Sequence-Dependent Biophysical Modeling of DNA Amplification

A theoretical framework for prediction of the dynamic evolution of chemical species in DNA amplification reactions, for any specified sequence and operating conditions, is reported. Using the polymerase chain reaction (PCR) as an example, we developed a sequence- and temperature-dependent kinetic model for DNA amplification using first-principles biophysical modeling of DNA hybridization and polymerization. We compare this kinetic model with prior PCR models and discuss the features of our model that are essential for quantitative prediction of DNA amplification efficiency for arbitrary sequences and operating conditions. Using this model, the kinetics of PCR is analyzed. The ability of the model to distinguish between the dynamic evolution of distinct DNA sequences in DNA amplification reactions is demonstrated. The kinetic model is solved for a typical PCR temperature protocol to motivate the need for optimization of the dynamic operating conditions of DNA amplification reactions. It is shown that amplification efficiency is affected by dynamic processes that are not accurately represented in the simplified models of DNA amplification that form the basis of conventional temperature cycling protocols. Based on this analysis, a modified temperature protocol that improves PCR efficiency is suggested. Use of this sequence-dependent kinetic model in a control theoretic framework to determine the optimal dynamic operating conditions of DNA amplification reactions, for any specified amplification objective, is discussed.     

Modeling DNA mutation and recombination for directed evolution experiments

Directed evolution experiments rely on the cyclical application of mutagenesis, screening and amplification in a test tube. They have led to the creation of novel proteins for a wide range of applications. However, directed evolution currently requires an uncertain, typically large, number of labor intensive and expensive experimental cycles before proteins with improved function are identified. This paper introduces predictive models for quantifying the outcome of the experiments aiding in the setup of directed evolution for maximizing the chances of obtaining DNA sequences encoding enzymes with improved activities. Two methods of DNA manipulation are analysed: error-prone PCR and DNA recombination. Error-prone PCR is a DNA replication process that intentionally introduces copying errors by imposing mutagenic reaction conditions. The proposed model calculates the probability of producing a specific nucleotide sequence after a number of PCR cycles. DNA recombination methods rely on the mixing and concatenation of genetic material from a number of parent sequences. This paper focuses on modeling a specific DNA recombination protocol, DNA shuffling. Three aspects of the DNA shuffling procedure are modeled: the fragment size distribution after random fragmentation by DNase I, the assembly of DNA fragments, and the probability of assembling specific sequences or combinations of mutations. Results obtained with the proposed models compare favorably with experimental data.     

Localised sequence regions possessing high melting temperatures prevent the amplification of a DNA mimic in competitive PCR.

The polymerase chain reaction is an immensely powerful technique for identification and detection purposes. Increasingly, competitive PCR is being used as the basis for quantification. However, sequence length, melting temperature and primary sequence have all been shown to influence the efficiency of amplification in PCR systems and may therefore compromise the required equivalent co-amplification of target and mimic in competitive PCR. The work discussed here not only illustrates the need to balance length and melting temperature when designing a competitive PCR assay, but also emphasises the importance of careful examination of sequences for GC-rich domains and other sequences giving rise to stable secondary structures which could reduce the efficiency of amplification by serving as pause or termination sites. We present data confirming that under particular circumstances such localised sequence, high melting temperature regions can act as permanent termination sites, and offer an explanation for the severity of this effect which results in prevention of amplification of a DNA mimic in competitive PCR. It is also demonstrated that when Taq DNA polymerase is used in the presence of betaine or a proof reading enzyme, the effect may be reduced or eliminated.     

