过量DMSO显著降低低模板浓度PCR扩增的特异性

DMSO通常经验性地用于提高PCR扩增的效率,但是过量的DMSO可以显降低特异序列的扩增效率,尤其是导致非特异性扩增的现象却被忽视。在6％的DMSO存在时,开始出现非特异条带,同时特异扩增产物减少。本首次报道DMSO对PCR产物特异性的影响并确定了克服上述现象产生的途径,即通过增加模板－引物的比例消除非特异条带。而通常提高复性温度只能部分减少非特异产物,不能避免非特异扩增。本结果有助于提高常规PCR,尤其是分子遗传学分析中经常使用的随机扩增多态性DNA（random amplifeid polymorphic DNA,RAPD）检测的准确度。     

过量DMSO显著降低低模板浓度PCR扩增的特异性

DMSO通常经验性地用于提高PCR扩增的效率,但是过量的DMSO可以显著降低特异序列的扩增效率,尤其是导致非特异性扩增的现象却被忽视.在6%的DMSO存在时,开始出现非特异条带,同时特异扩增产物减少.本文首次报道DMSO对PCR产物特异性的影响并确定了克服上述现象产生的途径,即通过增加模板-引物的比例消除非特异条带.而通常提高复性温度只能部分减少非特异产物,不能避免非特异扩增.本文结果有助于提高常规PCR,尤其是分子遗传学分析中经常使用的随机扩增多态性DNA(randomamplifiedpolymorphicDNA,RAPD)检测的准确度。 Abstract:DMSO is the most often empirically used to increase efficiency of PCR.However,it is ignored that DMSO can also decrease the amplification of specific sequences and result in non- specific amphfications.Non-specific bands are detected at 6% DMSO,as specific amplification declines.This is the first report about the effects of DMSO on the specificity of PCR and establishment of the method for avoiding non-specific products,which can be overcome by increasing template-primer ratio rather than annealing temperature.Our data will be of much help for random amphfied polymorphic DNA (RAPD) assays for molecular genetic analyses.     

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 25mol 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     

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。     

应用复合增强剂扩增人巨细胞病毒pp65全基因

在PCR过程中 ,模板GC含量过高是一个不利因素。如果设计扩增片段较长 ,则进一步增加了PCR扩增的难度。解决这一问题对于以PCR成功获取富含GC的长基因有非常重要的意义。以人巨细胞病毒pp65全基因 (约 1 95 0bp ,GC %为 67%)为例 ,在PCR系统中测试不同添加剂(甘油、乙醇、DMSO、甜菜碱等 )及各种组合 ,摸索扩增目的基因的最佳条件。结果发现 :无或单一的添加剂都不能获得目的基因片段 ,只有当同时使用DMSO和甜菜碱 ,并在适当浓度时才能够获得特异产物。在PCR系统中包含复合增强剂能有助于高GC %、长基因片段的扩增 ,为解决此类问题提供了一种有效的途径。     

西部马脑炎病毒基因组序列的半套式RT-PCR检测

为进一步提高RT－PCR检测西部马脑炎病毒（WEE）病毒基因组方法的敏感性,采用半套式PCR扩增病毒基因组特异序列,首先采用逆转录法将病毒基因组RNA逆转录为cDNA,然后以此cDNA为模板,进行扩增。对扩增后电泳检查无可见DNA条带的产物进行半套式PCR;与此同时对扩增的循环数、Mg^ 浓度和退火温度等条件进行了优化,以进一步提高扩增的特异性。结果第一轮PCR未扩出特异笥片段的WEE病毒稀释度,其半套式扩增出特定大小的DNA产物;同时优化的条件提高了扩增产物的特异性。扩增产物约为190bp的单一DNA片段,其大小与预期的相一致,结果表明采用半套式RT－PCR方法检测WEE病毒的基因组序列的敏感性可提高100倍以上。     

古DNA实时荧光定量PCR实验中标准品的制备

实时荧光定量PCR技术通过对PCR每一循环扩增产物的实时检测,可对模板的精确拷贝数进行绝对定量,从而用于古DNA实验中提取和扩增条件的比较和优化.本研究采用异硫氰酸胍碱裂解-SiO2吸附的方法,从采自黑龙江省的晚更新世斑鬣狗化石材料中提取得到了斑鬣狗线粒体基因组古DNA.经常规PCR扩增后,将纯化的扩增产物克隆到微生物体内使其大量复制,再用M13通用引物扩增出含少量外源DNA的古DNA目标片段,从而建立了适用于古DNA荧光定量PCR扩增的标准品的制备方法.经检测分析,运用该方法制备的标准品性质稳定,能够准确地指示反应体系中较为精确的古DNA模板拷贝数,从而反映古DNA的提取和扩增效率,用于比较并优化古DNA提取和扩增条件.     

