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。     

滚环扩增技术最新研究动态及展望

滚环扩增技术(rolling circle amplification,RCA)的建立模拟了自然界中环状病原生物DNA通过滚环模型方式自我复制的原理,经长期科学研究和实践应用,取得了诸多突破性成果。对最近几年在滚环扩增技术研究领域的最新动态进行了较全面的总结,其中包括了网状RCA、锁式探针RCA、目标成环RCA和跨越式RCA,也对滚环扩增中存在的问题进行了探讨,重点介绍了该技术在基础研究、实际检测、医疗诊断及纳米材料等方面的应用,最后对核酸等温扩增技术产业化的发展前景进行了展望。     

核酸体外扩增技术

核酸体外扩增是分子生物学研究的基础。随着生物技术的发展 ,出现了越来越多的核酸体外扩增技术。根据其特点可分为两类 :一类是靶核酸的直接扩增 ,如聚合酶链式反应、链替代扩增、连接酶链式反应、核酸依赖的扩增、Qβ复制、转录介导的扩增和滚环扩增等 ;另一类是信号放大扩增 ,如支链DNA、侵染探针等。就现有的核酸扩增技术的原理、特点及应用进行介绍。     

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。     

滚环DNA扩增的原理、应用和展望

滚环DNA扩增 (rollingcircleDNAamplification ,RCA)是一种等温信号扩增方法 ,其线性扩增倍数为 1 0 ⁵,指数化扩增能力大于 10⁹,产生的扩增产物连接在固相支持物 (如玻片、微孔板等 )表面的DNA引物或抗体上。RCA是一种适合在芯片上 (on chip)进行信号扩增的新技术 ,它既能提供研究分析的敏感性和特异性 ,又能保持立体分析的多元性。RCA亦是一种痕量的分子检测方法 ,可用于极其微量的生物大分子和生物标志的检测与研究     

滚环扩增信号放大技术在生物检测中应用的研究进展

滚环扩增(Rolling circle amplification,RCA)是一种快速、灵敏且恒温的单链DNA(Single-stranded DNA,ssDNA)扩增技术,与染色或探针联用可实现检测信号的放大,在生物检测等方面得到广泛的应用。文中对RCA的构建方法进行了简介,综述了近几年其在致病菌、核酸肿瘤标记物、蛋白质、生物小分子和病毒等检测中的研究进展,并对其未来的发展趋势进行了展望。     

滚环扩增技术及其在生物分子诊断中的应用

滚环扩增技术(RCA)是近年来发展起来的一种新型的核酸扩增技术.该技术是基于连接酶连接、引物延伸、与链置换扩增反应的一种等温核酸扩增方法.在恒温的条件下,可以产生大量的与环型探针互补的重复序列.与传统的核酸扩增方法相比,它具有扩增条件简单,特异性高,能在恒温条件下进行等特点.滚环扩增技术结合荧光、电化学、电化学发光等检...     

采用分子生物学技术诊断隐球菌脑膜脑炎的研究

目的采用分子检测技术对疑似隐球菌感染的脑膜炎病例进行诊断。方法收集患者的脑脊液样本,提取DNA,设计引物进行PCR扩增,采用DNA芯片技术对扩增产物进行分子检测。结果显示样本新生隐球菌阳性。结论通过ITS保守序列设计引物进行PCR扩增和DNA芯片技术对常规真菌学检查不能确定的疑似隐球菌脑膜炎患者脑脊液样本进行非培养检测,具有实验室诊断参考价值。     

植物病原真菌分子检测技术的研究进展

真菌是一类非常重要的植物病原菌。对这类病原菌进行分子快速检测是病害早期诊断、检疫、监测、预测预报和病害防治等工作的重要基础。本综述详细介绍与评述了一些常见的以PCR技术为基础的检测技术以及近年来发展起来的一些新技术如环介导等温扩增和核酸滚环扩增技术在植物病原真菌分子检测中的应用,旨在对该研究领域的进展有一个全面的了解。     