Integrated method for single-cell DNA extraction, PCR amplification, and sequencing of ribosomal DNA from harmful dinoflagellates Cochlodinium polykrikoides and Alexandrium catenella

A simplified technique was developed for DNA sequence-based diagnosis of harmful dinoflagellate species. This protocol integrates procedures for DNA extraction and polymerase chain reaction (PCR) amplification into a single tube. DNA sequencing reactions were performed directly, using unpurified PCR products as the DNA template for subsequent sequencing reactions. PCR reactions using DNA extracted from single cells of Cocodinium polykrikoides and Alexandrium catenella successfully amplified the target ribosomal DNA regions. DNA sequencing of the unpurified PCR products showed that DNA sequences corresponded to the expected locus of ribosomal DNA regions of both A. catenella and C. polykrikoides (each zero genetic distance and 100% sequence similarity). Using the protocol described in this article, there was little DNA loss during the purification step, and the technique was found to be rapid and inexpensive. This protocol clearly resolves the taxonomic ambiguities of closely related algal species (such as Alexandrium and Cochlodinium), and it constitutes a significant breakthrough for the molecular analysis of nonculturable dinoflagellate species.     

Dideoxy linear PCR on a commercial fluorescent automated DNA sequencer.

The use of automated fluorescent DNA sequencer systems and PCR-based DNA sequencing methods play an important role in the actual effort to improve the efficiency of large-scale DNA analysis. Here we show the application of the linear PCR using a single fluorescent primer and dideoxynucleotide terminators in four separate sequencing reactions on the EMBL/Pharmacia's fluorescent automated DNA sequencer. We have used dideoxy/deoxynucleoside triphosphate ratios and linear amplification cycle conditions to obtain an accurate sequencing response of up to, and over, 500 bases from just 400 ng of double-stranded DNA template without chemical denaturation. The sequencing protocol described in this paper is effectively suited for enhancement of sensitivity and performance of the automated DNA sequencing system.     

Emulsion PCR: a high efficient way of PCR amplification of random DNA libraries in aptamer selection

Aptamers are short RNA or DNA oligonucleotides which can bind with different targets. Typically, they are selected from a large number of random DNA sequence libraries. The main strategy to obtain aptamers is systematic evolution of ligands by exponential enrichment (SELEX). Low efficiency is one of the limitations for conventional PCR amplification of random DNA sequence library in aptamer selection because of relative low products and high by-products formation efficiency. Here, we developed emulsion PCR for aptamer selection. With this method, the by-products formation decreased tremendously to an undetectable level, while the products formation increased significantly. Our results indicated that by-products in conventional PCR amplification were from primer-product and product-product hybridization. In emulsion PCR, we can completely avoid the product-product hybridization and avoid the most of primer-product hybridization if the conditions were optimized. In addition, it also showed that the molecule ratio of template to compartment was crucial to by-product formation efficiency in emulsion PCR amplification. Furthermore, the concentration of the Taq DNA polymerase in the emulsion PCR mixture had a significant impact on product formation efficiency. So, the results of our study indicated that emulsion PCR could improve the efficiency of SELEX.     

QuantiLyse: reliable DNA amplification from single cells

Amplification of DNA sequencesfrom single cells via PCR is increasingly used in basic research and clinical diagnostics but remains technically difficult. We have developed a cell lysis protocol that uses an optimized proteinase K solution, named QuantiLyse and permits reliable amplification from individual cells. This protocol was compared to other published methods by means of real-time PCR with molecular beacons. The results demonstrate that QuantiLyse treatment of single lymphocytes renders gene targets more availablefor amplification than other published proteinase K methods or lysis in water. QuantiLyse and an optimized alkaline lysis were equally effective in terms of target availability, although QuantiLyse offers greaterflexibility, as it does not require neutralization and can comprise a higher percentage of the final PCR volume. Maximum gene target availability is also obtained following QuantiLyse treatment of samples containing up to 10000 cells (the largest number tested). Thus, QuantiLyse maximizes the chances that targeted DNA sequences will be available for amplification during the first cycle of PCR, thereby reducing the variability among replicate reactions as well as the likelihood of amplification failure or allele drop-out. QuantiLyse will be useful in a range of investigations aimed at gene detection in small numbers of cells.     

