Next-generation DNA sequencing of Panax samples revealed new genotypes: Burrows-Wheeler Aligner, Python-based abundance and clustering analysis.

Background: There are two major species of the Panax genus, namely Panax ginseng and Panax quinquefolius. Other than the nucleic acid test and nucleic acid amplification test, DNA sequencing can be used to authenticate the species of ginseng samples, especially when their physical forms cannot be used for differentiation. Method: In this work, next generation sequencing was used to obtain millions of reads from fourteen ginseng samples (root, powder, and granule). Then Gaussian Mixture clustering analysis was applied to analyze the reads from each sample. Results and Discussion: A new genotype has been revealed in this study. Two samples have been authenticated with certainty, while the others may be hybrid in nature as revealed by the clustering results.

Nucleic acid amplification test (NAAT) conducted in a microfluidic chip to differentiate between various ginseng species.

Panax ginseng and Panax quinquefolius have different medicinal properties and market values; however, they can be difficult to distinguish from one another based on physical appearances alone. Therefore, a molecular test that can be performed in commercial settings is needed to overcome this difficulty. A locus that contains a single nucleotide polymorphism (SNP) site to differentiate between P. ginseng and P. quinquefolius has been selected. An isothermal nucleic acid amplification test (NAAT) has been developed for use in a microfluidic chip; this NAAT method, which is based on lesion-induced DNA amplification (LIDA), amplifies the extracted plant genomic samples and enhances the detection of specific SNPs. This NAAT method was used to authenticate five ginseng root samples which indicated that two of the five samples appear to be mislabeled. These authentication results were consistent with those obtained from next generation sequencing (NGS) although this molecular test is more affordable and faster than NGS.

Centrifugal dynamic hybridization conducted in a microfluidic chip for signal enhancement in nucleic acid tests.

A rotating platform has been developed using a centrifugal chip holder to mount the standard chips for liquid delivery achieved by centrifugal pumping. This platform allows for dynamic hybridization to be performed in the microchannels constructed in the standard chips made using the 50 mm × 75 mm glass slides which allows for fast hybridization reactions. The results show that when the oligonucleotide-oligonucleotide hybridization is performed, there is good differentiation between perfectly complementary strands over 1 bp-mismatching counterparts when the long target strand is firstly immobilized and the short probe is secondly hybridized (Method 2), but not when the short probe is first immobilized, and the long target is subsequently hybridized (Method 1). When the differentiation between immobilized ginseng PCR product strands is performed, the correct result is achievable by Method 1, after signal enhancement and addition of formamide. The use of Method 2 is successful only when the PCR strand is captured, but not immobilized. In both methods, proper differentiation is achievable using the N1Q probe, un-achievable without centrifugal hybridization.

The genetic authentication of Panax ginseng and Panax quinquefolius based on using single nucleotide polymorphism (SNP) conducted in a nucleic acid test chip.

Panax ginseng and Panax quinquefolius, which are commonly called Chinese ginseng and American ginseng respectively, have different medicinal properties and market values; however, these samples can be difficult to differentiate from one another based on physical appearances of the samples especially when they are in powdery or granular forms. A molecular technique is thus needed to overcome this difficulty; this technique is based on the nucleic acid test (NAT) conducted on the microfluidic chip surface. Three single nucleotide polymorphism (SNP) sites (i.e. N1, N2, N3) on the Panax genome that differ between P. ginseng (G) and P. quinquefolius (Q) have been selected to design probes for the NAT. Primers were designed to amplify the antisense strands by asymmetric PCR. We have developed three different NAT methodologies involving surface immobilization and subsequent (stop flow or dynamic) hybridization of probes (i.e. N1G, N1Q, N2G, N2Q, N3Q) to the antisense strands. These NAT methods consist of two steps, namely immobilization and hybridization, and each method is distinguished by what is immobilized on the microfluidic chip surface in the first step (i.e. probe, target or capture strand). These three NATs developed are called probe-target method 1, target-probe method 2 and three-strand complex method 3. Out of the three methods, it was found that the capture strand-target-probe method 3 provided the best differentiation of the ginseng species, in which a 3' NH2 capture strand is first immobilized and the antisense PCR strand is then bound, while N2G and N3Q probes are used for detection of P. ginseng (G) and P. quinquefolius (Q) respectively.

Presence of an EML4-ALK gene fusion detected by microfluidic chip DNA hybridization.

Non-small cell lung cancer (NSCLC) accounts for ∼80-85% of all lung cancer cases, and the EML4-ALK fusion oncogene is a well-known contributor to NSCLC cases. Expensive methods such as FISH, IHC, and NGS have been used to detect the EML4-ALK fusion oncogene. Here, a cost-effective and facile method of detecting and differentiating an EML4-ALK fusion oncogene from the wild-type gene has been accomplished by DNA hybridization using the microfluidic biochip. First, oligonucleotide probes were confirmed for successful detection of immobilized sense strands. Second, capture of the sense PCR product strands (fusion and WT) and their subsequent detection and differentiation were accomplished. Our proof-of-concept study shows the ability to detect 1% fusion products, among WT ones.

Identification of cytidine 2',3'-cyclic monophosphate and uridine 2',3'-cyclic monophosphate in Pseudomonas fluorescens pfo-1 culture.

Cytidine 2',3'-cyclic monophosphate (2',3'-cCMP) and uridine 2',3'-cyclic monophosphate (2',3'-cUMP) were isolated from Pseudomonas fluorescens pfo-1 cell extracts by semi-preparative reverse phase HPLC. The structures of the two compounds were confirmed by NMR and mass spectroscopy against commercially available authentic samples. Concentrations of both intracellular and extracellular 2',3'-cCMP and 2',3'-cUMP were determined. Addition of 2',3'-cCMP and 2',3'-cUMP to P. fluorescens pfo-1 culture did not significantly affect the level of biofilm formation in static liquid cultures.