Truncated fragments in polymerase chain reaction-based DNA sequencing

Reconstitution experiments were performed by using an ordinary dye-primer protocol of a template spiked with known amounts of truncated fragments. We observed that as little as 0.2 mole-percentage of the truncated fragment caused sequence interpretation problems. Two protocols were developed for sequencing with dye-labeled terminators; this eliminates the problems with truncated fragments, which are adapted to a one-dye chemistry. One was designed for single extension sequencing using T7 DNA polymerase and one for cycle sequencing. To avoid precipitation and centrifugation and to facilitate automation, the dye-terminator protocols included the use of a biotinylated sequencing primer. Thus, the Sanger fragments were recovered and, by magnetic separation, washed and released by formamide, EDTA, and heat treatment before loading on the electrophoresis gel. Integrated procedures for sequencing PCR products using one-dye-labeled terminators suitable for automation are described. High quality data in terms of long reads and detection of polymorphisms is obtained. The protocols serve as attractive alternatives to internal labeling and dye-primer approaches.     

High-throughput polymerase chain reaction analysis of clinical samples by capillary electrophoresis with UV detection

Routine genetic analysis of large numbers of individuals by polymerase chain reaction (PCR) using capillary electrophoresis is often restricted by the low throughput of standard protocols and the tedious sample preparation process. Here, we demonstrate that capillary electrophoresis with UV detection can be used in PCR-based DNA analysis starting from clinical samples without purification or complicated sample manipulation. After PCR reaction using cheek cells, blood, or HIV-1 gag DNA, the reaction mixtures were injected into a capillary array either on-line or off-line by base stacking. The use of multiplexed absorption detection and the elimination of any purification steps both before and after PCR reaction can potentially provide significant benefits compared to current methods for DNA analysis with regard to time, cost, and labor.     

Highly sensitive polymerase chain reaction-free quantum dot-based quantification of forensic genomic DNA

Forensic DNA samples can degrade easily due to exposure to light and moisture at the crime scene. In addition, the amount of DNA acquired at a criminal site is inherently limited. This limited amount of human DNA has to be quantified accurately after the process of DNA extraction. The accurately quantified extracted genomic DNA is then used as a DNA template in polymerase chain reaction (PCR) amplification for short tandem repeat (STR) human identification. Accordingly, highly sensitive and human-specific quantification of forensic DNA samples is an essential issue in forensic study. In this work, a quantum dot (Qdot)-labeled Alu sequence was developed as a probe to simultaneously satisfy both the high sensitivity and human genome selectivity for quantification of forensic DNA samples. This probe provided PCR-free determination of human genomic DNA and had a 2.5-femtogram detection limit due to the strong emission and photostability of the Qdot. The Qdot-labeled Alu sequence has been used successfully to assess 18 different forensic DNA samples for STR human identification.     

Hybridization and polymerase chain reaction amplification of simple repeated DNA sequences for the analysis of forensic stains.

We have evaluated oligonucleotide hybridization and amplification techniques with regard to quantity and quality of genomic DNA that is under investigation in practical forensic case work. In order to obtain sufficient information from analyzing stain material, we use hypervariable simple repeat sequences for individualization, which occur in all eukaryotic genomes. For the analysis of larger amounts of stains (greater than 500 ng DNA) the multilocus probes (CAC)5/(GTG)5* are superior because of their discrimination potential--provided that the hybridizing DNA is of high molecular weight. The less discriminating probes (CT)8 and (GACA)4 are more sensitive (minimal amount: 100ng DNA) and still informative when the DNA is degraded. To increase the sensitivity of forensic stain analysis in special cases we have used the polymerase chain reaction technique to amplify hypervariable simple (gt)n/(ga)m repeat structures from the intron 2 of HLA-DRB genes. Largely independent of the starting amount of DNA and independent of the degradation status, we were able to generate discriminating DNA fragments, which can be used to type (i) microstains and (ii) totally degraded material including human mummy DNA.     

Multiple use of slab gels in sequencing apparatus for separation of polymerase chain reaction products

Attempting to assess whether a decrease of the electrophoresis temperature could prevent or reduce the extent of gel well deformations, and whether the utilization of native polyacrylamide gels (without urea) could speed up the separation of polymerase chain reaction (PCR)-amplified products with an automated 377 DNA sequencer, denatured PCR products were subjected to electrophoresis in 6% native gels under 45 degrees C. Results show that a decrease of the electrophoresis temperature from 51 degrees C (recommended by the User's Manual) to 45 degrees C substantially facilitates the preservation of gel wells, and that all PCR products tested migrate significantly faster in native than in denatured (with urea) gels of the same concentration. The combination of a 6% native gel and a lower (45 degrees C) electrophoresis temperature permits multiple uses of a given gel with consistent results, consequently reducing the electrophoresis time and reagent costs.     

