Single-base mismatch detection based on charge transduction through DNA

High-throughput DNA sensors capable of detecting single-base mismatches are required for the routine screening of genetic mutations and disease. A new strategy for the electrochemical detection of single-base mismatches in DNA has been developed based upon charge transport through DNA films. Double-helical DNA films on gold surfaces have been prepared and used to detect DNA mismatches electrochemically. The signals obtained from redox-active intercalators bound to DNA-modified gold surfaces display a marked sensitivity to the presence of base mismatches within the immobilized duplexes. Differential mismatch detection was accomplished irrespective of DNA sequence composition and mismatch identity. Single-base changes in sequences hybridized at the electrode surface are also detected accurately. Coupling the redox reactions of intercalated species to electrocatalytic processes in solution considerably increases the sensitivity of this assay. Reporting on the electronic structure of DNA, as opposed to the hybridization energetics of single-stranded oligonucleotides, electrochemical sensors based on charge transport may offer fundamental advantages in both scope and sensitivity.     

Dimer of 2,7-diamino-1,8-naphthyridine for the detection of mismatches formed by pyrimidine nucleotide bases

Discrimination of base mismatches from normal Watson-Crick base pairs in duplex DNA constitutes a key approach to the detection of single nucleotide polymorphisms (SNPs). We have developed a sensor for a surface plasmon resonance (SPR) assay system to detect G-G, A-A, and C-C mismatch duplexes by employing a surface upon which mismatch-binding ligands (MBLs) are immobilized. We synthesized a new MBL consisting of 2,7-diamino-1,8-naphthyridine (damND) and immobilized it onto a CM5 sensor chip to carry out the SPR assay of DNA duplexes containing a single-base mismatch. The SPR sensor with damND revealed strong responses to all C-C mismatches, and sequence-dependent C-T and T-T mismatches. Compared to ND- and naphthyridine-azaquinolone hybrid (NA)-immobilized sensor surfaces, with affinity to mismatches composed of purine nucleotide bases, the damND-immobilized surface was useful for the detection of the mismatches composed of pyrimidine nucleotide bases.     

Digestion of restriction enzyme for the detection of single-base mismatch in DNA

DNA hybridization and enzymatic digestion for the detection of mutation was investigated on the gold nanoparticles-calf thymus DNA (AuNPs-ctDNA) modified glassy carbon electrode (GCE). The thiol modified probe oligonucleotides (SH-ssDNA) were assembled on the surface of AuNPs-ctDNA modified GCE. The electrochemical response of the electrode was measured by differential pulse voltammetry and cyclic voltammetry. Methylene blue (MB) was used as the electroactive indicator. AuNPs were then dispersed effectively on the GCE surface in the presence of ct-DNA. When hybridization occurred, a decrease in the signal of MB current was observed. The modified electrode was used for the detection of mutations during the enzymatic digestion reaction in DNA. During this reaction, an increase in the signal of MB current was observed. So, the modified SH-ssDNA had a higher electrochemical response on the AuNPs-ctDNA/GCE because of the strong affinity of MB for guanine residues in it. The electrochemical detection of restriction enzyme digestion can provide a simple and practical method for observing single-base mismatches that can help in distinguishing mismatch sequences of DNA from the complementary ones.     

A guanine-linked end-effect is a sensitive reporter of charge flow through DNA and RNA double helices

The property of charge (electron hole) flow in DNA duplexes has been the subject of intensive study. RNA-DNA heteroduplexes have also been investigated; however, little information exists on the conductive properties of purely RNA duplexes. In investigating the relative conductive properties of a three molecule DNA-DNA duplex design, using piperidine and aniline to break strands at modified bases, we observed that duplexes with guanine-rich termini generated a large oxidative end-effect, which could serve as a highly sensitive reporter of charge flow through the duplexes. The end-effect was found faithfully to report attenuations in charge flow due to certain single-base mismatches within a duplex. Comparative charge flow experiments on DNA-DNA and RNA-RNA duplexes found large end-effects from both, suggesting that the A and B family of double helices conduct charge comparably. The sheer magnitude of the end-effect, and its high sensitivity to helical imperfections, suggest that it may be exploited as a sensitive reporter for DNA mismatches, as well as a versatile device for studying the structure, folding, and dynamics of complexly folded RNAs and DNAs.     

