Single base pair mutation analysis by PNA directed PCR clamping (original) (raw)
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2021
In the development of personalized medicine, the ultrasensitive detection of point mutations that correlate with diseases is important to improve the efficacy of treatment and guide clinical medication. In this study, locked nucleic acid (LNA) was introduced as an amplification suppressor of a massive number of wild-type alleles in an amplification refractory mutation system (ARMS) to achieve the detection of low-abundance mutations with high specificity and sensitivity of at least 0.1%. By integrating the length of clamp, base type, number and position of LNA modifications, we have established a “shortest length with the fewest LNA bases” principle from which each LNA base would play a key role in the affinity and the ability of single base discrimination could be improve. Finally, based on this LNA design guideline, a series of the most important single point mutation sites of epidermal growth factor receptor (EGFR) was verified to achieve the optimal amplification state which as ...
Detection of point mutations with a modified ligase chain reaction (Gap-LCR)
Nucleic Acids Research, 1995
DNA amplification systems are powerful technologies with the potential to impact a wide range of diagnostic applications. In this study we explored the feasibility and limitations of a modified ligase chain reaction (Gap-LCR) in detection and discrimination of DNAs that differ by a single base. LCR is a DNA amplification technology based on the ligation of two pairs of synthetic oligonucleotides which hybridize at adjacent positions to complementary strands of a target DNA. Multiple rounds of denaturation, annealing and ligation with a thermostable ligase result in the exponential amplification of the target DNA. A modification of LCR, Gap-LCR was developed to reduce the background generated by target-independent, blunt-end ligation. In Gap-LCR, DNA polymerase fills in a gap between annealed probes which are subsequently joined by DNA ligase. We have designed synthetic DNA targets with single base pair differences and analyzed them in a system where three common probes plus an allelespecific probe were used. A single base mismatch either at the ultimate 3' end or penultimate 3' end of the allele specific probe was sufficient for discrimination, though better discrimination was obtained with a mismatch at the penultimate 3' position. Comparison of Gap-LCR to allele-specific PCR (ASPCR) suggested that Gap-LCR has the advantage of having the additive effect of polymerase and ligase on specificity. As a model system, Gap-LCR was tested on a mutation in the reverse transcriptase gene of HIV, specifically, one of the mutations that confers AZT resistance. Mutant DNA could be detected and discriminated in the presence of up to 10 000-fold excess of wild-type DNA.
Single-molecule PCR: an artifact-free PCR approach for the analysis of somatic mutations
Expert Review of Molecular Diagnostics, 2005
A critical review of the clone-by-clone approach to the analysis of complex spectra of somatic mutations is presented. Studying of a priori, unknown, somatic mutations requires painstaking analysis of complex mixtures of multiple mutant and non-mutant DNA molecules. If mutant fractions are sufficiently high, these mixtures can be dissected by cloning of individual DNA molecules and scanning of the individual clones for mutations (e.g., by sequencing). Currently, the majority of such cloning is performed using PCR fragments. However, post-PCR cloning may result in various PCR artifacts -PCR errors and jumping PCR -and preferential amplification of certain mutations. This review argues that single-molecule PCR is a simple alternative that promises to evade the disadvantages inherent to post-PCR cloning and enhance mutational analysis in the future.
Nucleic Acids Research
The polymerase chain reaction (PCR) is a versatile method to amplify specific DNA with oligonucleotide primers. By designing degenerate PCR primers based on amino acid sequences that are highly conserved among all known gene family members, new members of a multigene family can be identified. The inherent weakness of this approach is that the degenerate primers will amplify previously identified, in addition to new, family members. To specifically address this problem, we synthesized a specific RNA for each known family member so that it hybridized to one strand of the template, adjacent to the 3′-end of the primer, allowing the degenerate primer to bind yet preventing extension by DNA polymerase. To test our strategy, we used known members of the soluble, nitric oxide-sensitive guanylyl cyclase family as our templates and degenerate primers that discriminate this family from other guanylyl cyclases. We demonstrate that amplification of known members of this family is effectively and specifically inhibited by the corresponding RNAs, alone or in combination. This robust method can be adapted to any application where multiple PCR products are amplified, as long as the sequence of the desired and the undesired PCR product(s) is sufficiently distinct between the primers.
Use of a PNA probe to block DNA-mediated PCR product formation in prokaryotic RT-PCR
BioTechniques, 2007
A novel method eliminating DNA-mediated PCR product formation in reverse transcription PCR (RT-PCR) amplification of specific RNA sequences is described. The method exploits the higher melting temperature values of peptide nucleic acid (PNA)/DNA duplexes compared with DNA/DNA duplexes by binding a sequence-specific PNA probe to a genomic sequence immediately overlapping one of the PCR-primer attachment sites within the sequence of interest. Hybridization of the blocking probe precludes primer attachment to DNA without affecting attachment of the same primer to the reverse transcription-generated cDNA sequence. A four-step PCR cycle is used that allows the PNA probe to hybridize to the DNA strand at a higher temperature just prior to the primer annealing step.
Analytical Biochemistry, 1999
A specialized form of ion-pair reversed-phase highperformance liquid chromatography is gaining widespread application in mutation detection for single nucleotide polymorphisms (SNP). The technique relies on temperature-modulated heteroduplex analysis (TMHA) by chromatographic separation of partially denatured DNA heteroduplexes from homoduplexes. Here, we demonstrate that fluorescent labeling is compatible with mutation analysis by this form of DNA chromatography and offers advantages over the use of unlabeled DNA fragments. Uniform labeling of wildtype and mutant alleles for TMHA yields peak patterns identical to unlabeled fragments. However, fluorescent labels increase retention times but do not influence resolution of heteroduplexes from homoduplexes. They increase sensitivity and decrease the amount of DNA required for analysis; e.g., in the case presented here, one allele can be detected in the presence of a 500-fold excess of another allele. Furthermore, allele-specific wild-type probes, fluorescently labeled on one strand only, make it possible to selectively monitor specific homoduplexes and wildtype/mutant heteroduplexes. This, in combination with an internal homoduplex standard, greatly reduces the complexity of fluorescence chromatograms compared with chromatograms recorded in the UV. These simplified chromatograms, in which only the internal homoduplex standard and the labeled heteroduplex are detected in the presence of a mutation, greatly facilitate the detection and identification of mutant alleles.
Detection of single base differences using biotinylated nucleotides with very long linker arms
Nucleic Acids Research, 1992
A simple primer extension method for detecting nucleotide differences is based on the substitution of mobility-shifting analogs for natural nucleotides (1). This technique can detect any single-base difference that might occur including previously unknown mutations or polymorphisms. Two technical limitations of the original procedure have now been addressed. First, switching to Thermococcus litoralis DNA polymerase has eliminated variability believed to be due to the addition of an extra, non-templated base to the 3' end of DNA by Taq DNA polymerase. Second, with the analogs used in the original study, the mobility shift induced by a single base change can usually be resolved only in DNA segments 200 nt or smaller. This size limitation has been overcome by synthesizing biotinylated nucleotides with extraordinarily long linker arms (36 atom backbone). Using these new analogs and conventional sequencing gels (0.4 mm thick), mutations in the human ,B-hexosaminidase a and CYP2D6 genes have been detected in DNA segments up to 300 nt in length. By using very thin (0.15 mm) gels, single-base polymorphisms in the human APOE gene have been detected in 500-nt segments.