Differentiation of Ehrlichia platys and E. equi infections in dogs by using 16S ribosomal DNA-based PCR.

We have encountered a previously unrecognized specificity problem when using the small-subunit ribosomal DNA (16S rDNA)-based PCR primers recommended for use in the identification of Ehrlichia equi in clinical samples. These PCR primers annealed to E. platys 16S rDNA in blood samples containing high levels of E. platys organisms. Therefore, we designed and tested new PCR primers for the identification of E. equi.

Coinfection with three Ehrlichia species in dogs from Thailand and Venezuela with emphasis on consideration of 16S ribosomal DNA secondary structure.

As part of a larger study to investigate tick-borne infections in dogs from Thailand and Venezuela, documentation of coinfection with three Ehrlichia species in two dogs, one from each country, became the focus of the present study. Although neither dog had clinical signs attributable to ehrlichiosis, both dogs were anemic and neutropenic and the Thai dog was thrombocytopenic. Genus- and species-specific PCR targeting the 16S rRNA genes indicated that both dogs were coinfected with Ehrlichia canis, E. platys, and E. equi. To our knowledge, these results provide the first molecular documentation for the presence of E. equi in dogs from these countries. Using universal bacterial PCR primers, one nearly full-length 16S rRNA gene could be amplified from each dog. The sequences were identical to each other and almost identical to that of E. platys (AF156784), providing the first E. platys 16S ribosomal DNA (rDNA) sequences reported from these two geographically divergent countries. To determine whether these sequence differences allow differentiation between these two strains and other published 16S rDNA E. platys sequences, we performed a phylogenetic analysis of the rRNA, incorporating the consideration of secondary structure.

Phylogenetic-comparative analysis of the eukaryal ribonuclease P RNA.

Ribonuclease P (RNase P) is the ribonucleoprotein enzyme that cleaves 5'-leader sequences from precursor-tRNAs. Bacterial and eukaryal RNase P RNAs differ fundamentally in that the former, but not the latter, are capable of catalyzing pre-tRNA maturation in vitro in the absence of proteins. An explanation of these functional differences will be assisted by a detailed comparison of bacterial and eukaryal RNase P RNA structures. However, the structures of eukaryal RNase P RNAs remain poorly characterized, compared to their bacterial and archaeal homologs. Hence, we have taken a phylogenetic-comparative approach to refine the secondary structures of eukaryal RNase P RNAs. To this end, 20 new RNase P RNA sequences have been determined from species of ascomycetous fungi representative of the genera Arxiozyma, Clavispora, Kluyveromyces, Pichia, Saccharomyces, Saccharomycopsis, Torulaspora, Wickerhamia, and Zygosaccharomyces. Phylogenetic-comparative analysis of these and other sequences refines previous eukaryal RNase P RNA secondary structure models. Patterns of sequence conservation and length variation refine the minimum-consensus model of the core eukaryal RNA structure. In comparison to bacterial RNase P RNAs, the eukaryal homologs lack RNA structural elements thought to be critical for both substrate binding and catalysis. Nonetheless, the eukaryal RNA retains the main features of the catalytic core of the bacterial RNase P. This indicates that the eukaryal RNA remains intrinsically a ribozyme.

Novel bacterium isolated from a lung transplant patient with cystic fibrosis.

The major clinical problem for patients with cystic fibrosis (CF) is progressive loss of pulmonary function, usually due to chronic bacterial infections. A patient with CF and a lung transplant was severely infected with a previously unidentified gram-negative bacterium. We isolated this organism (strain DS15158) from the patient and characterized it by phylogenetic analysis of the small-subunit rRNA and biochemically by the BIOLOG GN MicroPlate assay, fatty acid analysis, and various standard laboratory tests. No close match to any other organism could be found. Isolate DS15158 represents a new genus-level divergence within the bacterial subdivision alpha-Proteobacteria on the basis of the 16S rRNA gene analysis.

Comparative structure analysis of vertebrate ribonuclease P RNA.

Ribonuclease P cleaves 5'-precursor sequences from pre-tRNAs. All cellular RNase P holoenzymes contain homologous RNA elements; the eucaryal RNase P RNA, in contrast to the bacterial RNA, is catalytically inactive in the absence of the protein component(s). To understand the function of eucaryal RNase P RNA, knowledge of its structure is needed. Considerable effort has been devoted to comparative studies of the structure of this RNA from diverse organisms, including eucaryotes, primarily fungi, but also a limited set of vertebrates. The substantial differences in the sequences and structures of the vertebrate RNAs from those of other organisms have made it difficult to align the vertebrate sequences, thus limiting comparative studies. To expand our understanding of the structure of diverse RNase P RNAs, we have isolated by PCR and sequenced 13 partial RNase P RNA genes from 11 additional vertebrate taxa representing most extant major vertebrate lineages. Based on a recently proposed structure of the core elements of RNase P RNA, we aligned the sequences and propose a minimum consensus secondary structure for the vertebrate RNase P RNA.