Optimal conditions to use Pfu exo(-) DNA polymerase for highly efficient ligation-mediated polymerase chain reaction protocols

Ligation-Mediated Polymerase Chain Reaction (LMPCR) is the most sensitive sequencing technique available to map single-stranded DNA breaks at the nucleotide level of resolution using genomic DNA. LMPCR has been adapted to map DNA damage and reveal DNA-protein interactions inside living cells. However, the sequence context (GC content), the global break frequency and the current combination of DNA polymerases used in LMPCR affect the quality of the results. In this study, we developed and optimized an LMPCR protocol adapted for Pyrococcus furiosus exo(-) DNA polymerase (Pfu exo(-)). The relative efficiency of Pfu exo(-) was compared to T7-modified DNA polymerase (Sequenase 2.0) at the primer extension step and to Thermus aquaticus DNA polymerase (Taq) at the PCR amplification step of LMPCR. At all break frequencies tested, Pfu exo(-) proved to be more efficient than Sequenase 2.0. During both primer extension and PCR amplification steps, the ratio of DNA molecules per unit of DNA polymerase was the main determinant of the efficiency of Pfu exo(-), while the efficiency of Taq was less affected by this ratio. Substitution of NaCl for KCl in the PCR reaction buffer of Taq strikingly improved the efficiency of the DNA polymerase. Pfu exo(-) was clearly more efficient than Taq to specifically amplify extremely GC-rich genomic DNA sequences. Our results show that a combination of Pfu exo(-) at the primer extension step and Taq at the PCR amplification step is ideal for in vivo DNA analysis and DNA damage mapping using LMPCR.     

Detection of polychlorinated biphenyl degradation genes in polluted sediments by direct DNA extraction and polymerase chain reaction.

It was the aim of this study to specifically detect the DNA sequences for the bphC gene, the meta-cleavage enzyme of the aerobic catabolic pathway for biphenyl and polychlorinated biphenyl degradation, in aquatic sediments without prior cultivation of microorganisms by using extraction of total DNA, PCR amplification of bphC sequences, and detection with specific gene probes. The direct DNA extraction protocol used was modified to enhance lysis efficiency. Crude extracts of DNA were further purified by gel filtration, which yielded DNA that could be used for the PCR. PCR primers were designed for conserved regions of the bphC gene from a sequence alignment of five known sequences. The specificity of PCR amplification was verified by using digoxigenin-labeled DNA probes which were located internal to the amplified gene sequence. The detection limit for the bphC gene of Pseudomonas paucimobilis Q1 and Pseudomonas sp. strain LB400 was 100 cells per g (wet weight) or approximately five copies of the target sequence per PCR reaction mixture. In total-DNA extracts of aerobic top layers of sediment samples obtained from three different sampling sites along the Elbe River, which has a long history of anthropogenic pollution, Pseudomonas sp. strain LB 400-like sequences for the bphC gene were detected, but P. paucimobilis Q1 sequences were not detected. No bphC sequences were detected in an unpolluted lake sediment. A restriction analysis did not reveal any heterogeneity in the PCR product, and the possibility that sequences highly related to the bphC gene (namely, nahC and todE) were present was excluded.(ABSTRACT TRUNCATED AT 250 WORDS)     

Chromosomal walking of flanking regions from short known sequences in GC-rich plant genomic DNA

High-efficiency thermal asymmetric interlaced (HE-TAIL) PCR is a modified thermal asymmetric interlaced (TAIL) method for finding unknown genomic DNA sequences adjacent to known sequences in GC-rich plant DNA. Necessary modifications to obtain high-efficiency amplification of flanking sequences are the inclusion of 2 control reactions during tertiary cycling and the design of long gene-specific primers, which can be used during single-step annealing-extension PCR. The modified protocol is suitable to walk from short known sequences, such as sequence-tagged sites (STS), expressed sequence tags (EST), or short exon sequences, and enables researchers to clone full-length open reading frames (ORFs) without library screening. Moreover, the HE-TAIL method can be used to identify DNA sequences flanking T-DNA insertions or to isolate promoter regions. Although individual steps are limited to about 4 kb, multiple steps can be done to walk upstream or downstream of known regions.     

