Development of new procedures for the isolation of phytoplankton DNA from fixed samples

Phytoplankton samples collected for routine monitoring programmes have traditionally been preserved with fixatives before subsequent analytical procedures such as microscope-based identification, or simply to permit transport between laboratories. In recent years, to simplify identification and enumeration, the use of DNA or RNA probes coupled with the PCR assay has progressed and now represents a routine procedure for screening cultured and field samples. However, the phytoplankton cells have often still to be treated as fixed samples.The extraction of genomic DNA from fixed cultures of Alexandrium minutum cultures was compared using two new methods based on Magnetisable Solid Phase Support (MSPS) techniques with that using three commercial kits. Genomic DNA recovery and PCR amplification were observed and the results obtained from culture samples were validated using field samples. Among the DNA extraction techniques considered, the MSPS methods provided the best results.     

A novel method for whole blood PCR without pretreatment

PCR is usually performed on purified DNA. However, the extraction of DNA from whole blood is time consuming and involves the risk of contamination at every step. Hence, it is desirable to amplify DNA directly from whole blood. Earlier, investigators tried to achieve this target by either pretreatment of whole blood samples with different agents or by altering the conventional thermal cyclic conditions. This would make the technique cumbersome and time consuming. Here, we describe a simple protocol to amplify DNA directly from whole blood without the need of pretreatment. PCR buffer system was optimized in the laboratory and Apolipoprotein B gene was used as a model for this experiment. 480 bp was the target site for amplification. Fresh whole blood samples were used both from healthy and diseased individuals (coronary artery disease patients). Successful amplification was achieved with 1 μl volume of whole blood and it was comparable to that of genomic DNA. No pretreatment of whole blood samples was required with the optimized buffer system. 3mM concentration of MgCl(2) was observed to be optimal and hence used in the reaction mixture. Amplification was relatively better with this buffer system as compared to that of commercially available PCR buffer. With the present technique, amplicon detection did not require the centrifugation/dilution of the PCR products which further saves time. Successful amplification was achieved in both the healthy and diseased blood samples, indicating the robustness of the technique as changed blood composition and presence of increased inhibitory molecules in the diseased state did not seem to affect the efficacy of the present technique. In conclusion, as compared to the existing protocols for whole blood PCR, the present technique is relatively novel, simple, requires minimal steps and eliminates the need for additional standardizations.     

A New Approach to the Isolation of Genomic DNA from Yeast and Fungi: Preparation of DNA-containing Cell Envelopes and Their Use in PCR

A simple and rapid procedure for the preparation of yeast and fungal DNA samples useful in PCR amplification was developed. The DNA was purified from proteins, lipids, polysaccharides, and other impurities by high-temperature extraction (in a boiling water bath) with buffer solutions containing chaotropic salts. Under these conditions, yeast and fungal cell envelopes remain unbroken and retain the original DNA and RNA that could be used for direct PCR amplification. We called the proposed PCR technique as the PCR using DNA-containing cell envelopes.     

Identification and quantitation of species in complex DNA mixtures by real-time polymerase chain reaction

Six TaqMan real-time polymerase chain reaction (PCR) systems using minor groove binding (MGB) probes have been developed for the detection quantitation of bovine, porcine, lamb, chicken, turkey, and ostrich DNA in complex samples. Species-specific amplification was achieved by combining only two fluorogenic probes and 10 oligonucleotide primers targeting mitochondrial sequences, decreasing the cost of the assay significantly. The limits of detection ranged from 0.03 to 0.80 pg of template DNA. Analysis of experimental mixtures containing two to four different species showed the suitability of the assay for detection of more than 1% of pork, chicken, or turkey and of more than 5% of cattle or lamb. The quantitation accuracy in samples containing 10-100% of beef or pork DNA was close to 90%. The system is complemented with one additional TaqMan MGB detector based on consensus sequence segments of the nuclear 18S ribosomal RNA gene. A method to evaluate the presence of unknown eukaryotic DNA in a mixture, where data derived from the species-specific detection are compared with the experimental values obtained from the general 18S detector, is presented. This method allows the validation of the quantitative measurements, providing an internal control of the total content of PCR-amplifiable DNA in the sample. The system was tested on DNA mixtures containing different shares of up to four different species and on DNA extracted from processed commercial food samples.     

转水稻粗缩病毒运动蛋白缺陷型基因玉米的二重PCR检测研究

本研究以外源基因（RDV MP-）和玉米内源基因Zein作为PCR扩增对象,旨在建立一种简便有效的转基因玉米及其产品的二重PCR检测技术。转外源基因（RDV MP-）材料的常规PCR检测结果证明外源基因在转基因材料中可稳定遗传;对常规PCR检测的阴性结果材料进行二重PCR检测,扩增结果除进一步证实常规PCR检测的阴性结果结论外,还证明提取的植物总DNA质量符合试验要求,进而从二重PCR检测结果还得出常规PCR检测的阴性结果出错率为1.4%。此方法简单,实用,结果可靠,可适用于转基因植物及产品的检测。     

