temperature optima (25.0 to 35.6°C). The observed differences in temperature adaptation were generally in accordance with the thermal conditions in the habitats where the strains were isolated. Strains obtained from temperate zone habitats had the lowest temperature optima, strains from subtropical habitats had intermediate temperature optima, and a strain from a tropical habitat had the highest temperature optimum. Based on the observed temperature responses, we concluded that the strains investigated are well adapted to the thermal conditions in their home habitats. Consequently, these closely related strains represent different ecotypes adapted to different thermal niches.     

Nucleotide sequence of the Bacillus subtilis ribosomal RNA operon, rrnB

The primary sequence of DNA covering a complete ribosomal RNA (rRNA) operon from Bacillus subtilis, designated rrnB has been elucidated. Following a set of tandem promoters, rrnB encodes: (i) a 16S and a 23S rRNA determinant with no tRNA spacer region in between; (ii) a 5S rRNA determinant; and (iii) 21 contiguous tRNA species; before (iv) two characteristic terminator hairpins are found. More than 7 kb are included within this operon, which maps between aroG and thr5 on the B. subtilis chromosome. This represents the first report of the entire sequence of an rRNA operon from B. subtilis or from any Gram-positive organism.     

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.     

Nucleotide sequence of the single ribosomal RNA operon of pea chloroplast DNA

The nucleotide sequence of an 8 kbp region of pea ( Pisum sativum L.) chloroplast DNA containing the rRNA operon and putative promoter sites has been determined and compared to the corresponding sequences from maize, tobacco and the liverwort Marchantia polymorpha . The chloroplast DNA species of all vascular plants investigated, with the exception of a few legumes including pea, and of Marchantia contain an inverted repeat with an rRNA operon. The pea rRNA operon is the first sequenced rRNA operon from a plant with only one copy of the rRNA genes per molecule of chloroplast DNA. The organization of the operon is the same as for maize, tobacco and Marchantia . i.e. tRNA-Val gene/16S rRNA gene/spacer with intron-containing genes for tRNA-Ile and tRNA-Ala/23S rRNA gene/4.5S rRNA gene/5S rRNA gene. Current evidence suggests that the tRNA-Val gene may not be contranscribed with the other genes. For pea 16S, 23S, 4.5S and 5S rRNA have 1488, 2813, 105 and 121 nucleotides, respectively. The homologies of the entire operon (the tRNA-Val gene - 5S rRNA region) to those from tobacco, maize and Marchantia are 88, 82 and 79%, respectively. The corresponding homologies for tobacco/maize, tobacco/ Marchantia and maize/ Marchantia have similar values. The 16S and 23S rRNA genes from pea are more than 90% homologous to those from the 3 other species. We conclude that the fact that pea only has one set of rRNA genes per molecule of chloroplast DNA is apparently not correlated with any significant difference between the pea operon and the rRNA operons from tobacco, maize and Marchantia .     

Nucleotide sequence variability in the nontranscribed spacer of the rRNA locus in the oyster parasite Perkinsus marinus.

We examined the sequence variability of the nontranscribed spacer (NTS) and internal-transcribed spacer (ITS1 and ITS2) domains of the rRNA locus of Perkinsus marinus from Maryland, Florida, and Louisiana. The sequence of P. marinus DNA including the 5S rRNA, NTS, small subunit (SSU) rRNA, ITSI, and ITS2 regions confirmed their contiguity in the rRNA locus and revealed differences at 28 positions with the SSU rRNA sequences published earlier. The 307-bp polymerase chain reaction (PCR)-amplified fragments from the NTS domain of the various P. marinus isolates revealed the presence of 2 distinct sequences, designated as types I and II, that differed at 6 defined nucleotide positions. Based on these differences, nested PCR and restriction enzyme digests were used to distinguish between the 2 types. Sequences of the ITS1 and ITS2 domains of samples from either NTS type I (n = 3) or type II (n = 3) showed no variation and were identical to published sequences. Frequencies of the P. marinus NTS sequence types I and II in infected oysters varied with the geographic origin of the samples. All Maryland samples examined (n = 19) corresponded to the NTS type I sequence, the type II was the most frequent in the Florida samples (n = 17), and both types were about equally represented in the Louisiana samples (n = 19), with both sequence types found in individual oyster specimens. Although it has been suggested that P. marinus is diploid, it remains to be determined if both NTS sequence types can be present in a single P. marinus trophozoite.     

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.     

Rates and consequences of recombination between rRNA operons

A mutant strain of Escherichia coli was created by inserting a cassette encoding sucrose sensitivity and neomycin resistance (sacB-neo) into the small-subunit rRNA-encoding gene rrs in the rrnB operon. During growth in a complex medium, the cassette was lost from the population, and a complete rrs gene was restored at a rate of 5 x 10(-9) per cell division. Repair of this lesion required flanking regions of DNA that were similar to the six remaining intact rRNA operons and reestablished the full complement of seven rRNA operons. The relative fitness of strains with restored rrnB operons was 1 to 2% higher than that of the mutant strain. The rrnB operon normally contains a spacer region between the 16S and 23S rRNA-encoding genes that is similar in length and tRNA gene content to the spacer in rrnC, -E, and -G. In 2 of the 14 strains in which rrnB was restored, the spacer region had the same length as the spacer region in rrnA, -D, and -H. The requirement for flanking regions of nearly identical DNA and the replication of the spacer region from other rRNA operons during the repair of rrnB suggest that the restoration was accomplished via gene conversion. The rate of gene conversion was 10-fold less than the fixation of point mutations in the same region of the chromosome but was apparently sufficient to homogenize the sequences of rRNA genes in E. coli. These findings are discussed in the context of a conceptual model describing the presence of sequence heterogeneity in coevolving rRNA genes.     

