Application of electrophoresis technology to DNA analysis

We used the variable number tandem repeat (VNTR) polymorphism and the ten short tandem repeat (STR) polymorphisms to study a number of disputed paternity cases in the Japanese population. For the determination of VNTR locus (D1S80) and the ten STR loci (vWA, F13B, TH01, TPOX, CSF1PO, F13A01, LPL, D3S1744, D12S1090, D18S849) we used polymerase chain reaction (PCR) amplification and the vertical polyacrylamide gel electrophoresis technique followed by SYBR green I staining. The irregular repeats were analyzed by sequencing from bands of vertical polyacrylamide gel electrophoresis using the latest gene analyzing equipment, the ABI PRISM 310 Genetic Analyzer. The probable genotypes of the deceased putative father were deduced by Komatu's method from the genotypes of the widow and the genotypes of their children. The calculation of paternity probability used the Essen-Moller formula and Bayes's theorem. Calculated in eleven loci, the distinguishing probabilities (DP) and the mean exclusion chance (MEC) were 0.9999 and 0.9989, respectively. Therefore, information obtained from eleven DNA polymorphisms is enough to determine paternity plausibility.     

Visual screening for JAK2V617F mutation by a disposable dipstick

During the last 5 years, it was discovered that the JAK2V617F somatic mutation is present in virtually all patients with polycythemia vera and a large proportion of patients with essential thrombocythemia, primary myelofibrosis, and refractory anemia with ring sideroblasts and thrombocytosis. As a result, JAK2V617F was incorporated as a new clonal marker in the 2008 revision of the WHO diagnostic criteria. Current methods for JAK2 genotyping include direct sequencing, pyrosequencing, allele-specific PCR with electrophoresis, restriction fragment length polymorphism, real-time PCR, DNA-melting curve analysis, and denaturing HPLC. Some of these methods are labor intensive and time consuming, while the others require specialized costly equipment and reagents. We report a method for direct detection of the JAK2V617F allele by the naked eye using a dipstick test in a dry-reagent format. The method comprises a triprimer PCR combined with visual detection of the products within minutes by the dipstick test. Specialized instrumentation is not involved. The requirements for highly qualified technical personnel are minimized. Because the detection reagents exist in dry form on the dipstick, there is no need for multiple pipetting and incubation steps.     

Ultra-thin-layer agarose gel electrophoresis. I. Effect of the gel concentration and temperature on the separation of DNA fragments

A novel, rapid and efficient separation method is described for the analysis of double stranded (ds) DNA fragments in the form of horizontal ultra-thin-layer agarose gel electrophoresis. This separation technique combines the multilane, high-throughput separation format of agarose slab gel electrophoresis with the excellent performance of capillary electrophoresis. The electrophoretic separation of the fluorophore (Cy5)-labeled dsDNA molecules were imaged in real time by a scanning laser-induced fluorescence/avalanche photodiode detection system. Effects of the gel concentration (Ferguson plot) and separation temperature (Arrhenius plot) on the migration characteristics of the DNA fragments are discussed. An important genotyping application is also shown by characterizing the polymorphic region (2× or 4×48 base pair repeats) of the dopamine D₄ receptor gene (D₄DR, exon III region) for ten individuals, using PCR technology with Cy5-labeled primers and ultra-thin-layer agarose gel electrophoresis.     

Simultaneous analysis of multiple PCR amplicons enhances capillary SSCP discrimination of MHC alleles

Major histocompatibility complex (MHC) genotyping still remains one of the most challenging issues for evolutionary ecologists. To date, none of the proposed methods have proven to be perfect, and all provide both important pros and cons. Although denaturing capillary electrophoresis has become a popular alternative, allele identification commonly relies upon conformational polymorphisms of two single‐stranded DNA molecules at the most. Using the MHC class II (β chain, exon 2) of the black kite (Aves: Accipitridae) as our model system, we show that the simultaneous analysis of overlapping PCR amplicons from the same target region substantially enhances allele discrimination. To cover this aim, we designed a multiplex PCR capable to generate four differentially sized and labeled amplicons from the same allele. Informative peaks to assist allele calling then fourfold those generated by the analysis of single PCR amplicons. Our approach proved successful to differentiate all the alleles (N=13) isolated from eight unrelated birds at a single optimal run temperature and electrophoretic conditions. In particular, we emphasize that this approach may constitute a straightforward and cost‐effective alternative for the genotyping of single or duplicated MHC genes displaying low to moderate sets of divergent alleles.     

