Detection Of Single-base Mutations Research Articles

Detection of single-base mutation in RNA using T4 RNA ligase-based nick-joining or DNAzyme-based nick-generation

A single nucleotide polymorphism (SNP) is a common genetic variation when a single nucleotide differs between members of a species or paired chromosome. Due to its association with disease susceptibility and drug resistance, SNP detection is of great value in studying the variation in drug responses. Here we present two quantitative SNP detection methods for a single-base mismatch in RNA, based on nick-joining and nick-generating activities of T4 RNA ligase and DNAzyme, respectively. T4 RNA ligase successfully discriminated a one-base mismatch in the ligation junction, and the designed DNAzyme cleaved RNA by discerning a single-base mismatch in the cleaving site.

Detection of Single Base Mutation Causing Drug-resistance in Leukemia Gene by PNA-directed Clamping PCR

(A) Schematic representation of the PCR cycle profile used in PNA-directed clamping PCR. T1: temperature of PNA annealing step (20 sec), T2: temperature of PCR primer annealing step (20 sec). (B) Optimization of T1 for efficient PNA-directed PCR clamping . cDNA was PCR amplified (M: mutant, Bcr-Abl

Designed thiazole orange nucleotides for the synthesis of single labelled oligonucleotides that fluoresce upon matched hybridization

Probe molecules that enable the detection of specific DNA sequences are used in diagnostic and basic research. Most methods rely on the specificity of hybridization reactions, which complicates the detection of single base mutations at low temperature. Significant efforts have been devoted to the development of oligonucleotides that allow discrimination of single base mutations at temperatures where both the match and the mismatch probe-target complexes coexist. Oligonucleotides that contain environmentally sensitive fluorescence dyes such as thiazole orange (TO) provide single nucleotide specific fluorescence. However, most previously reported dye-DNA conjugates showed only little if any difference between the fluorescence of the single and the double stranded state. Here, we introduce a TO-containing acyclic nucleotide, which is coupled during automated oligonucleotide synthesis and provides for the desired fluorescence-up properties. The study reveals the conjugation mode as the most important issue. We show a design that leads to low fluorescence of the unbound probe (background) yet permits TO to adopt fluorescent binding modes after the probe-target complex has formed. In these probes, TO replaces a canonical nucleobase. Of note, the fluorescence of the "TO-base" remains low when a base mismatch is positioned in immediate vicinity.

Ultrasensitive Detection of KRAS2 Mutations in Bile and Serum from Patients with Biliary Tract Carcinoma Using LigAmp Technology

Patients with biliary tract carcinoma have a poor prognosis. Early detection efforts are urgently needed to ameliorate the dismal prognosis for these patients. Mutations of the KRAS2 gene are one of the most common genetic aberrations in this cancer. In this study, we used LigAmp, an ultrasensitive technology for detecting point mutations, to analyze KRAS2 mutations in patients with a variety of neoplastic and non-neoplastic pancreatobiliary diseases. DNA was isolated from 64 samples, including 44 bile samples and 20 serum samples. Oligonucleotides specific for KRAS2 G35A (GAT, G12D), G35T (GTT, G12V), and G34A (AGT, G12S) mutations were used. KRAS2 mutations were detected in 14 of 16 (87.5%) neoplastic bile samples and in 9 of 28 (32.1%) non-neoplastic bile samples. However, the mutation levels were significantly lower in the non-neoplastic bile (median = 0.4%) compared with those in the neoplastic bile (median = 5.1%). KRAS2 mutations were also detected in 9 of 11 (81.8%) serum samples from patients with biliary tract carcinoma, which was further confirmed by cloning BstN1-refractory PCR products and DNA sequencing. However, KRAS2 mutations were not present in the sera from eight patients with benign pancreatobiliary diseases. These data demonstrate that KRAS2 mutations are detectable in both bile and serum using LigAmp. This technology has the potential for early biliary tract carcinoma detection and possibly for residual disease monitoring post-therapy.