用均匀设计优化apo E基因的PCR扩增方案

由于PCR影响因素多,获得理想扩增结果比较困难,有必要寻找一种简单有效的方法建立最佳扩增体系.针对Mg²⁺浓度、二甲基亚砜(DMSO)浓度、变性时间、延伸时间、循环次数等因素进行4因素6水平和6因素10水平均匀设计实验优化apo E基因244 bp片段的PCR扩增条件.采用纯化模板和简易模板,只需6～10次实验即可获得特异性、高产率扩增结果.研究表明,将均匀设计用于PCR条件优化以及有关的样品处理、试剂选择等研究方面可以避免盲目性,迅速获得满意结果.     

食源性致病菌多重PCR快速检测方法建立与应用

利用PCR技术,建立多组多重食源性致病菌PCR快速检测方法。设计受试菌特异性引物,反应体系中加入多对引物和多种DNA模板,采用正交试验优化PCR反应条件,进行特异性引物的PCR扩增。建立了多组多重食源性致病菌PCR快速检测方法,方法中所检测受试菌株和模拟样品均出现特异性扩增条带,结果与实际相符。所建立多组多重PCR快速检测体系符合设计要求,可以应用于食源性突发公共卫生事件的应急检测和日常样品检测工作。     

一种改进后的重叠延伸PCR法对被孢霉重组载体的构建

为了提高DNA大片段的拼接效率,通过引入逐次退火的PCR的方法,改良了传统的重叠延伸PCR方法。逐次退火PCR法,一方面延长了重叠区的PCR引物长度;另一方面把原来在1个循环中1个退火温度改成若干个,逐次降低退火温度,适用于Tm值相差比较大的引物;相邻的退火温度之间相差3-6℃。结果显示,通过此种方法成功拼接了ω3(2)和HCT两个大片段;PCR产物电泳条带单一,克隆测序证实序列完全正确,可以直接应用于后续试验。这种改进后的方法可以有效减少非特异性扩增,提高灵敏度,把这种方法称之为逐次退火重叠延伸PCR。     

Bovine serum albumin further enhances the effects of organic solvents on increased yield of polymerase chain reaction of GC-rich templates

ABSTRACT: BACKGROUND: While being a standard powerful molecular biology technique, applications of the PCR to the amplification of high GC-rich DNA samples still present challenges which include limited yield and poor specificity of the reaction. Organic solvents, including DMSO and formamide, have been often employed as additives to increase the efficiency of amplification of high GC content (GC > 60%) DNA sequences. Bovine serum albumin (BSA) has been used as an additive in several applications, including restriction enzyme digestions as well as in PCR amplification of templates from environmental samples that contain potential inhibitors such as phenolic compounds. FINDINGS: Significant increase in PCR amplification yields of GC-rich DNA targets ranging in sizes from 0.4 kb to 7.1 kb were achieved by using BSA as a co-additive along with DMSO and formamide. Notably, enhancing effects of BSA occurs in the initial PCR cycles with BSA additions having no detrimental impact on PCR yield or specificity. When a PCR was set up such that the cycling parameters paused after every ten cycles to allow for supplementation of BSA, combining BSA and organic solvent produced significantly higher yields relative to conditions using the solvent alone. The co-enhancing effects of BSA in presence of organic solvents were also obtained in other PCR applications, including site-directed mutagenesis and overlap extension PCR. CONCLUSIONS: BSA significantly enhances PCR amplification yield when used in combination with organic solvents, DMSO or formamide. BSA enhancing effects were obtained in several PCR applications, with DNA templates of high GC content and spanning a broad size range. When added to the reaction buffer, promoting effects of BSA were seen in the first cycles of the PCR, regardless of the size of the DNA to amplify. The strategy outlined here provides a cost-effective alternative for increasing the efficiency of PCR amplification of GC-rich DNA targets over a broad size range.     