Novel division level bacterial diversity in a Yellowstone hot spring.

A culture-independent molecular phylogenetic survey was carried out for the bacterial community in Obsidian Pool (OP), a Yellowstone National Park hot spring previously shown to contain remarkable archaeal diversity (S. M. Barns, R. E. Fundyga, M. W. Jeffries, and N. R. Page, Proc. Natl. Acad. Sci. USA 91:1609-1613, 1994). Small-subunit rRNA genes (rDNA) were amplified directly from OP sediment DNA by PCR with universally conserved or Bacteria-specific rDNA primers and cloned. Unique rDNA types among > 300 clones were identified by restriction fragment length polymorphism, and 122 representative rDNA sequences were determined. These were found to represent 54 distinct bacterial sequence types or clusters (> or = 98% identity) of sequences. A majority (70%) of the sequence types were affiliated with 14 previously recognized bacterial divisions (main phyla; kingdoms); 30% were unaffiliated with recognized bacterial divisions. The unaffiliated sequence types (represented by 38 sequences) nominally comprise 12 novel, division level lineages termed candidate divisions. Several OP sequences were nearly identical to those of cultivated chemolithotrophic thermophiles, including the hydrogen-oxidizing Calderobacterium and the sulfate reducers Thermodesulfovibrio and Thermodesulfobacterium, or belonged to monophyletic assemblages recognized for a particular type of metabolism, such as the hydrogen-oxidizing Aquificales and the sulfate-reducing delta-Proteobacteria. The occurrence of such organisms is consistent with the chemical composition of OP (high in reduced iron and sulfur) and suggests a lithotrophic base for primary productivity in this hot spring, through hydrogen oxidation and sulfate reduction. Unexpectedly, no archaeal sequences were encountered in OP clone libraries made with universal primers. Hybridization analysis of amplified OP DNA with domain-specific probes confirmed that the analyzed community rDNA from OP sediment was predominantly bacterial. These results expand substantially our knowledge of the extent of bacterial diversity and call into question the commonly held notion that Archaea dominate hydrothermal environments. Finally, the currently known extent of division level bacterial phylogenetic diversity is collated and summarized.

A low molecular weight artificial RNA of unique size with multiple probe target regions.

Artificial RNAs (aRNAs) containing novel sequence segments embedded in a deletion mutant of Vibrio proteolyticus 5S rRNA have previously been shown to be expressed from a plasmid borne growth rate regulated promoter in E. coli. These aRNAs accumulate to high levels and their detection is a promising tool for studies in molecular microbial ecology and in environmental monitoring. Herein a new construct is described which illustrates the versatility of detection that is possible with aRNAs. This 3xPen aRNA construct carries a 72 nucleotide insert with three copies of a unique 17 base probe target sequence. This aRNA is 160 nucleotides in length and again accumulates to high levels in the E. coli cytoplasm without incorporating into ribosomes. The 3xPen aRNA illustrates two improvements in detection. First, by appropriate selection of insert size, we obtained an aRNA which provides a unique and hence, easily quantifiable peak, on a high resolution gel profile of low molecular weight RNAs. Second, the existence of multiple probe targets results in a nearly commensurate increase in signal when detection is by hybridization. These aRNAs are naturally amplified and carry sequence segments that are not found in known rRNA sequences. It thus may be possible to detect them directly. An experimental step involving RT-PCR or PCR amplification of the gene could therefore be avoided.

A novel approach for monitoring genetically engineered microorganisms by using artificial, stable RNAs.