Fluorescent DNA Base Modifications and Substitutes: Multiple Fluorophore Labeling and the DETEQ Concept

There is an increasing need for fluorescent nucleic acid probes that are able to sense genetic variations without the application of enzymes. The incorporation of organic fluorophores either as DNA base modifications or as DNA base substitutions represents a powerful and versatile method for such new fluorescent DNA assays. Multiple labeling of oligonucleotides using several adjacent chromophore-modified DNA bases yields fluorescence enhancement and modulation that are sensitive to single-base mismatches in the complementary oligonucleotide. Charge transfer processes that cause fluorescence quenching are DNA-base mediated and occur over several base pairs distance. Our "DETEQ" setup, consisting of a fluorescence DNA base substitution and the charge acceptor as a second modification two base pairs away, allows the homogeneous detection of single-base mutations simply by fluorescence readout. This could lead to new DNA microarrays which are based on charge transfer processes and can be analyzed by commonly used fluorescence readout techniques.

RNA-templated single-base mutation detection based on T4 DNA ligase and reverse molecular beacon

A novel RNA-templated single-base mutation detection method based on T4 DNA ligase and reverse molecular beacon (rMB) has been developed and successfully applied to identification of single-base mutation in codon 273 of the p53 gene. The discrimination was carried out using allele-specific primers, which flanked the variable position in the target RNA and was ligated using T4 DNA ligase only when the primers perfectly matched the RNA template. The allele-specific primers also carried complementary stem structures with end-labels (fluorophore TAMRA, quencher DABCYL), which formed a molecular beacon after RNase H digestion. One-base mismatch can be discriminated by analyzing the change of fluorescence intensity before and after RNase H digestion. This method has several advantages for practical applications, such as direct discrimination of single-base mismatch of the RNA extracted from cell; no requirement of PCR amplification; performance of homogeneous detection; and easily design of detection probes.

Detection of single‐base mutations using 1‐D microfluidic beads array

The application of a 1-D microfluidic beads array that is composed of individually addressable functionalized SiO2 beads has been demonstrated for detection of single-base mutations based on "sandwich" hybridization assay without additional sample labeling and PCR amplification. We concentrated on detection of mutations in the human p53 tumor suppressor gene with more than 50% mutation frequency in the known human cancers. Using a microinjection system, functionalized beads could be selectively and linearly arrayed in a single microfluidic channel comprising many periodic chambers. This 1-D microfluidic beads array was sufficiently sensitive to identify single-nucleotide mutations in 40 pM quantities of DNA targets and could discriminate the mutated alleles in an excess of nonmutated alleles at a level of one mutant in 100 wild-type sequences. The surface of beads was regenerated and rehybridized up to six times without obvious loss of signal. The entire reaction process was done at room temperature within minutes, and only 2-10 microL sample solution was needed to complete the whole detection process. The p53 genotypes of A549, CNE2, and SKBr-3 cell lines were also correctly evaluated by using mRNA extracts as target without need for sample labeling and amplification. Thus, this platform enabled rapid and exact discrimination of gene mutations with the advantages of reusability, simple handling of liquid, low cost, and little reagent consumption.

New cyanine dyes as base surrogates in PNA: Forced intercalation probes (FIT-probes) for homogeneous SNP detection

Forced intercalation probes (FIT-probes) are nucleic acid probes, in which an intercalator cyanine dye such as thiazole orange (TO) serves as a replacement of a canonical nucleobase. These probes signal hybridization by showing strong increases of fluorescence. TO in FIT-probes responds to adjacent base mismatches by attenuation of fluorescence intensities at conditions where both matched and mismatched target DNA are bound. The interesting features of TO labeled FIT-probes posed the question whether the forced intercalation concept can be extended to other cyanine dyes of the thiazole orange family. Herein, we present the synthesis of three asymmetrical cyanine dyes and their incorporation into PNA-conjugates by means of both divergent and linear solid-phase synthesis. Melting analysis revealed that the DNA affinity of PNA probes remained high irrespective of the replacement of a nucleobase by the cyanines YO (oxazole yellow), MO or JO. Of the three new tested dye–PNA-conjugates, the YO-containing PNA has properties useful for homogeneous SNP detection. YO–PNA is demonstrated to signal the presence of fully complementary DNA by up to 20-fold enhancement of fluorescence. In addition, YO emission discriminates against single base mismatches by attenuation of fluorescence. Oxazole yellow (YO) as a base surrogate in PNA may prove useful in the multiplex detection of single base mutations at non-stringent conditions.