Polymerase chain reaction optimization for amplification of Guanine-Cytosine rich templates using buccal cell DNA

CONTEXT:

Amplification of Guanine-Cytosine (GC) -rich sequences becomes important in screening and diagnosis of certain genetic diseases such as diseases arising due to expansion of GC-rich trinucleotide repeat regions. However, GC-rich sequences in the genome are refractory to standard polymerase chain reaction (PCR) amplification and require a special reaction conditions and/or modified PCR cycle parameters.

AIM:

Optimize a cost effective PCR assay to amplify the GC-rich DNA templates.

SETTINGS AND DESIGN:

Fragile X mental retardation gene (FMR 1) is an ideal candidate for PCR optimization as its GC content is more than 80%. Primers designed to amplify the GC rich 5’ untranslated region of the FMR 1 gene, was selected for the optimization of amplification using DNA extracted from buccal mucosal cells.

MATERIALS AND METHODS:

A simple and rapid protocol was used to extract DNA from buccal cells. PCR optimization was carried out using three methods, (a) substituting a substrate analog 7-deaza-dGTP to dGTP (b) in the presence of a single PCR additive and (c) using a combination of PCR additives. All PCR amplifications were carried out using a low-cost thermostable polymerase.

RESULTS:

Optimum PCR conditions were achieved when a combination of 1M betaine and 5% dimethyl sulfoxide (DMSO) was used.

CONCLUSIONS:

It was possible to amplify the GC rich region of FMR 1 gene with reproducibility in the presence of betaine and DMSO as additives without the use of commercially available kits for DNA extraction and the expensive thermostable polymerases.     

DMSO and Betaine Greatly Improve Amplification of GC-Rich Constructs in De Novo Synthesis

In Synthetic Biology, de novo synthesis of GC-rich constructs poses a major challenge because of secondary structure formation and mispriming. While there are many web-based tools for codon optimizing difficult regions, no method currently exists that allows for potentially phenotypically important sequence conservation. Therefore, to overcome these limitations in researching GC-rich genes and their non-coding elements, we explored the use of DMSO and betaine in two conventional methods of assembly and amplification. For this study, we compared the polymerase (PCA) and ligase-based (LCR) methods for construction of two GC-rich gene fragments implicated in tumorigenesis, IGF2R and BRAF. Though we found no benefit in employing either DMSO or betaine during the assembly steps, both additives greatly improved target product specificity and yield during PCR amplification. Of the methods tested, LCR assembly proved far superior to PCA, generating a much more stable template to amplify from. We further report that DMSO and betaine are highly compatible with all other reaction components of gene synthesis and do not require any additional protocol modifications. Furthermore, we believe either additive will allow for the production of a wide variety of GC-rich gene constructs without the need for expensive and time-consuming sample extraction and purification prior to downstream application.     

Enhancement of PCR Amplification of Moderate GC-Containing and Highly GC-Rich DNA Sequences

PCR is a commonly used and highly efficient technique in biomolecular laboratories for specific amplification of DNA. However, successful DNA amplification can be very time consuming and troublesome because many factors influence PCR efficiency. Especially GC-rich DNA complicates amplification because of generation of secondary structures that hinder denaturation and primer annealing. We investigated the impact of previously recommended additives such as dimethylsulfoxide (DMSO), magnesium chloride (MgCl₂), bovine serum albumin (BSA), or formamide. Furthermore, we tested company-specific substances as Q-Solution, High GC Enhancer, and Hi-Spec; various actively promoted polymerases as well as different PCR conditions for their positive effects on DNA amplification of templates with moderate and extremely high CG-content. We found considerable differences of specificity and quantity of product between different terms. In this article, we introduce conditions for optimized PCR to help resolve problems amplifying moderate to high GC-rich templates.     

一种新的用于提高lea3基因扩增特异性和产量的增强剂（英文）

在对目的DNA序列尤其是高GC含量的片段进行PCR扩增的时候,经常需要对一些试验条件进行优化。在一定条件下,二甲基亚砜、甲酰胺、甘油、NP-40和Tween20等可以在某种程度上提高PCR的特异性和效率。我们在对禾本科lea3基因进行分离克隆时发现了一种新的可以提高PCR产量和特异性的物质——极高热稳定单链结合蛋白（ETSSB）,研究发现在每50μlPCR反应体系中加入200ng的ETSSB,可以有效地抑制DNA片段的非特异性条带的产生,并可以提高目的片段的产量。     

