词条 | COLD-PCR |
释义 |
COLD-PCR (co-amplification at lower denaturation temperature-PCR) is a modified Polymerase Chain Reaction (PCR) protocol that enriches variant alleles from a mixture of wildtype and mutation-containing DNA. The ability to preferentially amplify and identify minority alleles and low-level somatic DNA mutations in the presence of excess wildtype alleles is useful for the detection of mutations. Detection of mutations is important in the case of early cancer detection from tissue biopsies and body fluids such as blood plasma or serum, assessment of residual disease after surgery or chemotherapy, disease staging and molecular profiling for prognosis or tailoring therapy to individual patients, and monitoring of therapy outcome and cancer remission or relapse. Common PCR will amplify both the major (wildtype) and minor (mutant) alleles with the same efficiency, occluding the ability to easily detect the presence of low-level mutations. The capacity to detect a mutation in a mixture of variant/wildtype DNA is valuable because this mixture of variant DNAs can occur when provided with a heterogeneous sample – as is often the case with cancer biopsies. Currently, traditional PCR is used in tandem with a number of different downstream assays for genotyping or the detection of somatic mutations. These can include the use of amplified DNA for RFLP analysis, MALDI-TOF (matrix-assisted laser-desorption–time-of-flight) genotyping, or direct sequencing for detection of mutations by Sanger sequencing or pyrosequencing. Replacing traditional PCR with COLD-PCR for these downstream assays will increase the reliability in detecting mutations from mixed samples, including tumors and body fluids. COLD-PCR Method OverviewThe underlying principle of COLD-PCR is that single nucleotide mismatches will slightly alter the melting temperature (Tm) of the double-stranded DNA. Depending on the sequence context and position of the mismatch, Tm changes of 0.2-1.5 °C (0.36-2.7 °F). are common for sequences up to 200bp or higher. Knowing this the authors of the protocol took advantage of two observations:
Keeping these principles in mind the authors developed the following general protocol:
There are two forms of COLD-PCR that have been developed to date. Full COLD-PCR and Fast COLD-PCR. Full COLD-PCRFull COLD-PCR is identical to the protocol outlined above. These five stages are used for each round of amplification. Fast COLD-PCRFast COLD-PCR differs from Full COLD-PCR in that the denaturation and intermediate annealing stages are skipped. This is because, in some cases, the preferential amplification of the mutant DNA is so great that ensuring the formation of the mutant/wildtype heteroduplex DNA is not needed. Thus the denaturation can occur at the Tc, proceed to primer annealing, and then polymerase-mediated extension. Each round of amplification will include these three stages in that order. By utilizing the lower denaturation temperature, the reaction will discriminate towards the products with the lower Tm – i.e. the variant alleles. Fast COLD-PCR produces much faster results due to the shortened protocol. However, it is important to note that Full COLD-PCR is essential for amplification of all possible mutations in the starting mixture of DNA. Two-round COLD-PCR is a modified version of Fast COLD-PCR. During the second round of Fast COLD-PCR nested primers are used. This improves the sensitivity of mutation detection compared to one-round Fast COLD-PCR.[1] Use of COLD-PCR to DateCOLD-PCR has been used to improve the reliability of a number of different assays that traditionally use conventional PCR. RFLP and COLD-PCRA restriction fragment length polymorphism results in the cleavage (or absence thereof) of DNA for a specific mutation by a selected restriction enzyme that will not cleave the wildtype DNA. In a study using a mixture of wildtype and mutation containing DNA amplified by regular PCR or COLD-PCR, COLD-PCR preceding RFLP analysis was shown to improve the mutation detection by 10-20 fold.[2] Sanger Sequencing and COLD-PCRSanger sequencing recently was used to evaluate the enrichment of mutant DNA from a mixture of 1:20 mutant:wildtype DNA. The variant DNA containing a mutation was obtained from a breast cancer cell line known to contain p53 mutations.[1] Comparison of Sanger sequencing chromatograms indicated that the mutant allele was enriched 13 fold when COLD-PCR was used compared to traditional PCR alone.