滚环扩增技术的原理及其应用的研究

滚环扩增是近年来发展起来的一种恒温核酸扩增方法。这种方法不仅可以直接扩增DNA和RNA,还可以实现对靶核酸的信号放大,灵敏度达到一个拷贝的核酸分子,因此,RCA技术在全基因组扩增、单核苷酸多态性、DNA芯片、蛋白质芯片等方面检测中具有很大的应用价值和潜力。     

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。     

转录介导的扩增技术及其在诊断中的应用

转录介导的扩增技术可以RNA或DNA为模板,利用RNA聚合酶和逆转录酶在约42°C等温反应条件下进行扩增,产物为RNA。该技术在每一循环可产生模板的100～1000个拷贝转录本,15～30 min可将模板扩增约1010倍,在人类白细胞抗原等位基因分型、细菌和病毒的快速检测中发挥了重要作用。     

重组酶聚合酶扩增技术：一种新的核酸扩增策略

重组酶聚合酶扩增 (recombinase polymerase amplification, RPA)是近年来兴起的一种等温核酸扩增技术,它比聚合酶链式反应(polymerase chain reaction, PCR)及其它等温扩增技术更快速、便捷、高效。本文将详细介绍RPA这项新颖的技术,并对其在医疗诊断、农业、食品、生物安全等方面的研究及应用进展进行综述。期望这项技术得到更多的关注,使其发展更加完善,将来在更多的领域充分发挥作用,甚至书写核酸检测历史新篇章。     

Enhanced PCR efficiency of high-fidelity DNA polymerase from Thermococcus waiotapuensis

Twa DNA polymerase from hyperthermophilic archaeon Thermococcus waiotapuensis has exceedingly high fidelity among family B DNA polymerases. However, Twa DNA polymerase has significant shortcomings in terms of a low extension rate and poor processivity. To resolve these weaknesses, we focused on two amino acid residues (N565 and H633) in the palm and thumb subdomains of the Twa DNA polymerase. These two residues were replaced by site-directed mutagenesis and the enzymatic properties of the mutants were analyzed. Here, Twa H633R DNA polymerase showed significantly improved polymerase function compared to wild-type Twa DNA polymerase in terms of processivity (2-fold), extension rate (1.5-fold) and PCR efficiency. Kinetic analysis using DNA as a template revealed that the k_cat value of the Twa H633R mutant was similar to that of wild-type, but the K_m of the Twa H633R mutant was about 1.6-fold lower than that of the wild-type. These results showed that the Arg residue substitution at H633 located in the thumb subdomain has a positive effect on processivity, extension rate and PCR efficiency, suggesting that the Twa H633R mutant allows a conformational change for easy access of the primer-template to the binding site of the polymerase domain.     

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。     

Strategies for microarray analysis of limiting amounts of RNA.

One of the critical limitations of current microarray technologies for use in expression analyses is the relatively large amount of input RNA required to generate labelled cDNA populations for array analysis. In situations where RNA is limiting, the options for expression profiling are to increase cDNA labelling and hybridisation efficiency, or to use an amplification strategy to generate enough RNA/cDNA for use with a standard labelling method. Sample amplification approaches must preserve the representation of the relative abundances of the different RNAs within the starting population and must also be highly reproducible. This review evaluates current signal and sample amplification technologies, including those that can be used to generate labelled cDNA populations for array analysis from as little as a single cell.     

多重环介导等温扩增技术研究进展

环介导等温扩增技术(Loop-mediated isothermal amplification, LAMP)因其扩增速度快、灵敏度和特异性高、仪器要求低等优点而被广泛应用于核酸诊断领域。为充分利用LAMP技术优势、提高诊断检测的效率与可靠性、扩展其应用范围,同时节约试剂成本,近年来多重LAMP技术的研究成为一大热点。常规的LAMP扩增产物检测方法多数以聚合反应的双链DNA产物或其副产物为基础,只能判断有无扩增反应发生,而难以识别多重扩增产物的靶标来源及其特异性。为实现多重扩增产物的高特异检测,各国学者通过对该技术巧妙的改进或与其他技术相偶联,发展了一系列多重LAMP扩增检测技术。然而上述狭义的多重LAMP技术依然存在因引物间相互干扰、扩增效率存在差异而引发歧视性扩增的局限,限制了多重扩增的重数。近年研究活跃的微型扩增技术以其实现多个平行、互不干扰的小体积单重扩增的技术优势打破了这一局限,由此产生了新型的广义多重LAMP扩增技术。这些技术还具有试剂消耗少、自动化程度较高、交叉污染风险更小以及更适合对较多靶标进行现场快速检测等优势。本文分别从狭义多重LAMP的方法原理及其扩增反应体系优化、广义多重LAMP的方法原理以及多重LAMP技术在诊断检测中的应用等方面对近年来多重LAMP技术的研究进展进行了综述。     