Further improvements in technology for efficient monitoring of genetically engineered microorganisms (GEMs) in the environment are needed. Technology for monitoring rRNA is well established but has not generally been applicable to GEMs because of the lack of unique rRNA target sequences. In the work described herein, it is demonstrated that a deletion mutant of a plasmid-borne Vibrio proteolyticus 5S rRNA gene continues to accumulate to high levels in Escherichia coli although it is no longer incorporated into 70S ribosomes. This deletion construct was subsequently modified by mutagenesis to create a unique recognition site for the restriction endonuclease BstEII, into which new sequences could be readily inserted. Finally, a novel 17-nucleotide identifier sequence from Pennisetum purpureum was embedded into the construct to create an RNA identification cassette. The artificial identifier RNA, expressed from this cassette in vivo, accumulated in E. coli to levels comparable to those of wild-type 5S rRNA without being seriously detrimental to cell survival in laboratory experiments and without entering the ribosomes. These results demonstrate that artificial, stable RNAs containing sequence segments remarkably different from those present in any known rRNA can be designed and that neither the deleted sequence segment nor ribosome incorporation is essential for accumulation of an RNA product.

Phylogenetic position of the genus Hydrogenobacter.

The genus Hydrogenobacter consists of extremely thermophilic, obligately chemolithotrophic organisms that exhibit anaerobic anabolism but aerobic catabolism. Preliminary studies of the phylogenetic position of these organisms based on limited 16S ribosomal DNA sequence data suggested that they belong to one of the earliest branching orders of the Bacteria. In this study, the complete 16S ribosomal DNA sequences of two type strains, Hydrogenobacter thermophilus TK-6 and Calderobacterium hydrogenophilum Z-829, and another isolate, Hydrogenobacter sp. strain T3, were determined, and the phylogenetic positions of these organisms were examined. Our results revealed that the two type strains are members of a single genus, the genus Hydrogenobacter. Our results also verified the previous conclusion that the Aquifex-Hydrogenobacter complex belongs to a very early branching order, the "Aquificales." Within this order, the relationships among the various organisms are such that only a single family, the "Aquificaceae," can be recognized at this time. Given the early branching point of the "Aquificales," the characteristics of these organisms support the view that the last common ancestor of existing life was thermophilic and suggest that this ancestor may have fixed carbon chemoautotrophically.

Further perspective on the catalytic core and secondary structure of ribonuclease P RNA.

Phylogenetic comparative analyses of RNase P RNA-encoding gene sequences from Chlorobium limicola, Chlorobium tepidum, Bacteroides thetaiotaomicron, and Flavobacterium yabuuchiae refine the secondary structure model of the general (eu)bacterial RNase P RNA and show that a highly conserved feature of that RNA is not essential. Two helices, comprised of 2 base pairs each, are added to the secondary structure model and form part of a cruciform in the RNA. Novel sequence variations in the B. thetaiotaomicron and F. yabuuchiae RNA indicate the likelihood that all secondary structure resulting from canonical base-pairing has been detected: there are no remaining unpaired, contiguous, canonical complementarities in the structure model common to all bacterial RNase P RNAs. A nomenclature for the elements of the completed secondary structure model is proposed. The Chlorobium RNase P RNAs lack a stem-loop structure that is otherwise universally present and highly conserved in structure in other (eu)bacterial RNase P RNAs. The Chlorobium RNAs are nevertheless catalytic, with kinetic properties similar to those of RNase P RNAs of Escherichia coli and other Bacteria. Removal of this stem-loop structure from the E. coli RNA affects neither its affinity for nor its catalytic rate for cleavage of a precursor transfer RNA substrate. These results show that this structural element does not play a direct role in substrate binding or catalysis.

Efficient cleavage of pre-tRNAs by E. coli RNAse P RNA requires the 2'-hydroxyl of the ribose at the cleavage site.

RNAse P cleaves pre-tRNAs to liberate 5'-flanks and 5'-matured, 5'-phosphorylated tRNAs. It is not evident if the 2'-hydroxyls of the ribose moieties in the substrate are involved in the reaction. To study their influence in two different pre-tRNAs, we have modified specifically the 2'-hydroxyl groups at the cleavage site and in neighbouring positions. We have shown that these hydroxyls are important but not essential for the processing of these substrates by E. coli RNase P RNA (M1 RNA). The reduction in the catalytic efficiency was moderate for 2'-deoxy and severe for 2'-methoxy substitutions at the cleavage site. Additional effects of modifications in neighbouring positions were smaller. Based on our data we suggest that the modifications do not interfere with binding of the substrate, whereas they prevent an optimal steric arrangement for the hydrolysis reaction.

Phylogeny of rapidly growing members of the genus Mycobacterium.

