High-throughput amplicon scanning of the TP53 gene in breast cancer using high-resolution fluorescent melting curve analyses and automatic mutation calling

Bastien, Roy R. L.; Lewis, Tracey; Hawkes, Jason E.; Quackenbush, John; Robbins, Thomas C.; Palazzo, Juan; Perou, Charles M.; Bernard, Philip S.

doi:10.1002/humu.20726

Cited by 45 publications

(51 citation statements)

References 43 publications

(50 reference statements)

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“…High-resolution melting has been used clinically to detect somatic changes in select exons of oncogenes such as EGFR, 53 KRAS, 54 PDGFRA, 55 KIT, 56 BRAF, 57 and TP53. 58 In tumors with mixed populations of tumor and normal cells, the sensitivity of scanning (Ͻ10%) is superior to sequencing (ϳ20%). 59 In genetics, the method has been applied to BRCA1/2, 60,61 cystic fibrosis, 52,62 hereditary hemorrhagic telangiectasia, 37 hemophilia, 63,64 and Charcot-Marie-Tooth disease, 65 and several others.…”

Section: Mutation Scanning By Meltingmentioning

confidence: 99%

LightCycler Technology in Molecular Diagnostics

Lyon

Wittwer

2009

The Journal of Molecular Diagnostics

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From the first report of the LightCycler as a real-time polymerase chain reaction (PCR) instrument 1 clinical laboratories quickly realized its potential as a diagnostic tool. Quantitative applications important for infectious disease and oncology applications were followed by genotyping assays that took advantage of accurate temperature control to melt DNA amplicons or probe/amplicon duplexes. The first Food and Drug Administration-cleared molecular genetic assays were developed for this platform, specifically genotyping single base variants in F5 and F2. According to a College of American Pathologists survey, 2 ϳ30% of clinical laboratories report using the LightCycler for these two assays. This article will review the history of LightCycler technology, focusing on those applications widely incorporated into molecular diagnostics. In addition we will review recent developments that may impact future clinical testing.Real-time PCR instruments simultaneously amplify and detect, eliminating the need to open tubes containing PCR amplicon and therefore reducing the risk of future contamination. Fluorescent dyes or probes allow continuous monitoring as template DNA is amplified.3 By monitoring fluorescence every cycle, the amount of original target can be calculated. By monitoring fluorescence as the temperature changes, genotyping and heterozygote scanning can be performed by melting analysis, often removing the need for downstream analysis.The first two platforms developed for real-time PCR were the LightCycler (Roche, Indianapolis, IN) and the ABI 7700 (Applied Biosystems, Foster City, CA). The instruments were as different as the groups that created them. At the time, ABI was the undisputed corporate leader of PCR technology and the 7700 was a large 96-well laser-based instrument focused on throughput.

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Section: Mutation Scanning By Meltingmentioning

confidence: 99%

LightCycler Technology in Molecular Diagnostics

Lyon

Wittwer

2009

The Journal of Molecular Diagnostics

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“…High-resolution melting (HRM or HRMA) is an effective method to screen for sequence variation and has been effectively used to assess genes involving inborn errors of metabolism, cancer susceptibility, and other genes whose dysfunction is associated with disease [Bastien et al, 2008;De Leeneer et al, 2008;Dobrowolski et al, 2007aDobrowolski et al, , 2007bDobrowolski et al, , 2005Erali et al, 2008;Laurie and George, 2009]. HRM profiling identifies the presence of sequence variants by deviation in the shape of a post-PCR melting profile using probe-based and amplicon-based strategies [Dobrowolski et al, 2007a[Dobrowolski et al, , 2007bMontgomery et al, 2007;Zhou et al, 2004].…”

Section: Introductionmentioning

confidence: 99%

Identifying sequence variants in the human mitochondrial genome using high-resolution melt (HRM) profiling

Dobrowolski¹,

Hendrickx

Bosch

et al. 2009

Hum. Mutat.

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Identifying mitochondrial DNA (mtDNA) sequence variants in human diseases is complicated. Many pathological mutations are heteroplasmic, with the mutant allele represented at highly variable percentages. Highresolution melt (HRM or HRMA) profiling was applied to comprehensive assessment of the mitochondrial genome and targeted assessment of recognized pathological mutations. The assay panel providing comprehensive coverage of the mitochondrial genome utilizes 36 overlapping fragments (301-658 bp) that employ a common PCR protocol. The comprehensive assay identified heteroplasmic mutation in 33 out of 33 patient specimens tested. Allele fraction among the specimens ranged from 1 to 100%. The comprehensive assay panel was also used to assess 125 mtDNA specimens from healthy donors, which identified 431 unique sequence variants. Utilizing the comprehensive mtDNA panel, the mitochondrial genome of a patient specimen may be assessed in less than 1 day using a single 384-well plate or two 96-well plates. Specific assays were used to identify the myopathy, encephalopathy, lactic acidosis and stroke-like episodes (MELAS) mutation m.3243A4G, myoclonus epilepsy, ragged red fibers (MERRF) mutation m.8344A4G, and m.1555A4G associated with aminoglycoside hearing loss. These assays employ a calibrated, amplicon-based strategy that is exceedingly simple in design, utilization, and interpretation, yet provides sensitivity to detect variants at and below 10% heteroplasmy. Turnaround time for the genotyping tests is about 1 hr.

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“…Good DNA quality is essential for HRM analysis; therefore, high-yield genomic DNA from peripheral blood leukocytes or saliva is the preferred material for analysis. However, the technique has already been successfully employed to scan for somatic mutations in various genes in archival FFPE tissues prone to DNA fragmentation (33 ), which is particularly appealing for retrospective studies and is within the framework of specimen processing in clinical pathology (34 ). To the best of our knowledge, our study is the first evaluation of 2 different instruments and implemented software modules for HRM assay on tumor DNA extracted from archival tumor material and of MSI detection by HRM.…”

Section: Discussionmentioning

confidence: 99%

Microsatellite Instability Detection by High-Resolution Melting Analysis

et al. 2010

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BACKGROUND:Microsatellite instability (MSI) is an important marker for screening for hereditary nonpolyposis colorectal cancer (Lynch syndrome) as well as a prognostic and predictive marker for sporadic colorectal cancer (CRC). The mononucleotide microsatellite marker panel is a well-established and superior alternative to the traditional Bethesda MSI analysis panel, and does not require testing for corresponding normal DNA. The most common MSI detection techniques-fluorescent capillary electrophoresis and denaturing HPLC (DHPLC)-both have advantages and drawbacks. A new high-resolution melting (HRM) analysis method enables rapid identification of heteroduplexes in amplicons by their lower thermal stability, a technique that overcomes the main shortcomings of capillary electrophoresis and DHPLC.

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High-throughput amplicon scanning of the TP53 gene in breast cancer using high-resolution fluorescent melting curve analyses and automatic mutation calling

Cited by 45 publications

References 43 publications

LightCycler Technology in Molecular Diagnostics

LightCycler Technology in Molecular Diagnostics

Identifying sequence variants in the human mitochondrial genome using high-resolution melt (HRM) profiling

Microsatellite Instability Detection by High-Resolution Melting Analysis

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