Detection of single DNA base mutations with mismatch repair enzymes.

A novel method for identifying DNA point mutations has been developed by using mismatch repair enzymes. The high specificity of the Escherichia coli MutY protein has permitted the development of a reliable and sensitive method for the detection and characterization of point mutations in the human genome. The MutY protein is involved in a repair pathway that can convert A/G or A/C mismatches to C/G or G/C basepairs, respectively. A/G or A/C mismatches formed by hybridization between two amplified genomic DNA samples or between specific DNA probes and target DNA are nicked at the mispaired adenine strand by MutY protein. As little as 1% of the mutant sequence can be detected by the mismatch repair enzyme cleavage (MREC) method in a mixture of normal and mutated DNAs (e.g., mutant cells are only present in 1% of the normal cell background). By using different probes, the assay also can determine the nucleotide sequence of the mutation. We have applied this method to detect single-base substitutions in human oncogenes.     

Detection of single-base mismatch at distal end of DNA duplex by electrochemical impedance spectroscopy

Herein, we report an anomalous electrochemical behavior of surface-bound DNA duplex that has single-base mismatches at its distal end. Single-stranded 15-base DNA was immobilized at its 5'end onto gold electrode surfaces. After hybridization with complementary or mismatched DNA, electrochemical impedance spectra were obtained using [Fe(CN)(6)]3-/4- as redox marker ions. Hybridization with the complementary DNA reduced the charge-transfer resistance (R(CT)), whereas single-base mismatches at the distal end of the duplex largely increased the R(CT). This anomaly was found only with the distal end: the increase in R(CT) was not observed for mismatches at either the middle or the proximal end. These results indicate that electrochemical detection of single-base alterations at an end of sample DNA is exceptionally easy because of the diametrically opposite responses. This detection principle is promising for the typing of single-nucleotide polymorphisms in combination with the single-base primer extension protocol.     

Effect of thiazole orange doubly labeled thymidine on DNA duplex formation

Nucleic acid oligonucleotides are widely used in hybridization experiments for specific detection of complementary nucleic acid sequences. For design and application of oligonucleotides, an understanding of their thermodynamic properties is essential. Recently, exciton-controlled hybridization-sensitive fluorescent oligonucleotides (ECHOs) were developed as uniquely labeled DNA oligomers containing commonly one thymidine having two covalently linked thiazole orange dye moieties. The fluorescent signal of an ECHO is strictly hybridization-controlled, where the dye moieties have to intercalate into double-stranded DNA for signal generation. Here we analyzed the hybridization thermodynamics of ECHO/DNA duplexes, and thermodynamic parameters were obtained from melting curves of 64 ECHO/DNA duplexes measured by ultraviolet absorbance and fluorescence. Both methods demonstrated a substantial increase in duplex stability (ΔΔG°(37) ～ -2.6 ± 0.7 kcal mol(-1)) compared to that of DNA/DNA duplexes of the same sequence. With the exception of T·G mismatches, this increased stability was mostly unaffected by other mismatches in the position opposite the labeled nucleotide. A nearest neighbor model was constructed for predicting thermodynamic parameters for duplex stability. Evaluation of the nearest neighbor parameters by cross validation tests showed higher predictive reliability for the fluorescence-based than the absorbance-based parameters. Using our experimental data, a tool for predicting the thermodynamics of formation of ECHO/DNA duplexes was developed that is freely available at http://genome.gsc.riken.jp/echo/thermodynamics/ . It provides reliable thermodynamic data for using the unique features of ECHOs in fluorescence-based experiments.     