Carbon nano-strings as reporters in lateral flow devices for DNA sensing by hybridization

Presently, there is a growing interest in the development of lateral flow devices for nucleic acid analysis that enable visual detection of the target sequence (analyte) while eliminating several steps required for pipetting, incubation, and washing out the excess of reactants. In this paper, we present, for the first time, lateral flow tests exploiting oligonucleotide-functionalized and antibody-functionalized carbon nanoparticles (carbon nano-strings, CBNS) as reporters that enable confirmation of the target DNA sequence by hybridization. The CBNS reporters were applied to (a) the detection of PCR products and (b) visual genotyping of single nucleotide polymorphisms in human genomic DNA. Biotinylated PCR product was hybridized with a dA-tailed probe. In one assay configuration, the hybrid is captured at the test zone of the strip by immobilized streptavidin and detected by (dT) ₃₀ -CBNS. In a second configuration, the hybrids are captured from immobilized (dA) strands and detected by antibiotin-CBNS. As low as 2.5 fmol of amplified DNA can be detected. For visual genotyping, allele-specific primers with a 5′ oligo(dA) segment are extended by DNA polymerase with a concomitant incorporation of biotin moieties. Extension products are detected either by (dT) ₃₀ -CBNS or by antibiotin-CBNS. Only three cycles of extension reaction are sufficient for detection. No purification of the PCR products or the extension product is required.     

Sample stacking capillary electrophoretic microdevice for highly sensitive mini Y short tandem repeat genotyping

Lab‐on‐a‐chip provides an ideal platform for short tandem repeat (STR) genotyping due to its intrinsic low sample consumption, rapid analysis, and high‐throughput capability. One of the challenges, however, in the forensic human identification on the microdevice is the detection sensitivity derived from the nanoliter volume sample handling. To overcome such a sensitivity issue, here we developed a sample stacking CE microdevice for mini Y STR genotyping. The mini Y STR includes redesigned primer sequences to generate smaller‐sized PCR amplicons to enhance the PCR efficiency and the success rate for a low copy number and degraded DNA. The mini Y STR amplicons occupied in the 5‐ and 10‐mm stacking microchannels are preconcentrated efficiently in a defined narrow region through the optimized sample stacking CE scheme, resulting in more than tenfold improved fluorescence peak intensities compared with that of a conventional cross‐injection microcapillary electrophoresis method. Such signal enhancement allows us to successfully analyze the Y STR typing with only 25 pg of male genomic DNA, with high background of female genomic DNA, and with highly degraded male genomic DNA. The combination of the mini Y STR system with the novel sample stacking CE microdevice provides the highly sensitive Y STR typing on a chip, making it promising to perform high‐performance on‐site forensic human identification.     

PCR-free digital minisatellite tandem repeat genotyping

We demonstrated a proof‐of‐concept for novel minisatellite tandem repeat typing, called PCR‐free digital VNTR (variable number tandem repeat) typing, which is composed of three steps: a ligation reaction instead of PCR thermal cycling, magnetic bead‐based solid‐phase capture for purification, and an elongated sample stacking microcapillary electrophoresis (μCE) for sensitive digital coding of repeat number. We designed a 16‐bp fluorescently labeled ligation probe which is complementary to a repeat unit of a biotinylated synthetic template mimicking the human D1S80 VNTR locus and is randomly hybridized with the minisatellite tandem repeats. A quick isothermal ligation reaction was followed to link the adjacent ligation probes on the DNA templates, and then the ligated products were purified by streptavidin‐coated magnetic beads. After a denaturing step, a large amount of ligated products whose size difference was equivalent to the repeat unit were released and recovered. Through the elongated sample stacking μCE separation on a microdevice, the fluorescence signal of the ligated products was generated in the electropherogram and the peak number was directly counted which was exactly matched with the repeat number of VNTR locus. We could successfully identify the minisatellite tandem repeat number with only 5 fmol of DNA template in 30 min.     