Molecular detection of anthrax spores on animal fibres

AIMS: To develop a rapid, specific and sensitive diagnostic test for the detection of the spores of Bacillus anthracis on commercial samples of animal fibres (e.g. wool and cashmere). METHODS AND RESULTS: Extraction of DNA from spores using a mechanical disruption method based on bead beating was evaluated but subsequently abandoned as it compromised the sensitivity of the overall protocol. A multiplex PCR and two nested amplification reactions designed for B. anthracis were developed during this study. CONCLUSIONS: A simple selective incubation step in combination with multiplex PCR was found to be more effective than generic DNA extraction coupled to a sensitive nested amplification reaction. SIGNIFICANCE AND IMPACT OF THE STUDY: The rapid diagnostic test could be applied to the analysis of commercial fibre samples for the detection of anthrax as required by health and safety legislation resulting in considerable savings in time and expense.     

Technical note: improved ancient DNA purification for PCR using ion-exchange columns

A novel method of ancient DNA (aDNA) purification was developed using ion-exchange columns to improve PCR-amplifiable DNA extraction from ancient bone samples. Thirteen PCR-resistant ancient bone samples aged 500-3,300 years were tested to extract aDNA using a recently reported, silica-based aDNA extraction method and an ion-exchange column method for the further purification. The PCR success rates of the aDNA extracts were evaluated for the amplification ability of the fragments of mitochondrial DNA, a high-copy DNA, and amelogenin, a low-copy DNA. The results demonstrate that the further purification of silica-based aDNA extracts using ion-exchange columns considerably improved PCR amplification. We suggest that the ion-exchange column-based method will be useful for the improvement of PCR-amplifiable aDNA extraction, particularly from the poorly preserved, PCR-resistant, ancient samples.     

硅-玻璃聚合酶链式反应微芯片对β-葡糖苷酸酶基因的扩增

聚合酶链式反应（PCR）微芯片是基于微机电系统（MEMS）制作,在微芯片上进行PCR反应,实现生物样品扩增的一项新技术.介绍了硅-玻璃PCR微芯片的设计和制作、微反应腔的清洗和表面处理、借助外置温度控制系统进行PCR扩增反应以及扩增产物在琼脂糖凝胶电泳下的检测分析,实现了对β-葡糖苷酸酶（GUS）基因的有效扩增,扩增时间由原来的90 min缩短到现在的37 min.     

Detection of bean yellow mosaic virus in gladioli corms by the polymerase chain reaction

The polymerase chain reaction (PCR) method readily detected bean yellow mosaic virus (BYMV) in gladioli leaves, but in initial tests PCR did not detect virus in corm tissue. Extracts of RN A from corm tissue were shown to inhibit the amplification of viral sequences when added to a PCR reaction. An additional purification step for the RNA extracts using a Sephadex G-50 column eliminated the inhibitory effect and enabled PCR to amplify and detect viral RNA in corm tissue preparations.     

On the causes,consequences, and avoidance of PCR duplicates: Towards a theory of library complexity

Library preparation protocols for most sequencing technologies involve PCR amplification of the template DNA, which open the possibility that a given template DNA molecule is sequenced multiple times. Reads arising from this phenomenon, known as PCR duplicates, inflate the cost of sequencing and can jeopardize the reliability of affected experiments. Despite the pervasiveness of this artefact, our understanding of its causes and of its impact on downstream statistical analyses remains essentially empirical. Here, we develop a general quantitative model of amplification distortions in sequencing data sets, which we leverage to investigate the factors controlling the occurrence of PCR duplicates. We show that the PCR duplicate rate is determined primarily by the ratio between library complexity and sequencing depth, and that amplification noise (including in its dependence on the number of PCR cycles) only plays a secondary role for this artefact. We confirm our predictions using new and published RAD-seq libraries and provide a method to estimate library complexity and amplification noise in any data set containing PCR duplicates. We discuss how amplification-related artefacts impact downstream analyses, and in particular genotyping accuracy. The proposed framework unites the numerous observations made on PCR duplicates and will be useful to experimenters of all sequencing technologies where DNA availability is a concern.     

Mini-prep method suitable for a plant breeding program

Plant breeders need a nondestructive and inexpensive protocol to screen large numbers of plants early after sowing. Isolation of DNA represents one of the limiting steps in this process: normally a person is capable of isolating 25 to 50 samples per day. To speed up the isolation of DNA in marker-assisted plant breeding programs, a CTAB mini-prep was modified into an inexpensive and nondestructive procedure. With this protocol a single individual can isolate 200 to 250 samples per day of high-quality DNA that is immediately suitable for testing by PCR. The amounts of DNA isolated are sufficient for about 150 PCR amplifications. These improvements are achieved by eliminating time-consuming and noncritical steps in the standard protocol, such as extensive grinding, washing with ethanol, and treatment with RNAse A.     