Characterization of palindromic loop mismatch repair tracts in mammalian cells

Single- and multi-base (loop) mismatches can arise in DNA by replication errors, during recombination, and by chemical modification of DNA. Single-base and loop mismatches of several nucleotides are efficiently repaired in mammalian cells by a nick-directed, MSH2-dependent mechanism. Larger loop mismatches (> or =12 bases) are repaired by an MSH2-independent mechanism. Prior studies have shown that 12- and 14-base palindromic loops are repaired with bias toward loop retention, and that repair bias is eliminated when five single-base mismatches flank the loop mismatch. Here we show that one single-base mismatch near a 12-base palindromic loop is sufficient to eliminate loop repair bias in wild-type, but not MSH2-defective mammalian cells. We also show that palindromic loop and single-base mismatches separated by 12 bases are repaired independently at least 10% of the time in wild-type cells, and at least 30% of the time in MSH2-defective cells. Palindromic loop and single-base mismatches separated by two bases were never repaired independently. These and other data indicate that loop repair tracts are variable in length. All tracts extend at least 2 bases, some extend <12 bases, and others >12 bases, on one side of the loop. These properties distinguish palindromic loop mismatch repair from the three known excision repair pathways: base excision repair which has one to six base tracts, nucleotide excision repair which has approximately 30 base tracts, and MSH2-dependent mismatch repair, which has tracts that extend for several hundred bases.     

Chemical interrogation of mismatches in DNA-DNA and DNA-RNA duplexes under nonstringent conditions by selective 2'-amine acylation

2'-Amine-substituted nucleotides in hybridized duplexes can be chemically tagged in an acylation reaction that is faster for mismatched or flexible nucleotides than for residues constrained by base pairing. Here we explore mismatch and hybridization detection using probe oligodeoxynucleotides containing single 2'-aminocytidine or -uridine nucleotides annealed to DNA or RNA targets under nonstringent conditions, below T(m). Consistent with a mechanism in which 2'-amine acylation is gated by local nucleotide flexibility, we find that efficient acylation is correlated with formation of weaker or fewer hydrogen bonds in base pair mismatches. Using 2'-aminocytidine-containing probes annealed to both DNA and RNA targets, mismatches are reliably detected as rapid selective acylation of the 2'-amine group in two sequence contexts. For probe oligonucleotides containing 2'-aminouridine residues, good discrimination between U-A base pairs and U-G mismatches could be obtained for DNA-DNA but not for DNA-RNA duplexes upon the introduction of a single 2'-O-Me group 5' to the 2'-amino nucleotide. The 2'-O-Me group introduces a structural perturbation, presumably to a more A-form-like structure, that exaggerates local flexibility at mismatches in DNA strands. Thus, 2'-amine acylation can be used to interrogate all possible mismatches in DNA-DNA duplexes and mismatches involving 2'-amine-substituted cytidine nucleotides in DNA-RNA heteroduplexes. Applications of this chemistry include detecting and chemically proofreading single nucleotide polymorphisms in both DNA and RNA targets and quantifying absolute amounts of RNA.     

Discrimination between perfect and mismatched duplexes with oligonucleotide gel microchips: role of thermodynamic and kinetic effects during hybridization

The efficiency of discrimination between perfect and mismatched duplexes during hybridization on microchips depends on the concentrations of target DNA in solution and immobilized probes, buffer composition, and temperature of hybridization and is determined by both thermodynamic relationships and hybridization kinetics. In this work, optimal conditions of discrimination were studied using hybridization of fluorescently labeled target DNA with custom-made gel-based oligonucleotide microchips. The higher the concentration of immobilized probes and the higher the association constant, the higher the concentration of the formed duplexes and the stronger the corresponding fluorescence signal, but, simultaneously, the longer the time needed to reach equilibrium. Since mismatched duplexes hybridize faster than their perfect counterparts, perfect-to-mismatch signal ratio is lower in transient regime, and short hybridization times may hamper the detection of mutations. The saturation time can be shortened by decreasing the probe concentration or augmenting the gel porosity. This improves the detection of mutations in transient regime. It is shown that the decrease in the initial concentration of oligonucleotide probes by an order of magnitude causes only 1.5-2.5-fold decrease of fluorescence signals after hybridization of perfect duplexes for 3-12 h. At the same time, these conditions improve the discrimination between perfect and mismatched duplexes more than two-fold. A similar improvement may be obtained using an optimized dissociation procedure.     