[1] This was determined by the size of the peaks on the chromatogram at the variant allele location. As well, COLD-PCR was used to detect p53 mutations from lung-adenocarcinoma samples. The study was able to detect 8 low level (under 20% abundance) mutations that would likely have been missed using conventional methods that don’t enrich for variant sequence DNA . Pyrosequencing and COLD-PCRSimilar to its use in direct Sanger sequencing, with pyrosequencing COLD-PCR was shown to be capable of detecting mutations that had a prevalence 0.5-1% from the samples used.[3] COLD-PCR was used to detect p53 and KRAS mutations by pyrosequencing, and was shown to outperform conventional PCR in both cases. MALDI-TOF and COLD-PCRThe same research group that developed COLD-PCR and used it to compare the sensitivity of regular PCR for genotyping with direct Sanger sequencing, RFLP, and pyrosequencing, also ran a similar study using MALDI-TOF as a downstream application for detecting mutations. Their results indicated that COLD-PCR could enrich mutation sequences from a mixture of DNA by 10-100 fold and that mutations with an initial prevalence of 0.1-0.5% would be detectable.[4] Compared to the 5-10% low-level detection rate expected with traditional PCR. QPCR and COLD-PCRCOLD-PCR run on a quantitative PCR machine, using TaqMan probes specific for a mutation, was shown to increase the measured difference between mutant and wildtype samples.[4] Advantages of COLD-PCR
Disadvantages of COLD-PCR
HistoryCOLD-PCR was originally described by Li et al. in a Nature Medicine paper published in 2008 from Dr. Mike Makrigiorgos’s lab group at the Dana Farber Cancer Institute of Harvard Medical School.[2] As summarized above, the technology has been used in a number of proof-of-principle experiments and medical research diagnostic experiments. Recently, the COLD-PCR technology has been licensed by Transgenomic, Inc. The licensing terms include the exclusive rights to commercialize the technology combined with Sanger sequencing. The plans are to develop commercial applications that will allow for rapid high-sensitivity detection of low-level somatic and mitochondrial DNA mutations.[5] AlternativesOther technologies are available for the detection of minority DNA mutations, and these methods can be segregated into their ability to enrich for and detect either known or unknown mutations.[6] See also
References1. ^1 2 {{cite journal |vauthors=Li J, Milbury CA, Li C, Makrigiorgos GM |title=Two-round COLD-PCR-based Sanger sequencing identifies a novel spectrum of low-level mutations in lung adenocarcinoma |journal=Human Mutation |volume=30 |issue=11 |pages=1583–90 |date=November 2009 |pmid=19760750 |pmc=2784016 |doi=10.1002/humu.21112}} 2. ^1 {{cite journal |vauthors=Li J, Wang L, Mamon H, Kulke MH, Berbeco R, Makrigiorgos GM |title=Replacing PCR with COLD-PCR enriches variant DNA sequences and redefines the sensitivity of genetic testing |journal=Nature Medicine |volume=14 |issue=5 |pages=579–84 |date=May 2008 |pmid=18408729 |doi=10.1038/nm1708}} 3. ^{{cite journal |vauthors=Zuo Z, Chen SS, Chandra PK |title=Application of COLD-PCR for improved detection of KRAS mutations in clinical samples |journal=Modern Pathology |volume=22 |issue=8 |pages=1023–31 |date=August 2009 |pmid=19430420 |doi=10.1038/modpathol.2009.59|display-authors=etal}} 4. ^1 {{cite journal |vauthors=Li J, Makrigiorgos GM |title=COLD-PCR: a new platform for highly improved mutation detection in cancer and genetic testing |journal=Biochemical Society Transactions |volume=37 |issue=2 |pages=427–32 |date=April 2009 |pmid=19290875 |doi=10.1042/BST0370427}} 5. ^{{cite web|author=Laboratorytalk editorial team|date=Oct 2009|title=Transgenomics licenses COLD-PCR technology|url=http://www.laboratorytalk.com/news/trb/trb121.html|access-date=2010-03-04|archive-url=https://web.archive.org/web/20110718232900/http://www.laboratorytalk.com/news/trb/trb121.html#|archive-date=2011-07-18|dead-url=yes|df=}} 6. ^{{cite journal |vauthors=Milbury CA, Li J, Makrigiorgos GM |title=PCR-Based Methods for the Enrichment of Minority Alleles and Mutations |journal=Clinical Chemistry |volume=55 |issue=4 |pages=632–40 |date=April 2009 |pmid=19201784 |pmc=2811432 |doi=10.1373/clinchem.2008.113035}} 6 : Molecular biology|Molecular biology techniques|Polymerase chain reaction|Laboratory techniques|Biotechnology|DNA profiling techniques |
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