David Ralph

Genetic and phenotypic analysis of Borrelia miyamotoi sp. nov., isolated from the ixodid tick Ixodes persulcatus, the vector for Lyme disease in Japan.

The ixodid tick Ixodes persulcatus is the most important vector of Lyme disease in Japan. Most spirochete isolates obtained from I. persulcatus ticks have been classified as Borrelia burgdorferi sensu lato because of their genetic, biological, and immunological characteristics. However, we found that a small number of isolates obtained from I. persulcatus contained a smaller 38-kDa endoflagellar protein and single 23S-5S rRNA gene unit. Representative isolate HT31T (T = type strain) had the same 23S rRNA gene physical map as Borrelia turicatae. The DNA base composition of strain HT31T was 28.6 mol% G+C. DNA-DNA hybridization experiments revealed that strain HT31T exhibited moderate levels of DNA relatedness (24 to 51%) with Borrelia hermsii, B. turicatae, Borrelia parkeri, and Borrelia coriaceae. However, the levels of DNA reassociation with the previously described Lyme disease borreliae (B. burgdorferi, Borrelia garinii, and Borrelia afzelii) were only 8 to 13%. None of the previously described species examined exhibited a high level of DNA relatedness with strain HT31T. In addition, the 16S rRNA gene sequence (length, 1,368 nucleotides) of strain HT31T was determined and aligned with the 16S rRNA sequences of other Borrelia species. Distance matrix analyses were performed, and a phylogenetic tree was constructed. The results showed that isolate HT31T is only distantly related to both previously described Lyme disease borreliae and relapsing fever borreliae. Thus, the spirochetes isolated from I. persulcatus and closely related isolates should be classified as members of a new Borrelia species. We propose the name Borrelia miyamotoi sp. nov. for this spirochete; strain HT31 is the type strain.

16S rRNA gene sequence of Neorickettsia helminthoeca and its phylogenetic alignment with members of the genus Ehrlichia

Neorickettsia helminthoeca (tribe Ehrlichieae, family Rickettsiaceae) is the agent of salmon poisoning disease, which affects members of the family Canidae. This bacterium is unusual in that it is the only known obligately intracellular bacterium that is transmitted via a helminth vector. The nucleotide sequence of the N. helminthoeca 16S rRNA gene was determined and compared with the sequences of intracellular bacteria belonging to the alpha subgroup of the Proteobacteria. The N. helminthoeca sequence was most similar to the sequences of two Ehrlichia species, Ehrlichia risticii and Ehrlichia sennetsu (levels of sequence similarity, > 95%). All other members of the tribe Ehrlichieae, including members of the other Ehrlichia species, and the related species Cowdria ruminantium and Anaplasma marginale, were only distantly related phylogenetically (levels of sequence similarity, 84 to 86%). Our results corroborate the results of previous ultrastructural and Western blot (immunoblot) comparisons of N. helminthoeca with other ehrlichial species. The genus Ehrlichia is phylogenetically incoherent and can be separated into three identifiable clusters of species. Each cluster is closely associated with a species classified in another non-Ehrlichia bacterial genus. The close relationships among N. helminthoeca, E. risticii, and E. sennetsu and the striking differences between these organisms and other members of the tribe Ehrlichieae suggest that in the future, these organisms should be treated as members of a new bacterial genus separate from the genus Ehrlichia.

Arbitrary primed PCR fingerprinting of RNA applied to mapping differentially expressed genes.

Differential gene expression between various tissues and developmental stages or between cells in vitro under different growth conditions can be rapidly and efficiently compared using the RNA arbitrarily primed polymerase chain reaction (RAP) fingerprinting method (Welsh et al., 1992b; Liang and Pardee, 1992). In RAP, a primer of arbitrary sequence primes both first and second strand cDNA synthesis. The mixture of products is then PCR amplified and resolved electrophoretically, yielding highly reproducible fingerprints that are tissue-specific or growth condition-specific. Differences between fingerprints arise from differentially expressed genes, as verified by Northern blot analysis. RAP can be performed on the RNA samples using various DNA primers. Each two day experiment yields a sample of approximately twenty cDNA products per lane making the identification of differentially or developmentally regulated genes no longer rate limiting. Those PCR products representing genes that are regulated can be cloned from the gel and sequenced. Sequences can be compared to the DNA and protein sequence databases to identify homologs, motifs and members of gene families. The clones can be placed on the genetic map as Expression Tagged Sites (ETS, Adams et al., 1991a).

Rapid isolation of tissue-specific and developmentally regulated brain cDNAs using RNA arbitrarily primed PCR (RAP-PCR).

RNA arbitrarily primed PCR (RAP-PCR) was used to isolate cDNAs that represent developmentally regulated brain-specific genes. Five clones with a restricted pattern of expression were identified and sequenced. Four cDNAs had no obvious homology to the sequences in GenBank. One clone had over 95% homology to a Ca2+/calmodulin-insensitive adenylyl cyclase, a recently cloned gene that was isolated from rat brain and was shown to be expressed only in adult brain and lung. Two novel cDNAs were investigated further by Northern blot analysis and were found to be expressed differentially during development; their expression was confined to the forebrain in the adult mouse. Further characterization byin situ hybridization showed that the mRNA corresponding to one clone was localized to a limited number of differentiating functional structures in the developing nervous system. In the adult brain, this message is confined to the forebrain with the highest level of expression in the cortex. These data suggest that the product of this gene is involved in the establishment of neuronal networks during brain development and in synaptic plasticity in the mature cortex. This work demonstrates that RAP-PCR is a powerful method for the simultaneous detection of differences between multiple RNA populations and, as such, can be used to study differential gene expression in the brain.

DNA fingerprinting by arbitrarily primed PCR (RAPDs)

Microbial ecosystems are characterized by genetic and taxonomic diversity. Investigations of microbial diversity have gained benefits from the development of various typing techniques to distinguish strains more precisely [1, 10, 14, 19]. These techniques may be divided into two categories, those based on phenotypic and those based on genotypic characters. Typing techniques based on phenotype include isozyme electrophoresis, whole-cell protein profiling [17], sugar metabolism profiling, total fatty acids profiling [6], phage typing [7], and various immunoblotting techniques [10, 12]. Typing techniques based on genotype include DNA-DNA hybridization, restriction enzyme analysis, RFLP, ribotyping [1], plasmid profiling [4, 5] and DNA fingerprinting by Arbitrarily Primed PCR (APPCR) [23, 24], RAPDs (Random Amplified Polymorphic DNA) [29], or rep-PCR [20]. APPCR is the subject of this chapter.

Arbitrarily Primed PCR Methods for Studying Bacterial Diseases

The most common application of the polymerase chain reaction (PCR) IS to exponenttally amplify a specific known and predictable sequence from a complex mixture of nucleic acids. This chapter describes a technique that, in contrast, uses PCR with arbitrary primers, to generate a fingerprint of PCR products from complex mixtures of nucleic acids and identify sequence polymorphisms and other differences that distinguish them. This robust and reproducible technique can amplify discrete sets of DNA fragments. When genomic DNAs from different individuals are compared, these differences represent point mutations and variously sized deletions and insertions When different sources of RNA are examined from an isogenic source, differences in the particular set of DNA fragments amplified represent differentially expressed genes.