基于微流控芯片的核酸等温扩增技术研究进展

核酸等温扩增技术是一种在恒温体系内对核酸进行高效扩增的分子扩增技术,它能够在短时间内实现目的基因的指数增长。微流控芯片(microfluidic chip)技术是把研究样品制备、核酸富集、纯化和检测等多个操作步骤集成到一块"微型化"的芯片上,经自动化处理,得出实验结果,即"样品进,结果出"。将核酸等温扩增技术与微流控芯片相结合,不仅可以实现核酸快速扩增,还可以降低对实验器材的依赖。在床边即时诊断、病原体快速筛查中具有广阔的应用前景。综合国内外相关研究报道,综述了各种等温扩增技术原理,以及基于微流控芯片的核酸等温扩增技术应用,展望了集成化微流控芯片的发展趋势和应用前景。     

Single-stranded DNA binding protein facilitates specific enrichment of circular DNA molecules using rolling circle amplification

Many techniques in molecular biology require the use of pure nucleic acids in general and circular DNA (plasmid or mitochondrial) in particular. We have developed a method to separate these circular molecules from a mixture containing different species of nucleic acids using rolling circle amplification (RCA). RCA of plasmid or genomic DNA using random hexamers and bacteriophage Phi29 DNA polymerase has become increasingly popular for the amplification of template DNA in DNA sequencing protocols. Recently, we reported that the mutant single-stranded DNA binding protein (SSB) from Thermus thermophilus (TthSSB) HB8 eliminates nonspecific DNA products in RCA reactions. We developed this method for separating circular nucleic acids from a mixture having different species of nucleic acids. Use of the mutant TthSSB resulted in an enhancement of plasmid or mitochondrial DNA content in the amplified product by approximately 500×. The use of mutant TthSSB not only promoted the amplification of circular target DNA over the background but also could be used to enhance the amplification of circular targets over linear targets.     

Molecular Zipper: a fluorescent probe for real-time isothermal DNA amplification

Rolling-circle amplification (RCA) and ramification amplification (RAM, also known as hyperbranched RCA) are isothermal nucleic acid amplification technologies that have gained a great application in in situ signal amplification, DNA and protein microarray assays, single nucleotide polymorphism detection, as well as clinical diagnosis. Real-time detection of RCA or RAM products has been a challenge because of most real-time detection systems, including Taqman and Molecular Beacon, are designed for thermal cycling-based DNA amplification technology. In the present study, we describe a novel fluorescent probe construct, termed molecular zipper, which is specially designed for quantifying target DNA by real-time monitoring RAM reactions. Our results showed that the molecular zipper has very low background fluorescence due to the strong interaction between two strands. Once it is incorporated into the RAM products its double strand region is opened by displacement, therefore, its fluorophore releases a fluorescent signal. Applying the molecular zipper in RAM assay, we were able to detect as few as 10 molecules within 90 min reaction. A linear relationship was observed between initial input of targets and threshold time (R² = 0.985). These results indicate that molecular zipper can be applied to real-time monitoring and qualification of RAM reaction, implying an amenable method for automatic RAM-based diagnostic assays.     

Signal amplification by rolling circle amplification on DNA microarrays

While microarrays hold considerable promise in large-scale biology on account of their massively parallel analytical nature, there is a need for compatible signal amplification procedures to increase sensitivity without loss of multiplexing. Rolling circle amplification (RCA) is a molecular amplification method with the unique property of product localization. This report describes the application of RCA signal amplification for multiplexed, direct detection and quantitation of nucleic acid targets on planar glass and gel-coated microarrays. As few as 150 molecules bound to the surface of microarrays can be detected using RCA. Because of the linear kinetics of RCA, nucleic acid target molecules may be measured with a dynamic range of four orders of magnitude. Consequently, RCA is a promising technology for the direct measurement of nucleic acids on microarrays without the need for a potentially biasing preamplification step.     