等温核酸扩增技术在病原体检测中的应用

近年来,新型传染病相继爆发,如严重急性呼吸综合征（severe acute respiratory syndrome,SARS）、H7N9禽流感等,严重威胁着人类健康和社会、经济的可持续发展,同时给传染病的防控带来了严峻挑战。病原体检测是传染病防控的重要环节,越来越多的新技术被应用其中。等温核酸扩增技术作为一种快速、灵敏度高的病原体检测技术,已取得了长足发展。对等温核酸扩增技术的原理、重要特性及其在病原体检测中的应用进展进行了较为全面的综述,以期为这一技术的推广和应用提供重要参考。     

微生物单细胞基因组技术及其在环境微生物研究中的应用

单细胞及单细胞基因组学研究是近年生命科学研究的热点之一,微生物单细胞基因组学研究是继微生物元基因组学(又称宏基因组学,Metagenomics)之后新发展起来的,可有效获取环境中大量无法培养的微生物遗传信息的技术。微生物单细胞基因组技术包括单细胞获取、全基因组扩增、全基因组测序以及数据分析等步骤,目前该技术在环境微生物研究中的应用主要集中于探索未被元基因组技术或其它常规技术探测到的新型功能基因,或是对环境中物种丰度极小的未培养微生物的发现,以及对微生物细胞生命进化过程的研究等。本文对微生物单细胞基因组技术中单细胞获取和全基因组扩增所涉及到的不同方法以及应用此技术对环境微生物取得的主要研究进展进行综述。     

Exploring whole genome amplification as a DNA recovery tool for molecular genetic studies.

The whole genome amplification (WGA) protocol evaluated during this study, GenomiPhi DNA amplification kit, is a novel method that is not based on polymerase chain reaction but rather relies on the highly processive and high fidelity Phi29 DNA polymerase to replicate linear genomic DNA by multiple strand displacement amplification. As little as 1 ng of genomic DNA template is sufficient to produce microgram quantities of high molecular weight DNA. The question explored during this study is whether such a WGA method is appropriate to reliably replenish and even recover depleted DNA samples that can be used for downstream genetic analysis. A series of human DNA samples was tested in our laboratory and validated using such analytical methods as gene-specific polymerase chain reaction, direct sequencing, microsatellite marker analysis, and single nucleotide polymorphism allelic discrimination using TaqMan and Pyrosequencing chemistries. Although degraded genomic DNA is not a good template for Phi29 WGA, this method is a powerful tool to replenish depleted DNA stocks and to increase the amount of sample for which biological tissue availability is scarce. The testing performed during the validation phase of the study indicates no discernable difference between WGA samples and the original DNA templates. Thus, GenomiPhi WGA can be used to increase precious or depleted DNA stocks, thereby extending the life of a family-based linkage analysis project and increasing statistical power.     

Loop-mediated isothermal amplification of single pollen grains

The polymerase chain reaction(PCR) has been a reliable and fruitful method for many applications in ecology.Nevertheless, unavoidable technical and instrumental requirements of PCR have limited its widespread application in field situations. The recent development of isothermal DNA amplification methods provides an alternative to PCR, which circumvents key limitations of PCR for direct amplification in the field. Being able to analyze DNA in the pollen cloud of an ecosystem would provide very useful ecological information, yet would require a field-enabled, high-throughput method for this potential to be realized. Here, we demonstrate the applicability of the loop-mediated DNA amplification method(LAMP), an isothermal DNA amplification technique, to be used in pollen analysis. We demonstrate that LAMP can provide a reliable method to identify species from the pollen cloud, and that it can amplify successfully with sensitivity down to single pollen grains, thus opening the possibility of field-based, high-throughput analysis.     

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.     

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...     

