Rapid cycle DNA amplification: time and temperature optimization

Rapid temperature cycling with hot air allows rigorous optimization of the times and temperatures required for each stage of the polymerase chain reaction. A thermal cycler based on recirculating hot air was used for rapid temperature control of 10-microliters samples in thin glass capillary tubes with the sample temperature monitored by a miniature thermocouple probe. The temperatures and times of denaturation, annealing and elongation were individually optimized for the amplification of a 536-base pair beta-globin fragment from human genomic DNA. Optimal denaturation at 92 degrees-94 degrees C occurred in less than one second; yield decreased with denaturation times greater than 30 seconds. Annealing for one second or less at 54 degrees-56 degrees C gave the best product specificity and yield. Non-specific amplification was minimized with a rapid denaturation to annealing temperature transition (9 seconds) as compared to a longer transition (25 seconds). An elongation temperature of 75 degrees-79 degrees C gave the greatest yield and increased yields were obtained with longer elongation times. Product specificity was improved with rapid air cycling when compared to slower conventional heat block cycling. Rapid thermal control of the temperature-dependent reactions in DNA amplification can improve product specificity significantly while decreasing the required amplification time by an order of magnitude.     

重组酶聚合酶扩增技术检测结核分枝杆菌

目的 利用重组酶聚合酶扩增（Recombinase Polymerase Amplification,RPA）技术检测结核分支杆菌。方法 采用Axxin T8-ISO扩增仪（TwistDX公司）,反应温度设置为39℃,反应时间20 min。检测分为实验组、阳性对照组和空白对照组。实验组模板DNA从痰液中提取。阳性对照模板DNA为H37Rv标准菌株样本DNA及卡介苗提取的DNA。空白对照为蒸馏水。结果 RPA技术可在20 min内明显区分103~106 copies/mL的阳性质粒与阴性对照。对分离培养的结核杆菌（H37Rv）DNA及卡介苗提取的DNA,阳性克隆质粒进行等温扩增,结果结核杆菌分离株DNA、卡介苗DNA、阳性克隆质粒均有阳性扩增反应,而非结核分枝杆菌分离株和阴性对照无阳性扩增反应。灵敏度为100%,特异性为82%。结论 RPA技术利用了重组酶、单链结合蛋白、DNA聚合酶代替了传统PCR变性、退火、延伸的热循环过程,在常温25℃~42℃、15~30 min内即可实现痕量核酸的快速扩增,可应用于快速检测人结核分枝杆菌,是一种全新的检测方法。     

Rapid DNA amplification in a capillary tube by natural convection with a single isothermal heater

Herein we describe a simple platform for rapid DNA amplification using convection. Capillary convective PCR (CCPCR) heats the bottom of a capillary tube using a dry bath maintained at a fixed temperature of 95°C. The tube is then cooled by the surrounding air, creating a temperature gradient in which a sample can undergo PCR amplification by natural convection through reagent circulation. We demonstrate that altering the melting temperature of the primers relative to the lowest temperature in the tube affects amplification efficiency; adjusting the denaturation temperature of the amplicon relative to the highest temperature in the tube affects maximum amplicon size, with amplicon lengths of ≤500 bp possible. Based on these criteria, we successfully amplified DNA sequences from three different viral genomes in 30 min using CCPCR, with a sensitivity of ~30 copies per reaction.     

Selective delivery of interleukine-1 receptor antagonist to inflamed joint by albumin fusion

Background

There is an increasing need for quantitative technologies suitable for molecular detection in a variety of settings for applications including food traceability and monitoring of genetically modified (GM) crops and their products through the food processing chain. Conventional molecular diagnostics utilising real-time polymerase chain reaction (RT-PCR) and fluorescence-based determination of amplification require temperature cycling and relatively complex optics. In contrast, isothermal amplification coupled to a bioluminescent output produced in real-time (BART) occurs at a constant temperature and only requires a simple light detection and integration device.

Results

Loop mediated isothermal amplification (LAMP) shows robustness to sample-derived inhibitors. Here we show the applicability of coupled LAMP and BART reactions (LAMP-BART) for determination of genetically modified (GM) maize target DNA at low levels of contamination (0.1-5.0% GM) using certified reference material, and compare this to RT-PCR. Results show that conventional DNA extraction methods developed for PCR may not be optimal for LAMP-BART quantification. Additionally, we demonstrate that LAMP is more tolerant to plant sample-derived inhibitors, and show this can be exploited to develop rapid extraction techniques suitable for simple field-based qualitative tests for GM status determination. We also assess the effect of total DNA assay load on LAMP-BART quantitation.

Conclusions

LAMP-BART is an effective and sensitive technique for GM detection with significant potential for quantification even at low levels of contamination and in samples derived from crops such as maize with a large genome size. The resilience of LAMP-BART to acidic polysaccharides makes it well suited to rapid sample preparation techniques and hence to both high throughput laboratory settings and to portable GM detection applications. The impact of the plant sample matrix and genome loading within a reaction must be controlled to ensure quantification at low target concentrations.     