Human complement factor 3 polymorphism determination by capillary electrophoresis of serum

Variability of complement factor 3 (C3) mobility in serum protein electrophoresis was investigated. We found that the migration time of C3 can be reproducibly determined (beween‐run CV=0.76%) using clinical capillary electrophoresis (CE) equipment (the Capillarys? 2 system, Sebia). Moreover, we found a significant difference (p<0.001) in migration times of the major C3 phenotypes FF (fast‐fast), FS (fast‐slow) and SS (slow‐slow). Glycosylation did not significantly affect test results. This is the first report on the migration time of C3 phenotypes on a clinical CE instrument. The presented method allows faster data than agarose‐electrophoresis or genotyping. Moreover, reference ranges for serum C3 concentration depend on C3 phenotype, which allows a better tailored clinical interpretation of C3 concentrations.     

Rapid microwell polymerase chain reaction with subsequent ultrathin-layer gel electrophoresis of DNA

Large-scale genotyping, mapping and expression profiling require affordable, fully automated high-throughput devices enabling rapid, high-performance analysis using minute quantities of reagents. In this paper, we describe a new combination of microwell polymerase chain reaction (PCR) based DNA amplification technique with automated ultrathin-layer gel electrophoresis analysis of the resulting products. This technique decreases the reagent consumption (total reaction volume 0.75-1 microL), the time requirement of the PCR (15-20 min) and subsequent ultrathin-layer gel electrophoresis based fragment analysis (5 min) by automating the current manual procedure and reducing the human intervention using sample loading robots and computerized real time data analysis. Small aliquots (0.2 microL) of the submicroliter size PCR reaction were transferred onto loading membranes and analyzed by ultrathin-layer gel electrophoresis which is a novel, high-performance and automated microseparation technique. This system employs integrated scanning laser-induced fluorescence-avalanche photodiode detection and combines the advantages of conventional slab and capillary gel electrophoresis. Visualization of the DNA fragments was accomplished by "in migratio" complexation with ethidium bromide during the electrophoresis process also enabling real time imaging and data analysis.     

Non‐hybridization single nucleotide polymorphism detection and genotyping assay through direct discrimination of single base mutation by capillary electrophoretic separation of single‐stranded DNA

The significant demands for single nucleotide polymorphism detection and genotyping assays have grown. Most common assays are based on the recognition of the target sequence by the hybridization with its specific probe having the complementary sequence of the target. Herein, a simple, label‐free, and economical non‐hybridization assay was developed for single nucleotide polymorphism detection and genotyping, based on the direct discrimination of single base mutation by simple capillary electrophoresis separation for single‐stranded DNA in an acidic electrophoretic buffer solution containing urea. Capillary electrophoresis separation of single‐base sequential isomers of DNA was achieved due to charge differences resulting from the different protonation properties of the DNA bases. Single nucleotide polymorphism detection and genotyping were achieved by discriminating the electropherogram pattern change, that is, peak number in the electropherogram, obtained by the proposed method. The successful practical application of the proposed method was demonstrated through single nucleotide polymorphism detection and genotyping on a known gene region of 84‐mer, in which guanine to adenine single‐base mutation is commonly observed, using a human hair sample in combination with genomic DNA extraction, polymerase chain reaction amplification, DNA purification from polymerase chain reaction products, and capillary electrophoresis separation.     

Combination of 768-well microplate array diagonal gel electrophoresis with duplex PCR of X and Y chromosome markers for quality control of epidemiological DNA banks

Large DNA banks for human epidemiological studies have become an increasingly important research tool. The power of genotype-phenotype studies is dependent both on the quality of phenotyping and of genotyping and of correct linking of phenotypes to genotypes. Samples must be tracked through numerous steps between subject or patient and post-genotypic data. Only one phenotype, sex, has a perfect and binary correlation with genotype. In mixed sex studies, it may be advantageous for purposes of quality control to keep sexes mixed during the steps from acquisition to DNA bank, in order to be able to check later for sample swaps. We have designed a duplex PCR combining an amplicon from MAOA marking the X chromosome and an amplicon from DDX3Y marking the Y chromosome. We combined this with a simple economical palmtop sized 768-well microplate compatible electrophoresis system developed in-house for examination of duplex PCR products. We applied this quality control test in the validation of two DNA banks.     

