多重等位基因特异性扩增—— 微流控芯片电泳法同时测定多个单核苷酸多态性位点

文章以微流控芯片电泳为检测平台, 建立了一种基于DNA适配器连接介导的多重等位基因特异性扩增同时测定多个单核苷酸多态性(SNP)位点的方法。以白细胞介素1β(IL1B)基因中的7个SNP位点(794C>T、1274C>T、2143T>C、2766T>del、3298G>A、5200G>A和5277C>T)为检测对象, 通过PCR预扩增得一段含该7个待测SNP位点的长片段; 用限制性内切酶MboⅠ将其消化成短片段, 再与DNA适配器(adapter)相连; 以连接产物为模板, 在两管中分别用7条等位基因特异性引物和一条公用引物进行7重等位基因特异性扩增; 最后用微流控芯片电泳法分离等位基因特异性扩增产物, 根据两管扩增产物的芯片电泳图谱中扩增片段的大小判断SNP的类型。采用本法成功测定了48名健康中国人的IL1B基因上的7个SNP位点, 与聚合酶链反应-限制性片段长度多态性法(PCR-RFLP)和测序法测定结果完全一致。本法结果准确, 可用于同时测定多个SNP位点; 以微流控芯片电泳作为检测平台, 分析速度快, 样品需要量少; 借助于自制筛分凝胶和重复使用芯片, 使得SNP分析成本大大降低。     

应用基于适配器连接介导的等位基因特异性扩增法检测LRRK2基因的单核苷酸多态性

目的：应用基于适配器连接介导的等位基因特异性扩增法（Adapter Ligation—mediated Allele-specific Amplification,简称ALM-ASA）技术,检测与帕金森病（PD）发病相关的LRRK2基因中的4个SNP位点（6055G〉A,7153G〉A,4321C〉T和2264C〉T）,探讨该法用于筛查帕金森病相关SNP位点的可行性,研究多个SNP住点同时检测的准确性和可靠性。方法：运用ALM—ASA法原理,改进使用多重PCR法代替单一预扩增法,使用4对引物在单管中预扩增含所待测SNP位点的四段片段,通过酶切、酶连和PCR特异性扩增检测判断SNP的类型。经PCR体外定点突变实验制备的相应位点的突变阳性片段,检验方法的准确性和可靠性。结果：采用该法成功测定了20名PD病人和20名健康中国人的LRRK2基因中最受关注的4个SNP位点的多态性。并随机对其中10分样本的检测结果以测序法检测进行验证,结果完全一致。结论：ALM-ASA法极大提高了PCR反应的特异性,是一种准确、可靠,且费用低廉的SNP筛查方法,可推广应用于临床和实验室进行与PD有关的单核苷酸多态性的筛查检测。     

高保真酶特异性检测大鼠SNP基因型新方法

目的应用高保真酶（Pfu）和3’末端修饰引物在单管双向等位基因特异性扩增（SB-ASA）中区分SNP基因型,建立高保真酶特异性检测SNP基因型的新方法。方法选取近交系大鼠SNP位点,以RS8149053为例,设计两个外部引物和两个等位基因特异性引物,四引物3’末端进行硫代磷酸化修饰,应用高保真聚合酶（Pfu）进行特异性扩增,扩增结果测序验证其可靠性。结果在RS8149053 SNP位点（C/T）上,等位基因型CC扩增出179 bp目的片段,基因型TT扩增出597 bp目的片段,基因型不同则扩增出分子量不同的片段,目的条带测序结果与Rat Genome Database数据库基因型结果一致,高保真酶扩增结果稳定且特异性强。结论高保真酶等位基因特异性扩增技术能有效降低假阳性率,是一种快速、特异的SNP基因分型新方法。     

四引物PCR扩增反应的单管SNP快速测定法

建立一种在单管中进行单核苷酸多型性 (SNP)快速测定的高效廉价方法 .以人ABCA1基因中的I82 3M为研究对象 ,设计 4种引物进行PCR扩增 ,其中两种引物用于扩增一段含有SNP位点的DNA片段 ,另两种引物为SNP位点特异性引物 ,4种引物在单管中同时进行PCR扩增反应 ,根据延伸产物的长度确定SNP的类型 .为提高SNP测定的特异性 ,在特异性引物的 3′端倒数第 3个碱基引入了一个人为错配碱基 ,使引物的错误延伸率显著降低 ,大大提高了SNP分析的准确性 .实验结果表明 ,所建立的方法简单 ,操作简便 ,可在单管中完成SNP的测定反应 .     

