核酸恒温扩增技术研究进展

核酸恒温扩增技术在生命科学研究及相关诸多领域已经得到了广泛应用。我们对核酸恒温扩增技术的最新进展作一简要综述,包括环介导恒温扩增、链替代扩增、依赖核酸序列的扩增、滚环扩增、切口酶核酸恒温扩增、依赖解旋酶的恒温扩增、转录依赖的扩增、杂交捕获法、转录介导的扩增等的原理、优缺点及应用。     

Helicase-dependent isothermal DNA amplification

Polymerase chain reaction is the most widely used method for in vitro DNA amplification. However, it requires thermocycling to separate two DNA strands. In vivo, DNA is replicated by DNA polymerases with various accessory proteins, including a DNA helicase that acts to separate duplex DNA. We have devised a new in vitro isothermal DNA amplification method by mimicking this in vivo mechanism. Helicase-dependent amplification (HDA) utilizes a DNA helicase to generate single-stranded templates for primer hybridization and subsequent primer extension by a DNA polymerase. HDA does not require thermocycling. In addition, it offers several advantages over other isothermal DNA amplification methods by having a simple reaction scheme and being a true isothermal reaction that can be performed at one temperature for the entire process. These properties offer a great potential for the development of simple portable DNA diagnostic devices to be used in the field and at the point-of-care.     

Alternative Molecular Tests for Virological Diagnosis

Several nucleic acid amplification techniques (NAATs), particularly PCR and real-time PCR, are currently used in the routine clinical laboratories. Such approaches have allowed rapid diagnosis with a high degree of sensitivity and specificity. However, conventional PCR methods have several intrinsic disadvantages such as the requirement for temperature cycling apparatus, and sophisticated and costly analytical equipments. Therefore, amplification at a constant temperature is an attractive alternative method to avoid these requirements. A new generation of isothermal amplification techniques are gaining a wide popularity as diagnostic tools due to their simple operation, rapid reaction and easy detection. The main isothermal methods reviewed here include loop-mediated isothermal amplification, nucleic acid sequence-based amplification, and helicase-dependent amplification. In this review, design criteria, potential of amplification, and application of these alternative molecular tests will be discussed and compared to conventional NAATs.     

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.     

等温扩增技术及其结合CRISPR在微生物快速检测中的研究进展

等温扩增技术因其对仪器依赖性低、核酸扩增高效等优势,非常适合于快速检测,已在微生物快速检测领域得到了广泛应用。本文从核酸提取、等温扩增(以环介导等温扩增技术(Loop-mediated isothermal amplification,LAMP)和重组酶聚合酶扩增技术(Recombinase polymerase amplification,RPA)为例)和产物检测角度,就近年来核酸等温扩增技术的发展及其在病原微生物核酸快速检测领域的应用进行综述,并概述了核酸等温扩增技术与CRISPR(Clustered regularly interspaced short palindromic repeats)基因编辑技术相结合的最新研究成果,为这些新兴技术的研究和未来的发展提供新思路。     

链替代扩增反应研究进展

链替代扩增反应作为一种体外恒温酶控扩增体系,主要基于限制酶打开缺口和无外切酶活性的DNA聚合酶的聚合替代的原理,随着该反应体系各环节的不断改进,目前该方法已应用于细菌尤其是分枝杆菌DNA的检测、体外进化模型的建立、核酸定量及芯片杂交等多个方面。     

One new method of nucleic acid amplification—Loop-mediated isothermal amplification of DNA

Loop-mediated isothermal amplification (LAMP) is a novel nucleic acid amplification method, which amplifies DNA with high specificity, sensitivity, rapidity and efficiency under isothermal conditions using a set of four specially designed primers and a Bst DNA polymerase with strand displacement activity. The basic principle, characteristics, development of LAMP and its applications are summarized in this article.     

One New Method of Nucleic Acid Amplification-Loop-mediated Isothermal Amplification of DNA

Loop-mediated isothermal amplification (LAMP) is a novel nucleic acid amplification method, which amplifies DNA with high specificity, sensitivity, rapidity and efficiency under isothermal conditions using a set of four specially designed primers and a Bst DNA polymerase with strand displacement activity. The basic principle, characteristics, development of LAMP and its applications are summarized in this article.     