Circumventing air bubbles in microfluidic systems and quantitative continuous-flow PCR applications

Polymerase chain reaction (PCR) is an essential part of research based on genomics or cell analysis. The development of a microfluidic device that would be suitable for high-temperature-based reactions therefore becomes an important contribution towards the integration of micro-total analysis systems (μTAS). However, problems associated with the generation of air bubbles in the microchannels before the introduction of the assay liquid, which we call the “initial start-up” in this study, made the flow irregular and unstable. In this report, we have tried to address these problems by adapting a novel liquid-flow method for high-temperature-based reactions. A PDMS-based microfluidic device was fabricated by soft-lithography techniques and placed on a cartridge heater. The generation of the air bubbles was prevented by introducing the fluorinated oil, an inert and highly viscous liquid, as the cap just before the introduction of the sample solutions into the microchannels. The technique was applied for continuous-flow PCR, which could perform PCR on-chip in a microfluidic system. For the evaluation of practical accuracy, plasmid DNA that serves as a reference molecule for the quantification of genetically modified (GM) maize was used as the template DNA for continuous-flow PCR. After PCR, the products were collected in a vial and analyzed by gel electrophoresis to confirm the accuracy of the results. Additionally, quantitative continuous-flow PCR was performed using TaqMan technology on our PCR device. A laser detection system was also used for the quantitative PCR method. We observed a linear relationship between the threshold cycle (Ct) and the initial DNA concentration. These results showed that it would be possible to quantify the initial copies of the template DNA on our microfluidic device. Accurate quantitative DNA analysis in microfluidic systems is required for the integration of PCR with μTAS, thus we anticipate that our device would have promising potential for applications in a wide range of research.     

Affinity capillary electrophoresis with a DNA-nanoparticle conjugate as a new tool for genotyping

We have developed a novel method for genotyping based on free solution affinity capillary electrophoresis. We prepared DNA-nanoparticle conjugates by mixing biotin-modified DNA and NeutrAvidin-modified polystyrene nanoparticles; this mixture was then injected into a capillary. Subsequently, we injected the fluorescent-labeled sample DNAs into the capillary, applied the voltage, increased its temperature after 7 min, and detected the fluorescence at its anodic end. This novel method was applied for genotyping human c-K-ras, and the three genotypes were definitely distinguishable with high reproducibility. This method can be easily automated, and it is useful for high-throughput gene mutation analysis.     

Gel immobilization of acrylamide-modified single-stranded DNA template for pyrosequencing

A novel two-step process was developed to prepare ssDNA templates for pyrosequencing. First, PCR-amplified DNA templates modified with an acrylamide group and acrylamide monomers were copolymerized in 0.1 M NaOH solution to form polyacrylamide gel spots. Second, ssDNA templates for pyrosequencing were prepared by removing electrophoretically unbound complementary strands, unmodified PCR primers, inorganic pyrophosphate (PPi), and excess deoxyribonucleotides under alkali conditions. The results show that the 3-D polyacrylamide gel network has a high immobilization capacity and the modified PCR fragments are efficiently captured. After electrophoresis, gel spots copolymerized from 10 microL of the crude PCR products and the acrylamide monomers contain template molecules on the order of pmol, which generate enough light to be detected by a regular photomultiplier tube. The porous structure of gel spots facilitated the fast transportation of the enzyme, dNTPs and other reagents, and the solution-mimicking microenvironment guaranteed polymerase efficiency for pyrosequencing. Successful genotyping from the crude PCR products was demonstrated. This method can be applied in any laboratory; it is cheap, fast, simple, and has the potential to be incorporated into a DNA-chip format for high-throughput pyrosequencing analysis.     