Quantification of DNA in forensic samples

Quantification of DNA in a forensic sample is of major importance for proper DNA amplification and STR profiling. Several methods have been developed to quantify DNA, from basic UV spectrometry, through gel-based techniques, to dye staining, blotting techniques, and, very recently, DNA amplification methods (polymerase chain reaction, PCR). Early techniques simply measured total DNA, but newer techniques can specifically measure human DNA while excluding non-human DNA (foodstuff, animal, or bacterial contamination). These newer assays can be faster and less expensive than traditional methods, making them ideal for the busy forensic laboratory. This paper reviews classic and newer quantification techniques and presents methods recently developed by the authors on the basis of PCR of Alu sequences.     

Ferrite supports for isolation of DNA from complex samples and polymerase chain reaction amplification

The influence of cobalt ferrite particles, with non-modified or modified surface, on the course of polymerase chain reaction (PCR) was investigated. DNA isolated from bacterial cells of Bifidobacterium bifidum was used in PCR evaluation of magnetic microspheres. The presence of cobalt ferrite particles inhibits PCR amplification. The effect is not dependent on the functional groups of the modifying reagents used (none, amino, carboxyl). Amplification was improved after the magnetic separation of magnetic particles. Proposed indirect method enabled verification of the suitability of designed particles for their application in PCR assays. Magnetic particles coated with alginic acid under high PEG and sodium chloride concentration were used for the isolation of PCR-ready bacterial DNA from various dairy products. DNA was isolated from crude bacterial cell lysates without phenol extraction of samples. Bifidobacterium and Lactobacillus DNAs were identified in dairy products using PCR.     

An 18 Multi-InDels panel for analysis of highly degraded forensic biological samples

DNA genotyping from trace and highly degraded biological samples is one of the most significant challenges of forensic DNA identification. There is a lack of simple and effective methods for genotyping highly degraded samples. In this study, a multiple loci insertion/deletion polymorphisms (Multi-InDels) panel was designed for detecting 18 autosomal Multi-InDels through capillary electrophoresis (CE) with amplicon sizes no longer than 125 bp. Studies of sensitivity, degradation, and species specificity were performed and a population study was carried out using 192 samples from Han populations in Hunan province in the south of China. The combined random match probability (CMP) of these 18 Multi-InDels was 3.23 × 10^–12 and the cumulative probability of exclusion (CPE) was 0.9989, suggesting this panel could be used independently for human identification and could provide efficient supporting information for parentage testing. Complete profiles were obtained from as low as 62.5 pg of total input DNA after increasing the number of PCR cycles. Moreover, all alleles were detected from artificially highly degraded DNA after 80 min of boiling water bath treatment. This 18 Multi-InDels panel is simple, fast, and effective for the forensic analysis of highly degraded DNA.     

An evaluation of trace element analysis in the forensic investigation of fibre samples

The use of trace element analysis in the forensic examination of fibres has been investigated. Samples of both natural and synthetic fibres have been analysed to show that it is possible to both identify and discriminate between samples that would, by present methods, be considered indistinguishable. A number of wool garments of predetermined trace element composition were sent for wear for a period of nine months. The conditions and frequency of wear and cleaning were reported to enable their effect upon the trace element composition of these garments to be determined. The wool samples were analysed by both short (30 min) and long (50 hrs) irradiations in a reactor flux of about 10¹² n·cm⁻²·sec⁻¹. This permitted the concentrations of the elements such as sodium, chlorine, iodine, manganese, cobalt and chromium to be determined. Both sodium iodide and lithium drifted germanium detectors were used to measure the induced activity of the wool samples. The composition of a range of acrylic fibres from a variety of sources has also been examined using a sodium iodide detector. The concentrations of sodium chlorine, bromine, managese, copper, aluminium, titanium, indium and barium were determined in these samples.     

Visible and near-infrared chemical imaging methods for the analysis of selected forensic samples

This study investigated various chemical imaging methods for the forensic analysis of paints, tapes and adhesives, inks and firearm propellants (absorption and photoluminescence in the UV-vis-NIR regions). Results obtained using chemical imaging technology were compared with those obtained using traditional techniques. The results show that chemical imaging offers significant advantages in the forensic context, for example the ability to display visual and spectral results side by side and to reduce sample preparation, hence minimizing the risk of contamination. Chemical imaging produced a greater discriminating power than traditional techniques for most evidence types. Chemical imaging also eliminated different brands of ammunition based on the fluorescence characteristics of the propellant grains preserving the evidence for further analysis. It is expected that this technology will find broader forensic applications in the future.     

