Gudrun H. Reed

High-Resolution Genotyping by Amplicon Melting Analysis Using LCGreen

BACKGROUND High-resolution amplicon melting analysis was recently introduced as a closed-tube method for genotyping and mutation scanning (Gundry et al. Clin Chem 2003;49:396-406). The technique required a fluorescently labeled primer and was limited to the detection of mutations residing in the melting domain of the labeled primer. Our aim was to develop a closed-tube system for genotyping and mutation scanning that did not require labeled oligonucleotides. METHODS We studied polymorphisms in the hydroxytryptamine receptor 2A (HTR2A) gene (T102C), beta-globin (hemoglobins S and C) gene, and cystic fibrosis (F508del, F508C, I507del) gene. PCR was performed in the presence of the double-stranded DNA dye LCGreen, and high-resolution amplicon melting curves were obtained. After fluorescence normalization, temperature adjustment, and/or difference analysis, sequence alterations were distinguished by curve shape and/or position. Heterozygous DNA was identified by the low-temperature melting of heteroduplexes not observed with other dyes commonly used in real-time PCR. RESULTS The six common beta-globin genotypes (AA, AS, AC, SS, CC, and SC) were all distinguished in a 110-bp amplicon. The HTR2A single-nucleotide polymorphism was genotyped in a 544-bp fragment that split into two melting domains. Because melting curve acquisition required only 1-2 min, amplification and analysis were achieved in 10-20 min with rapid cycling conditions. CONCLUSIONS High-resolution melting analysis of PCR products amplified in the presence of LCGreen can identify both heterozygous and homozygous sequence variants. The technique requires only the usual unlabeled primers and a generic double-stranded DNA dye added before PCR for amplicon genotyping, and is a promising method for mutation screening.

High-resolution DNA melting analysis for simple and efficient molecular diagnostics

High-resolution melting of DNA is a simple solution for genotyping, mutation scanning and sequence matching. The melting profile of a PCR product depends on its GC content, length, sequence and heterozygosity and is best monitored with saturating dyes that fluoresce in the presence of double-stranded DNA. Genotyping of most variants is possible by the melting temperature of the PCR products, while all variants can be genotyped with unlabeled probes. Mutation scanning and sequence matching depend on sequence differences that result in heteroduplexes that change the shape of the melting curve. High-resolution DNA melting has several advantages over other genotyping and scanning methods, including an inexpensive closed tube format that is homogenous, accurate and rapid. Owing to its simplicity and speed, the method is a good fit for personalized medicine as a rapid, inexpensive method to predict therapeutic response.

Rapid Genetic Analysis of X-Linked Chronic Granulomatous Disease by High-Resolution Melting

High-resolution melting analysis was applied to X-linked chronic granulomatous disease, a rare disorder resulting from mutations in CYBB. Melting curves of the 13 PCR products bracketing CYBB exons were predicted by Polands algorithm and compared with observed curves from 96 normal individuals. Primer plates were prepared robotically in batches and dried, greatly simplifying the 3- to 6-hour workflow that included DNA isolation, PCR, melting, and cycle sequencing of any positive products. Small point mutations or insertions/deletions were detected by mixing the hemizygous male DNA with normal male DNA to produce artificial heterozygotes, whereas detection of gross deletions was performed on unmixed samples. Eighteen validation samples and 22 clinical kindreds were analyzed for CYBB mutations. All blinded validation samples were correctly identified. The clinical probands were identified after screening for neutrophil oxidase activity. Nineteen different mutations were found, including seven near intron-exon boundaries predicting splicing defects, five substitutions within exons, three small deletions predicting premature termination, and four gross deletions of multiple exons. Ten novel mutations were found, including (c.) two missense (730T>A, 134T>G), one nonsense (90C>A), four splice site defects (45 + 1G>T, 674 + 4A>G, 1461 + 2delT, and 1462-2A>C), two small deletions (636delT, 1661_1662delCT), and one gross deletion of exons 6 to 8. High-resolution melting can provide timely diagnosis at low cost for effective clinical management of rare, genetic primary immunodeficiency disorders.

High-Resolution Melting Curve Analysis for Molecular Diagnostics

Publisher Summary Melting is non-destructive, allowing subsequent analysis of the PCR product when necessary. The simplicity and speed of high-resolution melting analysis are reflected by its increasing use in molecular diagnostics. The method is enabled by high-resolution melting instruments and dsDNA dyes that detect heteroduplexes. This chapter focuses on the high-resolution melting technique for genotyping, variant scanning, and sequence matching. Traditional genotyping by melting analysis relies on the use of labeled probes. Only those variants that are under the probe are detected. Conventional variant scanning identifies variants anywhere within a polymerase chain reaction (PCR) product, but requires separation of the mixture through a gel or other matrix. Both genotyping and scanning are performed with only a dsDNA dye and two primers. For fine discrimination of multiple variants within a particular region, an unlabeled probe or snapback primer tail can be included. High-resolution melting can rapidly establish sequence identity when specific genotyping is not required. Examples include HLA analysis for transplantation compatibility, repeat typing for identity matching, and genetic mapping. Dyes that detect heteroduplexes are critical for scanning and genotyping applications. Scanning and small amplicon melting methods depend strongly on instrument resolution, while genotyping with unlabeled probes or snapback primers can be performed adequately on standard instrumentation. These methods are fast, affordable, and simple.