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通过多重固相扩增和荧光微测序进行单核苷酸多态性基因分型

SNP genotyping by multiplexed solid-phase amplification and fluorescent minisequencing.

作者信息

Shapero M H, Leuther K K, Nguyen A, Scott M, Jones K W

机构信息

Affymax Inc., Palo Alto, California 94304, USA.

出版信息

Genome Res. 2001 Nov;11(11):1926-34. doi: 10.1101/gr.205001.

DOI:10.1101/gr.205001
PMID:11691857
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC311152/
Abstract

The emerging role of single-nucleotide polymorphisms (SNPs) in clinical association and pharmacogenetic studies has created a need for high-throughput genotyping technologies. We describe a novel method for multiplexed genotyping of SNPs that employs PCR amplification on microspheres. Oligonucleotide PCR primers were designed for each polymorphic locus such that one of the primers contained a recognition site for BbvI (a type IIS restriction enzyme), followed by 11 nucleotides of locus-specific sequence, which reside immediately upstream of the polymorphic site. Following amplification, this configuration allows for any SNP to be exposed by BbvI digestion and interrogated via primer extension, four-color minisequencing. Primers containing 5' acrylamide groups were attached covalently to the solid support through copolymerization into acrylamide beads. Highly multiplexed solid-phase amplification using human genomic DNA was demonstrated with 57 beads in a single reaction. Multiplexed amplification and minisequencing reactions using bead sets representing eight polymorphic loci were carried out with genomic DNA from eight individuals. Sixty-three of 64 genotypes were accurately determined by this method when compared to genotypes determined by restriction-enzyme digestion of PCR products. This method provides an accurate, robust approach toward multiplexed genotyping that may facilitate the use of SNPs in such diverse applications as pharmacogenetics and genome-wide association studies for complex genetic diseases.

摘要

单核苷酸多态性(SNP)在临床关联研究和药物遗传学研究中日益凸显的作用,使得对高通量基因分型技术的需求应运而生。我们描述了一种用于SNP多重基因分型的新方法,该方法采用在微球上进行PCR扩增。针对每个多态性位点设计寡核苷酸PCR引物,使得其中一个引物包含BbvI(一种IIS型限制性内切酶)的识别位点,随后是11个位点特异性序列的核苷酸,这些核苷酸位于多态性位点的紧邻上游。扩增后,这种结构允许任何SNP通过BbvI消化暴露,并通过引物延伸、四色微测序进行检测。含有5'丙烯酰胺基团的引物通过共聚到丙烯酰胺珠中而共价连接到固相支持物上。在单个反应中使用57个珠子对人基因组DNA进行了高度多重的固相扩增。使用代表八个多态性位点的珠子组对来自八个个体的基因组DNA进行了多重扩增和微测序反应。与通过PCR产物的限制性酶切确定的基因型相比,该方法准确确定了64个基因型中的63个。该方法为多重基因分型提供了一种准确、稳健的方法,可能有助于在药物遗传学和复杂遗传疾病的全基因组关联研究等多种应用中使用SNP。

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