Development of a novel multiplex polymerase chain reaction system for forensic individual identification using insertion/deletion polymorphisms

Insertion/deletion (InDel) polymorphisms have been widely used in the fields of population genetics, genetic map constructions, and forensic investigations owing to the advantages of their low mutation rates, widespread distributions in the human genome, and small amplicon sizes. In order to provide more InDels with high discrimination power in Chinese populations, we selected and constructed one novel multiplex PCR‐InDel panel for forensic individual identification. Genetic distributions of these 35 InDels in five reference populations from East Asia showed low genetic differentiations among these populations. Forensic efficiency evaluations of these InDels revealed that these loci could perform well for forensic individual identifications in these reference populations. In the meantime, genetic diversities and forensic parameters of these InDels were further investigated in the studied Kazak group. Mean value of polymorphism information content for 35 InDels was 0.3611. Cumulative power of discrimination of 35 InDels was 0.99999999999999603 in Kazak group. Given these results, the panel is suitable for individual identifications in the studied Kazak and these reference populations.     

Light-triggered polymerase chain reaction

Photochemical control of the polymerase chain reaction has been achieved through the incorporation of light-triggered nucleotides into DNA.     

Characterization and forensic analysis of soil samples using laser-induced breakdown spectroscopy (LIBS)

A method for the quantitative elemental analysis of surface soil samples using laser-induced breakdown spectroscopy (LIBS) was developed and applied to the analysis of bulk soil samples for discrimination between specimens. The use of a 266 nm laser for LIBS analysis is reported for the first time in forensic soil analysis. Optimization of the LIBS method is discussed, and the results compared favorably to a laser ablation inductively coupled plasma mass spectrometry (LA-ICP-MS) method previously developed. Precision for both methods was <10% for most elements. LIBS limits of detection were <33 ppm and bias <40% for most elements. In a proof of principle study, the LIBS method successfully discriminated samples from two different sites in Dade County, FL. Analysis of variance, Tukey’s post hoc test and Student’s t test resulted in 100% discrimination with no type I or type II errors. Principal components analysis (PCA) resulted in clear groupings of the two sites. A correct classification rate of 99.4% was obtained with linear discriminant analysis using leave-one-out validation. Similar results were obtained when the same samples were analyzed by LA-ICP-MS, showing that LIBS can provide similar information to LA-ICP-MS. In a forensic sampling/spatial heterogeneity study, the variation between sites, between sub-plots, between samples and within samples was examined on three similar Dade sites. The closer the sampling locations, the closer the grouping on a PCA plot and the higher the misclassification rate. These results underscore the importance of careful sampling for geographic site characterization.     

DNA damage promotes mistyping in the allele specific oligonucleotide probing analysis of forensic samples

Five polymerase chain reaction (PCR) products which could not be reliably typed by allele-specific oligonucleotide (ASO) probing at the human leukocyte antigen (HLA) DQA1 locus were analyzed by polyacrylamide gel electrophoresis and direct sequencing. The first method revealed the preferential amplification of only one of the two alleles in two cases. Direct sequencing of PCR products allowed unambiguous genetic typing but a high number of artifacts was observed. Several of these artifacts occurred in the sequences recognized by the ASOs. This finding provides an explanation for the mistyping in the ASO probing procedure because Taq polymerase errors both created new genetic specificities and eliminated site-specific polymorphisms. Reversed-phase HPLC-MS of the five forensic templates showed a high degree of DNA damage. These data together indicate that the risk of mistyping when using the ASO probing procedure cannot be neglected in the forensic analysis of damaged DNA samples.     

Electrochemical real-time polymerase chain reaction

In this work, we report the first electrochemistry-based real-time polymerase chain reaction technique for sequence-specific nucleic acid detection. This new technique builds upon the advantages of the well-established fluorescence-based counterpart, such as short assay time (simultaneous target DNA amplification and detection). In addition, this electrochemical approach could employ simple and miniaturizable instrumentation compared to the bulky and expensive optics required in the fluorescence-based schemes. We have demonstrated a proof-of-concept experiment showing that the utilization of solid-phase extension of the electrode surface-immobilized capture probe with Fc-dUTP during PCR resulted in the accumulation of the redox marker on the transducer surface. This new technique can be applied to a microfabricated PCR electrochemical device for point-of-care diagnostics as well as on-site environmental monitoring and biowarfare agent detection.     