Zoogloea ramigera: A phylogenetically diverse species

Abstract Amplification of the gene encoding 23S rRNA of Aeromonas hydrophila by polymerase chain reaction, with primers complementary to conserved regions of 16S and the 3'-end of 23S rRNA genes, resulted in a DNA fragment of approximately 3 kb. This fragment was cloned in Escherichia coli , and its nucleotide sequence determined. The region encoding 23S rRNA shows high homology with the published sequences of 23S rRNA from other members of the gamma division of Proteobacteria . The sequence of the intergenic spacer region, between the 16S and 23S rRNA genes, was determined in five clones. Three types of spacer were identified: two clones were identical and encoded tRNA^Ile and tRNA^Ala while the remaining three clones contained tRNA^Glu, only two had the same spacer sequences. This variation in sequence indicates that the different clones may be derived from different ribosomal RNA operons.     

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.     

cpcHID操纵子序列用于钝顶节旋藻品系分类与鉴定的研究

克隆并测定7株钝顶节旋藻品系的cpcHID操纵子序列,以及16SrRNA和16S-23SrRNA转录单元内间隔区(ITS)序列,进一步通过生物信息学和分子系统学等研究发现:(1)7株品系的cpcHID序列,以及16SrRNA和ITS序列具有很高的相似性。(2)基于7株品系cpcHID序列的GC含量绝对偏差平均值、碱基变异率和遗传距离系数普遍比基于16SrRNA和ITS序列的大。(3)基于cpcHID序列的分类结果与基于16SrRNA和ITS序列的十分相近。因此,cpcHID可作为节旋藻等蓝细菌分类与鉴定的一种新的分子标记,特别是以其丰富的信息量而在品系水平的分类鉴定中占有优势。     

Nucleotide sequence of the 16S - 23S spacer region in an rRNA gene cluster from tobacco chloroplast DNA.

The nucleotide sequence of a spacer region between 16S and 23S rRNA genes from tobacco chloroplasts has been determined. The spacer region is 2080 bp long and encodes tRNAIle and tRNAAla genes which contain intervening sequences of 707 bp and 710 bp, respectively. Strong homology between the two intervening sequences is observed. These spacer tRNAs are synthesized as part of an 8.2 kb precursor molecule containing 16S and 23S rRNA sequences.     

Complex structure of the ribosomal DNA spacer of Cucumis sativus (cucumber)

Summary The nuclear 18 S, 5.8 S and 25 S ribosomal RNA genes (rDNA) of Cucumis sativus (cucumber) occur in at least four different repeat types of 10.2, 10.5, 11.5, and 12.5 kb in length. The intergenic spacer of these repeats has been cloned and characterized with respect to sequence organization. The spacer structure is very unusual compared to those of other eukaryotes. Duplicated regions of 197 bp and 311 bp containing part of the 3 end of the 25 S rRNA coding region and approximately 470 bp of 25 S rRNA flanking sequences occur in the intergenic spacer. The data from sequence analysis suggest that these duplications originate from recombination events in which DNA sequences of the original rDNA spacer were paired with sequences of the 25 S rRNA coding region. The duplicated 3ends of the 25 S rRNA are separated from each other mostly by a tandemly repeated 30 bp element showing a high GC-content of 87.5%. In addition, another tandemly repeated sequence of 90 bp was found downstream of the 3flanking sequences of the 25 S rRNA coding region. These results suggest that rRNA coding sequences can be involved in the generation of rDNA spacer sequences by unequal crossing over.     

Evolution of the plastid ribosomal RNA operon in a nongreen parasitic plant: Accelerated sequence evolution,altered promoter structure,and tRNA pseudogenes

The nucleotide sequence of a 7.4 kb region containing the entire plastid ribosomal RNA operon of the nongreen parasitic plant Epifagus virginiana has been determined. Analysis of the sequence indicates that all four rRNA genes are intact and almost certainly functional. In contrast, the split genes for tRNA^Ile and tRNA^Ala present in the 16S-23S rRNA spacer region have become pseudogenes, and deletion upstream of the 16S rRNA gene has removed a tRNA^Val gene and most of the promoter region for the rRNA operon. The rate of nucleotide substitution in 16S and 23S rRNAs is several times higher in Epifagus than in tobacco, a related photosynthetic plant. Possible reasons for this, including relaxed translational constraints, are discussed.     

Study of a cloned ribosomal operon region coding for 5.8S rRNA in the loach Misgurnus fossilis L

A fragment of the loach (Misgurnus fossilis L.) ribosomal operon containing 5.8S rDNA and adjacent regions of the internal transcribed spacer (ITS-1, and ITS-2) was sequenced. The 5'-terminal sequencing in 5.8S rDNA was corrected by analysing the primary structure of the loach 5.8S rRNA. This RNA was shown to be presented by three types of molecules; one of these was shorter by 4 nucleotides at the 5'-end because of the processing site being shifted in the rRNA precursor. The two other types differed in the 5'-terminal nucleotide (UMP or AMP). In the cloned fragment under study, the sequence of 5.8S rDNA has TMP at the 5'-terminus. The known nucleotide sequences of 5.8S rRNAs were compared in eukaryotes; as a result, conservative regions were revealed at the sites of molecule modification. All the 5.8S rRNAs of the vertebrates studied were found to have coincidences in the localization of nucleotide substitutions and other mutations (inversions and deletions). The authors propose a model for the secondary structure of ITS-1 and ITS-2 in the region of 5.8S rRNA processing.