Chimerism analysis in sex-mismatched murine transplantation using quantitative real-time PCR

Marine experimental stem cell transplantations require the accurate discrimination and quantification of donor cells from host cells. A Y-chromosome-specific, quantitative real-time PCR (kinetic PCR) protocol for blood-derived DNA was developed. The assay sensitivity was extremely high with accurate detection of only 10 pg (six copies of Y target DNA) in a variable background of female DNA background ranging from 2.5 to 50 ng. The dynamic range of the assay provided accurate results ranging from 2.2 x 10(-2)% to 100% of male DNA in female background. The kinetic PCR assay can be used in all mouse strains, and a sample size as low as 2.5 ng total DNA is sufficient for analysis. Therefore, kinetic PCR allows engraftment kinetic studies on repeated blood draws of individual animals with no need for sacrifice. Compared to conventional PCR, the assay is much simplified, as neither the accurate adjustment of sample DNA concentration nor a post-reaction analysis procedure is required. The procedure is simple, free of radioactivity, and permits a throughput of 500-600 reactions per day.     

Real-time monitoring of the strand displacement amplification (SDA) of human cytomegalovirus by a new SDA-piezoelectric DNA sensor system

Nucleic acid amplification has long been used in biosensor technologies, such as DNA sensors, DNA chips and microarrays, due to its advantage of high sensitivity in detecting target DNA. However, dynamic monitoring of nucleic acid amplifications with traditional DNA sensors in real-time is difficult since a constant temperature must be maintained during detection. Thus, the piezoelectric sensor, one type of traditional DNA sensor, is not applicable in real-time monitoring PCR due to the dramatic change in temperature that occurs during reaction. In this study, we introduced strand displacement amplification (SDA), an well-developed nucleic acid amplification technique that can work under conditions of constant temperature, into the development of a novel piezoelectric sensor. Using the new SDA-piezoelectric DNA sensor, we designed a stable system for liquid-phase detection, in which the crystal oscillator plate was fixed by an easily adjustable screw-threaded clamping mechanism and successfully applied the new sensor system to real-time SDA monitoring of human cytomegalovirus (HCMV). This new technique overcomes the shortcomings of traditional DNA sensors in real-time monitoring of nucleic acid amplification. The technique has proved to be a markedly simplified procedure with a number of advantages, such as higher sensitivity, better time efficiency, and the ability of dynamic real-time detection.     

利用Taq DNA聚合酶对PCR产物直接进行顺序分析

Taq DNA聚合酶具有反应速度快、温度作用范围广及良好的续进性等特点,可视为一种理想的DNA顺序分析酶。本文首先对非对称性PCR扩增过程中单、双链DNA产物的积累情况进行了分析,然后采用标记延伸二步法,对Taq DNA聚合酶的性质及影响因素进行分析。为进一步改进Taq DNA聚合酶测序的方法,本反应建立了“Klenow-型”的直接掺入标记同位素测序法,即在反应液中加入与标记核苷酸相应的一定浓度的冷dNTP。此法不但解决了二步法中引物后部分DNA顺序无法读出的缺点,而且简化了反应步骤,亦能得到令人满意的顺序分析结果,每次可读出至少400碱基的序列。     

Single primer-mediated polymerase chain reaction: application in cloning of two different 5'-untranslated sequences of acidic fibroblast growth factor mRNA.

Polymerase chain reactions (PCR) are used to generate specific DNA sequences from minute amounts of DNA templates using a pair of oligonucleotide primers. To amplify regions of unknown sequence, methods such as inverted PCR, Alu PCR, and rapid amplification of cDNA ends (RACE) have been developed. These methods require several enzymatic manipulations of DNA which are either tedious or only suitable for certain special conditions. We have explored the possibility of PCR using a single primer. This method takes advantage of the fact that partial complementarity provides sufficient affinity for the oligonucleotide primer to anneal to a secondary, imperfect binding site. Thus, no modification of DNA template was required for the single primer-mediated PCR. We have used this method to generate two different aFGF cDNA clones containing different 5'-untranslated sequences.     

