实时荧光定量PCR技术及其应用

定量PCR的问世是继定性PCR(即常规PCR)后分子生物学方法学研究的一大飞跃,实现了对核酸信息量的分析比较,为疾病的诊断和治疗提供了更多、更有效的基因水平信息。本文介绍实时荧光定量PCR技术及其在兽医领域中的应用,包括近年来研究和应用较多的几种定量PCR技术。     

液相原位反转录PCR:一种研究基因原位表达的有效方法

介绍了液相原位反转录PCR(inwellinsituRTPCR)的操作程序、存在的问题及改良方法,最后探讨了原位反转录PCR在研究RNA转录、加工、编辑和多聚腺苷酸化等方面的应用。     

荧光定量PCR应用常见问题

1荧光定量PCR是什么荧光定量PCR(fluorescent quantitative PCR,FQ- PCR)是在PCR定性技术基础上发展起来的定量PCR技术。FQ—PCR技术是一种在PCR反应体系中加入荧光基团,利用荧光信号积累实时监测整个PCR进程,最后通过标准曲线对未知模板进行定量分析的方法,实现了PCR从定性到定量的飞跃。FQ—PCR仪在普通PCR仪的基础上加上了荧光探头和计算机。     

单分子PCR技术及其应用

常规PCR技术大都以大量DNA分子(一般为105个以上)为模板进行DNA扩增。新近发展起来的单分子PCR技术是一种以极少量DNA分子(1、5或10个分子)为模板进行扩增的技术。在高保真度DNA聚合酶作用下,单分子PCR技术能扩增出高度一致的DNA;在低保真度DNA聚合酶作用下,单分子PCR技术又能构建出含有大量突变基因的DNA库。该将介绍单分子PCR的基本原理、实验步骤、特点及其应用。     

扩增未知序列DNA片段的PCR技术研究进展

1985年,Mullis等人发明了PCR技术,短短十余年间,这一技术得到迅速发展和应用,已由扩增已知基因发展到扩增未知基因,本文旨在介绍利用PCR技术扩增未知序列DNA片段的最新进展及这些技术在基因克隆研究中的应用。     

荧光定量PCR技术在植物研究中的应用

荧光定量PCR技术是近年发展起来的一种用于基因定量分析的PCR方法,自同世以来在基础科学研究、临床诊断、疾病研究及药物研发等领域应用较为广泛.在植物研究方面应用起步较晚,现已开始用于植物基因表达分析、外源基因基因鉴定等方面的研究.介绍了实时荧光定量PCR技术的原理、优缺点和试验中潜在问题和条件的优化,并对其在植物研究中的应用及前景作了探讨.     

扩增未知序列DNA片段的PCR技术研究进展

1985年,Mullis等人发明了PCR技术,短短十余年间,这一技术得到迅速发展和应用,已由扩增已知基因发展到扩增未知基因。本文旨在介绍利用PCR技术扩增未知序列DNA片段的最新进展及这些技术在基因克隆研究中的应用。     

实时定量PCR技术的介绍

实时定量PCR(real-timePCR)技术是近几年发展起来的新技术 ,既保持了PCR技术灵敏、快速的特点 ,又克服了以往PCR技术中存在的假阳性污染和不能进行准确定量的缺点。另外 ,还有重复性好、省力、低费用等优点。实时定量PCR技术是从传统PCR技术发展而来 ,其基本原理是相同的 ,主要不同之处是其定量的体系。下面简单介绍一下该技术定量的原理。1　荧光染料的应用荧光染料的应用是实时PCR技术能够进行定量检测的一个重要部分 ,在PCR反应体系中应用荧光标记物 ,通过监测荧光信号的累积实现对整个PCR循环进程的观察。目前主要有四种方法…     

实时定量PCR技术及其应用

实时定量PCR(Real—time Quantitative Polymerase Chain Reaction,RQ—PCR)技术是20世纪90年代中期发展起来的一种新型核酸定量技术。该技术具有实时监测、快速、灵敏、精确等特点,是对原有PCR技术的革新,扩大了PCR的应用范围。本文综述了RQ—PCR技术的原理、RQ—PCR仪、RQ—PCR实时定量检测系统及其应用。     

Genetic mapping of four dinucleotide repeat loci, DXS453, DXS458, DXS454, and DXS424, on the X chromosome using multiplex polymerase chain reaction.

Dinucleotide CA repeat sequences in the human genome have been shown to be highly polymorphic due to variation in the length of the repeat-containing segment. Therefore, these markers can serve as anchor loci in the construction of a high-resolution genetic map of the human genome. In this study, we improved the efficiency of typing dinucleotide repeats using multiplex polymerase chain reaction (PCR). Dinucleotide repeat sequences of four previously identified markers (DXS453, DXS458, DXS454, and DXS424) on the long arm of the X chromosome were simultaneously amplified in a single PCR reaction. This multiplex PCR was applied to genotype individuals from the 40 CEPH reference families, and the genotypic data were used to determine the map position of the four loci with respect to eight reference markers in the Xq region by linkage analysis.     