PCR with 5-methyl-dCTP replacing dCTP.

When dCTP is replaced by methyl5-dCTP in the polymerase chain reaction some templates cannot be efficiently amplified by Taq polymerase or Vent polymerase using standard cycling parameters. However, this phenomenon can be overcome by increasing the temperature of the denaturation steps to 100 degrees C, or by adding dITP to destabilize the m5dC:dG base pairs. Once the block to amplification of m5dC-substituted DNA was overcome, methylated DNA from the 'superpolylinker' of the plasmid pSL 1180 was used as a substrate to check the methyl-sensitivity of a variety of restriction endonucleases. The m5dC-substituted DNAs should also be valuable substrates for defining the specificity of methyl-dependent endonucleases.     

Development of a temperature sensor array chip and a chip-based real-time PCR machine for DNA amplification efficiency-based quantification

A temperature sensor array chip was developed to monitor the thermal cycling profiles of a polymerase chain reaction (PCR). DNA amplification efficiency of each cycle was estimated through temperature data to fit the stochastic model. A fluorescence detector system was constructed to detect the PCR amplifications of latter cycles, at which the fluorescence intensity passed the optical detection threshold. Through monitoring of both temperature and fluorescence, DNA amplification efficiency curve was completed for quantification. The F?rster resonance energy transfer (FRET) was employed to detect the measurements of the PCR product amount at the reaction endpoint. The chip-based, real-time PCR machine was constructed to perform the amplification efficiency curve-based quantification method. This novel method achieved the absolute quantification of the Hepatitis B virus (HBV) DNA using a single sample without the construction of the standard curve. The coefficient of variation (CV) of the 15 replicates inter assay experiments was less than 5.87%. Compared with the CV values obtained from the commercial machine in the range of 4.33-14.56%, it is noted that CV values of the prototype with respect to the samples of different initial concentration ranging from 10(7) to 10(3)copies/ml are almost equable.     

免疫胶体金法提取环境标本中细菌DNA技术

将抗-DNA单克隆抗体标记在胶体金颗粒上制成免疫胶体金试剂,提取标本中DNA,直接用于PCR检测,从而建立一种简单、快速、高效的免疫胶体金方法提取环境标本中的DNA。结果表明：应用免疫胶体金试剂可有效去除环境标本中PCR抑制剂,浓缩模板,提高PCR检测敏感度3～4个数量级。操作步骤简单,无需使用有机溶剂,避免环境污染,吸附了DNA的免疫胶体金可直接用于PCR扩增。研制了免疫胶体金试剂并确定其最佳反应条件,有效提高PCR技术在检测现场环境标本中的敏感性和实用性。     

DNA detection using recombination proteins

DNA amplification is essential to most nucleic acid testing strategies, but established techniques require sophisticated equipment or complex experimental procedures, and their uptake outside specialised laboratories has been limited. Our novel approach, recombinase polymerase amplification (RPA), couples isothermal recombinase-driven primer targeting of template material with strand-displacement DNA synthesis. It achieves exponential amplification with no need for pretreatment of sample DNA. Reactions are sensitive, specific, and rapid and operate at constant low temperature. We have also developed a probe-based detection system. Key aspects of the combined RPA amplification/detection process are illustrated by a test for the pathogen methicillin-resistant Staphylococcus aureus. The technology proves to be sensitive to fewer than ten copies of genomic DNA. Furthermore, products can be detected in a simple sandwich assay, thereby establishing an instrument-free DNA testing system. This unique combination of properties is a significant advance in the development of portable and widely accessible nucleic acid–based tests.     

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).     

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.     

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.     

重组酶聚合酶扩增技术结合侧向流动试纸条快速检测锦鲤疱疹病毒

为建立一种快速、灵敏并适用于临床检测Ⅲ型鲤疱疹病毒(Cy HV-3, KHV)的方法,实验根据KHV SphI-5基因的保守序列片段设计引物及探针,采用重组酶聚合酶扩增技术结合侧流层析试纸条(RPA-LFD)检测KHV。重组酶聚合酶扩增技术(RPA)具恒温扩增及高灵敏度特点,简化了设备要求的同时又能做到高效检测病毒,再结合侧向流动试纸条(LFD)将RPA结果快速地可视化,提高了该疾病的检测效率。结果表明,在38℃的最适反应温度下,采用RPA-AGE技术仅需10min便可检测出病原的目标片段,结合LFD方法仅需5min便可将RPA结果通过试纸条可视化呈现。研究研发的KHV RPA-LFD检测方法简单、快捷,可为实验条件有限的养殖场快速诊断需求提供技术支撑。     

In situ polymerase chain reaction and cycling primed in situ amplification: improvements and adaptations

 Ethanol fixation combined with microwave pretreatment allows rapid and simple detection of signals produced by cycling primed in situ (PRINS) amplification, which uses a single primer, and in situ polymerase chain reaction (ISPCR) in intact cells. After thermal cycling, signals remain as discrete subnuclear spots in the region of amplification and are clearly distinguishable from non-specific background labelling. These methods are applicable to routine blood smears, even after Giemsa staining or immunocytochemistry, and cellular morphology is retained. Chromosome enumeration by cycling PRINS is demonstrated using primers for repeat DNA sequences, whilst single copy sequence detection is demonstrated using bcl-2, CFTR and chromosome 21 specific primer pairs in ISPCR. We show that ethanol fixation supports efficient extension of cycling PRINS products to approximately 550 bp using up to 70 rounds of thermal cycling. Accepted: 15 February 1999     

A rapid and efficient one-tube PCR-based mutagenesis technique using Pfu DNA polymerase.