The 16S rRNAs from nine rapidly growing Mycobacterium species were partially sequenced by using the dideoxynucleotide-terminated, primer extension method with cDNA generated by reverse transcriptase. The sequences were aligned with 47 16S rRNA or DNA sequences that represented 30 previously described and 5 undescribed species of the genus Mycobacterium, and a dendrogram was constructed by using equally weighted distance values. Our results confirmed the phylogenetic separation of the rapidly and slowly growing mycobacteria and showed that the majority of the slowly growing members of the genus represent the most recently evolved organisms. The 24 strains which represented 21 rapidly growing species constituted several sublines, which were defined by the following taxa: (i) Mycobacterium neoaurum and M. diernhoferi, (ii) M. gadium, (iii) the M. chubuense cluster, (iv) the M. fortuitum cluster, (v) M. kommossense, (vi) M. sphagni, (vii) M. fallax and M. chitae, (viii) M. aurum and M. vaccae, (ix) the M. flavescens cluster, and (x) M. chelonae subsp. abscessus. Our phylogenetic analysis confirmed the validity of the phenotypically defined species mentioned above, but our conclusions disagree with most of the conclusions about intrageneric relationships derived from numerical phenetic analyses.

Initiator oligonucleotides for the combination of chemical and enzymatic RNA synthesis.

Transcription reactions with T7 RNA polymerase were performed in the presence of short oligonucleotides (oligos) with guanosine at the 3'-end. We obtained transcripts which had included these 'initiator oligos' at their 5'-termini. The oligos could contain mixtures of deoxyribo-, ribo-, 2'-O-methylated and biotinylated nucleotides. Only the 3'-terminal guanosine of these oligos was encoded in the template DNA at the transcription start point, in contrast to the remainder of the sequence. This 5'-terminal sequence is variable and eliminates the limitation that transcripts must start with a 5'-terminal guanosine. With a 5'-biotinylated dinucleotide, we obtained end-labeled RNAs suitable for nonradioactive RNA sequencing.

Complete nucleotide sequence of the Mycobacterium leprae 23 S and 5 S rRNA genes plus flanking regions and their potential in designing diagnostic oligonucleotide probes.

The complete nucleotide sequences of the Mycobacterium leprae 23 S and 5 S rRNA genes and their flanking regions are presented. As compared to other eubacterial homologous molecules the 23 S rDNA exhibits two insertions. A 16 nucleotide long insertion is almost unique to members of the genus Mycobacterium, while the second represents an extended version of helix 54. The potential of both insertions to serve as target for diagnostic oligonucleotide probes was proven by comparative sequence analysis of 23 S rRNA of several Mycobacterium species and by dot blot hybridization. In addition, a 19-mer oligonucleotide probe is described, which can be considered genus Mycobacterium-specific.

Development of a highly specific diagnostic 23S rDNA oligonucleotide probe for Mycobacterium leprae.

A 21-mer DNA oligonucleotide probe targeting the 23S rRNA of Mycobacterium leprae was developed and its high specificity demonstrated by dot-blot hybridization. Even under relaxed hybridization and washing conditions (20 degrees C below Tm) the probe was highly selective in that positive signals were only detected with M. leprae, about half of the slow-growing and one of the fast-growing reference mycobacteria and Gordona bronchialis. At more stringent washing temperatures (6 degrees C below Tm) only the rRNA of Mycobacterium leprae was detectable.

Mycobacterium cookii sp. nov.

Strains of a new type of slowly growing scotochromogenic mycobacterium were isolated repeatedly from sphagnum vegetation and surface water of moors in New Zealand. These strains grew at 31 and 22 degrees C but not at 37 degrees C and possessed catalase, acid phosphatase, and arylsulfatase activities. They did not split amides, and most of them were susceptible to antituberculotic drugs. Furthermore, they did not tolerate 0.1% NaOH2 and 0.2% picric acid and did not grow on compounds used as single carbon sources and single nitrogen and carbon sources. The internal similarity of the strains as determined by numerical taxonomy methods was 96.6% +/- 3.09%. The whole-mycolate pattern is unique in that it has not been found previously in 23 species of slowly growing mycobacteria. Evaluation of long-reverse-transcriptase-generated stretches of the primary structure of the 16S rRNA confirmed that these organisms belong to the genus Mycobacterium. The phylogenetic position of these bacteria is unique; they are situated between slowly growing pathogenic and rapidly growing saprophytic species. The strains are not pathogenic for mice, guinea pigs, and rabbits, but they provoke a nonspecific hypersensitivity reaction to bovine tuberculin. Hence, they are considered members of a new species of nonpathogenic, slowly growing mycobacteria, for which the name Mycobacterium cookii is proposed. Strain NZ2 is the type strain; a culture of this strain has been deposited in the American Type Culture Collection as strain ATCC 49103.