A simple and affordable method for high-throughput DNA extraction from animal tissues for polymerase chain reaction

We have developed a very simple and inexpensive method for high-throughput DNA extraction from animal tissues. The procedure contains three steps (digestion, heating, and centrifugation) and it is compatible with the 96-well plate format commonly used in polymerase chain reaction (PCR) amplifications. The duration for processing a plate is about 1.5 h; therefore, one researcher can isolate DNA from up to 1000 samples during a single workday. A small piece of tissue (ca. 10-20 mg) yields enough template for at least 50-70 PCR amplifications, as demonstrated by using the processed samples as templates successfully for long distance PCR, multiplex PCR, and randomly amplified polymorphic DNA (RAPD) assay. The application of our method is expected to facilitate studies that require high-throughput DNA isolation for PCR amplification, such as genotyping by microsatellites for mapping and genetic diversity studies, as well as mutant screening in zebrafish.     

Rapid genotyping of CYP2D6, CYP2C19 and TPMT polymorphisms by primer extension reaction in a dipstick format

In recent years an increasing amount of interest has been directed at the study and routine testing of polymorphisms responsible for variations in drug metabolism. Most of the current methods involve either time-consuming electrophoresis steps or specialized and expensive equipment. In this context, we have developed a rapid, simple and robust method for genotyping of CYP2D6*3, CYP2D6*4, CYP2C19*2, CYP2C19*3 and TPMT*2 single nucleotide polymorphisms (SNP). Genomic DNA is isolated from whole blood and the segments that span the SNP of interest are amplified by PCR. The products are subjected directly (without purification) to two primer extension (PEXT) reactions (three cycles each) using normal and mutant primers in the presence of biotin-dUTP. The PEXT primers contain a (dA)₃₀ segment at the 5′ end. The PEXT products are detected visually by a dry-reagent dipstick-type assay in which the biotinylated extension products are captured from immobilized streptavidin on the test zone of the strip and detected by hybridization with oligo(dT)-functionalized gold nanoparticles. Patient samples (76 variants in total) were genotyped and the results were fully concordant with those obtained by direct DNA sequencing.     

High-throughput genotyping of factor V Leiden mutation by ultrathin-layer agarose gel electrophoresis.

Ultrathin-layer agarose gel electrophoresis is a novel combination of the established methodologies of slab gel electrophoresis and capillary gel electrophoresis. This new format provides a multilane separation platform with rapid analysis time and excellent sensitivity by using laser-induced fluorescence scanning detection system. Sample injection onto the ultrathin-layer separation platform is easily accomplished by membrane mediated loading technology. In this paper, we demonstrate the sensitivity and high-throughput fashion of this novel separation and detection system for rapid genotyping of the coagulation factor V Leiden mutation by polymerase chain reaction (PCR)-restriction fragment length polymorphism (RFLP) analysis. The PCR amplified fragment from exon 10 of the factor V gene was digested by the Mnl I restriction enzyme, followed by automated ultrathin-layer agarose gel electrophoresis analysis with "in migratio" fluorescent labeling during the separation process. Due to its speed and automation, this method should be considered for large scale screening of factor V Leiden mutation.     

A multiplex SNP genotyping by allele‐specificspecific PCR based on stem‐loop and universal fluorescent primers of Chr1daxin mice

Single nucleotide polymorphisms (SNPs) are one of the most common markers in mammals. Rapid, accurate, and multiplex typing of SNPs is critical for subsequent biological and genetic research. In this study, we have developed a novel method for multiplex genotyping SNPs in mice. The method involves allele‐specific PCR amplification of genomic DNA with two stem‐loop primers accompanied by two different universal fluorescent primers. Blue and green fluorescent signals were conveniently detected on a DNA sequencer. We verified four SNPs of 65 mice based on the novel method, and it is well suited for multiplex genotyping as it requires only one reaction per sample in a single tube with multiplex PCR. The use of universal fluorescent primers greatly reduces the cost of designing different fluorescent probes for each SNP. Therefore, this method can be applied to many biological and genetic studies, such as multiple candidate gene testing, genome‐wide association study, pharmacogenetics, and medical diagnostics.