Detection of Terminal Mismatches on DNA Duplexes in Homogeneous Assays or with Immobilized Probes

We recently reported the design of new fluorescent oligo-2′-deoxyribonucleotides (FODNs) for the detection of terminal mismatches on DNA duplexes in homogeneous assays. We now report the validation of this method in homogeneous assays with other sequences and the feasibility of the detection of terminal mismatches with immobilized FODNs. In all cases studied, the mismatched duplexes were more fluorescent than the perfect ones and results confirmed that the discrimination factor is sequence-dependent.     

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.     

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.     

Very stable mismatch duplexes: structural and thermodynamic studies on tandem G.A mismatches in DNA.

We have used ultraviolet melting techniques to compare the stability of several DNA duplexes containing tandem G.A mismatches to similar duplexes containing tandem A.G, I.A, and T.A base pairs. We have found that tandem G.A mismatches in 5'-Y-G-A-R-3' duplexes are more stable than their I.A counterparts and that they are sometimes more stable than tandem 5'-Y-T-A-R-3' sequences. This is not the case for tandem G.A mismatches in other base stacking environments, and it suggests that tandem G.A mismatches in 5'-Y-G-A-R-3' sequences have a unique configuration. In contrast to tandem 5'-G-A-3' mismatches, tandem 5'-A-G-3' mismatches were found to be unstable in all cases examined.     

Mutation detection by electrocatalysis at DNA-modified electrodes

Detection of mutations and damaged DNA bases is important for the early diagnosis of genetic disease. Here we describe an electrocatalytic method for the detection of single-base mismatches as well as DNA base lesions in fully hybridized duplexes, based on charge transport through DNA films. Gold electrodes modified with preassembled DNA duplexes are used to monitor the electrocatalytic signal of methylene blue, a redox-active DNA intercalator, coupled to [Fe(CN)6]3-. The presence of mismatched or damaged DNA bases substantially diminishes the electrocatalytic signal. Because this assay is not a measure of differential hybridization, all single-base mismatches, including thermodynamically stable GT and GA mismatches, can be detected without stringent hybridization conditions. Furthermore, many common DNA lesions and "hot spot" mutations in the human p53 genome can be distinguished from perfect duplexes. Finally, we have demonstrated the application of this technology in a chip-based format. This system provides a sensitive method for probing the integrity of DNA sequences and a completely new approach to single-base mismatch detection.     

RNase HII from Chlamydia pneumoniae discriminates mismatches incorporation into DNA-rN1-DNA/DNA duplexes

It was reported that RNase HII from Chlamydia pneumoniae (CpRNase HII) had RNase H activity on RNA/DNA duplex. We have analyzed the cleavage specificity of CpRNase HII on DNA-rN1-DNA/DNA duplex (rN1, one ribonucleotide). Various mismatches were introduced into the DNA-rN1-DNA/DNA duplexes at or around the ribonucleotide. The mismatches of duplexes resulted in slower cleavage rates compared to the matched duplexes. Furthermore, a greater reduction in cleavage activity was observed for the mismatches located at or adjacent to the ribonucleotide. The mismatches at the same position of DNA-rN1-DNA/DNA duplexes have different impact on the cleavage rates of CpRNase HII depending on the types of mismatches. These findings may offer further insights into the physical binding and catalytic properties of CpRNase HII-substrate interaction.     

Single-base-pair discrimination of terminal mismatches by using oligonucleotide microarrays and neural network analyses.

The effects of single-base-pair near-terminal and terminal mismatches on the dissociation temperature (T(d)) and signal intensity of short DNA duplexes were determined by using oligonucleotide microarrays and neural network (NN) analyses. Two perfect-match probes and 29 probes having a single-base-pair mismatch at positions 1 to 5 from the 5' terminus of the probe were designed to target one of two short sequences representing 16S rRNA. Nonequilibrium dissociation rates (i.e., melting profiles) of all probe-target duplexes were determined simultaneously. Analysis of variance revealed that position of the mismatch, type of mismatch, and formamide concentration significantly affected the T(d) and signal intensity. Increasing the concentration of formamide in the washing buffer decreased the T(d) and signal intensity, and it decreased the variability of the signal. Although T(d)s of probe-target duplexes with mismatches in the first or second position were not significantly different from one another, duplexes with mismatches in the third to fifth positions had significantly lower T(d)s than those with mismatches in the first or second position. The trained NNs predicted the T(d) with high accuracies (R(2) = 0.93). However, the NNs predicted the signal intensity only moderately accurately (R(2) = 0.67), presumably due to increased noise in the signal intensity at low formamide concentrations. Sensitivity analysis revealed that the concentration of formamide explained most (75%) of the variability in T(d)s, followed by position of the mismatch (19%) and type of mismatch (6%). The results suggest that position of the mismatch at or near the 5' terminus plays a greater role in determining the T(d) and signal intensity of duplexes than the type of mismatch.     

Conformational properties of Z-forming DNA oligomers bearing terminal unpaired bases.

