Juichi Saitoh

Intercalation activating fluorescence DNA probe and its application to homogeneous quantification of a target sequence by isothermal sequence amplification in a closed vessel.

We developed a completely homogeneous and isothermal method of detecting RNA sequences and demonstrated ultrarapid and direct quantification of pathogenic gene expression with high sensitivity. The assay is based on performing isothermal RNA sequence amplification in the presence of our novel DNA probe, an intercalation activating fluorescence DNA probe, and measuring the fluorescence intensity of the reaction mixture. When detecting mecA gene expression of methicillin-resistant Staphylococcus aureus, we quantified starting copies ranging from 10 to 10(7) copies within 10min. The primer sequences were designed to bind to secondary structure-free sites of the target RNA, which enabled a totally isothermal protocol to quantify mRNA specifically in a sample of existing genomic DNA. When we applied this to quantifying the expression of marker genes of Vibrio parahaemolyticus and Mycobacterium bovis BCG strain, the results correlated well with the viability of each bacterium. We also demonstrated monitoring Pab gene expression of M. bovis BCG during cultivation with antibiotics. The present method can potentially realize rapid antimicrobial susceptibility testing of slowly growing organisms, such as tuberculosis.

Fluorescence property of oxazole yellow-linked oligonucleotide. Triple helix formation and photocleavage of double-stranded DNA in the presence of spermine

Oxazole yellow is an intercalator that shows enhanced fluorescence upon binding to DNA. We prepared an oxazole yellow-linked oligonucleotide that can form triple helix with interleukin 2 receptor alpha chain promoter. The oxazole yellow-linked oligonucleotide showed linear increase of fluorescence by the triple helix formation with double-stranded DNA and also induced photocleavage of the targeted DNA in the presence of spermine upon visible illumination. Cleavage site of one strand was 7 or 8 bases away from the site of intercalation whereas the other strand was cleaved at the intercalated site.

Rapid detection of tdh and trh mRNAs of Vibrio parahaemolyticus by the transcription-reverse transcription concerted (TRC) method

We developed a novel method named the transcription-reverse transcription concerted (TRC) method and an instrument that allowed rapid and completely homogeneous real-time monitoring of RNA isothermal sequence amplification without any post-amplification analysis in our previous study [Ishiguro et al., Anal. Biochem., 314, 77-86 (2003)]. In this study, we newly established rapid and sensitive TRC systems for the detection of the mRNAs transcribed from two major virulence genes of Vibrio parahaemolyticus: the tdh gene encoding the thermostable direct hemolysin (tdh) and the trh gene encoding the thermostable direct hemolysin-related hemolysin. Examination of the standard RNAs prepared in vitro showed that a positive result, increase in the fluorescence intensity to the cut-off value within 25 min, was obtained for as few as 100 copies of RNA. The TRC method specific to the trh mRNA detected the mRNAs transcribed from the trh1 and trh2 genes, two representative trh variants sharing 84% sequence identity. The detection time gave a linear relationship to the logarithm of starting RNA copies ranging from 10(3) to 10(7) copies, showing that quantitative analysis is possible. The detection time for 10(3) copies of the standard RNAs ranged from 11 to 15 min. Examination of the total RNAs extracted from the standard strains of V. parahaemolyticus demonstrated that the new TRC systems are sufficiently sensitive to detect as few as 100 CFUs of the strains carrying the target genes. Total RNA preparations extracted from 24 strains of V. parahaemolyticus, 52 strains belonging to 31 other species of the genus Vibrio and 11 strains belonging to 8 species of non-Vibrio genera were examined. The results of the detection of tdh- and trh-specific mRNAs by the two TRC systems and those of the respective genes by the DNA colony hybridization method agreed. We conclude that the new TRC systems are rapid, highly sensitive, easy to manipulate, and are suitable for routine examination of virulent strains of V. parahaemolyticus in microbiological laboratories.