Genotypic Classification of Staphylococcus aureus and Bacillus cereus from Korean Slaughterhouses Using Semiautomated Repetitive Sequence-Based Polymerase Chain Reaction.

A repetitive sequence-based polymerase chain reaction (rep-PCR) technique utilizing a semiautomated system, namely DiversiLab, was applied to determine the genotypes of Staphylococcus aureus and Bacillus cereus obtained from slaughterhouses. Twenty-four S. aureus and 16 B. cereus isolates from pigs and Hanwoo cattle from three slaughterhouses were used to create a DNA fingerprint library with the system software. Scatterplots demonstrated that rep-PCR groupings of S. aureus isolates were in good agreement with their origins. Specifically, linked rep-PCR profiles were observed for S. aureus isolates recovered from the same slaughterhouse, and higher genetic similarities were found among strains isolated from adjacent regions. All S. aureus isolates except one (ID: A-Hanwoo-9) from slaughterhouse "A" clustered with the three S. aureus reference strains, Korea Culture Center of Microorganisms (KCCM) 41291, KCCM 12214, and Culture Collection of Antimicrobial Resistant Microbes (CCARM) 3A007 (similarity values >95%). Moreover, most isolates obtained from slaughterhouse "B" clustered with S. aureus KCCM 11335 and KCCM 41331, and two isolates from slaughterhouse "C" clustered with CCARM 0027. Therefore, for this species, genotypic characteristics of regional isolates can be used to track the pathway of contamination. In contrast, B. cereus isolates showed high genetic diversity and could not be clustered with any specific group. Collectively, this system is useful for analyzing genetic diversity and is a rapid and reproducible typing method; however, there is a need to develop rep-PCR libraries for its use as a rapid identification method.

A RNA producing DNA hydrogel as a platform for a high performance RNA interference system.

RNA interference (RNAi) is a mechanism in which small interfering RNA (siRNA) silences a target gene. Herein, we describe a DNA hydrogel capable of producing siRNA and interfering with protein expression. This RNAi-exhibiting gel (termed I-gel for interfering gel) consists of a plasmid carrying the gene transcribing siRNA against the target mRNA as part of the gel scaffold. The RNAi efficiency of the I-gel has been confirmed by green fluorescent protein (GFP) expression assay and RNA production quantification. The plasmid stability in the I-gel results in an 8-times higher transcription efficiency than that of the free plasmid. We further applied the I-gel to live cells and confirmed its effect in interfering with the GFP expression. The I-gel shows higher RNAi effect than plasmids in free form or complexed with Lipofectamine. This nanoscale hydrogel, which is able to produce RNA in a cell, provides a platform technology for efficient RNAi system.

A film-based integrated chip for gene amplification and electrochemical detection of pathogens causing foodborne illnesses.

Given the increased interest in public hygiene due to outbreaks of food poisoning, increased emphasis has been placed on developing novel monitoring systems for point-of-care testing (POCT) to evaluate pathogens causing foodborne illnesses. Here, we demonstrate a pathogen evaluation system utilizing simple film-based microfluidics, featuring simultaneous gene amplification, solution mixing, and electrochemical detection. To minimize and integrate the various functionalities into a single chip, patterned polyimide and polyester films were mainly used on a polycarbonate housing chip, allowing simple fabrication and alignment, in contrast to conventional polymerase chain reaction, which requires a complex biosensing system at a bench-top scale. The individual integrated sensing chip could be manually fabricated in 10 min. Using the developed film-based integrated biosensing chip, the genes from the pathogens causing foodborne illnesses were simultaneously amplified based on multiple designed microfluidic chambers and Hoechst 33258, which intercalates into double-stranded DNA, to generate the electrochemical signal. The target pathogen gene was accurately analyzed by square wave voltammetry (SWV) within the 25 s, while the gel electrophoresis required about 30 min. Based on the developed integrated biosensing chip, the 1.0 × 101 and 1.0 × 102 colony-forming unit (CFU) of Staphylococcus aureus and Escherichia coli were sensitively detected with high reproducibility in the 25 s. On the basis of the significant features of the film-based molecular analysis platform, we expect that the developed sensor could be applied to the screening of various pathogens as a POCT device.

Multiplex quantitative analysis of microRNA expression via exponential isothermal amplification and conformation-sensitive DNA separation.

Expression profiling of multiple microRNAs (miRNAs) generally provides valuable information for understanding various biological processes. Thus, it is necessary to develop a sensitive and accurate miRNA assay suitable for multiplexing. Isothermal exponential amplification reaction (EXPAR) has received significant interest as an miRNA analysis method because of high amplification efficiency. However, EXPAR cannot be used for a broader range of applications owing to limitations such as complexity of probe design and lack of proper detection method for multiplex analysis. Here, we developed a sensitive and accurate multiplex miRNA profiling method using modified isothermal EXPAR combined with high-resolution capillary electrophoresis-based single-strand conformation polymorphism (CE-SSCP). To increase target miRNA specificity, a stem-loop probe was introduced instead of a linear probe in isothermal EXPAR to allow specific amplification of multiple miRNAs with minimal background signals. CE-SSCP, a conformation-dependent separation method, was used for detection. Since CE-SSCP eliminates the need for probes to have different lengths, easier designing of probes with uniform amplification efficiency was possible. Eight small RNAs comprising six miRNAs involved in Caenorhabditis elegans development and two controls were analyzed. The expression patterns obtained using our method were concordant with those reported in previous studies, thereby supporting the proposed method's robustness and utility.

Simultaneous Determination of Multiple microRNA Levels Utilizing Biotinylated Dideoxynucleotides and Mass Spectrometry.