Molecular Detection, Quantification, and Diversity Evaluation of Microalgae

This study reviews the available molecular methods and new high-throughput technologies for their practical use in the molecular detection, quantification, and diversity assessment of microalgae. Molecular methods applied to other groups of organisms can be adopted for microalgal studies because they generally detect universal biomolecules, such as nucleic acids or proteins. These methods are primarily related to species detection and discrimination among various microalgae. Among current molecular methods, some molecular tools are highly valuable for small-scale detection [e.g., single-cell polymerase chain reaction (PCR), quantitative real-time PCR (qPCR), and biosensors], whereas others are more useful for large-scale, high-throughput detection [e.g., terminal restriction length polymorphism, isothermal nucleic acid sequence-based amplification, loop-mediated isothermal amplification, microarray, and next generation sequencing (NGS) techniques]. Each molecular technique has its own strengths in detecting microalgae, but they may sometimes have limitations in terms of detection of other organisms. Among current technologies, qPCR may be considered the best method for molecular quantification of microalgae. Metagenomic microalgal diversity can easily be achieved by 454 pyrosequencing rather than by the clone library method. Current NGS, third and fourth generation technologies pave the way for the high-throughput detection and quantification of microalgal diversity, and have significant potential for future use in field monitoring.     

食源性病毒核酸恒温检测技术研究进展

食源性病毒已成为全球引发食品安全事件的重要病原,对新型检测技术的不断发展提出了严峻的挑战.早期PCR技术在病原检测领域中的应用,推动了对食源性病毒的全面认识.近年来核酸恒温检测技术发展迅速,包括环介导等温扩增技术、重组酶聚合酶扩增技术、核酸序列依赖性扩增技术、链置换扩增技术、滚环扩增技术等,在抗复杂基质干扰、装备要求低...     

Libraries for genomic SELEX.

An increasing number of proteins are being identified that regulate gene expression by binding specific nucleic acidsin vivo. A method termed genomic SELEX facilitates the rapid identification of networks of protein-nucleic acid interactions by identifying within the genomic sequences of an organism the highest affinity sites for any protein of the organism. As with its progenitor, SELEX of random-sequence nucleic acids, genomic SELEX involves iterative binding, partitioning, and amplification of nucleic acids. The two methods differ in that the variable region of the nucleic acid library for genomic SELEX is derived from the genome of an organism. We have used a quick and simple method to construct Escherichia coli, Saccharomyces cerevisiae, and human genomic DNA PCR libraries that can be transcribed with T7 RNA polymerase. We present evidence that the libraries contain overlapping inserts starting at most of the positions within the genome, making these libraries suitable for genomic SELEX.     

环介导等温扩增核酸技术及其应用

环介导等温扩增(loop-mediated isothermal amplification,简称LAMP)是利用4个特殊设计的引物和具有链置换活性的DNA聚合酶,在恒温条件下特异、高效、快速地扩增DNA的新技术。该技术在1h内能扩增出109靶序列拷贝,扩增产物是一系列反向重复的靶序列构成的茎环结构和多环花椰菜样结构的DNA片段的混合物,电泳后在凝胶上显现出由不同大小的区带组成的阶梯式图谱。LAMP技术以其特异性强、灵敏度高、快速、准确和操作简便等优点在核酸的科学研究、疾病的诊断和转基因食品检测等领域得到了日益广泛的应用。     

Modern tools for identification of nucleic acid-binding proteins

Numerous biological mechanisms depend on nucleic acid--protein interactions. The first step to the understanding of these mechanisms is to identify interacting molecules. Knowing one partner, the identification of other associated molecular species can be carried out using affinity-based purification procedures. When the nucleic acid-binding protein is known, the nucleic acid can be isolated and identified by sensitive techniques such as polymerase chain reaction followed by DNA sequencing or hybridization on chips. The reverse identification procedure is less straightforward in part because interesting nucleic acid-binding proteins are generally of low abundance and there are no methods to amplify amino acid sequences. In this article, we will review the strategies that have been developed to identify nucleic acid-binding proteins. We will focus on methods permitting the identification of these proteins without a priori knowledge of protein candidates.     

Amplification of Nucleic Acids by Polymerase Chain Reaction (PCR) and Other Methods and their Applications

Abstract

The in vitro replication of DNA, principally using the polymerase chain reaction (PCR), permits the amplification of defined sequences of DNA. By exponentially amplifying a target sequence, PCR significantly enhances the probability of detecting target gene sequences in complex mixtures of DNA. It also facilitates the cloning and sequencing of genes. Amplification of DNA by PCR and other newly developed methods has been applied in many areas of biological research, including molecular biology, biotechnology, and medicine, permitting studies that were not possible before. Nucleic acid amplification has added a new and revolutionary dimension to molecular biology. This review examines PCR and other in vitro nucleic acid amplification methodologies—examining the critical parameters and variations and their widespread applications—giving the strengths and limitations of these methodologies.     