Nucleic acid sensing by regenerable surface-associated isothermal rolling circle amplification

A novel method for regenerating biosensors has been developed in which the highly specific detection of nucleic acid sequences is carried out using molecular padlock probe (MPP) technology and surface-associated rolling circle amplification (RCA). This technique has a low occurrence of false positive results when compared to polymerase chain reaction, and is an isothermal reaction, which is advantageous in systems requiring low power consumption such as remote field sensing applications. Gold-sputtered 96-well polystyrene microplates and a fluorescent label were used to explore the detection limits of the surface-associated RCA technique, specificity for different MPP, conditions for regeneration of the biomolecular sensing surface, and reproducibility of measurements on regenerated surfaces. The technique was used to create highly selective biomolecular surfaces capable of discriminating between DNA oligonucleotides with sequences identical to RNA from infectious salmon anemia (ISA) and infectious hematopoietic necrosis (IHN) virus. As little as 0.6 fmol of circularized MPP was detectable with this fluorimetric assay. The sensing layers could be reused for at least four cycles of amplification using thermal denaturation, with less than 33% decrease in RCA response over time. Because the nucleic acid product of the test is attached to a surface during amplification, the technique is directly applicable to a variety of existing sensing platforms, including acoustic wave and optical devices.     

基于CRISPR/Cas系统的核酸生物传感器

近年来,CRISPR/Cas系统已经成为转录调控和基因组编辑的重要工具。除了在基因编辑领域的贡献,CRISPR/Cas系统独特的靶核酸顺式切割和非特异性单链核酸反式切割能力,在开发核酸检测的新型生物传感器方面展现出巨大潜力。构建基于CRISPR/Cas系统高灵敏度生物传感器的关键通常依赖其与不同信号扩增策略,诸如核酸扩增技术或特定信号转导方法的结合。基于此,本文旨在通过介绍不同类型的CRISPR/Cas系统,全面概述基于该系统的核酸检测生物传感器的研究进展,并重点对结合核酸扩增技术（PCR、LAMP、RCA、RPA和EXPAR）、灵敏的信号转导方法（电化学和表面增强拉曼光谱）和特殊结构设计生物传感的三大类型信号放大策略的CRISPR/Cas生物传感器进行总结和评论。最后,本文对目前的挑战以及未来的前景进行展望。     

Protein detection via direct enzymatic amplification of short DNA aptamers

Aptamers are single-stranded nucleic acids that fold into defined tertiary structures to bind target molecules with high specificities and affinities. DNA aptamers have garnered much interest as recognition elements for biodetection and diagnostic applications due to their small size, ease of discovery and synthesis, and chemical and thermal stability. Here we describe the design and application of a short DNA molecule capable of both protein target binding and amplifiable bioreadout processes. Because both recognition and readout capabilities are incorporated into a single DNA molecule, tedious conjugation procedures required for protein-DNA hybrids can be omitted. The DNA aptamer is designed to be amplified directly by either polymerase chain reaction (PCR) or rolling circle amplification (RCA) processes, taking advantage of real-time amplification monitoring techniques for target detection. A combination of both RCA and PCR provides a wide protein target dynamic range (1 microM to 10 pM).     

Isothermal amplification detection of nucleic acids by a double-nicked beacon

Isothermal and rapid amplification detection of nucleic acids is an important technology in environmental monitoring, foodborne pathogen detection, and point-of-care clinical diagnostics. Here we have developed a novel method of isothermal signal amplification for single-stranded DNA (ssDNA) detection. The ssDNA target could be used as an initiator, coupled with a double-nicked molecular beacon, to originate amplification cycles, achieving cascade signal amplification. In addition, the method showed good specificity and strong anti-jamming capability. Overall, it is a one-pot and isothermal strand displacement amplification method without the requirement of a stepwise procedure, which greatly simplifies the experimental procedure and decreases the probability of contamination of samples. With its advantages, the method would be very useful to detect nucleic acids in point-of-care or field use.