An Isothermal Method for Whole Genome Amplification of Fresh and Degraded DNA for Comparative Genomic Hybridization, Genotyping and Mutation Detection

Molecular genotyping has important biomedical and forensic applications. However, limiting amounts of human biological material often yield genomic DNA (gDNA) in insufficient quantity and of poor quality for a reliable analysis. This motivated the development of an efficient whole genome amplification method with quantitatively unbiased representation usable on fresh and degraded gDNA. Amplification of fresh frozen, formalin-fixed paraffin-embedded (FFPE) and DNase-degraded DNA using degenerate oligonucleotide-primed PCR or primer extension amplification using a short primer sequence bioinformatically optimized for coverage of the human genome was compared with amplification using current primers by chromosome-based and BAC-array comparative genomic hybridization (CGH), genotyping at short tandem repeats (STRs) and single base mutation detection. Compared with current primers, genome amplification using the bioinformatically optimized primer was significantly less biased on CGH in self-self hybridizations, and replicated tumour genome copy number aberrations, even from FFPE tissue. STR genotyping could be performed on degraded gDNA amplified using our technique but failed with multiple displacement amplification. Of the 18 different single base mutations 16 (89.5%) were correctly identified by sequencing gDNA amplified from clinical samples using our technique. This simple and efficient isothermal method should be helpful for genetic research and clinical and forensic applications.

Detection of Single-Base Mutations by Fluorogenic Ribonuclease Protection Assay

The ribonuclease protection assay is a generally applicable technique for the detection of known mutations. We have developed a simple and rapid method for mutation detection based on the ribonuclease protection assay using fluorescently labeled oligodeoxyribonucleotide probes. The fluorogenic ribonuclease protection (FRAP) assay uses two differently labeled oligodeoxyribonucleotides, a donor probe and an acceptor probe, to obtain a fluorescence resonance energy transfer (FRET) signal. We have utilized the FRAP assay for the detection of a single-base mutation in the YMDD motif of the hepatic B virus DNA polymerase gene. The occurrence of mismatch-selective RNA cleavage was successfully discriminated by measuring the FRET signal between the donor and acceptor probes. Moreover, mutation sensing was successfully visualized by a UV transillumination. This simple and rapid mutation sensing method should facilitate a high-throughput mutation analysis.

Detection of single‐base mutation by affinity capillary electrophoresis using a DNA‐polyacrylamide conjugate

We have developed an affinity capillary electrophoresis (ACE) method for detection of gene point mutations using a DNA-polyacrylamide conjugate as a pseudostationary affinity phase. In this study, the target DNA was prepared by mixing two PCR products: the wild type of K-ras gene and its codon 12 point mutant. The ligand DNA was designed to be complementary to codons 11 and 12 of the wild type. The target DNA was denatured by the addition of formamide and by heating at 95 degrees C for 5 min, and then electrophoretically separated by difference in affinity to the pseudoimmobilized ligand DNA. The method successfully separated a mixture of the wild-type DNA and each of six codon 12 point mutants by the same ligand DNA. The limit of mutation detection was determined by mixing the wild-type DNA with decreasing concentrations of the mutant DNA. The lowest level of detection was 10% mutant DNA in a background of the wild type. The practicability of this method has been confirmed using a colorectal carcinoma cell line. This study is the first demonstration of detection of gene point mutation in polymerase chain reaction (PCR) products using ACE, and opens up a new possibility of CE-based gene diagnosis.

Label-free THz sensing of genetic sequences: towards 'THz biochips'.

THz-wave-based approaches for the label-free characterization of genetic material are described. Time-resolved THz spectroscopic analysis of genetic sequences (polynucleotides) demonstrate a distinct complex refractive index in the THz frequency range as a function of the binding state of the analysed DNA sequences. By monitoring THz signals, one can thus infer the binding state of oligo- and polynucleotides, enabling the label-free determination of the genetic composition of target polynucleotides by sensing their binding to known probe molecules. Here we review integrated THz sensing array developments exhibiting high sensitivity and single-base mutation detection capabilities. Recent achievements using functionalized biosensing arrays of high-Q resonators are illustrated.