MicroRNAs (miRNAs) are important regulators of gene translation and have been suggested as potent biomarkers in various disease states. In this study, we established an efficient method for simultaneous determination of multiple miRNA levels, employing the previously developed SPC-SBE (solid phase capture-single base extension) approach and MALDI-TOF mass spectrometry (MS). In this approach, we first perform reverse transcription of miRNAs extracted using stem-loop primers. Then the cDNA is co-amplified with competitors, synthetic oligonucleotides whose sequences precisely match cDNA except for one base, and the amplicons serve as templates for a multiplexed SBE reaction. Extension products are isolated using SPC and quantitatively analyzed with MALDI-TOF MS to determine multiple miRNA levels. Here we demonstrated concurrent analysis of four miRNA levels utilizing the approach. Furthermore, we showed the presented method significantly facilitated MS analysis of peak area ratio owing to SPC. The SPC process allowed effective removal of irrelevant reaction components prior to MS and promoted MS sample purification. Data obtained in this study was verified with RT-qPCR and agreement was shown on one order of magnitude scale, suggesting the SPC-SBE and MS approach has strong potential as a viable tool for high throughput miRNA analysis.

A robust and simple-to-design multiplex DNA methylation assay based on MS-MLPA-CE-SSCP.

Aberrant DNA methylation is a potential diagnostic marker for complex diseases, such as cancer. With the increase in the number of genes known to exhibit disease-associated aberrant methylation, the need for accurate multiplex assays for quantifying DNA methylation has increased. Methylation-specific multiplex ligation-dependent probe amplification (MS-MLPA) is one method that has been highlighted in this context. However, two limitations make the custom design of MS-MLPA assays impractical: the need for long probes containing stuffer sequences and a reliance on only one restriction enzyme. Here, we developed a variation of MS-MLPA that employs a simpler probe-design process. To overcome the above-mentioned limitations, we used stuffer-free MS-MLPA probes that are subsequently analyzed using high-resolution capillary electrophoresis-based single-strand conformational polymorphism (CE-SSCP) instead of conventional length-dependent CE. Moreover, multiple methylation-sensitive restriction enzymes (HhaI, HpaII, and AciI) were used simultaneously; thus, probes satisfying desired criteria were available for all targets. Using this assay concept, we analyzed 17 genes associated with hepatocellular carcinoma. Our results showed that the custom-designed assay based on MS-MLPA-CE-SSCP provided robust multiplex quantification of DNA methylation levels.

Precise expression profiling by stuffer-free multiplex ligation-dependent probe amplification.

In systems biological studies, precise expression profiling of functionally important gene sets is crucial. Real-time polymerase chain reaction is generally used for this purpose. Despite its widespread acceptance, however, this method is not suitable for multiplex analysis, resulting in an inefficient assay process. One alternative technology in the spotlight is multiplex ligation-dependent probe amplification (MLPA). But MLPA depends on length-based discrimination of amplified products, which complicates probe design and compromises analysis results. Here, we devised a variation of MLPA that utilizes conformation-sensitive capillary electrophoresis, and demonstrated the simplicity of the probe-design process and improved precision of the assay in analyses of 33 Escherichia coli metabolic genes and 16 Caenorhabditis elegans longevity-related genes. The results showed that relative expression could be quantitatively measured over a relevant dynamic range by using similar-sized probes. Importantly, the improved precision compared to conventional MLPA promises a wider application of this method for various biological systems.

Multiplex and quantitative pathogen detection with high-resolution capillary electrophoresis-based single-strand conformation polymorphism.

Among the molecular diagnostic methods for bacteria-induced diseases, capillary electrophoresis-based single-strand conformation polymorphism (CE-SSCP) combined with 16S rRNA gene-specific PCR has enormous potential because it can separate sequence variants using a simple procedure. However, conventional CE-SSCP systems have limited resolution and cannot separate most 16S rRNA gene-specific markers into separate peaks. A high-resolution CE-SSCP system that uses a poly(ethyleneoxide)-poly(propyleneoxide)-poly(ethyleneoxide) triblock copolymer matrix was recently developed and shown to effectively separate highly similar PCR products. In this report, a protocol for the detection of 12 pathogenic bacteria is provided. Pathogen markers were amplified by PCR using universal primers and separated by CE-SSCP; each marker peak was well separated at baseline and showed a characteristic mobility, allowing the easy identification of the pathogens.

Multiplex quantitative foodborne pathogen detection using high resolution CE-SSCP coupled stuffer-free multiplex ligation-dependent probe amplification.

Sensitive multiplex detection methods for foodborne pathogens are important in controlling food safety, and detection of genetic markers is accepted to be one of the best tools for sensitive detection. Although CE technology offers great potential in terms of sensitive multiplex detection, the necessary amplification is confined to markers sharing common primers such as the 16S rRNA gene. For precise and sensitive detection, pathogen-specific genes are optimal markers. Although multiplex ligation-dependent probe amplification (MLPA) is appropriate for amplification of specific markers, the requirement for stuffers, to ensure length-dependent separation on CE, is a major obstacle in detection of foodborne pathogens. In the present study, we developed stuffer-free MLPA using high-resolution CE-SSCP to sensitively detect ten foodborne pathogens. The probe set for MLPA prior to CE-SSCP analysis was designed for species-specific detection. After careful optimization of each MLPA step, to ensure that CE-SSCP analysis was informative, we found that all ten pathogens could be reliably identified; the limits of detection were 0.5-5 pg of genomic DNA, and more than 100-fold increase could be quantitatively determined. Thus, MLPA-CE-SSCP is a sensitive and reliable technique for pathogen detection.