甘南牦牛(Bos grunniens)FBXO32基因突变及其与胴体和肉质性状关联分析

为了分析甘南牦牛(Bos grunniens)肌肉萎缩盒蛋白32(F-box protein 32,FBXO32)基因的单核苷酸多态性(single nucleotide polymorphism, SNP)位点,以及基因型与胴体和肉质性状间的相关性,本研究以593头甘南牦牛为研究对象,采用混池测序和竞争性等位基因特异性PCR(kompetitive allele specific PCR, KASP)技术,检测了甘南牦牛FBXO32基因突变位点及基因型,分析了基因型与甘南牦牛胴体及肉质性状的相关性。结果表明,从甘南牦牛FBXO32基因检测到7个SNP位点,分别是位于5′UTR区的SNP1(g.267A>C)、外显子1区的SNP2(g.326G>T)、外显子8区的SNP3(g.31231G>C),以及3′UTR区的SNP4(g.31352G>A)、 SNP5(g.31424C>T)、 SNP6(g.31503A>C)和SNP7(g.31504A>G)。其中,SNP1、 SNP4、 SNP5、 SNP6与肌肉嫩度显著相关(P<0.05), ...     

棉铃虫细胞色素P450基因CYP9A17v2核心启动子区缺失分析

CYP9A17v2的过量表达与棉铃虫Helicoverpa armigera对拟除虫菊酯类杀虫剂的抗性相关。为了研究CYP9A17v2表达调控机制, 对CYP9A17v2核心启动子区域的功能进行了分析;构建了含荧光素酶报告基因和CYP9A17v2启动子不同长度缺失片段(-1 095~+43)的重组质粒, 转染Sf9细胞瞬时表达后用双荧光素酶报告基因检测系统检测启动子活性。功能分析结果表明: 所有的7个缺失片段均具有启动子活性, -197~+43启动子区域的转录活性最高。在CYP9A17v2基因5′-调控区-197~-113区域内可能存在转录增强因子的结合位点, 而在-1 095~-197区域内可能存在转录抑制因子的结合位点。本研究为探索棉铃虫CYP9A17v2过量表达的转录调控机理奠定了重要基础。     

四引物扩增受阻突变体系PCR快速测定绵羊 BMPR-IB基因型方法的建立

四引物ARMS PCR是检测SNP有效、快速、简便的方法.绵羊BMPR-lB基因是控制Booroola绵羊多胎性状的主效基因,此研究目的在于建立一种对BMPR-IB基因四引物ARMS PCR检测方法.根据四引物ARMS PCR技术原理,在绵羊BMPR-IB基因突变位点(A746G)设计一对特异性引物,并在突变点两侧设计一对参照引物,用来扩增含有突变点的DNA片段,可在一步PCR反应中根据电泳图谱准确判断绵羊个体的BMPR-IB基因型,对比PCR-RFLP检测结果表明,所建立的方法简单,操作简便,大大提高了检测效率.     

棉铃虫细胞色素P450 CYP9A12基因5′-上游区的克隆及序列分析

细胞色素P450基因CYP9A12的过量表达已被证实与棉铃虫Helicoverpa armigera对拟除虫菊酯的抗性相关。为探明棉铃虫CYP9A12基因的表达调控机理,根据棉铃虫CYP9A12基因cDNA全长的5′-末端核苷酸序列,采用基因组步移方法,获得CYP9A12的5′-上游区序列（总长为3 575 bp）。与cDNA序列进行比对,表明在起始密码子上游3 bp处有一长为2 124 bp的内含子。利用NNPP分析软件预测出转录起始位点,与根据CYP9A12全长cDNA序列推测的结果是一致的。TFSEARCH 1.3软件分析转录因子结合位点的结果显示,该序列不仅包含启动子的核心结构序列——TATA-box和CAAT-box,亦包含多个转录因子结合位点,如GATA-1,CdxA,Dfd等。本研究结果为深入研究棉铃虫CYP9A12的表达调控机制及其参与杀虫剂抗性的分子机理奠定了一定基础。     

小麦条锈菌国际鉴别寄主Vilmorin23的抗条锈病基因YrV23微卫星标记

Vilmorin23是小麦条锈菌国际鉴别寄主和国际上重要抗源材料。采用SSR技术,利用由Vilmorin23为基因供体转育而成的小麦抗条锈近等基因系Taichung29*6/YrV23,选用YrV23所在2B染色体上的55对SSR引物,对Taichung29*6/ YrV23及其轮回亲本Taichung29和抗性基因供体Vilmorin23的基因组DNA进行PCR扩增和聚丙烯酰胺凝胶电泳分析。结果显示,引物Xwmc356在近等基因系与轮回亲本间扩增出特异性DNA片段,经F₂代群体150个抗、感单株检测证实,该片段位点与抗条锈病基因YrV23有连锁关系,遗传距离为9.4 cM。Xwmc356可作为抗条锈基因YrV23的SSR标记。      