Directed immobilization of nucleic acids at ultramicroelectrodes using a novel electro-deposited polymer

A two-step method for the directed immobilization of nucleic acids at ultramicroelectrodes with micron-size dimensions is described. The approach is based on the immobilization of streptavidin at the surface of carbon or noble metal electrodes within a novel electro-deposited polymer, formed by electropolymerization of the natural compound scopoletin (7-hydroxy-6-methoxy-coumarin) at potentials between 0.4 and 0.7 V vs. Ag/AgCl. Biotin-tagged nucleic acids or proteins are immobilized on top of the modified electrodes in a second step. The new method has some advantages compared to classical electropolymerization approaches (e.g. polypyrrole, polyphenol) , because the growing polymer is highly hydrophilic, resulting in efficient incorporation of streptavidin and a high biotin binding capacity of 6 pmol cm −2. The polymer film seems to be non-conductive but shows good swelling properties in aqueous solutions. The feasibility of the method for the electro-directed biochemical modification of individual microelectrodes has been demonstrated by sequential immobilization of two different single strand oligonucleotides onto interdigitated ultramicroelectrodes. The resulting miniature DNA probe was used for single base mutation detection with two synthetic targets (fluorescence-labeled 17-mer oligomers) by evaluating the fluorescence patterns after hybridisation with the immobilised DNA probes. The new method is useful for the production of microelectrode based DNA chips and for the electro-directed immobilisation of biomolecules at microelectrode structures with high spatial resolution and yield.

A novel microgravimetric DNA sensor with high sensitivity

A novel method using an amplifier with a cantilever and gold nanoparticles successfully to extend the length of the target for the specific and high sensitive detection of DNA was reported. When the size of gold nanoparticle is 50 nm, a sensitivity of 10 −15 M for the single base mutation detection has been achieved.

Integrated THz technology for label-free genetic diagnostics

We report on a promising approach for the label-free analysis of DNA molecules using direct probing of the binding state of DNA with electromagnetic waves at THz frequencies. Passive THz resonator devices based on planar waveguides are used as sample carriers and transducers for THz transmission analysis. In comparison to a formerly used free-space detection scheme, this method provides a drastically enhanced sensitivity enabling analysis down to femtomol levels. We examine the potential of our approach on biologically relevant DNA samples and demonstrate the detection of single base mutations on DNA molecules.

Detection of single-base DNA mutations by enzyme-amplified electronic transduction.

Here we describe a method for the sensitive detection of a single-base mutation in DNA. We assembled a primer thiolated oligonucleotide, complementary to the target DNA as far as one base before the mutation site, on an electrode or a gold-quartz piezoelectric crystal. After hybridizing the target DNA, normal or mutant, with the sensing oligonucleotide, the resulting assembly is reacted with the biotinylated nucleotide, complementary to the mutation site, in the presence of polymerase. The labeled nucleotide is coupled only to the double-stranded assembly that includes the mutant site. Subsequent binding of avidin-alkaline phosphatase to the assembly, and the biocatalyzed precipitation of an insoluble product on the transducer, provides a means to confirm and amplify detection of the mutant. Faradaic impedance spectroscopy and microgravimetric quartz-crystal microbalance analyses were employed for electronic detection of single-base mutants. The lower limit of sensitivity for the detection of the mutant DNA is 1 x 10-14 mol/ml. We applied the method for the analysis of polymorphic blood samples that include the Tay-Sachs genetic disorder. The sensitivity of the method enables the quantitative analysis of the mutant with no PCR pre-amplification.