Pseudogene: lessons from PCR bias,identification and resurrection

Pseudogenes are fragments of non-functional genomic DNA with high sequences similarity to normal functional genes. They are a kind of non-coding DNA produced by gene duplications or retrotranspositions. Pseudogenes exist in human genome at a large quantity which is nearly as much as that of normal functional genes. They could cause PCR bias in molecular biology experiments and confuse related analysis. On the other hand, pesudogenes are important elements in genomics study for getting an integral picture of genome annotation. They give diverse information of evolutionary history and are regarded as genome fossils. Worldwide research project “encyclopedia of DNA elements”(ENCODE) founded in recent years have enhanced our understanding of pseudogenes. Approaches established to identify pseudogenes include PseudoPipe, HAVANA method, PseudoFinder, RetroFinder, GIS-PET method and consensus method. This paper discuss pseudogenes with respect to the formation mechanisms, distribution, and problems for PCR, importance and identification of pseudogenes. Furthermore, potential resurrection of pseudogenes and their potential function are discussed.     

甲基营养菌MP688基因组完成图构建

目的:在Solexa测序建立的甲基营养菌MP688基因组精细图的基础上,构建MP688基因组完成图。方法:根据MP688基因组序列设计引物,进行常规PCR扩增,填补Scaffold内部缺口;利用BLASTN、BLAT软件分析预测6个Scaffold定位关系;通过组合PCR、长距离PCR等填充Scaffold间的物理缺口。结果:常规PCR填充Scaffold内部4个缺口;BLASTN、BLAT软件分析预测了Scaffold定位关系;组合PCR填充Scaffold间的2个物理缺口,长距离PCR填充其余4个物理缺口。结论:得到了MP688的基因组完成图,为MP688的吡咯喹啉醌生物合成途径的阐明和进一步的代谢工程育种奠定了基础。     

郑氏比蜢线粒体基因组全序列的测定与分析

采用长距PCR扩增及保守引物步移法测定并注释了郑氏比蜢(Pielomastax zhengi)的线粒体基因组全序列。郑氏比蜢的线粒体基因组全长15602 bp,A+T含量为71.8%,37个基因位置与飞蝗的一致, 基因间隔序列共计10处47bp, 间隔长度从1～20bp不等; 有14对基因间存在52bp重叠, 重叠碱基数在1～8bp之间。蛋白质基因的起始密码子均为昆虫典型的起始密码子ATN。ND5基因使用了不完全终止密码子T,其余基因均为典型的TAA或TAG。除tRNASer(AGN)的DHU臂缺失外, 其余21个tRNA基因的二级结构均属典型的三叶草结构, 但在郑氏比蜢中有5个tRNA(tRNACys、tRNALys、 tRNAPhe、 tRNAPro tRNAArg)基因变异较大, 无法采用常规算法预测出来, 表现在这5个tRNA二级结构的TψC臂仅有3～4对配对碱基, tRNALys 和 tRNAArg的反密码臂仅有 4 对配对碱基。预测的lrRNA二级结构总共有6个结构域(结构域Ⅲ缺失), 44个茎环结构。预测的srRNA的二级结构包含3个结构域, 30个茎环结构。比较郑氏比蜢、西藏飞蝗(Locusta migratoria tibetensis)和疑钩额螽(Ruspolia dubia)rRNA二级结构后,发现郑氏比蜢与西藏飞蝗的更相似。A+T丰富区中存在一个被认为与复制及转录起始有关的Ploy(T)结构。     

甜菜碱增强长片段PCR的扩增

聚合酶链式反应(PCR)作为一项非常成熟的技术可以用于基因组序列的扩增。普通的PCR技术只适合于短片段DNA的扩增,一般在6kb以下。对于6kb至十几kb甚至几十kb以上的DNA片段的扩增就非常困难。通过添加不同化学物质,发现甜菜碱对长片段PCR的扩增有非常有效的增强作用。通过对玉米总DNA以及质粒DNA的扩增,发现1mol／L到2．5mol／L甜菜碱对改进PCR扩增效果明显。通过添加甜菜碱,可以从玉米基因组中扩增出9kb以上的单拷贝片段,从质粒中扩增出16kb以上片段。经过试验,发现不同GC含量的引物需要使用不同浓度的甜菜碱。甜菜碱可以减少甚至消除长片段PCR中的非特异性扩增。同时,我们发现其它的添加物,如DMSO,甘油,甲酰胺对长片段PCR的作用不明显。     