Kinetics of charge transfer in DNA containing a mismatch

Charge transfer (CT) in DNA offers a unique approach for the detection of a single-base mismatch in a DNA molecule. While the single-base mismatch would significantly affect the CT in DNA, the kinetic basis for the drastic decrease in the CT efficiency through DNA containing mismatches still remains unclear. Recently, we determined the rate constants of the CT through the fully matched DNA, and we can now estimate the CT rate constant for a certain fully matched sequence. We assumed that further elucidating of the kinetics in mismatched sequences can lead to the discrimination of the DNA single-base mismatch based on the kinetics. In this study, we investigated the detailed kinetics of the CT through DNA containing mismatches and tried to discriminate a mismatch sequence based on the kinetics of the CT in DNA containing a mismatch.     

DNA hybridization in nanostructural molecular assemblies enables detection of gene mutations without a fluorescent probe

We have developed a simple single nucleotide polymorphisms (SNPs) analysis utilizing DNA hybridization in nanostructural molecular assemblies. The novel technique enables the detection of a single-base mismatch in a DNA sequence without a fluorescent probe. This report describes for the first time that DNA hybridization occurs in the nanostructural molecular assemblies (termed reverse micelles) formed in an organic medium. The restricted nanospace in the reverse micelles amplifies the differences in the hybridization rate between mismatched and perfectly matched DNA probes. For a model system, we hybridized a 20-mer based on the p53 gene sequence to 20-mer complementary oligonucleotides with various types of mismatches. Without any DNA labeling or electrochemical apparatus, we successfully detected the various oligonucleotide mismatches by simply measuring the UV absorbance at 260 nm.     

Electrochemistry at DNA-modified surfaces: new probes for charge transport through the double helix

Electrochemistry at DNA-modified surfaces provides an alternative approach to photochemistry or radiation biology for studying charge migration through the double helix. Using short duplexes self-assembled onto gold, electrochemical reduction of redox-active reporter molecules has been observed through DNA films more than 50 A thick, with heterogeneous rate constants as great as approximately 100 s(-1). Though apparently insensitive to base content and sequence, even small distortions in the electronic structure of the pi-stack (caused, for example, by single-base mismatches and other DNA lesions) attenuate the rate of electron transport. Understanding the role of conformational dynamics within the double helix, as well as the cooperative effects of self-assembling individual duplexes into ordered superlattices remain important challenges for theory and experiment.     

Rapid photometric detection of thymine residues partially flipped out of double helix as a method for direct scanning of point mutations and apurinic DNA sites

A spectroscopic assay for detection of extrahelical thymine residues in DNA heteroduplexes under their modification by potassium permanganate has been developed. The assay is based on increase in absorbance at 420 nm due to accumulation of thymidine oxidation intermediates and soluble manganese dioxide. The analysis was carried out using a set of 19-bp DNA duplexes containing unpaired thymidines opposite tetrahydrofuranyl derivatives mimicking a widespread DNA damage (apurinic (AP) sites) and a library of 50-bp DNA duplexes containing all types of base mismatches in different surroundings. The relation between the selectivity of unpaired T oxidation and the thermal stability of DNA double helix was investigated. The method described here was shown to discriminate between DNA duplexes with one or two AP sites and to reveal thymine-containing mismatches and all noncanonical base pairs in AT-surroundings. Comparative results of CCM analysis and the rapid photometric assay for mismatch detection are demonstrated for the first time in the same model system. The chemical reactivity of target thymines was shown to correlate with local disturbance of double helix at the mismatch site. As the spectroscopic assay does not require the DNA cleavage reaction and gel electrophoresis, it can be easily automated and used for primary screening of somatic mutations.     