Three sets of semi-self-complementary deoxyribonucleotide decamers with the sequence XX-(5meCG)4, (5meCG)4-XX, or Y-(5meCG)4-Y, where XX = AA, CC, GG, or TT and Y = A, C, G, or T, were synthesized along with the self-complementary octamer (5meCG)4. The 8-mer duplex readily undergoes a B-to-Z conformational conversion upon increasing the NaCl concentration with a transitional midpoint of approximately 1.1 M NaCl. The 10-mers should form 8-bp duplexes a with core sequence of [(5meCG)4]2 with 5'-XX overhangs, 3'-XX overhangs, or 5',3'-Y/Y mismatches. Circular dichroism was employed to determine the conformations of all oligomers. Salt titrations were performed to measure the effect of overhangs and terminal mismatches on the B-to-Z conversion. In general, the presence of 5'-XX overhangs results in a transition midpoint equal to or slightly higher than the control, whereas the presence of 3'-XX overhangs results in a transition midpoint slightly lower than the control. The 3'-CC and 5'-GG overhangs are exceptions, with transition midpoints much higher than the control. These oligomers apparently form duplexes with 5',3'-C/C or 5',3'-G/G mismatches abutting a [(G5meC)4]2 duplex core. The presence of terminal mismatches in the third set of oligomers results in transition midpoints higher than the control. Ultraviolet absorbance methods were used to evaluate the effect of the various stacking motifs of the 10-mers on the thermodynamics of melting relative to the 8-mer for both B and Z conformations. We found that in both the B and Z conformations, the presence of an overhang stabilizes the [(5meCG)4]2 duplex, with the 5' overhangs having a greater stabilizing effect relative to the 3' overhangs. The presence of 5',3'-Y/Y mismatches also imparts a stabilizing effect on the control 8-mer in both the B and Z conformations. These results are discussed in terms of stacking interactions of the terminal unpaired 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.     

Thermodynamic and spectroscopic study of bulge loops in oligoribonucleotides

Thermodynamic parameters for bulge loops of one to three nucleotides in oligoribonucleotide duplexes have been measured by optical melting. The results indicate bulges Bn of An and Un have similar stabilities in the duplexes, GCGBmGCG + CGCCGC. The stability increment for a bulge depends on more than its adjacent base pairs. For example, the stability increment for a bulge is affected more than 1 kcal/mol by changing two nonadjacent base pairs or by adding terminal unpaired nucleotides (dangling ends) three base pairs away. Thus a nearest-neighbor approximation for helixes with bulges is oversimplified. Many of the non-self-complementary strands used in this study were observed to form homoduplexes. Such duplexes with GA mismatches were particularly stable.     

Parallel thermodynamic analysis of duplexes on oligodeoxyribonucleotide microchips.

A microchip method has been developed for massive and parallel thermodynamic analyses of DNA duplexes. Fluorescently labeled oligonucleotides were hybridized with oligonucleotides immobilized in the 100 x 100 x 20 mum gel pads of the microchips. The equilibrium melting curves for all microchip duplexes were measured in real time in parallel for all microchip duplexes. Thermodynamic data for perfect and mismatched duplexes that were obtained using the microchip method directly correlated with data obtained in solution. Fluorescent labels or longer linkers between the gel and the oligonucleotides appeared to have no significant effect on duplex stability. Extending the immobilized oligonucleotides with a four-base mixture from the 3'-end or one or two universal bases (5-nitroindole) from the 3'- and/or 5'-end increased the stabilities of their duplexes. These extensions were applied to increase the stabilities of the duplexes formed with short oligonucleotides in microchips, to significantly lessen the differences in melting curves of the AT- and GC-rich duplexes, and to improve discrimination of perfect duplexes from those containing poorly recognized terminal mismatches. This study explored a way to increase the efficiency of sequencing by hybridization on oligonucleotide microchips.     

C5-(1-propynyl)-2'-deoxy-pyrimidines enhance mismatch penalties of DNA:RNA duplex formation

UV melting experiments show that C5-(1-propynyl)ation of seven pyrimidines to give a fully propynylated oligodeoxynucleotide (PrODN) heptamer increases the thermodynamic stability of six Watson-Crick paired DNA:RNA duplexes by 8.2 kcal/mol, on average, at 37 degrees C. About 2.5 kcal/mol of this enhancement is due to long-range cooperativity between the propynylated pyrimidines, Y(p)'s. On average, penalties for dU(p):rG, dC(p):rA, dU(p):rC, and dC(p):rC mismatches are enhanced by 2.9 kcal/mol in PrODN:RNA duplexes over those in unmodified duplexes. This results in penalties as large as 10 kcal/mol for a single mismatch. Removing a single propyne two base pairs away from a mismatch in a PrODN:RNA duplex eliminates the enhancement in specificity. Evidently, enhanced specificity is directly linked to long-range cooperativity between Y(p)'s. In most cases, the enhanced specificity is larger for internal than for terminal mismatches. PrODN:RNA duplexes are destabilized by full phosphorothioate backbone substitution to give S-PrODN:RNA duplexes. The S-PrODN:RNA duplexes retain enhanced mismatch penalties, however. These results provide insight for utilizing long-range cooperativity and enhanced specificity to improve nucleic acid based probe and drug design.     