A rapid method for efficiently generating site-directed mutations on a clean sequence background is described. This modification of the megaprimer PCR mutagenesis approach can be performed in one tube in less than 4.5 hours, and does not require purification of intermediate products. High fidelity of DNA sequence replication is obtained by employing Pfu DNA polymerase and limiting the total number of amplification cycles to 30. The mutagenesis efficiency of the procedure is high enough to allow rapid, direct identification of mutants by restriction digest or sequencing techniques.     

PCR amplification using electrolytic resistance for heating and temperature monitoring

An alternative method of rapid-cycle PCR for DNA amplification is demonstrated using electrolyte resistance for heating and temperature monitoring. The PCR amplification solution is electrically conductive and can be heated by passing an alternating current through the sample. The temperature of the solution is evaluated by monitoring its electrical resistance. Cooling is accomplished by forced air convection at ambient temperature. Heating and cooling rates of up to 20 degrees C/s were achieved. The 35 cycles of PCR were completed in less than 12 min with product yields equivalent to conventional temperature cycling. Electrolyte resistance provides a method for both direct heating and monitoring the temperature of PCR samples.     

Fluorescence-based temperature control for polymerase chain reaction

The ability to accurately monitor solution temperature is important for the polymerase chain reaction (PCR). Robust amplification during PCR is contingent on the solution reaching denaturation and annealing temperatures. By correlating temperature to the fluorescence of a passive dye, noninvasive monitoring of solution temperatures is possible. The temperature sensitivity of 22 fluorescent dyes was assessed. Emission spectra were monitored and the change in fluorescence between 45 and 95 °C was quantified. Seven dyes decreased in intensity as the temperature increased, and 15 were variable depending on the excitation wavelength. Sulforhodamine B (monosodium salt) exhibited a fold change in fluorescence of 2.85. Faster PCR minimizes cycling times and improves turnaround time, throughput, and specificity. If temperature measurements are accurate, no holding period is required even at rapid speeds. A custom instrument using fluorescence-based temperature monitoring with dynamic feedback control for temperature cycling amplified a fragment surrounding rs917118 from genomic DNA in 3 min and 45 s using 35 cycles, allowing subsequent genotyping by high-resolution melting analysis. Gold-standard thermocouple readings and fluorescence-based temperature differences were 0.29 ± 0.17 and 0.96 ± 0.26 °C at annealing and denaturation, respectively. This new method for temperature cycling may allow faster speeds for PCR than currently considered possible.     

Rapid SNP diagnostics using asymmetric isothermal amplification and a new mismatch-suppression technology

We developed a rapid single nucleotide polymorphism (SNP) detection system named smart amplification process version 2 (SMAP 2). Because DNA amplification only occurred with a perfect primer match, amplification alone was sufficient to identify the target allele. To achieve the requisite fidelity to support this claim, we used two new and complementary approaches to suppress exponential background DNA amplification that resulted from mispriming events. SMAP 2 is isothermal and achieved SNP detection from whole human blood in 30 min when performed with a new DNA polymerase that was cloned and isolated from Alicyclobacillus acidocaldarius (Aac pol). Furthermore, to assist the scientific community in configuring SMAP 2 assays, we developed software specific for SMAP 2 primer design. With these new tools, a high-precision and rapid DNA amplification technology becomes available to aid in pharmacogenomic research and molecular-diagnostics applications.     

DNA amplification in the field: move over PCR,here comes LAMP

It would not be an exaggeration to say that among molecular technologies, it is PCR (polymerase chain reaction) that underpins the discipline of molecular ecology as we know it today. With PCR, it has been possible to target the amplification of particular fragments of DNA, which can then be analysed in a multitude of ways. The capability of PCR to amplify DNA from a mere handful of copies further means that conservationists and ecologists are able to sample DNA unobtrusively and with minimal disturbance to the environment and the organisms of interest. However, a key disadvantage of PCR‐based methods has been the necessity for a generally non‐portable, laboratory setting to undertake the time‐consuming thermocycling protocols. LAMP (loop‐mediated isothermal amplification) offers a logistically simpler protocol: a relatively rapid DNA amplification reaction occurs at one temperature, and the products are visualized with a colour change within the reaction tubes. In the first field application of LAMP for an ecological study, Centeno‐Cuadros et al. ( 2016 ) demonstrates how LAMP can be used to determine the sex of three raptor species. By enabling DNA amplification in situ and in ‘real‐time’, LAMP promises to revolutionize how molecular ecology is practised in the field.     

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.