Chemical cleavage of DNA duplexes with single base mismatches as a basis for detection of random point mutations

The most promising approaches to detection of random point mutations are based on chemical cleavage of mismatches and other noncomplementarities. To demonstrate the specificity of this method, a model system was obtained for the first time as sets of 50-mer imperfect DNA duplexes containg all variants of mismatched and unpaired internal residues located in an invariant context and flanked by either A · T or G · C base pairs. Chemical cleavage of DNA duplexes immobilized on magnetic beads via the biotin-streptavidin interaction was accomplished using potassium permanganate or hydroxylamine, which are sensitive to the secondary DNA structure and react with thymine and cytosine, respectively. The reactivity of different mismatches was connected with the local duplex structure and depended on their type, orientation, and flanking nucleotides. The use of potassium permanganate and hydroxylamine to modify a heteroduplex mixture makes it possible to unambiguously detect a mismatch and, based on the type of reagent and the size of the cleavage products, to suppose the type and position of the mismatch and the flanking nucleotides. The model system can be used to evaluate the sensitivity of a chemical cleavage method and to control false-positive and false-negative results when different protocols are applied to the detection of DNA point mutations.     

2'-anthraquinone-conjugated oligonucleotide as an electrochemical probe for DNA mismatch

We previously prepared the oligonucleotides (ODNs) conjugated to an anthraquinone (AQ) group via one carbon linker at the 2'-sugar position. When these modified ODNs bind to cDNA sequences, the AQ moiety can be intercalated into the predetermined base-pair pocket of a duplex DNA. In this paper, 2'-AQ-modified ODNs are shown to be an excellent electrochemical probe to clarify the effect of a mismatch base on the charge transfer (CT) though DNA. Two types of DNA-modified electrodes were constructed by assembly of disulfide-terminated 2'-AQ-ODN duplexes onto gold electrodes. One type of electrodes (system I) contains fully matched base pairs or a single-base mismatch in duplex DNA between the redox center and the electrode. The other (system II) consists of the mismatch but at the outside of the redox center. The modified electrodes were analyzed by cyclic voltammetry to estimate the CT rate through duplex DNA. In system I, the CT rate was found to be approximately 50 s (-1) for the fully matched AQ-ODN duplexes, while the CT rates of the mismatched DNA were considerably slower than that of the fully matched DNA. In system II, the AQ-ODN duplexes showed almost similar CT rates ( approximately 50 s (-1)) for the fully matched DNA and for the mismatched DNAs. The detection of a single-base mismatch was then performed by chronocoulometry (CC). All the DNA duplexes containing a mismatch base in system I gave the reduced electrochemical responses when compared to the fully matched DNA. In particular, the mismatched DNAs including G--A mismatch can be differentiated from fully matched DNA without using any electrochemical catalyst. We further tested the usefulness of single-stranded (ss) AQ-ODN immobilized on a gold electrode in the electrochemical detection of a single-base mismatch through hybridization assay. The ss-AQ-ODN electrodes were immersed in target-containing buffer at room temperature, and the CC measurements were carried out to see the changes in the integrated charge. Within 60 min, the mismatched DNA was clearly distinguishable by the CC differences from the fully matched target. Thus, the electrochemical hybridization assay provides an easy and convenient detection for DNA mutation that does not require any extra reagents, catalyst, target labeling, and washing steps.     

Hybridization of DNA targets to glass-tethered oligonucleotide probes

Hybridization of nucleic acids to surface-tethered oligonucleotide probes has numerous potential applications in genome mapping and DNA sequence analysis. In this article, we describe a simple standard protocol for routine preparation of terminal amine-derivatized 9-mer oligonucleotide arrays on ordinary microscope slides and hybridization conditions with DNA target strands of up to several hundred bases in length with good discrimination against mismatches. Additional linker arms separating the glass surface from the probe sequence are not necessary. The technique described here offers a powerful tool for the detection of specific genetic mutations.     