Experimental analysis of gene assembly with TopDown one-step real-time gene synthesis

Herein we present a simple, cost-effective TopDown (TD) gene synthesis method that eliminates the interference between the polymerase chain reactions (PCR) assembly and amplification in one-step gene synthesis. The method involves two key steps: (i) design of outer primers and assembly oligonucleotide set with a melting temperature difference of >10°C and (ii) utilization of annealing temperatures to selectively control the efficiencies of oligonucleotide assembly and full-length template amplification. In addition, we have combined the proposed method with real-time PCR to analyze the step-wise efficiency and the kinetics of the gene synthesis process. Gel electrophoresis results are compared with real-time fluorescence signals to investigate the effects of oligonucleotide concentration, outer primer concentration, stringency of annealing temperature, and number of PCR cycles. Analysis of the experimental results has led to insights into the gene synthesis process. We further discuss the conditions for preventing the formation of spurious DNA products. The TD real-time gene synthesis method provides a simple and efficient method for assembling fairly long DNA sequence, and aids in optimizing gene synthesis conditions. To our knowledge, this is the first report that utilizes real-time PCR for gene synthesis.     

Multiple displacement amplification as a pre-polymerase chain reaction (pre-PCR) to process difficult to amplify samples and low copy number sequences from natural environments

Microbial assessment of natural biodiversity is usually achieved through polymerase chain reaction (PCR) amplification. Deoxyribonucleic acid (DNA) sequences from natural samples are often difficult to amplify because of the presence of PCR inhibitors or to the low number of copies of specific sequences. In this study, we propose a non-specific preamplification procedure to overcome the presence of inhibitors and to increase the number of copies prior to carrying out standard amplification by PCR. The pre-PCR step is carried out through a multiple displacement amplification (MDA) technique using random hexamers as priming oligonucleotides and phi 29 DNA polymerase in an isothermal, whole-genome amplification reaction. Polymerase chain reaction amplification using specific priming oligonucleotides allows the selection of the sequences of interest after a preamplification reaction from complex environmental samples. The procedure (MDA-PCR) has been tested on a natural microbial community from a hypogean environment and laboratory assemblages of known bacterial species, in both cases targeting the small subunit ribosomal RNA gene sequences. Results from the natural community showed successful amplifications using the two steps protocol proposed in this study while standard, direct PCR amplification resulted in no amplification product. Amplifications from a laboratory assemblage by the two-step proposed protocol were successful at bacterial concentrations >or= 10-fold lower than standard PCR. Amplifications carried out in the presence of different concentrations of fulvic acids (a soil humic fraction) by the MDA-PCR protocol generated PCR products at concentrations of fulvic acids over 10-fold higher than standard PCR amplifications. The proposed procedure (MDA-PCR) opens the possibility of detecting sequences represented at very low copy numbers, to work with minute samples, as well as to reduce the negative effects on PCR amplifications of some inhibitory substances commonly found in environmental samples.     

Improved high-throughput sunflower and cotton genomic DNA extraction and PCR fidelity

The extraction of high-quality genomic DNA for PCR amplification from sunflower (Helianthus annuus) and cotton (Gossypium spp.) is challenging because of the presence of polysaccharides, secondary metabolites, and polyphenolics in the tissues. A high-throughput DNA extraction protocol was needed in our laboratory for simple sequence repeats (SSR)-marker screening and other molecular analyses that do not require organic extraction steps of phenol or chloroform. Here we describe 2 improved highthroughput protocols for DNA extraction and in-PCR modification that result in successful PCR amplification of sunflower and cotton. While the sunflower DNA extraction protocol uses reducing agents such as sodium metabisulfite and dithiothreitol (DTT), the cotton protocol uses polyvinylpyrrolidone (PVP) in PCR reactions and reducing agents in the DNA extraction procedure.