滚环复制技术的建立及在RNA病毒基因检测中的初步应用

滚环复制是噬菌体繁殖所采取的一种基因复制方式,这种方式可使单链的环形分子在聚合酶和引物的作用下进行体外自我扩增。本文中用可特异性连接环化的寡核苷酸链作为探针,分别进行了1份细胞培养的禽流感病毒H5N1亚型样品、1份细胞培养的SARS病毒样品和4份丙型肝炎病毒阳性血清样品的检测。检测原理是探针与靶序列杂交后便可在T4DNA连接酶的作用下形成滚环复制中的环化单链分子,该分子在同温下可被特异性引物滚动复制和支链扩增。本文还利用按禽流感病毒NA1基因区序列合成的模拟DNA分子对该检测方法的灵敏度进行了测试。结果显示：利用固相RCA技术成功检测到三种RNA病毒的基因,该方法的灵敏度可达到能检测10^3拷贝模式DNA分子的水平。与传统的PCR方法敏感性的比较尚待进一步研究。     

A short review of variants calling for single-cell-sequencing data with applications

The field of single-cell sequencing is fleetly expanding, and many techniques have been developed in the past decade. With this technology, biologists can study not only the heterogeneity between two adjacent cells in the same tissue or organ, but also the evolutionary relationships and degenerative processes in a single cell. Calling variants is the main purpose in analyzing single cell sequencing (SCS) data. Currently, some popular methods used for bulk-cell-sequencing data analysis are tailored directly to be applied in dealing with SCS data. However, SCS requires an extra step of genome amplification to accumulate enough quantity for satisfying sequencing needs. The amplification yields large biases and thus raises challenge for using the bulk-cell-sequencing methods. In order to provide guidance for the development of specialized analyzed methods as well as using currently developed tools for SNS, this paper aims to bridge the gap. In this paper, we firstly introduced two popular genome amplification methods and compared their capabilities. Then we introduced a few popular models for calling single-nucleotide polymorphisms and copy-number variations. Finally, break-through applications of SNS were summarized to demonstrate its potential in researching cell evolution.     

一种DNA扩增的新技术： 利用热稳定的Bst DNA聚合酶驱动跨越式滚环等温扩增反应

Bst DNA聚合酶具有热稳定性、链置换活性及聚合酶活性,在体外DNA等温扩增反应中起重要作用. 本文利用Bst DNA聚合酶的5′→3′聚合酶、核苷酸（末端）转移酶及链置换酶活性发展了一种新的体外环式DNA扩增技术跨越式滚环等温扩增(saltatory rolling circle amplification,SRCA)．在SRCA反应中,Bst DNA聚合酶以上游引物P1为模板合成其互补链RcP1,并和P1形成双链DNA|之后,Bst DNA聚合酶用其核苷酸转移酶活性在其P1的3′末端沿5′→3′方向随机掺入脱氧核糖核苷酸聚合形成寡聚核苷酸（dNMP)m序列,即DNA的合成反应跨越了RcP1 与下游引物P2之间的缺口|然后,以下游引物P2为模板形成互补序列（RcP2）;接着,Bst DNA聚合酶继续将脱氧核糖核苷酸随机添加到RcP2的3′末端,形成（dNMP)n序列．继而,Bst DNA聚合酶以RcP1为模板,继续催化聚合反应合成互补新链,并通过其链置换酶活性替换P1|如此往复,形成［P1-(dNMP)m-RcP2-(dNMP)n …］序列．本文通过电泳、酶切、测序等方法对扩增产物进行分析,演绎出上述扩增过程,并就工作原理进行了讨论．该反应可能对开发等温扩增技术检测微生物有一定助益,也为解释环介导等温扩增技术中假阳性反应和滚环等温扩增反应中的背景信号提供了线索．     

NASBA(依赖核酸序列的扩增)及其在病毒检测中的应用

NASBA(nucleic acid sequence based amplification)即依赖核酸序列的扩增技术,是一种扩增RNA的新技术,是由一对引物介导的、连续均一的、体外特异核苷酸序列等温扩增的酶促反应过程。反应在42℃进行,可以在2h左右将模板RNA扩增约109~12倍,不需特殊的仪器。NASBA已经广泛应用于细菌、病毒等多种病原微生物的检测,就NASBA的技术原理及其在病毒检测中的应用作一综述。