通过小扩增子的高分辨率熔解对单核苷酸多态性进行基因分型。

Genotyping of single-nucleotide polymorphisms by high-resolution melting of small amplicons.

作者信息

Liew Michael, Pryor Robert, Palais Robert, Meadows Cindy, Erali Maria, Lyon Elaine, Wittwer Carl

机构信息

Institute for Clinical and Experimental Pathology, ARUP, Salt Lake City, UT, USA.

出版信息

Clin Chem. 2004 Jul;50(7):1156-64. doi: 10.1373/clinchem.2004.032136.

DOI:10.1373/clinchem.2004.032136

PMID:15229148

Abstract

BACKGROUND

High-resolution melting of PCR amplicons with the DNA dye LCGreen I was recently introduced as a homogeneous, closed-tube method of genotyping that does not require probes or real-time PCR. We adapted this system to genotype single-nucleotide polymorphisms (SNPs) after rapid-cycle PCR (12 min) of small amplicons (</=50 bp).

METHODS

Engineered plasmids were used to study all possible SNP base changes. In addition, clinical protocols for factor V (Leiden) 1691G>A, prothrombin 20210G>A, methylenetetrahydrofolate reductase (MTHFR) 1298A>C, hemochromatosis (HFE) 187C>G, and beta-globin (hemoglobin S) 17A>T were developed. LCGreen I was included in the reaction mixture before PCR, and high-resolution melting was obtained within 2 min after amplification.

RESULTS

In all cases, heterozygotes were easily identified because heteroduplexes altered the shape of the melting curves. Approximately 84% of human SNPs involve a base exchange between A::T and G::C base pairs, and the homozygotes are easily genotyped by melting temperatures (T(m)s) that differ by 0.8-1.4 degrees C. However, in approximately 16% of SNPs, the bases only switch strands and preserve the base pair, producing very small T(m) differences between homozygotes (<0.4 degrees C). Although most of these cases can be genotyped by T(m), one-fourth (4% of total SNPs) show nearest-neighbor symmetry, and, as predicted, the homozygotes cannot be resolved from each other. In these cases, adding 15% of a known homozygous genotype to unknown samples allows melting curve separation of all three genotypes. This approach was used for the HFE 187C>G protocol, but, as predicted from the sequence changes, was not needed for the other four clinical protocols.

CONCLUSIONS

SNP genotyping by high-resolution melting analysis is simple, rapid, and inexpensive, requiring only PCR, a DNA dye, and melting instrumentation. The method is closed-tube, performed without probes or real-time PCR, and can be completed in less than 2 min after completion of PCR.

摘要

背景

近期引入了一种使用DNA染料LCGreen I对PCR扩增子进行高分辨率熔解分析的方法，作为一种无需探针或实时PCR的均相闭管基因分型方法。我们对该系统进行了改进，用于在小扩增子（≤50 bp）快速循环PCR（12分钟）后对单核苷酸多态性（SNP）进行基因分型。

方法

使用工程化质粒研究所有可能的SNP碱基变化。此外，还制定了针对因子V（莱顿）1691G>A、凝血酶原20210G>A、亚甲基四氢叶酸还原酶（MTHFR）1298A>C、血色素沉着症（HFE）187C>G和β-珠蛋白（血红蛋白S）17A>T的临床检测方案。在PCR之前将LCGreen I加入反应混合物中，扩增后2分钟内即可获得高分辨率熔解曲线。

结果

在所有情况下，杂合子都很容易被识别，因为异源双链改变了熔解曲线的形状。大约84%的人类SNP涉及A::T和G::C碱基对之间的碱基交换，纯合子通过相差0.8 - 1.4℃的熔解温度（Tm）很容易进行基因分型。然而，在大约16%的SNP中，碱基仅转换链而保留碱基对，导致纯合子之间的Tm差异非常小（<0.4℃）。尽管这些情况中的大多数可以通过Tm进行基因分型，但四分之一（占总SNP的4%）表现出最近邻对称性，正如所预测的那样，纯合子无法相互区分。在这些情况下，向未知样品中加入15%已知的纯合基因型可实现所有三种基因型的熔解曲线分离。该方法用于HFE 187C>G检测方案，但正如从序列变化所预测的那样，其他四个临床检测方案不需要该方法。