Detection of a single base substitution in a single cell using the LightCycler™

For known mutations, real time polymerase chain reaction followed by melting curve analysis, using hybridization probes, is highly sensitive, rapid and an efficient approach to mutation detection. We have used this approach on the LightCycler™ for the detection of single base mutations in a single cell, without nested PCR. Hybridization probes were designed for two sequences in the BRCA1 gene containing a single base substitution and deletion, respectively. Polymerase chain reactions of small fragments (100–200 bp) containing the probe sequences were optimized using SYBR Green1, before using hybridization probes. The 5′-probes were 3′-labeled with FITC, whereas the 3′-probes, covering the mutation, were 5′-labeled with LC-Red640 (wild type probes) or LC-Red705 (mutant probes). Dual color detection of wild type and mutant sequences in a single tube was tested on single cells. The reaction mix was prepared in reaction capillaries and a single cell, picked by micromanipulation, was added to this mix. The DNA from the cell is released during the 5-min preheating step of the PCR, using the FastStart hybridization kit (Roche). Reproducible results were obtained, without the need of nested PCR. The technique is useful for microdissected tumors and, with other genes, has great potential for pre-implantation diagnosis in IVF and analysis of residual disease in cancer.

Adaptation of conformation-sensitive gel electrophoresis to an ALFexpress DNA sequencer to screen BRCA1 mutations.

Conformation-sensitive gel electrophoresis (CSGE) has been introduced as the most reliable method for the screening of large and multi-exon genes because of its simplicity, sensitivity and specificity. Based on heteroduplex formation and with the use of mildly denaturing solvents, it allows detection of single-base mutations with accuracy. This is important in genes such as BRCA1 and BRCA2, in which alterations span the entire gene. We have adapted the CSGE assay to a fluorescent platform--a DNA sequencer one-color technology--that reduces the time involved and enhances resolving power for the complete scanning of the BRCA genes. Electrophoresis has high sensitivity and is performed in less than three hours, and the gel does not require staining with ethidium bromide. Eighteen single-base and six frameshift mutations in the BRCA1 gene were analyzed. We compared the manual and fluorescent CSGE methods, and all mutations were detected with accuracy.

Molecular biology in cytopathology: current applications and future directions.

The use of molecular techniques in cytopathology has become an accepted and billable practice for certain applications. Other applications still are in the developmental or experimental stages but may soon be clinically useful. The current study provides a review of these techniques including molecular detection of clonality, in situ hybridization, loss of heterozygosity, and single base mutation detection. A number of new molecular techniques recently have been described that may have a dramatic impact on diagnostic pathology. These techniques, in situ detection of single base mutations and microarray technology, are introduced and discussed in the context of potential applications to cytopathology in the future.

Multichannel Electrochemical Detection System for Quantitative Monitoring of PCR Amplification

AndCare has developed an economical and easy to use Electrochemical Nucleic Acid Detection System that enables ultrasensitive quantification of DNA and RNA directly or after PCR or reverse transcription-PCR amplification of target sequences (1)(2)(3)(4)(5)(6)(7)(8). The system consists of a multichannel pulse monitor and disposable, multielectrode sensor arrays. The simplicity and versatility of the system have been demonstrated in nonamplified and post-PCR assays involving genetic sequences of several pathogens such as Escherichia coli , Salmonella , poliovirus, and Dengue virus. The specificity of the system in detection of single-base mutations has been demonstrated using as models naturally occurring mutations in human genes including BRCA1 , p53 , and β-globin . This report focuses on the ability of the multichannel detection system to quantitatively monitor PCR amplification reactions and to conduct simultaneous measurements of multiple targets in mixtures. The results shown here represent a small sampling of the large volume of experimental data collected over the past 2 years in our laboratory as well as by other researchers using our instrumentation and assays. The AndCare Pulse Monitor was designed to operate using intermittent pulse amperometry (IPA). IPA is a novel, sensitive electrochemical technique developed recently at AndCare for simultaneous and independent measurements of DNA and RNA in multitarget samples using low- or high-density sensor arrays. IPA measurements involve a series of millisecond pulses of constant potential separated by longer periods when the electrode is disconnected from the potentiostat. IPA currents are substantially larger than those measured by conventional DC amperometry. In comparison to differential pulse amperometry, IPA offers more precise and accurate measurement of currents attributable to very low concentrations of one form of a redox couple (mediator) in the presence of large excess of the other form. …