乙二醇和1，2-丙二醇增强富含GC碱基人类基因组DNA模板的PCR扩增

基因（组）操作者常会遇到高GC序列难于扩增的问题。全球范围内也还没有很成熟的通用方法来解决这个问题。经过系统的摸索,发现选用有机试剂乙二醇和1,2-丙二醇能得到比较满意的特异的PCR产物。104段随机选取的GC含量在60%~80%之间的人类基因组序列（长度在700~800bp）基本上全部得到较好的扩增。     

Extension temperature of 60°C required for PCR amplification of large DNA fragments (>5 kb) from a low GC bacterium Clostridium acetobutylicum

PCR amplification of DNA fragments has been routinely used in gene cloning and engineering of microbial strains for biotechnological purposes such as production of biofuels and green chemicals. However, it is often a challenge to amplify large DNA fragments (>5 kb) from low GC microorganisms using the standard PCR protocols. In this brief communication, we report a modified PCR method with an extension temperature of 60°C, which efficiently amplified a 5.3 and a 5.5 kb DNA fragment (an extension time of 6 min) from a low GC bacterium Clostridium acetobutylicum (~30% GC). A lower than normal extension temperature (72°C) approach may also facilitate PCR amplification of large DNA fragments (>5 kb) from other low GC microorganisms.     

纳米金增强复杂体系中PCR扩增低拷贝基因的反应特异性初步研究

目的：利用纳米金颗粒提高复杂体系基因组低拷贝基因PCR扩增的反应特异性。方法：首先,模拟复杂基因组扩增模式体系,以接近单拷贝的λDNA为模板,在PCR过程中加入纳米金颗粒,设计优化实验,以便模拟建立复杂基因组低拷贝目的基因PCR扩增的模式体系。随后,扩增人类基因组的疾病相关的低拷贝基因模板（如人基因组肿瘤坏死因子基因外显子1的380bp）,以检验纳米金优化增强PCR反应特异性的实际效果。结果：在复杂体系基因组的低拷贝基因PCR扩增中,纳米金颗粒能够较好地增强其PCR反应的特异性。结论：初步表明基于纳米金的纳米粒子PCR方法可以对复杂的实际基因组体系低拷贝基因的PCR扩增起到优化作用,这对于PCR反应优化方法的改进、推广具有重要的参考价值。     

The enhancement of PCR amplification by low molecular-weight sulfones.

DNA amplification by polymerase chain reaction (PCR) is frequently complicated by the problems of low yield and specificity, especially when the GC content of the target sequence is high. A common approach to the optimization of such reactions is the addition of small quantities of certain organic chemicals, such as dimethylsulfoxide (DMSO), betaine, polyethylene glycol and formamide, to the reaction mixture. Even in the presence of such additives, however, the amplification of GC-rich templates is often ineffective. In this paper, we introduce a novel class of PCR-enhancing compounds, the low molecular-weight sulfones, that are effective in the optimization of high GC template amplification. We describe here the results of an extensive structure-activity investigation in which we studied the effects of a series of six different sulfones on PCR amplification. We identify two sulfones, sulfolane and methyl sulfone, that are especially potent enhancers of high GC template amplification, and show that these compounds often outperform DMSO and betaine, two of the most effective PCR enhancers currently used. We conclude with a brief discussion of the role that the sulfone functional group may play in such enhancement.     

Amplification of GC-rich DNA for High-Throughput Family-Based Genetic Studies

Researchers face a significant problem in PCR amplification of DNA fragments with high GC contents. Analysis of these regions is of importance since many regulatory regions of different genes and their first exons are GC-rich. There are a large number of protocols for amplification of GC-rich DNA, some of which perform well but are costly. Most of the economical protocols fail to perform consistently, especially on products with >80 % GC contents and a size of >300 bp. One of these protocols requires multiple additions of DNA polymerase during thermal cycling which therefore rules out its utility if a large number of samples have to be amplified. We have established a method for simultaneous amplification of specific PCR products from a large number of human DNA samples using general laboratory reagents. These amplicons have GC contents ranging from 65–85 % and sizes up to 870 bp. The protocol uses a PCR buffer containing co-solvents including 2-mercaptoethanol and bovine serum albumin for amplification of DNA. A specific thermal cycling profile is also used which incorporates a high annealing temperature in the first 7 cycles of the reactions. The PCR products are suitable for different molecular biology applications including sequencing.