Shinya Kurata

Retrieval of entire genes from environmental DNA by inverse PCR with pre‐amplification of target genes using primers containing locked nucleic acids

We had been unsuccessful to amplify desired nucleotide sequences from various environmental DNA samples by using the inverse polymerase chain reaction (IPCR) technique, most probably because the copy numbers of target DNA sequences had been quite low. To enrich the target DNA sequences prior to IPCR, a rolling-circle amplification was used with a site-specific primer containing locked nucleic acids (LNAs). This pre-amplified IPCR (PAI-PCR) method increased the sensitivity of PCR almost 10 000 times compared with the standard IPCR in model experiments using Escherichia coli. We then applied the PAI-PCR method to isolate glycosyl hydrolase genes from DNAs extracted from vermiform appendixes of horses and termite guts. The flanking sequences of the target genes were amplified and cloned successfully using PAI-PCR, whereas standard IPCR resulted in no amplification.

Universal Quenching Probe System: Flexible, Specific, and Cost-Effective Real-Time Polymerase Chain Reaction Method

We have developed a flexible, specific, and cost-effective real-time polymerase chain reaction (PCR) method. In this technique, a quenching probe (QProbe) and a nonfluorescent 3-tailed probe are used. The QProbe is a singly labeled oligonucleotide bearing a fluorescent dye that is quenched via electron transfer between the dye and a guanine base at a particular position. The nonfluorescent 3-tailed probe consists of two parts: one is the target-specific sequence on the 5 side, and the other is complementary to the QProbe on the 3 side. When the QProbe/nonfluorescent 3-tailed probe complex hybridizes with the target in PCR, the fluorescence of the dye is quenched. Fluorescence quenching efficiency is proportional to the amount of the target. We called this method the universal QProbe system. This method substantially reduces the cost of real-time PCR setup because the same QProbe can be used for different target sequences. Moreover, this method allows accurate quantification even in the presence of nonspecific PCR products because the use of nonfluorescent 3-tailed probe significantly increases specificity. Our results demonstrate that this method can accurately and reproducibly quantify specific nucleic acid sequences in crude samples, comparable with conventional TaqMan chemistry. Furthermore, this method is also applicable to single-nucleotide polymorphism (SNP) genotyping.

Application of capillary electrophoresis to monitor populations of Cellulomonas cartae KYM-7 and Agrobacterium tumefaciens KYM-8 in mixed culture.

A bacterial cell mixture of Cellulomonas cartae KYM‐7 and Agrobacterium tumefaciens KYM‐8 was analyzed by capillary zone electrophoresis (CZE) and capillary gel electrophoresis (CGE). Both pherograms showed two discrete peaks. The cells in the peaks were collected, Gram stained, and examined with a microscope. The cells of the two strains were well separated by CGE, and each CGE peak consisted almost entirely of cells of one strain (greater than 98% purity), whereas each CZE peak contained cells of both strains (about 90% purity). In the concentration range of 1.0×1010 to 1.0×1012 cells/mL, the area of CGE peaks was proportional to the amount of cells. The growth of the two strains in mixed culture was measured by CGE. The CGE quantification data were in good agreement with those obtained using fluorescence in situ hybridization. The CGE analyses were accomplished in 1 h, using a relatively uncomplicated procedure. Thus, CGE exhibited great advantages in accuracy, rapidity, and simplicity.

Quantitative detection of chloroethene-reductive bacteria Dehalococcoides spp. using alternately binding probe competitive polymerase chain reaction

Dehalococcoides spp. are responsible for the reductive dehalogenation of environmental contaminants and are candidates for engineered bioremediation. The development of a sensitive, reliable, and rapid method for the quantification of Dehalococcoides spp. is required for the effective use of the organisms in bioremediation sites. Here, we describe the quantification of the 16S rRNA gene of Dehalococcoides spp. using a recently developed quantification method named alternately binding probe competitive PCR (ABC-PCR). The primers and probe sets that were newly designed for ABC-PCR were found to have a high specificity for Dehalococcoides spp. The standard curve of ABC-PCR had a good fitting (R = 0.999), and the lower detection limit was 10 copies/microl of template DNA. We also investigated the effects of inherent PCR-inhibiting compounds in an environmental sample on the quantification using ABC-PCR or real-time PCR by adding the soil extraction solution to PCR mixtures. ABC-PCR was more robust against the PCR amplification inhibitors than real-time PCR. The copy number of the 16S rRNA gene of Dehalococcoides spp. in soil and groundwater samples was successfully quantified using ABC-PCR. In conclusion, ABC-PCR is useful for the quantification of Dehalococcoides spp. populations and dynamics at bioremediation sites.

Extracellular Acidic Polysaccharide Production by a Two-membered Bacterial Coculture

A two-membered coculture of strains KYM-7 and KYM-8, identified as Cellulomonas cellulans and Agrobacterium tumefaciens, respectively, produced a large amount of an extracellular polysaccharide, designated APK-78, from starch. Each strain in pure culture produced only very little amount of polysaccharide from starch; the coexistence of the two strains from the early stage of cultivation was indispensable for a large amount of polysaccharide to be produced. The polysaccharide APK-78 was acidic and composed of glucose, galactose, succinic acid, and pyruvic acid with a molar ratio of 8.1:1.0:1.7:1.0, indicating that it is a succinoglycan type of polysaccharide.