The influence of locked nucleic acid residues on the thermodynamic properties of 2'-O-methyl RNA/RNA heteroduplexes

The influence of locked nucleic acid (LNA) residues on the thermodynamic properties of 2′-O-methyl RNA/RNA heteroduplexes is reported. Optical melting studies indicate that LNA incorporated into an otherwise 2′-O-methyl RNA oligonucleotide usually, but not always, enhances the stabilities of complementary duplexes formed with RNA. Several trends are apparent, including: (i) a 3′ terminal U LNA and 5′ terminal LNAs are less stabilizing than interior and other 3′ terminal LNAs; (ii) most of the stability enhancement is achieved when LNA nucleotides are separated by at least one 2′-O-methyl nucleotide; and (iii) the effects of LNA substitutions are approximately additive when the LNA nucleotides are separated by at least one 2′-O-methyl nucleotide. An equation is proposed to approximate the stabilities of complementary duplexes formed with RNA when at least one 2′-O-methyl nucleotide separates LNA nucleotides. The sequence dependence of 2′-O-methyl RNA/RNA duplexes appears to be similar to that of RNA/RNA duplexes, and preliminary nearest-neighbor free energy increments at 37°C are presented for 2′-O-methyl RNA/RNA duplexes. Internal mismatches with LNA nucleotides significantly destabilize duplexes with RNA.     

Two strands of DNA are not equivalent as probes in hybridizations at low stringency

Only one of the two complementary strands of a restriction fragment hybridizes under low stringency conditions to a cloned Arabidopsis thaliana genomic DNA fragment. We propose that this effect is caused by the energetic nonequivalence of the two possible mismatched duplexes, resulting from the accumulation of mismatches and extrahelical bases. These mismatches will differ between the two duplexes. The choice of probe strand may therefore be important for the success of heterologous hybridizations utilizing single-stranded probes.     

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.     

Mismatch-containing oligonucleotide duplexes bound by the E. coli mutS-encoded protein.

The binding of the mutS gene product, a protein involved in at least two E. coli mismatch correction pathways, to a series of synthetic DNA duplexes containing mismatches or mismatch analogues of the purine/pyrimidine type was studied in order to establish whether a correlation exists between the recognition of these mispairs and the efficiency of their correction in vivo. Experiments using nitrocellulose filter binding or band-shift assays revealed that duplexes containing a G/T mismatch or its analogues I/T and DI/T were bound by the protein with affinities correlating to the efficiency of their repair in vivo. In contrast, the A/C mismatch, contained within the same sequence, was bound only poorly, despite being efficiently corrected in vivo. The analogues of the A/C mispair, uncorrected in vivo, were not detectably bound under the conditions of these assays.     

2'-O-methyl-modified anti-MDR1 fork-siRNA duplexes exhibiting high nuclease resistance and prolonged silencing activity

The thermodynamic asymmetry of siRNA duplexes determines their silencing activity. Favorable asymmetry can be achieved by incorporation of mismatches into the 3' part of the sense strand, providing fork-siRNAs, which exhibit higher silencing activity and higher sensitivity to nucleases. Recently, we found that selective 2'-O-methyl modifications of the nuclease-sensitive sites of siRNA significantly improve its nuclease resistance without substantial loss of silencing activity. Here, we examined the impact of nucleotide mismatches and the number and location of 2'-O-methyl modifications on the silencing activity and nuclease resistance of anti-MDR1 siRNAs. We found that both nonmodified and selectively modified fork-siRNAs with 4 mismatches at the 3' end of the sense strand suppress the expression of target gene at lower effective concentrations than the parent siRNAs with classical duplex design. The selective modification of nuclease-sensitive sites significantly improved the stability of fork-siRNAs in the presence of serum. The selectively modified fork-siRNA duplexes provided inhibitory effect over a period of 12 days posttransfection, whereas the gene silencing activity of the nonmodified analogs expired within 6 days. Thus, selective chemical modifications and structural alteration of siRNA duplexes improve their silencing properties and significantly prolong the duration of their silencing effect.     

Thermodynamics of single mismatches in RNA duplexes

The thermodynamic properties and structures of single mismatches in short RNA duplexes were studied in optical melting and imino proton NMR experiments. The free energy increments at 37 degrees C measured for non-GU single mismatches range from -2.6 to 1.7 kcal/mol. These increments depend on the identity of the mismatch, adjacent base pairs, and the position in the helix. UU and AA mismatches are more stable close to a helix end, but GG mismatch stability is essentially unaffected by the position in the helix. Approximations are suggested for predicting stabilities of single mismatches in short RNA duplexes.     

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.