一种高效的植物DNA提取和PCR扩增体系建立

报道一种高效简易的植物DNA提取和PCR扩增体系。该体系仅需一步即可提取DNA,扩增时延长PCR预变性时间便能获得较好的目的基因扩增结果。本体系具有较高的实验稳定性和较好的物种适用性,将大大提高植物分子生物学实验和基于分子标记辅助的植物育种实验效率,节省科研成本。     

Real-time quantitative PCR assay for analysis of platelet glycoprotein IIIa gene expression

A quantitative detection assay for analysis of platelet glycoprotein GPIIIa gene expression is presented. The assay uses two fluorescently labeled TaqMan MGB probes to detect the polymorphic site in GPIIIa nucleotide sequence, leading to antigens HPA-1a and HPA-1b. In order to avoid the influence of DNA contamination on RNA quantification, a forward primer was constructed to span an exon-exon junction. The assay is therefore applicable to expression studies also in samples containing only a small amount of contaminating DNA. To standardize the amount of sample cDNA added to the reaction, amplification of endogenous control 18SrRNA was included in a separate well. The amplification validation experiment showed a high real-time PCR efficiency for HPA-1a, HPA-1b and 18SrRNA. Relative quantification was therefore performed using the comparative C(T) method. The assay was optimized on a reversely transcribed total RNA from platelets, and the specificity rate was determined by sequencing. The amount of cDNA at which amplification was still clearly detectable was 5 ng. This newly developed real-time quantitative PCR assay is a sensitive, reproducible and reliable method. It is suitable for studying different stages of megakaryopoiesis, monitoring molecular alteration in defective platelets and determining differences in the GPIIIa expression level between normal and pathological megakaryocytic differentiation pathways.     

High-throughput PCR in silicon based microchamber array

Highly integrated hybridization assay and capillary electrophoresis have improved the throughput of DNA analysis. The shift to high throughput analysis requires a high speed DNA amplification system, and several rapid PCR systems have been developed. In these thermal cyclers, the temperature was controlled by effective methodology instead of a large heating/cooling block preventing rapid thermal cycling. In our research, high speed PCR was performed using a silicon-based microchamber array and three heat blocks. The highly integrated microchamber array was fabricated by semiconductor microfabrication techniques. The temperature of the PCR microchamber was controlled by alternating between three heat blocks of different temperature. In general, silicon has excellent thermal conductivity, and the heat capacity is small in the miniaturized sample volume. Hence, the heating/cooling rate was rapid, approximately 16 °C/s. The rapid PCR was therefore completed in 18 min for 40 cycles. The thermal cycle time was reduced to 1/10 of a commercial PCR instrument (Model 9600, PE Applied Biosystems-3 h).     

Uniform amplification of multiple DNAs by emulsion PCR

When several DNAs are amplified by PCR in one PCR tube, biased amplification is known to occur because amplification efficiency differs from one DNA to another. Therefore, we conducted PCR in the water in oil-emulsion (W/O emulsion) to examine whether the procedure allows the uniform amplification of several DNAs. In the amplification of a model library consisting of two clones, the emulsification of the PCR mixture successfully reduced the difference in its amplification efficiency to approximately one-seventh the value obtained without emulsification. Furthermore, we conducted repeated PCR to amplify a model library consisting of ten short hairpin RNA (shRNA) expression vectors as a model experiment for gene discovery using an shRNA expression library. Consequently, the emulsification of the PCR mixture successfully reduced PCR bias. Our results indicate that emulsion PCR is capable of uniformly amplifying libraries of shRNA, ribozyme, cDNA, and others, and is useful also for gene discovery using these libraries.     

A new approach to the isolation of genomic DNA samples from yeast and fungi: preparation of DNA-containing cell envelopes and their use in PCR

A simple and rapid procedure for the preparation of yeast and fungal DNA samples useful in PCR amplification was developed. The DNA was purified from proteins, lipids, polysaccharides, and other impurities by their high-temperature extraction (in a boiling water bath) with buffer solutions containing chaotropic salts. Under these conditions, yeast and fungal cell envelopes remain unbroken and retain the original DNA and RNA that could be used for direct PCR amplification. We called the proposed PCR technique as the PCR using DNA-containing cell envelopes.     

Effect of primer mismatch, annealing temperature and PCR cycle number on 16S rRNA gene-targetting bacterial community analysis

In the attempt to explore complex bacterial communities of environmental samples, primers hybridizing to phylogenetically highly conserved regions of 16S rRNA genes are widely used, but differential amplification is a recognized problem. The biases associated with preferential amplification of multitemplate PCR were investigated using 'universal' bacteria-specific primers, focusing on the effect of primer mismatch, annealing temperature and PCR cycle number. The distortion of the template-to-product ratio was measured using predefined template mixtures and environmental samples by terminal restriction fragment length polymorphism analysis. When a 1 : 1 genomic DNA template mixture of two strains was used, primer mismatches inherent in the 63F primer presented a serious bias, showing preferential amplification of the template containing the perfectly matching sequence. The extent of the preferential amplification showed an almost exponential relation with increasing annealing temperature from 47 to 61 degrees C. No negative effect of the various annealing temperatures was observed with the 27F primer, with no mismatches with the target sequences. The number of PCR cycles had little influence on the template-to-product ratios. As a result of additional tests on environmental samples, the use of a low annealing temperature is recommended in order to significantly reduce preferential amplification while maintaining the specificity of PCR.