Renewable microcolumns for automated DNA purification and flow-through amplification: from sediment samples through polymerase chain reaction

There is an increasing need for field-portable systems for the detection and characterization of microorganisms in the environment. Nucleic acids analysis is frequently the method of choice for discriminating between bacteria in complex systems, but standard protocols are difficult to automate and current microfluidic devices are not configured specifically for environmental sample analysis. In this report, we describe the development of an integrated DNA purification and polymerase chain reaction (PCR) amplification system and demonstrate its use for the automated purification and amplification of Geobacter chapellei DNA (genomic DNA or plasmid targets) from sediments. The system includes renewable separation columns for the automated capture and release of microparticle purification matrices, and can be easily reprogrammed for new separation chemistries and sample types. The DNA extraction efficiency for the automated system ranged from 3 to 25%, depending on the length and concentration of the DNA target. The system was more efficient than batch capture methods for the recovery of dilute genomic DNA even though the reagent volumes were smaller than required for the batch procedure. The automated DNA concentration and purification module was coupled to a flow-through, Peltier-controlled DNA amplification chamber, and used to successfully purify and amplify genomic and plasmid DNA from sediment extracts. Cleaning protocols were also developed to allow reuse of the integrated sample preparation system, including the flow-through PCR tube.     

Practical integration of polymerase chain reaction amplification and electrophoretic analysis in microfluidic devices for genetic analysis

An integrated system of a silicon-based microfabricated polymerase chain reaction (microPCR) chamber and microfabricated electrophoretic glass chips have been developed. The PCR chamber was made of silicon and had aluminum heaters and temperature sensors integrated on the glass anodically bonded cover. Temperature uniformity in the reaction chamber was +/-0.3 degrees C using an improved novel "joint-heating" scheme. Thermal cycling was digitally controlled with a temperature accuracy of +/- 0.2 degrees C. Small operating volumes together with high thermal conductivity of silicon made the device well suited to rapid cycling; 16 s/cycle were demonstrated. For analysis of the PCR products, the chamber output was transferred to the glass microchip by pressure. Analysis time of PCR amplified genomic DNA was obtained in the microchip in less than 180 s. The analysis procedure employed was reproducible, simple and practical by using viscous sieving solutions of hydroxypropylmethylcellulose and dynamically coated microchip channels with poly(vinylpyrrolidone). DNA fragments that differ in size by 18 base pairs (bp) were resolved. Analysis of genomic male and female amplified DNA by microPCR was achieved in microchip, and application of the integrated microPCR-microchip for the identification of bird sex was tested. Genomic DNA samples from several bird species such as pigeon and chicken were analyzed. Hence, the system could be used as well to determine the sex of avian species.     

Evaluation of the LTQ-Orbitrap mass spectrometer for the analysis of polymerase chain reaction products

We have investigated the potential and robustness of the off‐line coupling of polymerase chain reaction (PCR) with electrospray ionization mass spectrometry (ESI‐MS), for further applications in the screening of single‐nucleotide polymorphisms (SNPs). This was based on recently reported data demonstrating that anion‐exchange solid‐phase extraction was the most efficient technique for efficiently desalting PCR products, with a recovery of ～70%. Results showed that this purification approach efficiently removes almost all the chemicals commonly added to PCR buffers. ESI‐MS analysis of a model 114‐bp PCR product performed on the LTQ‐Orbitrap instrument demonstrated that detection limits in the nM range along with an average mass measurement uncertainty of 9.15 ± 7.11 ppm can be routinely obtained using an external calibration. The PCR/ESI‐MS platform was able to detect just a few copies of a targeted oligonucleotide. However, it was shown that if two PCR products are present in a mixture in a ratio higher than 10 to 1, the lower abundance one might not be reproducibly detected. Applications to SNPs demonstrated that an LTQ‐Orbitrap with a resolution of 30 000 (at m/z 400) easily identified a single (A ? G) switch, i.e. a 16 Da difference, in binary mixtures of ～ 35 kDa PCR products. Complementary experiments also showed that the combination of endonucleases and ESI‐MS could be used to confirm base composition and sequence, and thus to screen for unknown polymorphisms in specific sequences. For example, a single (T ? A) switch (9 Da mass difference) was successfully identified in a 114‐bp PCR product. Copyright © 2010 John Wiley & Sons, Ltd.