Multiple strategies to improve sensitivity,speed and robustness of isothermal nucleic acid amplification for rapid pathogen detection

Background  

In the past decades the rapid growth of molecular diagnostics (based on either traditional PCR or isothermal amplification technologies) meet the demand for fast and accurate testing. Although isothermal amplification technologies have the advantages of low cost requirements for instruments, the further improvement on sensitivity, speed and robustness is a prerequisite for the applications in rapid pathogen detection, especially at point-of-care diagnostics. Here, we describe and explore several strategies to improve one of the isothermal technologies, helicase-dependent amplification (HDA).     

环介导等温扩增技术的研究进展

环介导等温扩增(loop-mediated isothermal amplification,LAMP)是一种新式核酸扩增技术,它依靠一种具有链置换活性的DNA聚合酶和2对特殊设计的引物,不需要反复的温度循环和昂贵的仪器设备,在等温条件下即可高效快速地完成扩增反应,目前已广泛应用于细菌、病毒、寄生虫等病原体的检测,及动物胚胎性别的鉴定。该文总结了LAMP技术的基本原理、相对于传统核酸检测技术的优点、产物的检测方法及其临床应用,最后指出LAMP目前存在的不足以及采取的相应措施,并对其发展前景进行了展望。     

Application of nucleic acid amplification in clinical microbiology

The use of nucleic acid amplification methods in routine clinical microbiology laboratories is becoming increasingly widespread. The theory of polymerase chain reaction is described, including discussion of suitable microbal targets, extraction of nucleic acid from clinical samples, choice of primers, optimization of the process, laboratory design, contamination, and other problems as well as quality control. Other nucleic acid amplification methods such as ligase chain reaction, self-sustained sequence replication, strand displacement amplification, and branched DNA signal amplification are described and the choice of technology is discussed.     

环介导等温扩增核酸技术及其在食品安全检测领域的应用

环介导等温扩增(Loop-mediated isothermal amplification,简称LAMP)是利用能识别靶序列上6个位点的4个特殊设计的引物和一种具有链置换活性的DNA聚合酶,在恒温条件下,特异、高效、快速地扩增核酸的新技术。该技术在1h内扩增效率可达到109-1010个数量级,扩增产物是一系列反向重复的靶序列构成的茎环结构和多环花椰菜样结构的DNA片段混合物,电泳后在凝胶上显现出由不同大小的区带组成的阶梯式图谱。近年来LAMP技术以其特异性强、等温灵敏、操作简单、产物易检测等优点已经应用于食品安全检测领域的多个方面。     

Amplification of target-specific,ligation-dependent circular probe

We describe a novel polymerase chain reaction (PCR)-based gene amplification method utilizing a circularizable oligodeoxyribonucleotide probe (C-probe). The C-probe contains two target complementary regions located at each terminus and an interposed generic PCR primer binding region. The hybridization of C-probe to a target brings two termini in direct apposition as the complementary regions of C-probe wind around the target to form a double helix. Subsequent ligation of the two termini results in a covalently linked C-probe that becomes `locked on to' the target. The circular nature of the C-probe allows for the generation of a multimeric single-stranded DNA (ssDNA) via extension of the antisense primer by Taq DNA polymerase along the C-probe and displacement of downstream strand, analogous to `rolling circle' replication of bacteriophage in vivo. This multimeric ssDNA then serves as a template for multiple sense primers to hybridize, extend, and displace downstream DNA, generating a large ramified (branching) DNA complex. Subsequent thermocycling denatures the dsDNA and initiates the next round of primer extension and ramification. This model results in significantly improved amplification kinetics (super-exponential) as compared to conventional PCR. Our results show that the C-probe was 1000 times more sensitive than the corresponding linear hemiprobes for detecting Epstein–Barr virus early RNA. The C-probe not only increases the power of amplification but also offers a means for decontaminating carryover amplicons. As the ligated C-probes possess no free termini, they are resistant to exonuclease digestion, whereas contaminated linear amplicons are susceptible to digestion. Treatment of the ligation reaction mixture with exonuclease prior to amplification eliminated the amplicon contaminant, which could also have been co-amplified with the same PCR primers; only the ligated C-probes were amplified. The combined advantages of the C-probe and thermocycling have a broad applicability for the detection of both DNA and RNA. Finally, we described a novel isothermal amplification method, ramification extension amplification, utilizing circular nature of C-probe and displacement activity of DNA polymerase.