Molecular breeding of polymerases for amplification of ancient DNA

In the absence of repair, lesions accumulate in DNA. Thus, DNA persisting in specimens of paleontological, archaeological or forensic interest is inevitably damaged. We describe a strategy for the recovery of genetic information from damaged DNA. By molecular breeding of polymerase genes from the genus Thermus (Taq (Thermus aquaticus), Tth (Thermus thermophilus) and Tfl (Thermus flavus)) and compartmentalized self-replication selection, we have evolved polymerases that can extend single, double and even quadruple mismatches, process non-canonical primer-template duplexes and bypass lesions found in ancient DNA, such as hydantoins and abasic sites. Applied to the PCR amplification of 47,000-60,000-year-old cave bear DNA, these outperformed Taq DNA polymerase by up to 150% and yielded amplification products at sample dilutions at which Taq did not. Our results demonstrate that engineered polymerases can expand the recovery of genetic information from Pleistocene specimens and may benefit genetic analysis in paleontology, archeology and forensic medicine.     

Theoretical analysis of the kinetics of DNA hybridization with gel-immobilized oligonucleotides.

A new method of DNA sequencing by hybridization using a microchip containing a set of immobilized oligonucleotides is being developed. A theoretical analysis is presented of the kinetics of DNA hybridization with deoxynucleotide molecules chemically tethered in a polyacrylamide gel layer. The analysis has shown that long-term evolution of the spatial distribution and of the amount of DNA bound in a hybridization cell is governed by "retarded diffusion," i.e., diffusion of the DNA interrupted by repeated association and dissociation with immobile oligonucleotide molecules. Retarded diffusion determines the characteristic time of establishing a final equilibrium state in a cell, i.e., the state with the maximum quantity and a uniform distribution of bound DNA. In the case of cells with the most stable, perfect duplexes, the characteristic time of retarded diffusion (which is proportional to the equilibrium binding constant and to the concentration of binding sites) can be longer than the duration of the real hybridization procedure. This conclusion is indirectly confirmed by the observation of nonuniform fluorescence of labeled DNA in perfect-match hybridization cells (brighter at the edges). For optimal discrimination of perfect duplexes from duplexes with mismatches the hybridization process should be brought to equilibrium under low-temperature nonsaturation conditions for all cells. The kinetic differences between perfect and nonperfect duplexes in the gel allow further improvement in the discrimination through additional washing at low temperature after hybridization.     

Chemical cleavage of DNA with single base mismatches for detection of mutations of unknown localization

The most promising approach for detection of random point mutations relies upon the DNA chemical cleavage near associated mismatching base pairs. In our study, the series of heteroduplexes with all types of mismatches and extrahelical nucleotide residues surrounded by both A x T and G x C pairs were performed via hybridization of 50-mer synthetic oligonucleotides differing in only one nucleotide at the central position. The chemical cleavage of DNA duplexes immobilized on magnetic beads by means of biotin-streptavidin interaction was carried out with chemicals, which able to attack only nucleobases flipped out of the base stack: potassium permanganate and hydroxylamine reacting to T and C respectively. The chemical reactivity of different mismatches was shown to correlate clearly with the target local structure in a particular sequence context. This work makes up for a deficiency in systematic study of DNA cleavage near mismatches in dependence on their type, orientation and flanking nucleotides. The model system elaborated may be applied to estimate the sensitivity of the methodology and to control the possibility of false-positive and false-negative result appearance, when different protocols for detection of DNA mutations are used. The modification of heteroduplex mixtures by potassium permanganate and hydroxylamine allows to reveal any non-canonical base pair and suggest its type and neighboring nucleotides from the nature of chemical as well as its localization from the length of cleavage products.