Multiplex single nucleotide polymorphism genotyping by adapter ligation-mediated allele-specific amplification

An improved approach for increasing the multiplex level of single nucleotide polymorphism (SNP) typing by adapter ligation-mediated allele-specific amplification (ALM-ASA) has been developed. Based on an adapter ligation, each reaction requires n allele-specific primers plus an adapter-specific primer that is common for all SNPs. Thus, only n+1 primers are used for an n-plex PCR amplification. The specificity of ALM-ASA was increased by a special design of the adapter structure and PCR suppression. Given that the genetic polymorphisms in the liver enzyme cytochrome P450 CYP2D6 (debrisoquine 4-hydroxylase) have profound effects on responses of individuals to a particular drug, we selected 17 SNPs in the CYP2D6 gene as an example for the multiplex SNP typing. Without extensive optimization, we successfully typed 17-plex SNPs in the CYP2D6 gene by ALM-ASA. The results for genotyping 70 different genome samples by the 17-plex ALM-ASA were completely consistent with those obtained by both Sanger's sequencing and PCR restriction fragment length polymorphism (PCR-RFLP) analysis. ALM-ASA is a potential method for SNP typing at an ultra-low cost because of a high multiplex level and a simple optimization step for PCR. High-throughput SNP typing could be readily realized by coupling ALM-ASA with a well-developed automation device for sample processing.     

High-Throughput Genotyping by Coupling Adapter-Ligation Mediated Allele-Specific Amplification with Microplate Array Parallel Gel Electrophoresis

Recently, we have developed a method of adapter-ligation mediated allele-specific amplification (ALM-ASA) for simultaneously typing multiple single nucleotide polymorphisms (SNPs) at a low cost. We usually use agarose gel-electrophoresis for analyzing PCR products. As the processes of sampling and PCR can be carried out at a format of 96-well or 384-well, the throughput-bottleneck of whole process of ALM-ASA is only the agarose gel-electrophoresis. Here we improved the typing throughput of ALM-ASA by using a microplate array parallel gel electrophoresis (MAPGE) system, with which 96 amplicons can be detected at a time. By coupling with multiplexed preamplification, seven SNPs distributed on four different human genes (IL1A (549C>T), 1L1B (794C>T and 5277C>T), IL10 (2940G>A, 3203C>T, and 3430C>A), and TNFA (1431G>A)) were successfully typed. The optimization of allele-specific primers in ALM-ASA was performed by the software of “SNiPdesigner” which was designed especially for ALM-ASA. We also demonstrated that the specificity of ALM-ASA assay for SNP typing is superior to that of amplification refractory mutation system (ARMS).     

Single nucleotide polymorphism genotyping using allele-specific PCR and fluorescence melting curves

We present a PCR method for identification of single nucleotide polymorphisms (SNPs), using allele-specific primers designed for selective amplification of each allele. Matching the SNP at the 3' end of the forward or reverse primer, and additionally incorporating a 3' mismatch to prevent amplification of the incorrect allele, results in selectivity of the allele-specific primers. DNA melting analysis with fluorescent SYBR Green affords detection of the PCR products. By incorporating a GC-rich sequence into one of the two allele-specific primers to increase the melting temperature, both alleles can be measured simultaneously at their respective melting temperatures. Applying the DNA melting analysis to SNPs in ApoE and ABCA1 yielded results identical to those obtained with other genotyping methods. This provides a cost-effective, high-throughput method for amplification and scoring of SNPs.     

MARA: a novel approach for highly multiplexed locus-specific SNP genotyping using high-density DNA oligonucleotide arrays

We have developed a locus-specific DNA target preparation method for highly multiplexed single nucleotide polymorphism (SNP) genotyping called MARA (Multiplexed Anchored Runoff Amplification). The approach uses a single primer per SNP in conjunction with restriction enzyme digested, adapter-ligated human genomic DNA. Each primer is composed of common sequence at the 5′ end followed by locus-specific sequence at the 3′ end. Following a primary reaction in which locus-specific products are generated, a secondary universal amplification is carried out using a generic primer pair corresponding to the oligonucleotide and genomic DNA adapter sequences. Allele discrimination is achieved by hybridization to high-density DNA oligonucleotide arrays. Initial multiplex reactions containing either 250 primers or 750 primers across nine DNA samples demonstrated an average sample call rate of ~95% for 250- and 750-plex MARA. We have also evaluated >1000- and 4000-primer plex MARA to genotype SNPs from human chromosome 21. We have identified a subset of SNPs corresponding to a primer conversion rate of ~75%, which show an average call rate over 95% and concordance >99% across seven DNA samples. Thus, MARA may potentially improve the throughput of SNP genotyping when coupled with allele discrimination on high-density arrays by allowing levels of multiplexing during target generation that far exceed the capacity of traditional multiplex PCR.     