大卫绢蛱蝶线粒体基因组全序列测定和分析

目前有关蝶类线粒体基因组全序列及其分子进化的研究报道还不多见。本文利用long PCR和引物步移法得到大卫绢蛱蝶Calinaga davidis的线粒体基因组全序列, 同时就其基因组成和结构特点作了初步分析。结果显示： 其基因组全长为15 267 bp (GenBank登录号为HQ658143), 包括13个蛋白质编码基因(ATP6, ATP8, COI-III, ND1-6, ND4L, Cytb)、22个tRNA基因、2个rRNA基因(16S和12S)以及非编码的控制区。与其他鳞翅目昆虫相一致, 其基因组未出现基因重排现象。基因组共包含11个基因间隔区,总长度为130 bp, 间隔长度1~46 bp, 最大间隔在tRNA^Gln与ND2基因之间; 基因间共存在13处重叠, 总长度为66 bp, 重叠碱基数1~35 bp, 最长的重叠区位于COII与tRNA^Lys基因。lrRNA和srRNA基因长度分别为1 337 bp和773 bp; 除tRNA^Ser(AGN)缺少二氢尿嘧啶臂(DHU stem), 在相应的位置上只形成一个简单环外, 其余的tRNA基因都能形成典型的三叶草结构。13个蛋白编码基因总长度为11 247 bp, 共有3 737个密码子, 它们的碱基组成和密码子的使用具有明显的偏倚性; 除COI外(起始密码子TTG), 其余的12个蛋白质编码基因都以标准的ATN作为起始密码子; COI基因终止密码子为不完全T, ND4基因终止密码子为不完全TA, 其余基因都以TAA为终止密码子。A+T丰富区全长为389 bp, A+T含量高达92.0%, 其中存在2段类似微卫星的重复序列(TA)₆和(AAT)₄。本文的研究结果为探讨绢蛱蝶亚科在蛱蝶科中的系统学地位及其与其他亚科间的系统发生关系等问题提供了重要的分子生物学数据。     

AFLP Fingerprinting for Assessing Intraspecific Variation and Genome Mapping in Mites

Molecular genetic techniques have come a long way in the last decade. With the advent of PCR, genetic markers are now accessible for all organisms, including mites. However, there is usually a trade-off between the accuracy of the molecular technique or genetic marker and expediency. In mites, many molecular techniques are not applicable due to their small size. Here we describe a relatively new molecular fingerprinting technique, amplified fragment length polymorphism (AFLP), which is currently used widely in plant genomic research. We outline the AFLP procedure adapted for mites, show results using this technique from our own research and discuss the benefits and limitations of AFLPs for assessing genetic variation and for genome mapping. It is our intention to highlight the possible use of AFLPs as genetic markers with a broad application in acarological research.     

Applications of the polymerase chain reaction to genome analysis

The objectives of the Human Genome Project are to create high-resolution genetic and physical maps, and ultimately to determine the complete nucleotide sequence of the human genome. The result of this initiative will be to localize the estimated 50,000-100,000 human genes, and acquire information that will enable development of a better understanding of the relationship between genome structure and function. To achieve these goals, new methodologies that provide more rapid, efficient, and cost effective means of genomic analysis will be required. From both conceptual and practical perspectives, the polymerase chain reaction (PCR) represents a fundamental technology for genome mapping and sequencing. The availability of PCR has allowed definition of a technically credible form that the final composite map of the human genome will take, as described in the sequence-tagged site proposal. Moreover, applications of PCR have provided efficient approaches for identifying, isolating, mapping, and sequencing DNA, many of which are amenable to automation. The versatility and power provided by PCR have encouraged its involvement in almost every aspect of human genome research, with new applications of PCR being developed on a continual basis.     

Use of ‘long’ polymerase chain reaction and magnetic beads for extraction of chromosome-specific cDNAs

The detection of expressed sequences of genomic DNA is an important aspect of the human genome project. A technique is described where ‘long’ polymerase chain reaction (LPCR), which allows for extended large fragment production of > 10–20 kb, is used with Alu primers to generate a biotinylated template for cDNA hybridization. Streptavidin-coated magnetic beads are used to extract the long PCR templates and bound cDNAs, which are recovered by standard PCR. This method allows the isolation of cDNAs from virtually any human DNA source and should be valuable in expression mapping, positional cloning and gene isolation.     

纳豆激酶基因的克隆及其在毕赤酵母中的表达

纳豆激酶纳是从日本传统食品纳豆中发现的一类具有溶栓效果的蛋白酶,由于其具有安全,高效,作用时间长,易吸收,廉价等优点,现在正成为一个开发治疗血栓类疾病药物的研究热点。从本实验室保存的一株高溶栓的纳豆杆菌N07出发,提取总基因组DNA,利用PCR手段扩增获得了纳豆激酶长为825bp的成熟肽基因片段。构建重组表达质粒pPICZaA-NK,经EcoR I、Xba I双酶切、PCR、测序验证得出重组表达质粒上的外源基因即为825bp的目的片段;将重组质粒pPICZaA-NK用内切酶Sac I线性化后电击导入毕赤酵母X33,通过含Zeocin的YPDS平板筛选获得重组酵母。重组酵母在BMMY培养基中发酵培养,用1%甲醇诱导目的蛋白表达。用纤维蛋白平板法检测发现发酵上清具有纤溶活性,经硫酸铵盐析、透析、Sephadex-G50过柱等步骤分离得到纳豆激酶蛋白,进行SDS-PAGE鉴定表明,表达的纳豆激酶蛋白分子量为27KD。以尿激酶为标准,实验所得纳豆激酶发酵上清液溶栓活性约为195U/mL。成功的将纳豆激酶成熟肽基因在毕赤酵母X33中表达,为纳豆激酶基因工程进一步研究奠定基础。