Single-reaction for SNP Genotyping on Agarose Gel by Allele-specific PCR in Black Poplar (Populus nigra L.)

The wide development of single nucleotide polymorphism (SNP) markers also in non-model species increases the need for inexpensive methods that do not require sophisticated equipment and time for optimization. This work presents a new method for polymerase chain reaction (PCR) amplification of multiple specific alleles (PAMSA), which allows efficient discrimination of SNP polymorphisms in one reaction tube with standard PCR conditions. This improved PAMSA requires only three unlabeled primers: a common reverse primer and two allele-specific primers having a tail of different length to differentiate the two SNP alleles by the size of amplification products on agarose gel. A destabilizing mismatch within the five bases of the 3′ end is also added to improve the allele specificity. To validate the accuracy of this method, 94 full-sib individuals were genotyped with three SNPs and compared to the genotypes obtained by cleaved amplified polymorphic sequence (CAPS) or derived CAPS. This method is flexible, inexpensive, and well suited for high throughput and automated genotyping.     

A simple method for genotyping the bovine growth hormone gene

An allele-specific polymerase chain reaction (PCR) amplification method was developed to determine the genotypes at the bovine growth hormone locus that result from two nucleotide substitutions in exon 5 of the gene. This method was a multiplex PCR (ASM–PCR) employing a common primer pair and two allele-specific reverse primers. The common primer pair was designed to amplify a target region containing two substitution points from the three variants of the bovine growth hormone gene. The allele-specific primers were designed to be mismatched with other genotypes at the 3' end of oligonucleotides. When the common and allele-specific reverse primers competed with each other, the shorter allele-specific fragments were amplified preferentially. Consequently, the PCR products of the variant-specific fragments were 347, 483 and 656 bp for alleles A, B and C, respectively, of the bovine growth hormone gene. Genotypes of the bovine growth hormone gene were easily identified by agarose gel electrophoresis of PCR products. The results suggested that this multiplex PCR method would be useful for identification of genetic variants caused by point mutations.     

A Unique Primer with an Inosine Chain at the 5′-Terminus Improves the Reliability of SNP Analysis Using the PCR-Amplified Product Length Polymorphism Method

Polymerase chain reaction-amplified product length polymorphism (PCR-APLP) is one of the most convenient and reliable methods for single nucleotide polymorphism (SNP) analysis. This method is based on PCR, but uses allele-specific primers containing SNP sites at the 3′-terminus of each primer. To use this method at least two allele-specific primers and one “counter-primer”, which serves as a common forward or reverse primer of the allele-specific primers, are required. The allele-specific primers have SNP sites at the 3′-terminus, and another primer should have a few non-complementary flaps at the 5′-terminus to detect SNPs by determining the difference of amplicon length by PCR and subsequent electrophoresis. A major disadvantage of the addition of a non-complementary flap is the non-specific annealing of the primer with non-complementary flaps. However, a design principle for avoiding this undesired annealing has not been fully established, therefore, it is often difficult to design effective APLP primers. Here, we report allele-specific primers with an inosine chain at the 5′-terminus for PCR-APLP analysis. This unique design improves the competitiveness of allele-specific primers and the reliability of SNP analysis when using the PCR-APLP method.     

Molecular haplotype determination using allele-specific PCR and pyrosequencing technology

Haplotyping of single-nucleotide polymorphisms (SNPs) is usually performed statistically by computational analysis or by time-consuming cloning techniques. Here we present a simple molecular approach for reliable haplotype determination on individual samples. The procedure is based on allele-specific PCR (AS-PCR) in combination with Pyrosequencing analysis. AS-PCR primers for each allelic variant of the investigated SNPs were used. A mismatch introduced at the second base from the 3' end dramatically improved allele specificity. Analysis of multiple SNPs on amplified fragments using Pyrosequencing technology allowed determination of haplotypes. Genotyping of heterozygote samples after AS-PCR gave a typical monoallelic pattern at each SNP, in which the identity of the present allele depended on the allele-specific initial amplification. Haplotype determination by the described procedure proved to be highly reliable. The results obtained by Pyrosequencing technology have the benefit of being truly quantitative, enabling detection of any nonspecific allele amplification.